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有没有大神有opa2662的spice模型,官网上找不到。谢谢

Other Parts Discussed in Thread: OPA656, LMH6624, LMH6601, OPA860, OPA861, OPA615

如题,求解决

  • OPA2662已经在官网搜不到,在代理商那里也买不到了,没有spice模型。
    高速跨阻放大器可以选用OPA656/657.
    有其他引用需求也可以提出来,给您推荐合适的器件。
  • 希望这个文档对你有所帮助,自己建spice吧,有参数的。

    * Library of Burr-Brown Opamps
    * $Revision:   1.28  $
    * $Author:   RPEREZ  $
    * $Date:   25 Mar 1998 08:47:36  $
    *
    **************************************************************************
    *
    *                           WELCOME TO
    *
    *                      BURR-BROWN CORPORATION
    *                  *** BASED MACROMODEL LIBRARY
    *
    *                       6730 S. TUCSON BLVD.
    *                       TUCSON,  AZ  85706
    *                          800-548-6132
    *
    *
    *
    * INTRODUCTION
    * This library is a collection of *** macromodels of BURR-BROWN op amps,
    * difference amps, instrumentation amps, isolation amps, and analog 
    * function circuits. 
    *	
    * The Standard macromodels were derived using standard simulation
    * software. This software uses the common Boyle op amp model structure.
    *	
    * The second level of macromodel is an enhanced version of the standard
    * model, which is indicated by the suffix "E" in the model's name.
    * These models offer improved behaviour in terms of input bias current
    * and quiescent power. Also, voltage and current noise as well
    * as input capacitance is added.
    *
    * The Multiple Pole/Zero macromodels uses the same input stage as the 
    * standard or enhanced op amp macromodel, but has multiple poles and 
    * pole/zero pairs in the mid-section. These models have the designation
    * "M", and are primarily used for wide bandwidth op amps.
    *
    * In some instances, a fourth type of model is available, which are
    * designated by either a "X", "X1" or a "X2" suffix. The models of this
    * level are not a "macromodel", but rather a simplified circuit model
    * at the transistor level.
    *
    * This library is complemented by the application bulletin AB-020F, which
    * contains more information and details on the topologies used. Please write or call 
    * BURR-BROWN at the address and number given above in order to obtain one.
    *
    * APPLICATION INFORMATION
    * This library and the application bulletin are revised frequently.
    * To ensure that you have the most current revision, please contact your
    * nearest sales office or BURR-BROWN directly.
    *
    * Each model net-list starts with a header containing the part number and the 	
    * revision date. The structure of the net-list co
    * Also, the format of the file specification has been changed in order
    * to provide a better and faster overview. The 'date' following the file
    * name now reflects the actual date of creation of each model. The 'time'
    * is now used as an indicator for the revision status of each model. 
    * For example:
    * OPA131E.MOD   1-15-95  1:00:00 am   ---> REV.A
    * OPA121E.MOD   3-21-92  2:00:00 am   ---> REV.B    etc.
    *
    * Happy simulation!!
    *
    *  ------------------------------------------------------------------------ 
    * |  NOTICE: THE INFORMATION PROVIDED HEREIN IS BELIEVED TO BE RELIABLE;   |
    * |  HOWEVER; BURR-BROWN ASSUMES NO RESPONSIBILITY FOR INACCURACIES OR     |
    * |  OMISSIONS.  BURR-BROWN ASSUMES NO RESPONSIBILITY FOR THE USE OF THIS  |
    * |  INFORMATION, AND ALL USE OF SUCH INFORMATION SHALL BE ENTIRELY AT     |
    * |  THE USER'S OWN RISK.  NO PATENT RIGHTS OR LICENSES TO ANY OF THE      |
    * |  CIRCUITS DESCRIBED HEREIN ARE IMPLIED OR GRANTED TO ANY THIRD PARTY.  |
    * |  BURR-BROWN DOES NOT AUTHORIZE OR WARRANT ANY BURR-BROWN PRODUCT FOR   |
    * |  USE IN LIFE-SUPPORT DEVICES AND/OR SYSTEMS.                           |
    *  ------------------------------------------------------------------------ 
    * While reasonable care has been taken in their preparation, we cannot
    * be responsible for correct application on any and all computer
    * systems.
    *
    * Model users are hereby notified that these models are supplied
    * "as is", with no direct or implied responsibility on the part of
    * Burr-Brown for their operation within a customer circuit or system.
    * Further, Burr-Brown Corporation reserves the right to change these
    * models without prior notice.
    *
    * In all cases, the current data sheet information for a given real
    * device is your final design guideline, and is the only actual
    * performance guarantee.
    *$
    **************************************************************************
    * ACF2101M (switched integrator) MULTIPLE POLE/ZERO MACROMODEL
    * Created 2-14-92 BCB
    * REV.B 3/21/92 BCB input bias current correction circuitry added
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |                                                             |
    * |  Neither this library nor any part may be copied without    |
    * |  the express written consent of Burr-Brown Corporation.     |
    * |                                                             |
    * |  The users should carefully note the following factors      |
    * |  regarding this model.                                      |
    * |                                                             |
    * |-------------------------------------------------------------|
    * 
    * NOTES : 
    *    1.  The transient time for the input to the switches (HOLD, 
    *        RESET, and SELECT) should be programmed to 6V/usec.  
    *        Complying with this requirment will give you greater
    *        success in convergence during transient analysis and
    *        a more accurate simulation of the effect of the 200nsec
    *        switching speed of the actual switching transistors in 
    *        the ACF2101.  This is easily implemented with the PULSE
    *        command in ***.  If your input signal to the switches
    *        is faster than recommended above, the R-C, low-pass filter
    *        on the input of the switch will slow the signal down some-
    *        what, however not enough to comply with the data sheet stated
    *        switching speeds of 200nsec.
    *    2.  To insure proper operation, always establish the initial 
    *        bias point for the transient analysis with RESET and 
    *        HOLD equal to the potential at COM
    *
    *                   COMMON
    *                   |   SWITCH IN
    *                   |   |   IN
    *                   |   |   |   CAPACITOR
    *                   |   |   |   |   OUTPUT
    *                   |   |   |   |   |   SWITCH OUT
    *                   |   |   |   |   |   |   SWITCH COMMON
    *                   |   |   |   |   |   |   |   RESET
    *                   |   |   |   |   |   |   |   |   HOLD
    *                   |   |   |   |   |   |   |   |   |   SELECT
    *                   |   |   |   |   |   |   |   |   |   |   POSITIVE SUPPLY
    *                   |   |   |   |   |   |   |   |   |   |   |   NEGATIVE SUPPLY
    *                   |   |   |   |   |   |   |   |   |   |   |   |   GROUND
    *                   |   |   |   |   |   |   |   |   |   |   |   |   |
    .SUBCKT ACF2101M/BB 3  31 2  37 6  32 33 36 34 35 7  4  30
    *
    * Amp input stage (2nd pole @ 35M Hz)
    J11 15  2  14 JX
    J12 16 13  14 JX
    C12 15 16  18.2E-12
    R13 15  7  796
    R14 16  7  796
    ISS 14  4  1.11E-3
    VOS 13  3  0.5E-3
    G1 2 30 POLY(3) (15,2) (14,2) (30,2) 0 1E-12 1E-12 1E-12
    G2 13 30 POLY(3) (16,13) (14,13) (30,13) 0 1E-12 1E-12 1E-12
    * Amp gain stage (130dB) and first pole (@ 4.20K HZ)
    R27  7 21 2.45E9
    R28  4 21 2.45E9
    C22  7 21 100E-12
    C23  4 21 100E-12
    G21  7 21 POLY(1) 15 16 1.751E-3 1.256E-3
    G22 21  4 POLY(1) 16 15 1.751E-3 1.256E-3
    V21 22  3 0.409
    V22 23  4 1.885
    D21 21 22 DX
    D22 23 21 DX
    * Amp correction current and output stage
    IPS   7 30 9E-3
    RPS   7 30 100E3
    R9    7 71 100E3
    R10   4 71 100E3
    D91  21  6 DX
    D92   6 21 DX
    D93   7 94 DX
    D94   7 95 DX
    D95   4 94 DY
    D96   4 95 DY
    G91   7  6 21 7 .020387
    G92   4  6 21 4 .020387
    G95  94  4 6 21 .020387
    G96  95  4 21 6 .020387
    R91   7  6 49.051
    R92   4  6 49.051
    CINT 37  6 CC 100E-12
    * Switches
    SH1 31  2 34 30 SWH
    SH2 31  2 31 30 SWT
    SR   2  6 36 30 SWH
    SS   6 32 35 30 SWS
    SC   3 33 35 30 SWS
    *
    * Models
    .MODEL JX NJF(BETA=.788E-3 VTO=-2 IS=5E-14)
    .MODEL DX D(IS=1E-15)
    .MODEL DY D(IS=1E-15  BV=50)
    .MODEL SWH VSWITCH(RON=1000G ROFF=1.5K VON=2 VOFF=0.8)
    .MODEL SWS VSWITCH(RON=1000G ROFF=250 VON=2 VOFF=0.8)
    .MODEL SWT VSWITCH(RON=1000G ROFF=10 VON=0.45 VOFF=0.55)
    .MODEL CC CAP(VC1=25E-6 TC1=-25E-6)
    .ENDS
    *$
    **************************************************************************
    * BUF600X1 - DIAMOND BUFFER MACROMODEL SIMPLIFIED VERSION
    * CREATED 8/92 KL
    * REV.B  7/9/93 BCB : CLARIFICATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|*
    *
    * NOTE : THIS MACRO MODEL WILL CONVERGE QUICKER BY USING THE 
    *        NODESETS  V(Xyour.21)=+4.2847 AND  V(Xyour.24)=-4.2855 IN THE ROOT
    *        SIMULATION FILE. ("Xyour" IS DEVICE NAME CALLED OUT IN
    *        ROOT SIMULATION FILE.)
    *
    *
    * CONNECTIONS:      POSITIVE POWER SUPPLY
    *                   | VOLTAGE IN
    *                   | | NEGATIVE POWER SUPPLY
    *                   | | | VOLTAGE OUT
    *                   | | | |
    .SUBCKT BUF600X1/BB 1 4 5 8
    *
    C208  8  0 2E-12
    I21  21 24  0.1E-6
    V41   1 41  1.5
    V42  42  5  1.5
    C33  33  0  2E-12
    C39  39  0  0.02E-12
    C40  40  0  0.02E-12
    R33  33  0  6.4E6
    R34  33  4  100
    RQC  22  5  590
    Q21  21 21  1 5  PI
    Q22  21 24 22 1  NI 12
    Q23  24 21  1 5  PI
    Q24  24 24  5 1  NI
    Q29  39 21  1 5  PI
    Q30  40 24  5 1  NI
    Q33   5 33 39 5  PI
    Q34   1 33 40 1  NI
    Q41  41 39  8 1  NIL 16
    Q42  42 40  8 5  PIL 16
    *
    .MODEL PI PNP
    .MODEL NI NPN
    .MODEL NIL NPN (BF = 500)
    .MODEL PIL PNP (BF = 500)
    .ENDS
    *$
    **************************************************************************
    * BUF600X2 - DIAMOND BUFFER MACROMODEL COMPLEX VERSION
    * CREATED 8/92 KL
    * REV.B   7/9/93 BCB : CLARIFICATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : THIS MACROMODEL WILL CONVERGE QUICKER IF THE NODESETS
    *        V(Xyour.21)=+4.2902, V(Xyour.24)=-4.2910, 
    *        V(Xyour.27)=+4.2131  AND 
    *        V(Xyour.28)=-4.2129 IN THE ROOT SIMULATION FILE.
    *        ("Xyour" IS DEVICE NAME CALLED OUT IN ROOT SIMULATION FILE.)
    *
    * CONNECTIONS:      POSITIVE POWER SUPPLY
    *                   | VOLTAGE IN
    *                   | | NEGATIVE POWER SUPPLY
    *                   | | | VOLTAGE OUT
    *                   | | | |
    .SUBCKT BUF600X2/BB 1 4 5 8
    *
    I21  21 24  0.1E-6
    RQC  22  5  730
    C204  4  0  2E-12
    C208  8  0  2E-12
    Q21  21 21  1 5  PI
    Q22  21 24 22 1  NI 12
    Q23  24 21  1 5  PI
    Q24  24 24  5 1  NI
    Q25  28 21  1 5  PI
    Q26  27 24  5 1  NI
    Q27  27 27  1 5  PIJ 1.4
    Q28  28 28  5 1  NIJ 1.4
    Q29  31 27  1 5  PIJ 1.4
    Q30  32 28  5 1  NIJ 1.4
    Q31  31 31 35 1  NIJ 2
    Q32  32 32 36 5  PIJ 2
    Q33  28  4 35 5  PIJ
    Q34  27  4 36 1  NIJ
    Q35  35 35 34 1  NIJ
    Q36  36 36 34 5  PIJ
    Q37   1 31 39 1  NIJ 6
    Q38   5 32 40 5  PIJ 6
    Q39  39 39 41 1  NIJ 6
    Q40  40 40 41 5  PIJ 6
    Q41   1 39  8 1  NIJ 16
    Q42   5 40  8 5  PIJ 16
    *
    .MODEL NI NPN
    .MODEL PI PNP
    .MODEL PIJ PNP
    +(BF = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680
    *
    .MODEL NIJ NPN
    +(BF = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    .ENDS
    *$
    **************************************************************************
    * BUF601X1 - DIAMOND BUFFER MACROMODEL SIMPLIFIED VERSION
    * CREATED 8/92 KL
    * REV.B  7/9/93 BCB : CLARIFICATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : THIS MACROMODEL WILL CONVERGE QUICKER IS THE NODESETS 
    *        V(Xyour.21)=+4.2689 AND  V(Xyour.24)=-4.2697 ARE IN THE 
    *        ROOT SIMULATION FILE. ("Xyour" IS DEVICE NAME IN ROOT
    *        FILE.)
    *
    * CONNECTIONS:      POSITIVE POWER SUPPLY   
    *                   | VOLTAGE IN
    *                   | | NEGATIVE POWER SUPPLY
    *                   | | | VOLTAGE OUT
    *                   | | | |
    .SUBCKT BUF601X1/BB 1 4 5 8
    *
    I21  21 24 0.1E-6
    V41   1 41 1.5
    V42  42 5  1.5
    C33  33 0  2E-12
    C39  39 0  0.04E-12
    C40  40 0  0.04E-12
    C208  8 0  2E-12
    R33  33 0  2.4E6
    R34  33 4  65
    RQC  22 5  320
    Q21  21 21  1 5  PI
    Q22  21 24 22 1  NI 12
    Q23  24 21  1 5  PI
    Q24  24 24  5 1  NI
    Q29  39 21  1 5  PI
    Q30  40 24  5 1  NI
    Q33   5 33 39 5  PI
    Q34   1 33 40 1  NI
    Q41  41 39  8 1  NIL 16
    Q42  42 40  8 5  PIL 16
    *
    .MODEL PI PNP
    .MODEL NI NPN
    .MODEL NIL NPN (BF = 500)
    .MODEL PIL PNP (BF = 500)
    .ENDS
    *$
    **************************************************************************
    * BUF601X2 - DIAMOND BUFFER MACROMODEL COMPLEX VERSION
    * CREATED 8/92 KL
    * REV.B7/9/93 BCB : CLARIFICATION OF NODE SET INSTRUCTIONS.
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : THIS MACROMODEL WILL CONVERGE QUICKER IF THE NODESET
    *        V(Xyour.27)=+4.1907,  V(Xyour.28)=-4.1904, V(Xyour.21)=+4.2689,
    *        AND V(Xyour.24)=-4.2697 ARE INCLUDED IN THE ROOT SIMULATION
    *        FILE. ("Xyour" IS DEVICE CALLED OUT IN ROOT FILE.)
    *
    * CONNECTIONS:      POSITIVE POWER SUPPLY 
    *                   | VOLTAGE IN
    *                   | | NEGATIVE POWER SUPPLY
    *                   | | | VOLTAGE OUT
    *                   | | | |
    .SUBCKT BUF601X2/BB 1 4 5 8
    *
    I21  21 24  0.1E-6
    RQC  22  5  351
    C204  4  0  2E-12
    C208  8  0  2E-12
    Q21  21 21  1 5  PI
    Q22  21 24 22 1  NI 12
    Q23  24 21  1 5  PI
    Q24  24 24  5 1  NI
    Q25  28 21  1 5  PI
    Q26  27 24  5 1  NI
    Q27  27 27  1 5  PIJ 1.4
    Q28  28 28  5 1  NIJ 1.4
    Q29  31 27  1 5  PIJ 1.4
    Q30  32 28  5 1  NIJ 1.4
    Q31  31 31 35 1  NIJ 2
    Q32  32 32 36 5  PIJ 2
    Q33  28  4 35 5  PIJ
    Q34  27  4 36 1  NIJ
    Q35  35 35 34 1  NIJ
    Q36  36 36 34 5  PIJ
    Q37   1 31 39 1  NIJ 6
    Q38   5 32 40 5  PIJ 6
    Q39  39 39 41 1  NIJ 6
    Q40  40 40 41 5  PIJ 6
    Q41   1 39  8 1  NIJ 16
    Q42   5 40  8 5  PIJ 16
    *
    .MODEL PI PNP
    .MODEL NI NPN
    .MODEL PIJ PNP
    +(BF = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *
    .MODEL NIJ NPN
    +(BF = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    .ENDS
    *$
    **************************************************************************
    *  BUF634X SIMPLIFIED CIRCUIT MACROMODEL
    *  CREATED 1/2/95   SB
    *  REV. A
    *
    * CONNECTIONS:       INPUT
    *                    |  POSITIVE POWER SUPPLY
    *                    |  |  NEGATIVE POWER SUPPLY
    *                    |  |  |  OUTPUT
    *                    |  |  |  |   
    .SUBCKT BUF634X/BB   1  80 90 16 
    *
    RIN    1   2    200
    R1     6  13    500
    R2     4   9    500
    RO1   15  16    5
    RO2   16  17    5
    R5    20  90    150
    R6    23  90    12E3
    R7    94  90    60
    R8    98  90    40
    R9    80  85    40
    R10   80  86    60
    CP     1   2    1E-10
    C1    13   0    1.5E-12
    C2     9   0    1.5E-12
    CO    16   0    2E-12 
    Q1     5   2     3   QN 8
    Q2     8   2     7   QP 8
    Q3     4   8    94   QN 8
    Q4     6   5    86   QP 8
    Q5    90   9    10   QP 8
    Q6    80  13    12   QN 8
    Q7    90  10    17   QP 96
    Q8    80  12    15   QN 96
    Q9    22  21    20   QN 2
    Q10    5  21    20   QN 2
    Q11   22  24    80   QP 4
    Q12    8  22    24   QP 4
    D1     3   4         DX 8
    D2    85   5         DX 8
    D3     8  98         DX 8
    D4     6   7         DX 8
    D5    11  10         DX 2
    D6    12  11         DX 2  
    D8    21  23         DX 2
    D9    80  24         DX 4
    D10    7  73         DX 8
    D11   73   3         DX 8
    ISS   80  21    60E-6 
    * Input Errors
    VOS     2  102    30E-3
    IB     80    1    5E-6
    CIN     1    0    6E-12
    * Input Protection Circuit
    R29    2   57  1E3
    R30   16   58  1E3
    Q57   16   57    2   QN  4  
    Q58    2   58   16   QN  4
    V1    16   57    3
    V2     2   58    3
    * Short Circuit Current Protection
    R24   15   14   1.5E3
    R25   14   16   1E3
    R26   16   18   1E3
    R27   18   17   1.5E3
    Q35   86   14   16   QN
    Q36   94   18   16   QP
    *
    .MODEL DX D(IS=8E-16)
    .MODEL QN NPN(IS=1E-15  BF=200) 
    .MODEL QP PNP(IS=1E-15  BF=200)
    .ENDS
    *$
    **************************************************************************
    * BURR-BRN.LIB      LINEAR DIVISION MACROMODEL FILE 
    * REV.A CREATED JUNE 1997 BY NEIL P. ALBAUGH
    * BURR-BRN.SLB      LINEAR DIVISION SYMBOL FILE FOR P-*** DESIGN CENTER(R)OrCad CORP
    * REV.A CREATED JUNE 1997 BY NEIL P. ALBAUGH
    *
    *  ------------------------------------------------------------------------ 
    * |  NOTICE: THE INFORMATION PROVIDED HEREIN IS BELIEVED TO BE RELIABLE;   |
    * |  HOWEVER; BURR-BROWN ASSUMES NO RESPONSIBILITY FOR INACCURACIES OR     |
    * |  OMISSIONS.  BURR-BROWN ASSUMES NO RESPONSIBILITY FOR THE USE OF THIS  |
    * |  INFORMATION, AND ALL USE OF SUCH INFORMATION SHALL BE ENTIRELY AT     |
    * |  THE USER'S OWN RISK.  NO PATENT RIGHTS OR LICENSES TO ANY OF THE      |
    * |  CIRCUITS DESCRIBED HEREIN ARE IMPLIED OR GRANTED TO ANY THIRD PARTY.  |
    * |  BURR-BROWN DOES NOT AUTHORIZE OR WARRANT ANY BURR-BROWN PRODUCT FOR   |
    * |  USE IN LIFE-SUPPORT DEVICES AND/OR SYSTEMS.                           |
    *  ------------------------------------------------------------------------ 
    *
    * INA101 = A1_101 + A2_101 + A3_101 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.A
    *
    * INA101 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SET 1
    *                          |   |   |   |   |   |   |   GAIN SET 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA101/BB          1   2   3   4   5   8   9  10
    *
    * A1_101 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                      2   9   3   4  11   A1_101
    *
    * A2_101 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                      1  10   3   4  12   A2_101
    *
    * A3_101 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_101
    *
    R1    11  13  10.0000K
    R2    13   5   9.9994K
    C2    13   5   0.8000PF
    R3    12  14  10.0000K
    R4    14   8  10.0000K
    RFB1   9  11  20.0000K
    CC1    9  11  15.0000PF
    RFB2  10  12  20.0000K
    CC2   10  12  15.0000PF
    .ENDS
    *
    * A1_101 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 12:56
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_101   1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 70.20E6 -70E6 70E6 70E6 -70E6
    GA    6  0 11 12 320.4E-6
    GCM   0  6 10 99 2.022E-9
    IEE  10  4 DC 30.05E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 3.121E3
    RC2   3 12 3.121E3
    RE1  13 10 1.394E3
    RE2  14 10 1.394E3
    REE  10 99 6.656E6
    RO1   8  5 25
    RO2   7 99 25
    RP    3  4 10.70E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=600)
    .ENDS
    *
    * A2_101 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 11:30
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_101   1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 59.67E6 -60E6 60E6 60E6 -60E6
    GA    6  0 11 12 377.0E-6
    GCM   0  6 10 99 1.192E-9
    IEE  10  4 DC 30.05E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.653E3
    RC2   3 12 2.653E3
    RE1  13 10 926.8
    RE2  14 10 926.8
    REE  10 99 6.656E6
    RO1   8  5 25
    RO2   7 99 25
    RP    3  4 10.70E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=600)
    .ENDS
    *
    * A3_101 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 11:39
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_101   1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 10.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 358.0E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 62.83E-6
    GCM   0  6 10 99 198.7E-12
    IEE  10  4 DC 5.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 15.92E3
    RC2   3 12 15.92E3
    RE1  13 10 5.515E3
    RE2  14 10 5.515E3
    REE  10 99 39.60E6
    RO1   8  5 25
    RO2   7 99 25
    RP    3  4 10.61E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=100)
    .ENDS 
    *$
    **************************************************************************
    * INA101E = A1_101E + A2_101E + A3_101E OP AMPS + PRECISION RESISTOR NETWORK
    * "E" IS ENHANCED MODEL
    * CREATED ON 10/30/90 AT 15:01
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA101E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA101E/BB         1   2   3   4   5   8   9  10
    *
    * A1_101E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                      2   9   3   4  11   A1_101E
    *
    * A2_101E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                      1  10   3   4  12   A2_101E
    *
    * A3_101E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_101E
    *
    R1    11  13  10.0000K
    R2    13   5   9.9994K
    C2    13   5   0.8000PF
    R3    12  14  10.0000K
    R4    14   8  10.0000K
    RFB1   9  11  20.0000K
    CC1    9  11  15.0000PF
    RFB2  10  12  20.0000K
    CC2   10  12  15.0000PF
    *
    .ENDS
    *
    * A1_101E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 12:56
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |  POSITIVE POWER SUPPLY
    *                |   |  | NEGATIVE POWER SUPPLY
    *                |   |  | | OUTPUT
    *                |   |  | | |
    .SUBCKT A1_101E INP INN 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 70.20E6 -70E6 70E6 70E6 -70E6
    GA    6  0 11 12 320.4E-6
    GCM   0  6 10 99 2.022E-9
    IEE  10  4 DC 30.05E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 3.121E3
    RC2   3 12 3.121E3
    RE1  13 10 1.394E3
    RE2  14 10 1.394E3
    REE  10 99 6.656E6
    RO1   8  5 25
    RO2   7 99 25
    *  RP    3  4 10.70E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    ****************************
    * A1_101 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  2.136E-3  1
    FQ2   0  4 POLY(1) VQ2  2.136E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  4.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT PROTECTION
    R1IN  INP 1  1000
    D1IN   1  2  DX
    R2IN  INN 2  1000
    D2IN   2  1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=600)
    .ENDS
    *
    * A2_101E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 11:30
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |  POSITIVE POWER SUPPLY
    *                |   |  | NEGATIVE POWER SUPPLY
    *                |   |  | | OUTPUT
    *                |   |  | | |
    .SUBCKT A2_101E INP INN 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 59.67E6 -60E6 60E6 60E6 -60E6
    GA    6  0 11 12 377.0E-6
    GCM   0  6 10 99 1.192E-9
    IEE  10  4 DC 30.05E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.653E3
    RC2   3 12 2.653E3
    RE1  13 10 926.8
    RE2  14 10 926.8
    REE  10 99 6.656E6
    RO1   8  5 25
    RO2   7 99 25
    *  RP    3  4 10.70E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    ****************************
    * A2_101 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  2.136E-3  1
    FQ2   0  4 POLY(1) VQ2  2.136E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  4.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT PROTECTION
    R1IN  INP 1  1000
    D1IN   1  2  DX
    R2IN  INN 2  1000
    D2IN   2  1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=600)
    .ENDS
    *
    * A3_101E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 11:39
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_101E  1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 10.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 358.0E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 62.83E-6
    GCM   0  6 10 99 198.7E-12
    IEE  10  4 DC 5.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 15.92E3
    RC2   3 12 15.92E3
    RE1  13 10 5.515E3
    RE2  14 10 5.515E3
    REE  10 99 39.60E6
    RO1   8  5 25
    RO2   7 99 25
    *  RP    3  4 10.61E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    ****************************
    * A3_101 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  2.162E-3  1
    FQ2   0  4 POLY(1) VQ2  2.162E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  4.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=100)
    .ENDS
    *$
    **************************************************************************
    * INA102 = A1_102 + A2_102 + A3_102 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.A
    * REV.B 16 June 97 NPA Added Note 1.
    * NOTE 1.USE EXTERNAL RESISTORS TO MODEL PIN-STRAPPED GAINS: Av= 1V/V   RG= OPEN
    *   									       Av= 10V/V  RG=4.44K
    *										 Av= 100V/V RG=404
    *										 Av= 1K V/V RG=40.4
    * UNMODELLED PINS: 1. INTERNAL GAIN RESISTORS
    *			 2. OFFSET NULL
    *			 3. CMR TRIM & FILTER	
    * REV.C  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA102 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |  INVERTING INPUT
    *                          |  |  POSITIVE POWER SUPPLY
    *                          |  |  |  NEGATIVE POWER SUPPLY
    *                          |  |  |  |  OUTPUT
    *                          |  |  |  |  |  REFERENCE
    *                          |  |  |  |  |  |  GAIN SET 1
    *                          |  |  |  |  |  |  |  GAIN SET 2
    *                          |  |  |  |  |  |  |  |
    .SUBCKT INA102/BB          1  2  3  4  5  8  9 10
    *
    * A1_102 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                      2  9  3  4 11  A1_102
    *
    * A2_102 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X2                      1 10  3  4 12  A2_102
    *
    * A3_102 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X3                     14 13  3  4  5  A3_102
    *
    R1    11  13  20.000K
    R2    13   5  19.999K
    C2    13   5   6.000PF
    R3    12  14  20.000K
    R4    14   8  20.000K
    C4    14   8   5.000PF
    RFB1   9  11  20.000K
    CC1    9  11   5.000PF
    RFB2  10  12  20.000K
    CC2   10  12   5.000PF
    *
    .ENDS
    *
    * A1_102 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 15:39
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_102   1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 47.37E6 -50E6 50E6 50E6 -50E6
    GA    6  0 11 12 52.78E-6
    GCM   0  6 10 99 1.053E-9
    IEE  10  4 DC 6.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 18.95E3
    RC2   3 12 18.95E3
    RE1  13 10 10.24E3
    RE2  14 10 10.24E3
    REE  10 99 33.06E6
    RO1   8  5 100
    RO2   7 99 400
    RP    3  4 186.8E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=120)
    .ENDS
    *
    * A2_102 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 15:36
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_102   1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 44.21E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 56.55E-6
    GCM   0  6 10 99 565.5E-12
    IEE  10  4 DC 6.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 17.68E3
    RC2   3 12 17.68E3
    RE1  13 10 8.988E3
    RE2  14 10 8.988E3
    REE  10 99 33.06E6
    RO1   8  5 100
    RO2   7 99 400
    RP    3  4 186.8E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=120)
    .ENDS
    *
    * A3_102 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 15:36
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_102   1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 44.21E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 56.55E-6
    GCM   0  6 10 99 565.5E-12
    IEE  10  4 DC 6.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 17.68E3
    RC2   3 12 17.68E3
    RE1  13 10 8.988E3
    RE2  14 10 8.988E3
    REE  10 99 33.06E6
    RO1   8  5 100
    RO2   7 99 400
    RP    3  4 186.8E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=120)
    .ENDS 
    *$
    **************************************************************************
    * INA102E = A1_102E + A2_102E + A3_102E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.A
    * REV.B 16 June 97 NPA Added Note 1.
    * NOTE 1.USE EXTERNAL RESISTORS TO MODEL PIN-STRAPPED GAINS: Av= 1V/V   RG= OPEN
    *									       Av= 10V/V  RG=4.44K
    *										 Av= 100V/V RG=404
    *										 Av= 1K V/V RG=40.4
    * UNMODELLED PINS: 1. INTERNAL GAIN RESISTORS
    *		       2. OFFSET NULL
    *			 3. CMR TRIM & FILTER	
    * REV.C  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA102E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |  INVERTING INPUT
    *                          |  |  POSITIVE POWER SUPPLY
    *                          |  |  |  NEGATIVE POWER SUPPLY
    *                          |  |  |  |  OUTPUT
    *                          |  |  |  |  |  REFERENCE
    *                          |  |  |  |  |  |  GAIN SET 1
    *                          |  |  |  |  |  |  |  GAIN SET 2
    *                          |  |  |  |  |  |  |  |
    .SUBCKT INA102E/BB         1  2  3  4  5  8  9 10
    *
    * A1_102E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                      2  9  3  4 11  A1_102E
    *
    * A2_102E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X2                      1 10  3  4 12  A2_102E
    *
    * A3_102E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X3                     14 13  3  4  5  A3_102E
    *
    R1    11  13  20.0000K
    R2    13   5  19.9990K
    C2    13   5   6.0000PF
    R3    12  14  20.0000K
    R4    14   8  20.0000K
    C4    14   8   5.0000PF
    RFB1   9  11  20.0000K
    CC1    9  11   5.0000PF
    RFB2  10  12  20.0000K
    CC2   10  12   5.0000PF
    *
    .ENDS
    *
    * A1_102E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 15:39
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_102E  1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 47.37E6 -50E6 50E6 50E6 -50E6
    GA    6  0 11 12 52.78E-6
    GCM   0  6 10 99 1.053E-9
    IEE  10  4 DC 6.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 18.95E3
    RC2   3 12 18.95E3
    RE1  13 10 10.24E3
    RE2  14 10 10.24E3
    REE  10 99 33.06E6
    RO1   8  5 100
    RO2   7 99 400
    *  RP    3  4 186.8E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    ****************************
    * A1_102 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.45E-4  1
    FQ2   0  4 POLY(1) VQ2  1.45E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.0E6
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=120)
    .ENDS
    *
    * A2_102E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 15:39
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_102E  1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 44.21E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 56.55E-6
    GCM   0  6 10 99 565.5E-12
    IEE  10  4 DC 6.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 17.68E3
    RC2   3 12 17.68E3
    RE1  13 10 8.988E3
    RE2  14 10 8.988E3
    REE  10 99 33.06E6
    RO1   8  5 100
    RO2   7 99 400
    *  RP    3  4 186.8E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    ****************************
    * A2_102 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.45E-4  1
    FQ2   0  4 POLY(1) VQ2  1.45E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.0E6
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=120)
    .ENDS
    *
    * A3_102E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/06/90 AT 15:39
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_102E  1 2 3 4 5
    *
    C1   11 12 8.660E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 44.21E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 56.55E-6
    GCM   0  6 10 99 565.5E-12
    IEE  10  4 DC 6.050E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 17.68E3
    RC2   3 12 17.68E3
    RE1  13 10 8.988E3
    RE2  14 10 8.988E3
    REE  10 99 33.06E6
    RO1   8  5 100
    RO2   7 99 400
    *  RP    3  4 186.8E3
    VB    9  0 DC 0
    VC    3 53 DC 2.500
    VE   54  4 DC 2.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    ****************************
    * A3_102 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.45E-4  1
    FQ2   0  4 POLY(1) VQ2  1.45E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.0E6
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=120)
    .ENDS 
    *$
    **************************************************************************
    * INA103 = A1_103 + A2_103 + A3_103 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA103 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA103/BB          1   2   3   4   5   8   9  10
    *
    * A1_103 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_103
    *
    * A2_103 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_103
    *
    * A3_103 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_103
    *
    R1    11  13   6.0000K
    R2    13   5   5.9994K
    C2    13   5   2.0000PF
    R3    12  14   6.0000K
    R4    14   8   6.0000K
    R1FB   9  11   3.0000K
    CC1   17  11  35.0000PF
    R2FB  10  12   3.0000K
    CC2   16  12  35.0000PF
    RCE   17   9   75MEG
    I1     3  16  DC  1.300E-3
    I2     3  17  DC  1.300E-3
    I3    10   4  DC  1.300E-3
    I4     9   4  DC  1.300E-3
    D1    17  15      DX
    D2    16  15      DX
    Q1    16   1  10  QX
    Q2    17   2   9  QX
    V1     3  15  DC  2.000
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_103 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/15/90 AT 13:24
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_103   1 2 3 4 5
    *
    C1   11 12 2.098E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E6 -3E6 3E6 3E6 -3E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 2.987E-9
    ISS   3 10 DC 100.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 5.305E3
    RD2   4 12 5.305E3
    RO1   8  5 20
    RO2   7 99 20
    RP    3  4 14.06E3
    RSS  10 99 2.000E6
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-12 BETA=177.7E-6 VTO=-1)
    .ENDS
    *
    * A2_103 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/13/90 AT 11:47
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_103   1 2 3 4 5
    *
    C1   11 12 2.098E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E6 -3E6 3E6 3E6 -3E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 2.987E-9
    ISS   3 10 DC 100.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 5.305E3
    RD2   4 12 5.305E3
    RO1   8  5 20
    RO2   7 99 20
    RP    3  4 14.06E3
    RSS  10 99 2.000E6
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-12 BETA=177.7E-6 VTO=-1)
    .ENDS
    *
    * A3_103 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/09/90 AT 10:20
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_103   1 2 3 4 5
    *
    C1   11 12 3.356E-12
    C2    6  7 8.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 16.62E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 301.6E-6
    GCM   0  6 10 99 4.780E-9
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 3.316E3
    RD2   4 12 3.316E3
    RO1   8  5 10
    RO2   7 99 10
    RP    3  4 14.06E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 70
    VLN   0 92 DC 70
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-12 BETA=284.3E-6 VTO=-1)
    .ENDS 
    *$
    **************************************************************************
    * INA103E = A1_103E + A2_103E + A3_103E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.B 3/21/92 BCB: added input bias current correction
    * REV.C  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA103E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA103E/BB         1   2   3   4   5   8   9  10
    *
    * A1_103E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_103E
    *
    * A2_103E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_103E
    *
    * A3_103E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_103E
    *
    R1    11  13   6.0000K
    R2    13   5   5.9994K
    C2    13   5   2.0000PF
    R3    12  14   6.0000K
    R4    14   8   6.0000K
    R1FB   9  11   3.0000K
    CC1   17  11  35.0000PF
    R2FB  10  12   3.0000K
    CC2   16  12  35.0000PF
    RCE   17   9  75MEG
    I1     3  16  DC  1.300E-3
    I2     3  17  DC  1.300E-3
    I3    10   4  DC  1.300E-3
    I4     9   4  DC  1.300E-3
    D1    17  15      DX
    D2    16  15      DX
    Q1    16   1  10  QX
    Q2    17   2   9  QX
    V1     3  15  DC  2.000
    C1CM   1   0   2.5PF
    C2CM   2   0   2.5PF
    CDIF   1   2   2.0PF
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_103E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/13/90 AT 14:01
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_103E  1 2 3 4 5
    *
    C1   11 12 2.098E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E6 -3E6 3E6 3E6 -3E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 2.987E-9
    ISS   3 10 DC 100.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 5.305E3
    RD2   4 12 5.305E3
    RO1   8  5 20
    RO2   7 99 20
    *  RP    3  4 14.06E3
    RSS  10 99 2.000E6
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    ****************************
    * A1_103 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.70E-3  1
    FQ2   0  4 POLY(1) VQ2  1.70E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  9.0E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-12 BETA=177.7E-6 VTO=-1)
    .ENDS
    *
    * A2_103E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/13/90 AT 11:47
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_103E  1 2 3 4 5
    *
    C1   11 12 2.098E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E6 -3E6 3E6 3E6 -3E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 2.987E-9
    ISS   3 10 DC 100.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 5.305E3
    RD2   4 12 5.305E3
    RO1   8  5 20
    RO2   7 99 20
    *  RP    3  4 14.06E3
    RSS  10 99 2.000E6
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    ****************************
    * A2_103 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.70E-3  1
    FQ2   0  4 POLY(1) VQ2  1.70E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  9.0E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-12 BETA=177.7E-6 VTO=-1)
    .ENDS
    *
    * A3_103E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/09/90 AT 10:20
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_103E  1 2 3 4 5
    *
    C1   11 12 3.356E-12
    C2    6  7 8.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 16.62E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 301.6E-6
    GCM   0  6 10 99 4.780E-9
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 3.316E3
    RD2   4 12 3.316E3
    RO1   8  5 10
    RO2   7 99 10
    *  RP    3  4 14.06E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 70
    VLN   0 92 DC 70
    ****************************
    * A3_103 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.64E-3  1
    FQ2   0  4 POLY(1) VQ2  1.64E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  9.0E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-12 BETA=284.3E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA105 = A3_105 OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * CREATED ON 08/21/90 AT 12:54
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA105 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |  INVERTING INPUT
    *                          |  |  POSITIVE POWER SUPPLY
    *                          |  |  |  NEGATIVE POWER SUPPLY
    *                          |  |  |  |  OUTPUT
    *                          |  |  |  |  |  REFERENCE
    *                          |  |  |  |  |  |  SENSE
    *                          |  |  |  |  |  |  |
    .SUBCKT INA105/BB          1  2  3  4  5  8  9
    *
    * A3_105 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_105
    *
    R1     2  13   25000
    R2    13   9   24997.5
    C2    13   9   0.1P
    R3     1  14   25000
    R4    14   8   25000
    C1CM  14   0   1.5PF
    C2CM  13   0   1.5PF
    CDIF  14  13   1.5PF
    *
    .ENDS
    *
    * A3_105 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/19/90 AT 11:02
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_105   1 2 3 4 5
    *
    C1   11 12 1.146E-12
    C2    6  7 13.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 10.20E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 163.4E-6
    GCM   0  6 10 99 163.4E-12
    IEE  10  4 DC 39.14E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 6.121E3
    RC2   3 12 6.121E3
    RE1  13 10 4.778E3
    RE2  14 10 4.778E3
    REE  10 99 5.110E6
    RO1   8  5 60
    RO2   7 99 60
    RP    3  4 20.53E3
    VB    9  0 DC 0
    VC    3 53 DC 4.500
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=278.6)
    .ENDS
    *$
    **************************************************************************
    * INA105E = A3_105E OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * "E" IS ENHANCED MODEL
    * CREATED ON 08/28/90 AT 9:50
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA105E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |  INVERTING INPUT
    *                          |  |  POSITIVE POWER SUPPLY
    *                          |  |  |  NEGATIVE POWER SUPPLY
    *                          |  |  |  |  OUTPUT
    *                          |  |  |  |  |  REFERENCE
    *                          |  |  |  |  |  |  SENSE
    *                          |  |  |  |  |  |  |
    .SUBCKT INA105E/BB         1  2  3  4  5  8  9
    *
    * A3_105E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_105E
    *
    R1     2  13   25000
    R2    13   9   24997.5
    C2    13   9   0.1PF
    R3     1  14   25000
    R4    14   8   25000
    C1CM  14   0   1.5PF
    C2CM  13   0   1.5PF
    CDIF  14  13   1.5PF
    *
    .ENDS
    *
    * A3_105E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/09/90 AT 08:58
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_105E  1 2 3 4 5
    *
    C1   11 12 1.146E-12
    C2    6  7 13.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 10.20E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 163.4E-6
    GCM   0  6 10 99 163.4E-12
    IEE  10  4 DC 39.14E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 6.121E3
    RC2   3 12 6.121E3
    RE1  13 10 4.778E3
    RE2  14 10 4.778E3
    REE  10 99 5.110E6
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 20.53E3
    VB    9  0 DC 0
    VC    3 53 DC 4.500
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    ****************************
    * A3_105 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.414E-3  1
    FQ2   0  4 POLY(1) VQ2  1.414E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  6.5E5
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=278.6)
    .ENDS
    *$
    **************************************************************************
    * INA106 = A3_106 OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * CREATED ON 08/21/90 AT 12:54
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA106 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |  INVERTING INPUT
    *                          |  |  POSITIVE POWER SUPPLY
    *                          |  |  |  NEGATIVE POWER SUPPLY
    *                          |  |  |  |  OUTPUT
    *                          |  |  |  |  |  REFERENCE
    *                          |  |  |  |  |  |  SENSE
    *                          |  |  |  |  |  |  |
    .SUBCKT INA106/BB          1  2  3  4  5  8  9
    *
    * A3_106 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_106
    *
    R1     2  13   10.0000K
    R2    13   9  100.0100K
    C2    13   9    0.1000PF
    R3     1  14   10.0000K
    R4    14   8  100.0000K
    C1CM  14   0    1.5PF
    C2CM  13   0    1.5PF
    CDIF  14  13    1.5PF
    *
    .ENDS
    *
    * A3_106 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/18/90 AT 13:55
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_106   1 2 3 4 5
    *
    C1   11 12 9.283E-12
    C2    6  7 13.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.081E6 -4E6 4E6 4E6 -4E6
    GA    6  0 11 12 408.4E-6
    GCM   0  6 10 99 408.4E-12
    IEE  10  4 DC 39.14E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.449E3
    RC2   3 12 2.449E3
    RE1  13 10 1.118E3
    RE2  14 10 1.118E3
    REE  10 99 5.110E6
    RO1   8  5 60
    RO2   7 99 60
    RP    3  4 20.53E3
    VB    9  0 DC 0
    VC    3 53 DC 4.500
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=278.6)
    .ENDS
    *$
    **************************************************************************
    * INA106E = A3_106E OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * "E" IS ENHANCED MODEL
    * CREATED ON 08/28/90 AT 9:50
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA106E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |  INVERTING INPUT
    *                          |  |  POSITIVE POWER SUPPLY
    *                          |  |  |  NEGATIVE POWER SUPPLY
    *                          |  |  |  |  OUTPUT
    *                          |  |  |  |  |  REFERENCE
    *                          |  |  |  |  |  |  SENSE
    *                          |  |  |  |  |  |  |
    .SUBCKT INA106E/BB         1  2  3  4  5  8  9
    *
    * A3_106E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_106E
    *
    R1     2  13   10000
    R2    13   9   100010
    C2    13   9   0.1PF
    R3     1  14   10000
    R4    14   8   100000
    C1CM  14   0   1.5PF
    C2CM  13   0   1.5PF
    CDIF  14  13   1.5PF
    *
    .ENDS
    *
    * A3_106E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/09/90 AT 08:58
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_106E  1 2 3 4 5
    *
    C1   11 12 9.283E-12
    C2    6  7 13.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.081E6 -4E6 4E6 4E6 -4E6
    GA    6  0 11 12 408.4E-6
    GCM   0  6 10 99 408.4E-12
    IEE  10  4 DC 39.14E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.449E3
    RC2   3 12 2.449E3
    RE1  13 10 1.118E3
    RE2  14 10 1.118E3
    REE  10 99 5.110E6
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 20.53E3
    VB    9  0 DC 0
    VC    3 53 DC 4.500
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    ****************************
    * A3_106 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.414E-3  1
    FQ2   0  4 POLY(1) VQ2  1.414E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  6.5E5
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=278.6)
    .ENDS
    *$
    **************************************************************************
    * INA110 = A1_110 + A2_110 + A3_110 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.B 1/6/93   BCB :Removed Gain Set 1 and Gain Set 2 pins from model 
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA110 SUB-CIRCUIT
    * CONNECTIONS:            NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    *		           	   |   |   |   |   |   |   |   |
    *			         |   |   |   |   |   |   |   |
    .SUBCKT INA110/BB          1   2   3   4   5   8   9  10
    *
    * A1_110 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_110
    *
    * A2_110 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_110
    *
    * A3_110 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_110
    *
    R1    11  13  10.0000K
    R2    13   5   9.9995K
    C2    13   5   6.0000PF
    R3    12  14  10.0000K
    R4    14   8  10.0000K
    C4    14   8   5.0000PF
    R1FB   9  11  20.0000K
    CC1   17  11   5.0000PF
    R2FB  10  12  20.0000K
    CC2   16  12   5.0000PF
    RCE   17   9   400MEG
    I1     3  16  DC  50.00E-6
    I2     3  17  DC  50.00E-6
    I3    10   4  DC  50.00E-6
    I4     9   4  DC  50.00E-6
    I5     3  21  DC 200.00E-6
    I6     3  22  DC 200.00E-6
    CG1    9   0  30.0000PF
    CG2   10   0  20.0000PF
    D1    17  15      DX
    D2    16  15      DX
    Q1    16  21  10  QX
    Q2    17  22   9  QX
    J1     4   1  21  JX
    J2     4   2  22  JX
    V1     3  15  DC  3.000
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .MODEL JX PJF(IS=10.00E-12 BETA=500.0E-6 VTO=-1)
    .ENDS
    *
    * A1_110 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/14/90 AT 11:10
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_110   1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A2_110 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/14/90 AT 11:12
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_110   1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A3_110 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/14/90 AT 12:59
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_110   1 2 3 4 5
    *
    C1   11 12 7.151E-12
    C2    6  7 12.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 27.96E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 377.0E-6
    GCM   0  6 10 99 1.889E-9
    ISS   3 10 DC 240.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 2.653E3
    RD2   4 12 2.653E3
    RO1   8  5 30
    RO2   7 99 30
    RP    3  4 37.50E3
    RSS  10 99 833.3E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=296.0E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA110E = A1_110E + A2_110E + A3_110E OP AMPS + PRECISION RESISTOR NETWORK
    * "E" IS ENHANCED MODEL
    * CREATED ON 10/30/90 AT 15:01
    * REV.B 3/21/92 BCB added input bias current correction
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA110E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA110E/BB         1   2   3   4   5   8   9  10
    *
    * A1_110E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_110E
    *
    * A2_110E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_110E
    *
    * A3_110E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_110E
    *
    R1    11  13  10.0000K
    R2    13   5   9.9995K
    C2    13   5   6.0000PF
    R3    12  14  10.0000K
    R4    14   8  10.0000K
    C4    14   8   5.0000PF
    R1FB   9  11  20.0000K
    CC1   17  11   5.0000PF
    R2FB  10  12  20.0000K
    CC2   16  12   5.0000PF
    RCE   17   9   400MEG
    I1     3  16  DC  50.00E-6
    I2     3  17  DC  50.00E-6
    I3    10   4  DC  50.00E-6
    I4     9   4  DC  50.00E-6
    I5     3  21  DC 200.00E-6
    I6     3  22  DC 200.00E-6
    CG1    9   0  30.0000PF
    CG2   10   0  20.0000PF
    D1    17  15      DX
    D2    16  15      DX
    Q1    16  21  10  QX
    Q2    17  22   9  QX
    J1     4   1  21  JX
    J2     4   2  22  JX
    G11  1 4 POLY(2) (21,1) (4,1) 0 1E-12 1E-12
    G21  2 4 POLY(2) (22,2) (4,2) 0 1E-12 1E-12
    V1     3  15  DC  3.000
    C1CM   1   0   1.0PF
    C2CM   2   0   1.0PF
    CDIF   1   2   6.0PF
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .MODEL JX PJF(IS=5.00E-12 BETA=500.0E-6 VTO=-1)
    .ENDS
    *
    * A1_110E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/14/90 AT 11:10
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_110E  1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    ****************************
    * A1_110 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.16E-4  1
    FQ2   0  4 POLY(1) VQ2  4.16E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A2_110E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/14/90 AT 11:12
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_110E  1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    ****************************
    * A2_110 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.16E-4  1
    FQ2   0  4 POLY(1) VQ2  4.16E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A3_110E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/14/90 AT 12:59
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_110E  1 2 3 4 5
    *
    C1   11 12 7.151E-12
    C2    6  7 12.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 27.96E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 377.0E-6
    GCM   0  6 10 99 1.889E-9
    ISS   3 10 DC 240.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 2.653E3
    RD2   4 12 2.653E3
    RO1   8  5 30
    RO2   7 99 30
    *  RP    3  4 37.50E3
    RSS  10 99 833.3E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    ****************************
    * A3_110 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.264E-4  1
    FQ2   0  4 POLY(1) VQ2  4.264E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=296.0E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA111 = A1_111 + A2_111 + A3_111 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 12/1/92 AT 10:00 HB
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA111 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA111/BB          1   2   3   4   5   8   9  10
    *
    * A1_111 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_111
    *
    * A2_111 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_111
    *
    * A3_111 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_111
    *
    R1    11  13   10.0000E3
    R3    12  14   10.0000E3
    R2    13   5    9.9993E3
    R4    14   8   10.0000E3
    C2    13   5    6.0000E-12
    C4    14   8    5.0000E-12
    R1FB   9  11   25.0000E3
    R2FB  10  12   25.0000E3
    CC1   17  11   5.0000E-12
    CC2   16  12   5.5000E-12
    RCE   17   9   400E6
    I1     3  16  DC  50.00E-6
    I2     3  17  DC  50.00E-6
    I3    10   4  DC  50.00E-6
    I4     9   4  DC  50.00E-6
    I5     3  21  DC 200.00E-6
    I6     3  22  DC 200.00E-6
    CG1    9   0  13.5000E-12
    CG2   10   0  12.0000E-12
    D1    17  15      DX
    D2    16  15      DX
    Q1    16  21  10  QX
    Q2    17  22   9  QX
    J1     4   1  21  JX
    J2     4   2  22  JX
    V1     3  15  DC  3.000
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .MODEL JX PJF(IS=10.00E-12 BETA=500.0E-6 VTO=-1)
    .ENDS
    *
    * A1_111 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_111   1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A2_111 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_111   1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A3_111 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_111   1 2 3 4 5
    *
    C1   11 12 7.151E-12
    C2    6  7 12.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 27.96E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 377.0E-6
    GCM   0  6 10 99 1.889E-9
    ISS   3 10 DC 240.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 2.653E3
    RD2   4 12 2.653E3
    RO1   8  5 30
    RO2   7 99 30
    RP    3  4 37.50E3
    RSSS  10 99 833.3E3
    VB    9  0 DC 0
    VC    3 53 DC 2.300
    VE   54  4 DC 2.300
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=296.0E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA111E = A1_111E + A2_111E + A3_111E OP AMPS + PRECISION RESISTOR NETWORK
    * "E" IS ENHANCED MODEL
    * CREATED ON 12/1/92 AT 10:00 HB
    * REV.A
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |                                                             |
    * |  Neither this library nor any part may be copied without    |
    * |  the express written consent of Burr-Brown Corporation.     |
    * |                                                             |
    * |-------------------------------------------------------------|
    *
    * INA111E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA111E/BB         1   2   3   4   5   8   9  10
    *
    * A1_111E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_111E
    *
    * A2_111E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_111E
    *
    * A3_111E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_111E
    *
    R1    11  13   10.0000E3
    R3    12  14   10.0000E3
    R2    13   5    9.9993E3
    R4    14   8   10.0000E3
    C2    13   5    6.0000E-12
    C4    14   8    5.0000E-12
    R1FB   9  11   25.0000E3
    R2FB  10  12   25.0000E3
    CC1   17  11    5.0000E-12
    CC2   16  12    5.5000E-12
    RCE   17   9   400E6
    I1     3  16  DC  50.00E-6
    I2     3  17  DC  50.00E-6
    I3    10   4  DC  50.00E-6
    I4     9   4  DC  50.00E-6
    I5     3  21  DC 200.00E-6
    I6     3  22  DC 200.00E-6
    CG1    9   0   13.5000E-12
    CG2   10   0   12.0000E-12
    D1    17  15      DX
    D2    16  15      DX
    Q1    16  21  10  QX
    Q2    17  22   9  QX
    J1     4   1  21  JX
    J2     4   2  22  JX
    V1     3  15  DC  3.000
    C1CM   1   0    1.0E-12
    C2CM   2   0    1.0E-12
    CDIF   1   2    6.0E-12
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .MODEL JX PJF(IS=10.00E-12 BETA=500.0E-6 VTO=-1)
    .ENDS
    *
    * A1_111E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_111E  1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    ****************************
    * A1_111 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.16E-4  1
    FQ2   0  4 POLY(1) VQ2  4.16E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A2_111E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_111E  1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    ****************************
    * A2_111 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.16E-4  1
    FQ2   0  4 POLY(1) VQ2  4.16E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A3_111E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_111E  1 2 3 4 5
    *
    C1   11 12 7.151E-12
    C2    6  7 12.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 27.96E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 377.0E-6
    GCM   0  6 10 99 1.889E-9
    ISS   3 10 DC 240.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 2.653E3
    RD2   4 12 2.653E3
    RO1   8  5 30
    RO2   7 99 30
    *  RP    3  4 37.50E3
    RSSS  10 99 833.3E3
    VB    9  0 DC 0
    VC    3 53 DC 2.300
    VE   54  4 DC 2.300
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    ****************************
    * A3_111 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.264E-4  1
    FQ2   0  4 POLY(1) VQ2  4.264E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=296.0E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA111Z = A1_111Z + A2_111Z + A3_111Z OP AMPS + PRECISION RESISTOR NETWORK
    * "Z" IS ENHANCED MODEL
    * CREATED ON 12/1/92 AT 10:00 HB
    * REV.A
    * REV.B  13 June 97 NPA: Changed "E" to "Z" to correct run error
    * REV.C  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA111Z SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |   REFERENCE
    *                       |   |   |   |   |   |   GAIN SENSE 1
    *                       |   |   |   |   |   |   |   GAIN SENSE 2
    *                       |   |   |   |   |   |   |   |
    .SUBCKT INA111Z/BB      1   2   3   4   5   8   9  10
    *
    * A1_111Z SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_111Z
    *
    * A2_111Z SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_111Z
    *
    * A3_111Z SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_111Z
    *
    R1    11  13   10.0000E3
    R3    12  14   10.0000E3
    R2    13   5    9.9993E3
    R4    14   8   10.0000E3
    C2    13   5    6.0000E-12
    C4    14   8    5.0000E-12
    R1FB   9  11   25.0000E3
    R2FB  10  12   25.0000E3
    CC1   17  11    5.0000E-12
    CC2   16  12    5.5000E-12
    RCE   17   9    400E6
    I1     3  16  DC  50.00E-6
    I2     3  17  DC  50.00E-6
    I3    10   4  DC  50.00E-6
    I4     9   4  DC  50.00E-6
    I5     3  21  DC 200.00E-6
    I6     3  22  DC 200.00E-6
    CG1    9   0   13.5000E-12
    CG2   10   0   12.0000E-12
    D1    17  15       DX
    D2    16  15       DX
    Q1    16  21   10  QX
    Q2    17  22    9  QX
    J1     4   1   21  JX
    J2     4   2   22  JX
    V1     3  15  DC  3.000
    C1CM   1   0    1.0E-12
    C2CM   2   0    1.0E-12
    CDIF   1   2    6.0E-12
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .MODEL JX PJF(IS=10.00E-12 BETA=500.0E-6 VTO=-1)
    .ENDS
    *
    * A1_111Z OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "Z" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_111Z  1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    ****************************
    * A1_111 "Z" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.16E-4  1
    FQ2   0  4 POLY(1) VQ2  4.16E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A2_111Z OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "Z" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_111Z  1 2 3 4 5
    *
    C1   11 12 1.443E-12
    C2    6  7 5.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E3 -3E3 3E3 3E3 -3E3
    GA    6  0 11 12 628.3E-6
    GCM   0  6 10 99 6.283E-6
    ISS   3 10 DC 250.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.592E3
    RD2   4 12 1.592E3
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 37.50E3
    RSS  10 99 800.0E3
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 60
    VLN   0 92 DC 60
    ****************************
    * A2_111 "Z" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.16E-4  1
    FQ2   0  4 POLY(1) VQ2  4.16E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=789.5E-6 VTO=-1)
    .ENDS
    *
    * A3_111Z OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "Z" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/1/92 AT 10:00
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_111Z  1 2 3 4 5
    *
    C1   11 12  7.151E-12
    C2    6  7 12.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 27.96E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 377.0E-6
    GCM   0  6 10 99 1.889E-9
    ISS   3 10 DC 240.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 2.653E3
    RD2   4 12 2.653E3
    RO1   8  5 30
    RO2   7 99 30
    *  RP    3  4 37.50E3
    RSSS  10 99 833.3E3
    VB    9  0 DC 0
    VC    3 53 DC 2.300
    VE   54  4 DC 2.300
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    ****************************
    * A3_111 "Z" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.264E-4  1
    FQ2   0  4 POLY(1) VQ2  4.264E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.25E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=296.0E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA114 = A1_114 + A2_114 + A3_114 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 1/30/92 AT 4:30PM
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    * 
    * NOTE:  THE OUTPUT PERFORMANCE OF THIS MACRO MODEL WILL BE ERRONEOUS IF
    *        NODE 6 (FEEDBACK) IS NOT CONNECTED PROPERLY.
    *
    * INA114 SUB-CIRCUIT
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |   INVERTING INPUT
    *                    |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   |   OUTPUT
    *                    |   |   |   |   |   FEEDBACK
    *                    |   |   |   |   |   |    REFERENCE
    *                    |   |   |   |   |   |   |   GAIN SET 1
    *                    |   |   |   |   |   |   |   |   GAIN SET 2
    *                    |   |   |   |   |   |   |   |   |
    .SUBCKT INA114/BB    1   2   3   4   5   6   8   9   10
    *
    * A1_114 SUBCIRCUIT
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X1                2   9   3   4   11   A1_114
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X2                1   10  3   4   12   A2_114
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X3                14  13  3   4   5   A3_114
    *
    R1   11 13 25K
    R2   13  6 24.9985K
    C2   13  6 5P
    R3   12 14 25K
    R4   14  8 25K
    RFB1  9 11 25K
    CC1   9 11 5P
    RFB2 10 12 25K
    CC2  10 12 5P
    *
    .ENDS
    *
    * A1_114 OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:21
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_114   1 2 3 4 5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB   7  99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA   6   0 11 12 188.5E-6
    GCM  0   6 10 99 188.5E-12
    IEE 10   4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1  11   2 13 QX
    Q2  12   1 14 QX
    R2   6   9 100.0E3
    RC1  3  11 5.305E3
    RC2  3  12 5.305E3
    RE1 13  10 4.348E3
    RE2 14  10 4.348E3
    REE 10  99 7.4074E6
    RO1  8   5 40
    RO2  7  99 320
    RP   3   4 52.53E3
    VB   9   0 DC 0
    VC   3  53 DC 1.672
    VE  54   4 DC 1.672
    VLIM 7   8 DC 0
    VLP 91   0 DC 2
    VLN  0  92 DC 2
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3)
    .ENDS
    *
    * A2_114 OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:30
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_114   1 2 3 4 5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 188.5E-12
    IEE  10  4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 5.305E3
    RC2   3 12 5.305E3
    RE1  13 10 4.318E3
    RE2  14 10 4.348E3
    REE  10 99 7.4074E6
    RO1   8  5 40
    RO2   7 99 320
    RP    3  4 52.53E3
    VB    9  0 DC 0
    VC    3 53 DC 1.672
    VE   54  4 DC 1.672
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3)
    .ENDS
    *
    * A3_114 OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:46
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_114   1 2 3 4 5
    *
    C1   11 12 13.51E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 251.9E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 339.3E-6
    GCM   0  6 10 99 339.3E-12
    IEE  10  4 DC 18E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.947E3
    RC2   3 12 2.947E3
    RE1  13 10 74.778
    RE2  14 10 74.778
    REE  10 99 11.111E6
    RO1   8  5 13
    RO2   7 99 117
    RP    3  4 30.123E3
    VB    9  0 DC 0
    VC    3 53 DC 1.972
    VE   54  4 DC 1.972
    VLIM  7  8 DC 0
    VLP  91  0 DC 12
    VLN   0 92 DC 12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=30.00E3)
    .ENDS
    *$
    **************************************************************************
    * INA114E = A1_114E + A2_114E + A3_114E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 1/30/92 AT 4:30PM
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * NOTE:  THE OUTPUT PERFORMANCE OF THE MACRO MODEL WILL BE ERRONEOUS IF
    *        NODE 6 (FEEDBACK) IS NOT CONNECTED PROPERLY.
    * 
    * INA114E SUB-CIRCUIT
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |   INVERTING INPUT
    *                    |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   |   OUTPUT
    *                    |   |   |   |   |   FEEDBACK
    *                    |   |   |   |   |   |    REFERENCE
    *                    |   |   |   |   |   |   |   GAIN SET 1
    *                    |   |   |   |   |   |   |   |   GAIN SET 2
    *                    |   |   |   |   |   |   |   |   |
    .SUBCKT INA114E/BB   1   2   3   4   5   6   8   9   10
    *
    * A1_114E SUBCIRCUIT
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X1                2   9   3   4   11   A1_114E
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X2                1   10  3   4   12   A2_114E
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X3                14  13  3   4   5   A3_114E
    *
    R1   11 13 25K
    R2   13  6 24.9985K
    C2   13  6 5P
    R3   12 14 25K
    R4   14  8 25K
    RFB1  9 11 25K
    CC1   9 11 5P
    RFB2 10 12 25K
    CC2  10 12 5P
    *
    .ENDS
    *
    * A1_114E OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:21
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |   POSITIVE POWER SUPPLY
    *                |   |   |   NEGATIVE POWER SUPPLY
    *                |   |   |   |   OUTPUT
    *                |   |   |   |   |
    .SUBCKT A1_114E  1   2   3   4   5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 188.5E-12
    IEE  10  4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 5.305E3
    RC2   3 12 5.305E3
    RE1  13 10 4.348E3
    RE2  14 10 4.348E3
    REE  10 99 7.4074E6
    RO1   8  5 40
    RO2   7 99 320
    VB    9  0 DC 0
    VC    3 53 DC 1.672
    VE   54  4 DC 1.672
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    ****************************
    * A1_114E "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0
    FQ1  3  0 POLY(1) VQ1 0 1
    FQ2  0  4 POLY(1) VQ2 0 -1
    * QUIESCIENT CURRENT
    RQ 3 4 52.53E3
    * DIFF INPUT CAPACITANCE
    CDIF 1 2 3E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM 1 0 3E-12
    C2CM 2 0 3E-12
    * INPUT PROTECTION
    VS11  3 31 0
    FS11  0  3 VS11 1
    S11  31  0 1 0 SP
    FS12  1  4 VS11 1
    VS21 32  4 0
    FS21  4  0 VS21 1
    S21   0 32 1 0 SM
    FS22  3  1 VS21 1
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3 NC=100 NR=100)
    .MODEL SP VSWITCH(RON=10K ROFF=100G VON=15.6 VOFF=15.5)
    .MODEL SM VSWITCH(RON=10K ROFF=100G VON=-15.6 VOFF=-15.5)
    .ENDS
    *
    * A2_114E OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:30
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |   POSITIVE POWER SUPPLY
    *                |   |   | NEGATIVE POWER SUPPLY
    *                |   |   |   |   OUTPUT
    *                |   |   |   |   |
    .SUBCKT A2_114E  1   2   3   4   5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 188.5E-12
    IEE  10  4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 5.305E3
    RC2   3 12 5.305E3
    RE1  13 10 4.348E3
    RE2  14 10 4.348E3
    REE  10 99 7.4074E6
    RO1   8  5 40
    RO2   7 99 320
    VB    9  0 DC 0
    VC    3 53 DC 1.672
    VE   54  4 DC 1.672
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    ****************************
    * A2_114E "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0
    FQ1  3  0 POLY(1) VQ1 0 1
    FQ2  0  4 POLY(1) VQ2 0 -1
    * QUIESCIENT CURRENT
    RQ   3  4 52.53E3
    * DIFF INPUT CAPACITANCE
    CDIF 1  2 3E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM 1  0 3E-12
    C2CM 2  0 3E-12
    * INPUT PROTECTION
    VS11  3 31 0
    FS11  0  3 VS11 1
    S11  31  0 1 0 SP
    FS12  1  4 VS11 1
    VS21 32  4 0
    FS21  4  0 VS21 1
    S21   0 32 1 0 SM
    FS22  3  1 VS21 1
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3 NC=100 NR=100)
    .MODEL SP VSWITCH(RON=10K ROFF=100G VON=15.6 VOFF=15.5)
    .MODEL SM VSWITCH(RON=10K ROFF=100G VON=-15.6 VOFF=-15.5)
    .ENDS
    *
    * A3_114E OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:46
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_114E  1 2 3 4 5
    *
    C1   11 12 13.51E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 251.9E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 339.3E-6
    GCM   0  6 10 99 339.3E-12
    IEE  10  4 DC 18E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.947E3
    RC2   3 12 2.947E3
    RE1  13 10 74.778
    RE2  14 10 74.778
    REE  10 99 11.111E6
    RO1   8  5 13
    RO2   7 99 117
    VB    9  0 DC 0
    VC    3 53 DC 1.972
    VE   54  4 DC 1.972
    VLIM  7  8 DC 0
    VLP  91  0 DC 12
    VLN   0 92 DC 12
    ****************************
    * A3_114E "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0
    FQ1  3  0 POLY(1) VQ1 0 1
    FQ2  0  4 POLY(1) VQ2 0 -1
    * QUIESCIENT CURRENT
    RQ   3  4 30.123E3
    * DIFF INPUT CAPACITANCE
    CDIF 1  2 10E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM 1  0 5E-12
    C2CM 2  0 5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=30.00E3)
    .ENDS
    *$
    **************************************************************************
    * INA115 = 2 x A1_115 + A3_115 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 1/10/94 BY JLA
    * REV.A
    *   NODE ASSIGNMENTS OF SUBCKT INA115 CORRESPOND TO SURFACE MOUNT PACKAGE OF
    *   BURR-BROWN'S INA115 (NO DIP AVAILABLE)
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * NOTE:  THE OUTPUT PERFORMANCE OF THE MACRO MODEL WILL BE ERRONEOUS IF
    *        NODE 12 (FEEDBACK) IS NOT CONNECTED PROPERLY.  THIS IS GENERALLY
    *        CONNECTED TO NODE 11 (OUTPUT).
    *
    * INA115 SUB-CIRCUIT
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |   INVERTING INPUT
    *                    |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   |   OUTPUT
    *                    |   |   |   |   |   FEEDBACK
    *                    |   |   |   |   |   |    REFERENCE
    *                    |   |   |   |   |   |    |   GAIN SET 1
    *                    |   |   |   |   |   |    |   |   GAIN SET 2
    *                    |   |   |   |   |   |    |   |   |   GAIN SENSE 1
    *                    |   |   |   |   |   |    |   |   |   |   GAIN SENSE 2
    *                    |   |   |   |   |   |    |   |   |   |   |
    .SUBCKT INA115/BB    5   4   13  7   11  12   10  3   14  2   15
    *
    * A1_115 SUBCIRCUIT
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X1                4   2   13  7   1   A1_115
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X2                5   15  13  7   8   A1_115
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X3                17  18  13  7   11   A3_115
    *
    RFB1 1  3 25K
    RFB2 8 14 25K
    R1   1 18 25K
    R2  18 12 24.9985K
    R3   8 17 25K
    R4  17 10 25K
    C1  17 10 5P
    C2  18 12 5P
    CC1  1  3 5P
    CC2  8 14 5P
    *
    .ENDS
    *
    * A1_115 OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:21
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |   POSITIVE POWER SUPPLY
    *                |   |   |   NEGATIVE POWER SUPPLY
    *                |   |   |   |   OUTPUT
    *                |   |   |   |   |
    .SUBCKT A1_115   1   2   3   4   5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 188.5E-12
    IEE  10  4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 5.305E3
    RC2   3 12 5.305E3
    RE1  13 10 4.348E3
    RE2  14 10 4.348E3
    REE  10 99 7.4074E6
    RO1   8  5 40
    RO2   7 99 320
    RP    3  4 52.53E3
    VB    9  0 DC 0
    VC    3 53 DC 1.672
    VE   54  4 DC 1.672
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3 NC=100 NR=100)
    .ENDS
    *
    * A3_115 OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:46
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_115  1 2 3 4 5
    *
    C1   11 12 13.51E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 251.9E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 339.3E-6
    GCM   0  6 10 99 339.3E-12
    IEE  10  4 DC 18E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.947E3
    RC2   3 12 2.947E3
    RE1  13 10 74.778
    RE2  14 10 74.778
    REE  10 99 11.111E6
    RO1   8  5 13
    RO2   7 99 117
    RP    3  4 30.123E3
    VB    9  0 DC 0
    VC    3 53 DC 1.972
    VE   54  4 DC 1.972
    VLIM  7  8 DC 0
    VLP  91  0 DC 12
    VLN   0 92 DC 12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=30.00E3)
    .ENDS
    *$
    **************************************************************************
    * INA115E = 2 x A1_115E + A3_115E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 1/10/94 BY JLA
    * REV.A
    * NODE ASSIGNMENTS OF SUBCKT INA115 CORRESPOND TO SURFACE MOUNT PACKAGE OF
    * BURR-BROWN'S INA115 (NO DIP AVAILABLE)
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * NOTE:  THE OUTPUT PERFORMANCE OF THE MACRO MODEL WILL BE ERRONEOUS IF
    *        NODE 12 (FEEDBACK) IS NOT CONNECTED PROPERLY.  THIS IS GENERALLY
    *        CONNECTED TO NODE 11 (OUTPUT).
    * 
    * INA115E SUB-CIRCUIT
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |   INVERTING INPUT
    *                    |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   |   OUTPUT
    *                    |   |   |   |   |   FEEDBACK
    *                    |   |   |   |   |   |    REFERENCE
    *                    |   |   |   |   |   |    |   GAIN SET 1
    *                    |   |   |   |   |   |    |   |   GAIN SET 2
    *                    |   |   |   |   |   |    |   |   |   GAIN SENSE 1
    *                    |   |   |   |   |   |    |   |   |   |   GAIN SENSE 2
    *                    |   |   |   |   |   |    |   |   |   |   |
    .SUBCKT INA115E/BB   5   4   13  7   11  12   10  3   14  2   15
    *
    * A1_115E SUBCIRCUIT
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X1                4   2   13  7   1   A1_115E
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X2                5   15  13  7   8   A1_115E
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X3                17  18  13  7   11   A3_115E
    *
    RFB1 1  3 25K
    RFB2 8 14 25K
    R1   1 18 25K
    R2  18 12 24.9985K
    R3   8 17 25K
    R4  17 10 25K
    C1  17 10 5P
    C2  18 12 5P
    CC1  1  3 5P
    CC2  8 14 5P
    *
    .ENDS
    *
    * A1_115E OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:21
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |   POSITIVE POWER SUPPLY
    *                |   |   |   NEGATIVE POWER SUPPLY
    *                |   |   |   |   OUTPUT
    *                |   |   |   |   |
    .SUBCKT A1_115E  1   2   3   4   5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 188.5E-12
    IEE  10  4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 5.305E3
    RC2   3 12 5.305E3
    RE1  13 10 4.348E3
    RE2  14 10 4.348E3
    REE  10 99 7.4074E6
    RO1   8  5 40
    RO2   7 99 320
    VB    9  0 DC 0
    VC    3 53 DC 1.672
    VE   54  4 DC 1.672
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    ****************************
    * A1_115E "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0
    FQ1  3  0 POLY(1) VQ1 0 1
    FQ2  0  4 POLY(1) VQ2 0 -1
    * QUIESCIENT CURRENT
    RQ   3 4 52.53E3
    * DIFF INPUT CAPACITANCE
    CDIF 1 2 3E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM 1 0 3E-12
    C2CM 2 0 3E-12
    * INPUT PROTECTION
    VS11  3 31 0
    FS11  0  3 VS11 1
    S11  31  0 1 0 SP
    FS12  1  4 VS11 1
    VS21 32  4 0
    FS21  4  0 VS21 1
    S21   0 32 1 0 SM
    FS22  3  1 VS21 1
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3 NC=100 NR=100)
    .MODEL SP VSWITCH(RON=10K ROFF=100G VON=15.6 VOFF=15.5)
    .MODEL SM VSWITCH(RON=10K ROFF=100G VON=-15.6 VOFF=-15.5)
    .ENDS
    *
    * A3_115E OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:46
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_115E  1 2 3 4 5
    *
    C1   11 12 13.51E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 251.9E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 339.3E-6
    GCM   0  6 10 99 339.3E-12
    IEE  10  4 DC 18E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.947E3
    RC2   3 12 2.947E3
    RE1  13 10 74.778
    RE2  14 10 74.778
    REE  10 99 11.111E6
    RO1   8  5 13
    RO2   7 99 117
    VB    9  0 DC 0
    VC    3 53 DC 1.972
    VE   54  4 DC 1.972
    VLIM  7  8 DC 0
    VLP  91  0 DC 12
    VLN   0 92 DC 12
    ****************************
    * A3_115E "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1 0 1
    FQ2   0  4 POLY(1) VQ2 0 -1
    * QUIESCIENT CURRENT
    RQ    3  4 30.123E3
    * DIFF INPUT CAPACITANCE
    CDIF  1  2 10E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  0 5E-12
    C2CM  2  0 5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=30.00E3)
    .ENDS
    *$
    **************************************************************************
    * INA117 = A3_117 OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * CREATED ON 08/21/90 AT 12:54
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA117 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  |  POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |  REFERENCE A
    *                       |  |  |  |  |  |  REFERENCE B
    *                       |  |  |  |  |  |  |
    .SUBCKT INA117/BB       1  2  3  4  5  8  9
    *
    * A3_117 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_117
    *
    R1    2   13   380.0000K
    R2   13    5   380.0000K
    C2   13    5     0.500PF
    R3    1   14   380.0000K
    R4   14    8    19.9990K
    R5   13    9    21.1111K
    C1CM 14    0     3PF
    C2CM 13    0     3PF
    CDIF 14   13     7PF
    *
    .ENDS
    *
    * A3_117 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/19/90 AT 12:37
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_117   1 2 3 4 5
    *
    C1   11 12 9.283E-12
    C2    6  7 13.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.081E6 -4E6 4E6 4E6 -4E6
    GA    6  0 11 12 408.4E-6
    GCM   0  6 10 99 408.4E-12
    IEE  10  4 DC 39.14E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.449E3
    RC2   3 12 2.449E3
    RE1  13 10 1.118E3
    RE2  14 10 1.118E3
    REE  10 99 5.110E6
    RO1   8  5 60
    RO2   7 99 60
    RP    3  4 20.53E3
    VB    9  0 DC 0
    VC    3 53 DC 4.500
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=278.6)
    .ENDS 
    *$
    **************************************************************************
    * INA117E = A3_117E OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * "E" IS ENHANCED MODEL
    * CREATED ON 08/28/90 AT 9:50
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA117E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  |  POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |  REFERENCE A
    *                       |  |  |  |  |  |  REFERENCE B
    *                       |  |  |  |  |  |  |
    .SUBCKT INA117E/BB      1  2  3  4  5  8  9
    *
    * A3_117E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  | POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_117E
    *
    R1    2   13   380.0000K
    R2   13    5   380.0000K
    C2   13    5     0.5000PF
    R3    1   14   380.0000K
    R4   14    8    19.9990K
    R5   13    9    21.1111K
    C1CM 14    0     3PF
    C2CM 13    0     3PF
    CDIF 14   13     7PF
    *
    .ENDS
    *
    * A3_117E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/09/90 AT 08:58
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_117E  1 2 3 4 5
    *
    C1   11 12 9.283E-12
    C2    6  7 13.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.081E6 -4E6 4E6 4E6 -4E6
    GA    6  0 11 12 408.4E-6
    GCM   0  6 10 99 408.4E-12
    IEE  10  4 DC 39.14E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.449E3
    RC2   3 12 2.449E3
    RE1  13 10 1.118E3
    RE2  14 10 1.118E3
    REE  10 99 5.110E6
    RO1   8  5 60
    RO2   7 99 60
    *  RP    3  4 20.53E3
    VB    9  0 DC 0
    VC    3 53 DC 4.500
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    ****************************
    * A3_117 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.414E-3  1
    FQ2   0  4 POLY(1) VQ2  1.414E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  6.5E5
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=278.6)
    .ENDS
    *$
    **************************************************************************
    * INA118 = A1_118 + A2_118 + A3_118 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 05/20/94 AT 15:01
    * REV.A
    *
    * INA118 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA118/BB          1   2   3   4   5   8   9  10
    *
    * A1_118 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_118
    *
    * A2_118 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_118
    *
    * A3_118 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_118
    *
    R1    11  13   60.0000K
    R2    13   5   59.994K
    R3    12  14   60.0000K
    R4    14   8   60.0000K
    CIN   13  14    4.0000PF
    R1FB   9  11   25.0000K
    CC1   17  11  13.0000PF
    R2FB  10  12   25.0000K
    CC2   16  12  13.0000PF
    CG1    9   0  10.0000PF
    CG2   10   0   9.0000PF
    RCE   17   9   1.7G
    I1     3  16  DC  15.00E-6
    I2     3  17  DC  15.00E-6
    IB1CAN 3   1  DC  29.00E-9
    IB2CAN 3   2  DC  29.00E-9
    Ibal   0   4  DC  31.30E-6
    D1    15  17      DX
    D2    15  16      DX
    Q1    16   1  10  QX
    Q2    17   2   9  QX
    V1     3  15  DC  1.100
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_118 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 05/20/94 at 09:20
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A1_118   1 2 3 4 5
    *
    c1   11 12 1.340E-12
    c2    6  7 10.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 110.0E-6
    gcm   0  6 10 99 11.00E-12
    iss   3 10 dc 10.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 9.095E3
    rd2   4 12 9.095E3
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 900.0E12
    rss  10 99 20.00E6
    vb    9  0 dc 0
    vc    3 53 dc .6
    ve   54  4 dc .6
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=1.209E-3 Vto=-1)
    .ends
    *
    * A2_118 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 05/20/94 at 09:20
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A2_118   1 2 3 4 5
    *
    c1   11 12 1.340E-12
    c2    6  7 10.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 110.0E-6
    gcm   0  6 10 99 11.00E-12
    iss   3 10 dc 10.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 9.095E3
    rd2   4 12 9.095E3
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 900.0E12
    rss  10 99 20.00E6
    vb    9  0 dc 0
    vc    3 53 dc .6
    ve   54  4 dc .6
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=1.209E-3 Vto=-1)
    .ends
    *
    * A3_118 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 05/20/94 at 09:22
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_118   1 2 3 4 5
    *
    c1   11 12 3.501E-12
    c2    6  7 10.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 212.2E6 -210E6 210E6 210E6 -210E6
    ga    6  0 11 12 75.40E-6
    gcm   0  6 10 99 754.0E-12
    iee  10  4 dc 9.002E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   3 11 13.26E3
    rc2   3 12 13.26E3
    re1  13 10 7.514E3
    re2  14 10 7.514E3
    ree  10 99 22.22E6
    ro1   8  5 75
    ro2   7 99 75
    rp    3  4 103.09E3
    vb    9  0 dc 0
    vc    3 53 dc 1.400
    ve   54  4 dc .8
    vlim  7  8 dc 0
    vlp  91  0 dc 4.5
    vln   0 92 dc 11.5
    *
    .model dx D(Is=800.0E-18)
    .model qx NPN(Is=800.0E-18 Bf=4.500E3)
    .ends
    *$
    **************************************************************************
    * INA118E = A1_118E + A2_118E + A3_118E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 05/20/94 AT 15:01 TLB
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA118E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |   REFERENCE
    *                       |   |   |   |   |   |   GAIN SENSE 1
    *                       |   |   |   |   |   |   |   GAIN SENSE 2
    *                       |   |   |   |   |   |   |   |
    .SUBCKT INA118E/BB      1   2   3   4   5   8   9  10
    *
    * A1_118E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_118E
    *
    * A2_118E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_118E
    *
    * A3_118E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_118E
    *
    R1    11  13   60.0000K
    R2    13   5   59.994K
    R3    12  14   60.0000K
    R4    14   8   60.0000K
    CIN   13  14    4.0000PF
    R1FB   9  11   25.0000K
    CC1   17  11   13.0000PF
    R2FB  10  12   25.0000K
    CC2   16  12   13.0000PF
    CG1    9   0   10.0000PF
    CG2   10   0    9.0000PF
    ****************************
    * INA118 "E" - ENHANCEMENTS
    ****************************
    RDIFF  1   2    1.0000E10
    R1CM   1   0    2.5000E10
    R2CM   2   0    2.5000E10
    CDIF   1   2    1.0000PF
    C1CM   1   0    4.0000PF
    C2CM   2   0    4.0000PF
    RCE   17   9    1.7G
    I1     3  16  DC  15.00E-6
    I2     3  17  DC  15.00E-6
    IB1CAN 3   1  DC  29.00E-9
    IB2CAN 3   2  DC  29.00E-9
    D1    15  17      DX
    D2    15  16      DX
    Q1    16   1  10  QX
    Q2    17   2   9  QX
    V1     3  15  DC  1.100
    *********************************
    * INA118 "E" - ENHANCEMENTS
    *********************************
    * POS INPUT PROTECTION
    VS11  3  31 0
    S11  31   0 1 0 SP
    FS12  1   4 VS11 1 
    FS11  0   3 VS11 1
    VS21 32   4 0 
    S21   0  32 1 0 SM
    FS22  3   1 VS21 1   
    FS21  4   0 VS21 1
    * NEG INPUT PROTECTION
    VS11- 3  33 0
    S11-  33  0 2 0 SP
    FS12- 2   4 VS11- 1
    FS11- 0   3 VS11- 1
    VS21- 34  4 0 
    S21-  0  34 2 0 SM
    FS22- 3   2 VS21- 1
    FS21- 4   0 VS21- 1
    *
    .model sp vswitch(ron=300k roff=100g von=14.8 voff=14.7) 
    .model sm vswitch(ron=3.5k roff=100g von=-15.1 voff=-15.0)
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_118E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 05/20/94 at 09:20
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A1_118E  1 2 3 4 5
    *
    c1   11 12 1.340E-12
    c2    6  7 10.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 110.0E-6
    gcm   0  6 10 99 11.00E-12
    iss   3 10 dc 10.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 9.095E3
    rd2   4 12 9.095E3
    ro1   8  5 50
    ro2   7 99 25
    rss  10 99 20.00E6
    vb    9  0 dc 0
    vc    3 53 dc .6
    ve   54  4 dc .6
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    ****************************
    * A1_118 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0 
    FQ1  3  0 POLY(1) VQ1 0 1
    FQ2  0  4 POLY(1) VQ2 0 -1
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=1.209E-3 Vto=-1)
    .ends
    *
    * A2_118E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 05/20/94 at 09:20
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A2_118E  1 2 3 4 5
    *
    c1   11 12 1.340E-12
    c2    6  7 10.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 110.0E-6
    gcm   0  6 10 99 11.00E-12
    iss   3 10 dc 10.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 9.095E3
    rd2   4 12 9.095E3
    ro1   8  5 50
    ro2   7 99 25
    rss  10 99 20.00E6
    vb    9  0 dc 0
    vc    3 53 dc .6
    ve   54  4 dc .6
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    ****************************
    * A2_118 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0 
    FQ1  3  0 POLY(1) VQ1 0 1
    FQ2  0  4 POLY(1) VQ2 0 -1
    ****************************
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=1.209E-3 Vto=-1)
    .ends
    *
    * A3_118E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 05/20/94 at 09:22
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_118E  1 2 3 4 5
    *
    c1   11 12 3.501E-12
    c2    6  7 10.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 212.2E6 -210E6 210E6 210E6 -210E6
    ga    6  0 11 12 75.40E-6
    gcm   0  6 10 99 754.0E-12
    iee  10  4 dc 9.002E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   3 11 13.26E3
    rc2   3 12 13.26E3
    re1  13 10 7.514E3
    re2  14 10 7.514E3
    ree  10 99 22.22E6
    ro1   8  5 75
    ro2   7 99 75
    vb    9  0 dc 0
    vc    3 53 dc 1.400
    ve   54  4 dc .8
    vlim  7  8 dc 0
    vlp  91  0 dc 4.5
    vln   0 92 dc 11.5
    ****************************
    * A3_118 "E" ENHANCEMENTS
    ****************************
    *OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0 
    FQ1  3  0 POLY(1) VQ1 260.8E-6 1
    FQ2  0  4 POLY(1) VQ2 261.0E-6 -1
    * SUPPLY CURRENT VARIATION
    RQ   3  4 1.365E6
    *
    .model dx D(Is=800.0E-18)
    .model qx NPN(Is=800.0E-18 Bf=4.500E3)
    .ends
    *$
    **************************************************************************
    * INA120 = A1_120 + A2_120 + A3_120 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.A
    *
    * INA120 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |   REFERENCE
    *                       |   |   |   |   |   |   GAIN SENSE 1
    *                       |   |   |   |   |   |   |   GAIN SENSE 2
    *                       |   |   |   |   |   |   |   |
    .SUBCKT INA120/BB       1   2   3   4   5   8   9  10
    *
    * A1_120 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                      2   9   3   4  11   A1_120
    *
    * A2_120 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                      1  10   3   4  12   A2_120
    *
    * A3_120 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_120
    *
    R1    11  13  10.0000K
    R2    13   5   9.9995K
    C2    13   5   1.0000PF
    R3    12  14  10.0000K
    R4    14   8  10.0000K
    R1FB   9  11  20.0000K
    CC1    9  11  10.0000PF
    R2FB  10  12  20.0000K
    CC2   10  12  10.0000PF
    *
    .ENDS
    *
    * A1_120 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/07/90 AT 16:07
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A1_120   1 2 3 4 5
    *
    C1   11 12 16.38E-12
    C2    6  7 90.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 23.58E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 1.696E-3
    GCM   0  6 10 99 3.385E-9
    IEE  10  4 DC 108.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 589.5
    RC2   3 12 589.5
    RE1  13 10 110.5
    RE2  14 10 110.5
    REE  10 99 1.852E6
    RO1   8  5 25
    RO2   7 99 25
    RP    3  4 33.63E3
    VB    9  0 DC 0
    VC    3 53 DC 2.200
    VE   54  4 DC 2.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=7.714E3)
    .ENDS
    *
    * A2_120 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/07/90 AT 16:08
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A2_120   1 2 3 4 5
    *
    C1   11 12 16.38E-12
    C2    6  7 90.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 20.21E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 1.979E-3
    GCM   0  6 10 99 1.979E-9
    IEE  10  4 DC 108.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 505.3
    RC2   3 12 505.3
    RE1  13 10 26.28
    RE2  14 10 26.28
    REE  10 99 1.852E6
    RO1   8  5 25
    RO2   7 99 25
    RP    3  4 33.63E3
    VB    9  0 DC 0
    VC    3 53 DC 2.200
    VE   54  4 DC 2.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=7.714E3)
    .ENDS
    *
    * A3_120 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 11/07/90 AT 16:10
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_120   1 2 3 4 5
    *
    C1   11 12 17.32E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 159.2E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 251.3E-6
    GCM   0  6 10 99 251.3E-12
    ISS   3 10 DC 20.00E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 3.979E3
    RD2   4 12 3.979E3
    RO1   8  5 25
    RO2   7 99 25
    RP    3  4 30.00E3
    RSS  10 99 10.00E6
    VB    9  0 DC 0
    VC    3 53 DC 2.200
    VE   54  4 DC 2.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 24
    VLN   0 92 DC 24
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=10.00E-12 BETA=1.579E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA120E = A1_120E + A2_120E + A3_120E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 10/30/90 AT 15:01
    * REV.B 3/21/92 BCB: added input bias current correction
    *
    * INA120E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |   REFERENCE
    *                       |   |   |   |   |   |   GAIN SENSE 1
    *                       |   |   |   |   |   |   |   GAIN SENSE 2
    *                       |   |   |   |   |   |   |   |
    .SUBCKT INA120E/BB      1   2   3   4   5   8   9  10
    *
    * A1_120E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                      2   9   3   4  11   A1_120E
    *
    * A2_120E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                      1  10   3   4  12   A2_120E
    *
    * A3_120E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_120E
    *
    R1    11  13  10.0000K
    R2    13   5   9.9995K
    C2    13   5   1.0000PF
    R3    12  14  10.0000K
    R4    14   8  10.0000K
    R1FB   9  11  20.0000K
    CC1    9  11  10.0000PF
    R2FB  10  12  20.0000K
    CC2   10  12  10.0000PF
    *
    .ENDS
    *
    * A1_120E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/07/90 AT 16:07
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |  POSITIVE POWER SUPPLY
    *                |   |  | NEGATIVE POWER SUPPLY
    *                |   |  | | OUTPUT
    *                |   |  | | |
    .SUBCKT A1_120E INP INN 3 4 5
    *
    C1   11 12 16.38E-12
    C2    6  7 90.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 23.58E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 1.696E-3
    GCM   0  6 10 99 3.385E-9
    IEE  10  4 DC 108.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 589.5
    RC2   3 12 589.5
    RE1  13 10 110.5
    RE2  14 10 110.5
    REE  10 99 1.852E6
    RO1   8  5 25
    RO2   7 99 25
    *  RP    3  4 33.63E3
    VB    9  0 DC 0
    VC    3 53 DC 2.200
    VE   54  4 DC 2.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    ****************************
    * A1_120 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  8.72E-4  1
    FQ2   0  4 POLY(1) VQ2  8.72E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.5E6
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT PROTECTION
    R1IN  INP 1  1000
    D1IN   1  2  DX
    R2IN  INN 2  1000
    D2IN   2  1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=7.714E3)
    .ENDS
    *
    * A2_120E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/07/90 AT 16:08
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |  POSITIVE POWER SUPPLY
    *                |   |  | NEGATIVE POWER SUPPLY
    *                |   |  | | OUTPUT
    *                |   |  | | |
    .SUBCKT A2_120E INP INN 3 4 5
    *
    C1   11 12 16.38E-12
    C2    6  7 90.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 20.21E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 1.979E-3
    GCM   0  6 10 99 1.979E-9
    IEE  10  4 DC 108.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 505.3
    RC2   3 12 505.3
    RE1  13 10 26.28
    RE2  14 10 26.28
    REE  10 99 1.852E6
    RO1   8  5 25
    RO2   7 99 25
    *  RP    3  4 33.63E3
    VB    9  0 DC 0
    VC    3 53 DC 2.200
    VE   54  4 DC 2.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    ****************************
    * A2_120 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  8.72E-4  1
    FQ2   0  4 POLY(1) VQ2  8.72E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.5E6
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT PROTECTION
    R1IN  INP 1  1000
    D1IN   1  2  DX
    R2IN  INN 2  1000
    D2IN   2  1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=7.714E3)
    .ENDS
    *
    * A3_120E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 11/07/90 AT 16:10
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_120E  1 2 3 4 5
    *
    C1   11 12 17.32E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 159.2E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 251.3E-6
    GCM   0  6 10 99 251.3E-12
    ISS   3 10 DC 20.00E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (12,1) (10,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 3.979E3
    RD2   4 12 3.979E3
    RO1   8  5 25
    RO2   7 99 25
    *  RP    3  4 30.00E3
    RSS  10 99 10.00E6
    VB    9  0 DC 0
    VC    3 53 DC 2.200
    VE   54  4 DC 2.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 24
    VLN   0 92 DC 24
    ****************************
    * A3_120 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  9.60E-4  1
    FQ2   0  4 POLY(1) VQ2  9.60E-4 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.5E6
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  3.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=10.00E-12 BETA=1.579E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * INA126P MICROPOWER INSTRUMENTATION AMPLIFIER MACROMODEL 
    * REV A. 4/14/97 WM
    * REV B. 27 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO TOP OF FILE.
    * INA126 two opamp connections
    *
    * connections:      Rg
    *                   | negative input
    *                   | | positive input
    *                   | | | negative power supply
    *                   | | | | ref
    *                   | | | | |  output
    *                   | | | | | | positive power supply
    *                   | | | | | | | Rg
    *                   | | | | | | | |
    .subckt INA126P/BB  1 2 3 4 5 6 7 8 
    * 
    x1        2 1 7 4 222 5    opamp1_126
    x2        3 8 7 4 6 222    opamp2_126
    *
    .ends
    *
    * INA126 operational amplifier "macromodel" subcircuits:
    * connections:       non-inverting input
    *                    | inverting input
    *                    | | positive power supply
    *                    | | | negative power supply
    *                    | | | | output
    *                    | | | | | ref input
    *                    | | | | | |
    .subckt OPAMP1_126   1 2 3 4 5 22 
    *
    c1   11 12 2.9E-12
    c2    6  7 12.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 42.44E6 -42E6 42E6 42E6 -42E6
    ga    6  0 11 12 94.25E-6
    gcm   0  6 10 99 942.5E-12
    iee   3 10 dc 6.040E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   4 11 10.61E3
    rc2   4 12 10.61E3
    re1  13 10 1.976E3
    re2  14 10 1.976E3
    ree  10 99 33.11E6
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 379.8E3
    vb    9  0 dc 0
    vc    3 53 dc 1
    ve   54  4 dc 1
    vlim  7  8 dc 0
    vlp  91  0 dc 2
    vln   0 92 dc 2
    *
    .model dx D(Is=800.0E-18)
    .model qx PNP(Is=800.0E-18 Bf=150)
    *     FEEDBACK RESISTORS
    RFB1    2 22    40K
    RFB2    2  5    10K
    *
    .ends
    *
    * connections:       non-inverting input
    *                    | inverting input
    *                    | | positive power supply
    *                    | | | negative power supply
    *                    | | | | output
    *                    | | | | | ref input
    *                    | | | | | |
    .subckt OPAMP2_126   1 2 3 4 5 22
    *
    c1   11 12 2.9E-12
    c2    6  7 12.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 42.44E6 -42E6 42E6 42E6 -42E6
    ga    6  0 11 12 94.25E-6
    gcm   0  6 10 99 942.5E-12
    iee   3 10 dc 6.040E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   4 11 10.61E3
    rc2   4 12 10.61E3
    re1  13 10 1.976E3
    re2  14 10 1.976E3
    ree  10 99 33.11E6
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 379.8E3
    vb    9  0 dc 0
    vc    3 53 dc 1
    ve   54  4 dc 1
    vlim  7  8 dc 0
    vlp  91  0 dc 2
    vln   0 92 dc 2
    *
    .model dx D(Is=800.0E-18)
    .model qx PNP(Is=800.0E-18 Bf=150)
    *
    *     FEEDBACK RESISTORS
    RFB3    2 22   10K
    RFB4    2  5   40K
    *
    .ends
    *$
    **************************************************************************
    * INA128 = A1_128 + A2_128 + A3_128 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 11/20/96 AT 15:01
    *
    *  Note:  A1_128, A2_128 and A3_128 op amps modeled here for the INA128
    *         ARE NOT related to any standard BB op amps such as the OPA128.
    *
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA128 SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA128/BB          1   2   3   4   5   8   9  10
    *
    * A1_128 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_128
    *
    * A2_128 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_128
    *
    * A3_128 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_128
    *
    R1    11  13   40.0000K
    R2    13   5   39.996K
    R3    12  14   40.0000K
    R4    14   8   40.0000K
    CIN   13  14   4.0000PF
    R1FB   9  11   25.000K
    CC1   17  11   5.0000PF
    R2FB  10  12   25.000K
    CC2   16  12   5.0000PF
    CG1    9   0   10.0000PF
    CG2   10   0   8.0000PF
    RCE   17   9   20G
    I1     3  16  DC  20.00E-6
    I2     3  17  DC  20.00E-6
    IB1CAN 3   1  DC  40.00E-9
    IB2CAN 3   2  DC  40.00E-9
    Ibal   0   4  DC  60.0E-6
    D1    15  17      DX
    D2    15  16      DX
    Q1    16   1  10  QX
    Q2    17   2   9  QX
    V1     3  15  DC  1.700
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_128 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A1_128   1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    ip 	3  4 dc 120u
    rp    3  4 3.00E6
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A2_128 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A2_128   1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    ip    3  4 dc 120u
    rp    3  4 3.00E6
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A3_128 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:33
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_128   1 2 3 4 5
    *
    c1   11 12 2.730E-12
    c2    6  7 15.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 163.2E6 -160E6 160E6 160E6 -160E6
    ga    6  0 11 12 122.5E-6
    gcm   0  6 10 99 12.25E-12
    iee  10  4 dc 63.95E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   3 11 8.162E3
    rc2   3 12 8.162E3
    re1  13 10 7.327E3
    re2  14 10 7.327E3
    ree  10 99 3.127E6
    ro1   8  5 10
    ro2   7 99 10
    ip	3  4 dc 220u
    rp 	3  4 1.87E6
    vb    9  0 dc 0
    vc    3 53 dc 1.500
    ve   54  4 dc 1.400
    vlim  7  8 dc 0
    vlp  91  0 dc 5
    vln   0 92 dc 14
    *
    .model dx D(Is=800.0E-18)
    .model qx NPN(Is=800.0E-18 Bf=318.8)
    .ends
    *$
    **************************************************************************
    * INA128E = A1_128E + A2_128E + A3_128E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 12/11/96 AT 15:01
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA128E SUB-CIRCUIT
    * CONNECTIONS:             NON-INVERTING INPUT
    *                          |   INVERTING INPUT
    *                          |   |   POSITIVE POWER SUPPLY
    *                          |   |   |   NEGATIVE POWER SUPPLY
    *                          |   |   |   |   OUTPUT
    *                          |   |   |   |   |   REFERENCE
    *                          |   |   |   |   |   |   GAIN SENSE 1
    *                          |   |   |   |   |   |   |   GAIN SENSE 2
    *                          |   |   |   |   |   |   |   |
    .SUBCKT INA128E/BB         1   2   3   4   5   8   9  10
    *
    * A1_128E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_128E
    *
    * A2_128E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_128E
    *
    * A3_128E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_128E
    *
    R1    11  13   40.0000K
    R2    13   5   39.996K
    R3    12  14   40.0000K
    R4    14   8   40.0000K
    CIN   13  14   4.0000PF
    R1FB   9  11   25.000K
    CC1   17  11   5.0000PF
    R2FB  10  12   25.000K
    CC2   16  12   5.0000PF
    CG1    9   0   10.0000PF
    CG2   10   0   8.0000PF
    RCE   17   9   20G
    I1     3  16  DC  20.00E-6
    I2     3  17  DC  20.00E-6
    IB1CAN 3  42  DC  40.00E-9
    IB2CAN 3  46  DC  40.00E-9
    IBAL   0   4  DC  6.5E-6
    D1    15  17      DX
    D2    15  16      DX
    Q1    16  42  10  QX
    Q2    17  46   9  QX
    V1     3  15  DC  1.700
    ******************************
    * Additions for the INA128E  *
    * (Enhanced) macromodel	     *
    ******************************
    * INPUT PROTECTION
    RIN1  1   41 1K
    I11  41   42 .7MA
    S11  41   42 1 41 SP
    DI1  43   41 DX
    I12   4   43 DC .8MA
    S12   4   43 1 41 SM
    RIN2  2   45 1K
    I21  45   46 .7MA
    S21  45   46 2 45 SP
    DI2  47   45 DX
    I22   4   47 DC .8MA 
    S22   4   47 2 45 SM
    *************************
    * Anti-inversion clamps *
    *************************
    VSET1 3 40 DC 2.0
    QSET1 4 40 42 QY
    VSET2 3 44 DC 2.0
    QSET2 4 44 46 QY
    *
    .model sp vswitch(ron=10 roff=100E3 von=.7 voff=1) 
    .model sm vswitch(ron=10 roff=100E3 von=-.7 voff=-1)
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .MODEL QY PNP(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_128E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A1_128E  1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    ******************************
    * Additions for the INA128E  *
    * (Enhanced) macromodel	     *
    * A1_128e sub-circuit	     *
    ******************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0 
    FQ1   3  0 POLY(1) VQ1 120u 1
    FQ2   0  4 POLY(1) VQ2 120u -1
    RP    3  4 3.00E6
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A2_128E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A2_128E  1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    ******************************
    * Additions for the INA128E  *
    * (Enhanced) macromodel	     *
    * A2_128e sub-circuit	     *
    ******************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0 
    FQ1   3  0 POLY(1) VQ1 120u 1
    FQ2   0  4 POLY(1) VQ2 120u -1
    RP    3  4 3.00E6
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A3_128E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:33
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_128E  1 2 3 4 5
    *
    c1   11 12 2.730E-12
    c2    6  7 15.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 163.2E6 -160E6 160E6 160E6 -160E6
    ga    6  0 11 12 122.5E-6
    gcm   0  6 10 99 12.25E-12
    iee  10  4 dc 63.95E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   3 11 8.162E3
    rc2   3 12 8.162E3
    re1  13 10 7.327E3
    re2  14 10 7.327E3
    ree  10 99 3.127E6
    ro1   8  5 300
    ro2   7 99 300
    vb    9  0 dc 0
    vc    3 53 dc 1.500
    ve   54  4 dc 1.400
    vlim  7  8 dc 0
    vlp  91  0 dc 5
    vln   0 92 dc 14
    ******************************
    *			           *
    * Additions for the INA128E  *
    * (Enhanced) macromodel	     *
    * A3_128e sub-circuit	     *
    *			           *
    ******************************
    *OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX 
    VQ1  21  0 0
    VQ2  22  0 0 
    FQ1   3  0 POLY(1) VQ1 206.7E-6 1
    FQ2   0  4 POLY(1) VQ2 206.7E-6 -1
    RQ    3  4 1.87e6
    *
    .model dx D(Is=800.0E-18)
    .model qx NPN(Is=800.0E-18 Bf=318.8)
    .ends
    *$
    **************************************************************************
    * INA129 = A1_129 + A2_129 + A3_129 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 11/20/96 AT 15:01
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA129 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |   REFERENCE
    *                       |   |   |   |   |   |   GAIN SENSE 1
    *                       |   |   |   |   |   |   |   GAIN SENSE 2
    *                       |   |   |   |   |   |   |   |
    .SUBCKT INA129/BB       1   2   3   4   5   8   9  10
    *
    * A1_129 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_129
    *
    * A2_129 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_129
    *
    * A3_129 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_129
    *
    R1    11  13   40.0000K
    R2    13   5   39.996K
    R3    12  14   40.0000K
    R4    14   8   40.0000K
    CIN   13  14   4.0000PF
    R1FB   9  11   24.700K
    CC1   17  11   5.0000PF
    R2FB  10  12   24.700K
    CC2   16  12   5.0000PF
    CG1    9   0   10.0000PF
    CG2   10   0   8.0000PF
    RCE   17   9   20G
    I1     3  16  DC  20.00E-6
    I2     3  17  DC  20.00E-6
    IB1CAN 3   1  DC  40.00E-9
    IB2CAN 3   2  DC  40.00E-9
    Ibal   0   4  DC  60.0E-6
    D1    15  17      DX
    D2    15  16      DX
    Q1    16   1  10  QX
    Q2    17   2   9  QX
    V1     3  15  DC  1.700
    *
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_129 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A1_129   1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    ip 	3  4 dc 120u
    rp    3  4 3.00E6
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A2_129 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A2_129   1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    ip    3  4 dc 120u
    rp    3  4 3.00E6
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A3_129 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:33
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_129   1 2 3 4 5
    *
    c1   11 12 2.730E-12
    c2    6  7 15.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 163.2E6 -160E6 160E6 160E6 -160E6
    ga    6  0 11 12 122.5E-6
    gcm   0  6 10 99 12.25E-12
    iee  10  4 dc 63.95E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   3 11 8.162E3
    rc2   3 12 8.162E3
    re1  13 10 7.327E3
    re2  14 10 7.327E3
    ree  10 99 3.127E6
    ro1   8  5 10
    ro2   7 99 10
    ip	3  4 dc 220u
    rp 	3  4 1.87E6
    vb    9  0 dc 0
    vc    3 53 dc 1.500
    ve   54  4 dc 1.400
    vlim  7  8 dc 0
    vlp  91  0 dc 5
    vln   0 92 dc 14
    *
    .model dx D(Is=800.0E-18)
    .model qx NPN(Is=800.0E-18 Bf=318.8)
    .ends
    *$
    **************************************************************************
    * INA129E = A1_129E + A2_129E + A3_129E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 12/11/96 AT 15:01
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA129E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |   REFERENCE
    *                       |   |   |   |   |   |   GAIN SENSE 1
    *                       |   |   |   |   |   |   |   GAIN SENSE 2
    *                       |   |   |   |   |   |   |   |
    .SUBCKT INA129E/BB      1   2   3   4   5   8   9  10
    *
    * A1_129E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X1                     15  17   3   4  11   A1_129E
    *
    * A2_129E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X2                     15  16   3   4  12   A2_129E
    *
    * A3_129E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |   INVERTING INPUT
    *                       |   |   POSITIVE POWER SUPPLY
    *                       |   |   |   NEGATIVE POWER SUPPLY
    *                       |   |   |   |   OUTPUT
    *                       |   |   |   |   |
    X3                     14  13   3   4   5   A3_129E
    *
    R1    11  13   40.0000K
    R2    13   5   39.996K
    R3    12  14   40.0000K
    R4    14   8   40.0000K
    CIN   13  14   4.0000PF
    R1FB   9  11   24.700K
    CC1   17  11   5.0000PF
    R2FB  10  12   24.700K
    CC2   16  12   5.0000PF
    CG1    9   0   10.0000PF
    CG2   10   0   8.0000PF
    RCE   17   9   20G
    I1     3  16  DC  20.00E-6
    I2     3  17  DC  20.00E-6
    IB1CAN 3  42  DC  40.00E-9
    IB2CAN 3  46  DC  40.00E-9
    IBAL   0   4  DC  6.5E-6
    D1    15  17      DX
    D2    15  16      DX
    Q1    16  42  10  QX
    Q2    17  46   9  QX
    V1     3  15  DC  1.700
    ******************************
    * Additions for the INA129E  *
    * (Enhanced) macromodel	     *
    ******************************
    * INPUT PROTECTION
    RIN1  1   41 1K
    I11  41   42 .7MA
    S11  41   42 1 41 SP
    DI1  43   41 DX
    I12   4   43 DC .8MA
    S12   4   43 1 41 SM
    RIN2  2   45 1K
    I21  45   46 .7MA
    S21  45   46 2 45 SP
    DI2  47   45 DX
    I22   4   47 DC .8MA 
    S22   4   47 2 45 SM
    *************************
    * Anti-inversion clamps *
    *************************
    VSET1 3 40 DC 2.0
    QSET1 4 40 42 QY
    VSET2 3 44 DC 2.0
    QSET2 4 44 46 QY
    *
    .model sp vswitch(ron=10 roff=100E3 von=.7 voff=1) 
    .model sm vswitch(ron=10 roff=100E3 von=-.7 voff=-1)
    .MODEL DX D(IS=1.0E-24)
    .MODEL QX NPN(IS=800.0E-18 BF=500)
    .MODEL QY PNP(IS=800.0E-18 BF=500)
    .ENDS
    *
    * A1_129E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A1_129E  1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    ******************************
    * Additions for the INA129E  *
    * (Enhanced) macromodel	     *
    * A1_129e sub-circuit	     *
    ******************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0 
    FQ1   3  0 POLY(1) VQ1 120u 1
    FQ2   0  4 POLY(1) VQ2 120u -1
    RP    3  4 3.00E6
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A2_129E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:19
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A2_129E  1 2 3 4 5
    *
    c1   11 12 2.887E-12
    c2    6  7 10.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 79.58E6 -80E6 80E6 80E6 -80E6
    ga    6  0 11 12 1.257E-3
    gcm   0  6 10 99 125.7E-12
    iss   3 10 dc 50.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 795.8
    rd2   4 12 795.8
    ro1   8  5 10
    ro2   7 99 10
    rss  10 99 4.000E6
    vb    9  0 dc 0
    vc    3 53 dc 1.5
    ve   54  4 dc .9
    vlim  7  8 dc 0
    vlp  91  0 dc 14
    vln   0 92 dc 14
    ******************************
    * Additions for the INA129E  *
    * (Enhanced) macromodel	     *
    * A2_129e sub-circuit	     *
    ******************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0 
    FQ1   3  0 POLY(1) VQ1 120u 1
    FQ2   0  4 POLY(1) VQ2 120u -1
    RP    3  4 3.00E6
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=15.00E-12 Beta=31.58E-3 Vto=-1)
    .ends
    *
    * A3_129E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.3a on 11/18/96 at 14:33
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_129E  1 2 3 4 5
    *
    c1   11 12 2.730E-12
    c2    6  7 15.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 163.2E6 -160E6 160E6 160E6 -160E6
    ga    6  0 11 12 122.5E-6
    gcm   0  6 10 99 12.25E-12
    iee  10  4 dc 63.95E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx
    r2    6  9 100.0E3
    rc1   3 11 8.162E3
    rc2   3 12 8.162E3
    re1  13 10 7.327E3
    re2  14 10 7.327E3
    ree  10 99 3.127E6
    ro1   8  5 300
    ro2   7 99 300
    vb    9  0 dc 0
    vc    3 53 dc 1.500
    ve   54  4 dc 1.400
    vlim  7  8 dc 0
    vlp  91  0 dc 5
    vln   0 92 dc 14
    ******************************
    * Additions for the INA129E  *
    * (Enhanced) macromodel	     *
    * A3_129e sub-circuit	     *
    ******************************
    *OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX 
    VQ1  21  0 0
    VQ2  22  0 0 
    FQ1   3  0 POLY(1) VQ1 206.7E-6 1
    FQ2   0  4 POLY(1) VQ2 206.7E-6 -1
    RQ    3  4 1.87e6
    *
    .model dx D(Is=800.0E-18)
    .model qx NPN(Is=800.0E-18 Bf=318.8)
    .ends
    *
    XDUT    1 2 3 4 5 8 9 10 INA129E/BB
    VSUP1   3 0 DC 15
    VSUP2   0 4 DC 15
    VREF    8 0 DC 0
    VP      1 0 DC 0
    *VP      1 0 PULSE(0 .1 2ns 2ns 2ns 30us 60us)
    VM      2 0 AC 1
    *VM  	2 0 PULSE(0 -.1 2ns 2ns 2ns 80us 160us)
    RG      9 10 RMOD {RVAL}
    *RG      9 10 50.05
    *RL      5 0  10K
    *CL      5 0 10000PF
    *
    .MODEL RMOD RES(R=1)
    *
    .OP
    .PROBE
    .AC DEC 10 .010 10000000
    .DC VP -40 40 .05
    .PARAM RVAL:1000
    .STEP PARAM RVAL LIST 1000000000000 5555.5 505.05 50.05
    *.TRAN 2ns 60us 100ns 100ns
    *.NOISE V([5]) VM 10
    *.OPTIONS ITL1=1000 ;ITL2=100
    *$
    **************************************************************************
    * INA131 = 2 x A1_131 + A3_131 OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 1/10/93 BY JLA.  INA114E.MOD MODIFIED TO INA131
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * NODE ASSIGNMENTS OF SUBCKT INA131 CORRESPOND TO 8 PIN DIP PACKAGE OF
    * BURR-BROWN'S INA131
    *
    * INA131 SUB-CIRCUIT
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |   INVERTING INPUT
    *                    |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   |   OUTPUT
    *                    |   |   |   |   |   REFERENCE
    *                    |   |   |   |   |   |   GAIN SET 1
    *                    |   |   |   |   |   |   |   GAIN SET 2
    *                    |   |   |   |   |   |   |   |
    .SUBCKT INA131/BB    3   2   7   4   6   5   1   8
    *
    * A1_131 SUBCIRCUIT
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X1                2   1   7   4   10   A1_131
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X2                3   8   7   4   11   A1_131
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X3                13  12  7   4   6   A3_131
    *
    RFB1 10  1 25K
    RFB2 11  8 25K
    R1   10 12 5K
    R2   12  6 24.9985K
    R3   11 13 5K
    R4   13  5 25K
    C1   12  6 5P
    C2   13  5 5P
    CC1  10  1 5P
    CC2  11  8 5P
    RG1   1  8 2631.58
    *
    .ENDS
    *
    * A1_131 OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:21
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |   POSITIVE POWER SUPPLY
    *                |   |   |   NEGATIVE POWER SUPPLY
    *                |   |   |   |   OUTPUT
    *                |   |   |   |   |
    .SUBCKT A1_131  1   2   3   4   5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 188.5E-12
    IEE  10  4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 5.305E3
    RC2   3 12 5.305E3
    RE1  13 10 4.348E3
    RE2  14 10 4.348E3
    REE  10 99 7.4074E6
    RO1   8  5 40
    RO2   7 99 320
    RP    3  4 52.53E3
    VB    9  0 DC 0
    VC    3 53 DC 1.672
    VE   54  4 DC 1.672
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3 NC=100 NR=100)
    .ENDS
    *
    * A3_131 OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:46
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_131   1 2 3 4 5
    *
    C1   11 12 13.51E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 251.9E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 339.3E-6
    GCM   0  6 10 99 339.3E-12
    IEE  10  4 DC 18E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.947E3
    RC2   3 12 2.947E3
    RE1  13 10 74.778
    RE2  14 10 74.778
    REE  10 99 11.111E6
    RO1   8  5 13
    RO2   7 99 117
    RP    3  4 30.123E3
    VB    9  0 DC 0
    VC    3 53 DC 1.972
    VE   54  4 DC 1.972
    VLIM  7  8 DC 0
    VLP  91  0 DC 12
    VLN   0 92 DC 12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=30.00E3)
    .ENDS
    *$
    **************************************************************************
    * INA131E = 2 x A1_131E + A3_131E OP AMPS + PRECISION RESISTOR NETWORK
    * CREATED ON 1/10/93 BY JLA.  INA114E.MOD MODIFIED TO INA131
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * NODE ASSIGNMENTS OF SUBCKT INA131 CORRESPOND TO 8 PIN DIP PACKAGE OF
    * BURR-BROWN'S INA131
    *
    * INA131E SUB-CIRCUIT
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |   INVERTING INPUT
    *                    |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   |   OUTPUT
    *                    |   |   |   |   |   REFERENCE
    *                    |   |   |   |   |   |   GAIN SET 1
    *                    |   |   |   |   |   |   |   GAIN SET 2
    *                    |   |   |   |   |   |   |   |
    .SUBCKT INA131E/BB   3   2   7   4   6   5   1   8
    *
    * A1_131E SUBCIRCUIT
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X1                2   1   7   4   10   A1_131E
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X2                3   8   7   4   11   A1_131E
    *
    * CONNECTIONS:    NON-INVERTING INPUT
    *                 |   INVERTING INPUT
    *                 |   |   POSITIVE POWER SUPPLY
    *                 |   |   |   NEGATIVE POWER SUPPLY
    *                 |   |   |   |   OUTPUT
    *                 |   |   |   |   |
    X3                13  12  7   4   6   A3_131E
    *
    RFB1 10  1 25K
    RFB2 11  8 25K
    R1   10 12 5K
    R2   12  6 24.9985K
    R3   11 13 5K
    R4   13  5 25K
    C1   12  6 5P
    C2   13  5 5P
    CC1  10  1 5P
    CC2  11  8 5P
    RG1   1  8 2631.58
    *
    .ENDS
    *
    * A1_131E OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:21
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |   INVERTING INPUT
    *                |   |   POSITIVE POWER SUPPLY
    *                |   |   |   NEGATIVE POWER SUPPLY
    *                |   |   |   |   OUTPUT
    *                |   |   |   |   |
    .SUBCKT A1_131E  1   2   3   4   5
    *
    C1   11 12 6.060E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 165.8E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 188.5E-12
    IEE  10  4 DC 27E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 5.305E3
    RC2   3 12 5.305E3
    RE1  13 10 4.348E3
    RE2  14 10 4.348E3
    REE  10 99 7.4074E6
    RO1   8  5 40
    RO2   7 99 320
    VB    9  0 DC 0
    VC    3 53 DC 1.672
    VE   54  4 DC 1.672
    VLIM  7  8 DC 0
    VLP  91  0 DC 2
    VLN   0 92 DC 2
    ****************************
    * A1_131E "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3  0 20 POLY(1) VLIM 0 1
    DQ1 20 21 DX
    DQ2 22 20 DX
    VQ1 21  0 0
    VQ2 22  0 0
    FQ1  3  0 POLY(1) VQ1 0 1
    FQ2  0  4 POLY(1) VQ2 0 -1
    * QUIESCIENT CURRENT
    RQ   3 4 52.53E3
    * DIFF INPUT CAPACITANCE
    CDIF 1 2 3E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM 1 0 3E-12
    C2CM 2 0 3E-12
    * INPUT PROTECTION
    VS11  3 31 0
    FS11  0  3 VS11 1
    S11  31  0 1 0 SP
    FS12  1  4 VS11 1
    VS21 32  4 0
    FS21  4  0 VS21 1
    S21   0 32 1 0 SM
    FS22  3  1 VS21 1
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=36.00E3 NC=100 NR=100)
    .MODEL SP VSWITCH(RON=10K ROFF=100G VON=15.6 VOFF=15.5)
    .MODEL SM VSWITCH(RON=10K ROFF=100G VON=-15.6 VOFF=-15.5)
    .ENDS
    *
    * A3_131E OPERATIONAL AMPLIFIER " MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 5.0 ON 1/22/92 AT 13:46
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT A3_131E  1 2 3 4 5
    *
    C1   11 12 13.51E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 251.9E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 339.3E-6
    GCM   0  6 10 99 339.3E-12
    IEE  10  4 DC 18E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 2.947E3
    RC2   3 12 2.947E3
    RE1  13 10 74.778
    RE2  14 10 74.778
    REE  10 99 11.111E6
    RO1   8  5 13
    RO2   7 99 117
    VB    9  0 DC 0
    VC    3 53 DC 1.972
    VE   54  4 DC 1.972
    VLIM  7  8 DC 0
    VLP  91  0 DC 12
    VLN   0 92 DC 12
    ****************************
    * A3_131E "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0 1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1 0 1
    FQ2   0  4 POLY(1) VQ2 0 -1
    * QUIESCIENT CURRENT
    RQ    3  4 30.123E3
    * DIFF INPUT CAPACITANCE
    CDIF  1  2 10E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  0 5E-12
    C2CM  2  0 5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=30.00E3)
    .ENDS
    *$
    **************************************************************************
    * INA132 = A3_132 OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * CREATED ON 11/12/96 AT 4:50
    * REV.A
    * REV.B  18 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    *  Notes on the INA132 macromodel:  The only modification
    *  made to the standard model was the inclusion of current source
    *  ip. The combination of ip and rp give a better simulation of
    *  quiescent current over different supply voltages.
    *
    * INA132 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  |  POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |  REFERENCE
    *                       |  |  |  |  |  |  SENSE
    *                       |  |  |  |  |  |  |
    .SUBCKT INA132/BB       1  2  3  4  5  8  9
    *
    * A3_132 SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  |  POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_132
    *
    R1    2  13   40000
    R2   13   9   39997
    C2   13   9   .15p
    R3    1  14   40000
    R4   14   8   40000
    *
    .ENDS
    *
    * INA132 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 11/08/96 at 17:04
    * Parts is a OrCAD product.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_132   1 2 3 4 5
    *
    c1   11 12 7.279E-12
    c2    6  7 40.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 1.326E9 -1E9 1E9 1E9 -1E9
    ga    6  0 11 12 75.40E-6
    gcm   0  6 10 99 377.0E-12
    iee   3 10 dc 4.730E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12  1 14 qx          
    r2    6  9 100.0E3
    rc1   4 11 13.26E3
    rc2   4 12 13.26E3
    re1  13 10 .9k        
    re2  14 10 .9k           
    ree  10 99 42.28E6
    ro1   8  5  200           
    ro2   7 99  200           
    vb    9  0 dc 0
    vc    3 53 dc 1.350
    ve   54  4 dc .80
    vlim  7  8 dc 0
    vlp  91  0 dc 12
    vln   0 92 dc 12
    rp    3  4  5E6       
    ip    3  4  149u     
    *
    .model dx D(Is=800.0E-18)
    .model qx PNP(Is=800.0E-18 Bf=300)
    .ENDS
    *$
    **************************************************************************
    * INA132E = A3_132E OPERATIONAL AMPLIFIER + PRECISION RESISTOR NETWORK
    * "E" IS ENHANCED MODEL
    * CREATED ON 11/11/96 AT 2:50
    * REV.A
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * INA132E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  |  POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |  REFERENCE
    *                       |  |  |  |  |  |  SENSE
    *                       |  |  |  |  |  |  |
    .SUBCKT INA132E/BB      1  2  3  4  5  8  9
    *
    * A3_132E SUB-CIRCUIT
    * CONNECTIONS:          NON-INVERTING INPUT
    *                       |  INVERTING INPUT
    *                       |  |  POSITIVE POWER SUPPLY
    *                       |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  OUTPUT
    *                       |  |  |  |  |
    X1                     14 13  3  4  5  A3_132E
    *
    R1    2  13   40000
    R2   13   9   39997
    C2   13   9   .15p
    R3    1  14   40000
    R4   14   8   40000
    *
    .ENDS
    *
    * INA132E operational amplifier "macromodel" subcircuit
    * created using Parts release 6.0 on 11/08/96 at 17:04
    * Parts is a OrCAD product.
    *
    * Notes on construction of the INA132E Extended Macromodel:
    *
    * Differential and Common-Mode capacitances for the op-amp have been
    * eliminated because the inputs to the op-amp are not brought out of
    * the package. This limits the capacitance at those nodes. Any effect
    * on the AC performance of the part (particularly the AC CMRR) is
    * minimal because of the INA132's bandwidth of 300kHz
    *
    * The noise of the simulated op-amp is larger than that in the actual
    * circuit. This comes from the op-amp that was generated by the Micro-
    * Sim Parts program. It should be noted that the dominant source of
    * voltage noise is the four 40K resistors. VN1, VN2, DN1, DN2, and EN
    * are included so that the 1/f noise is accurately simulated.
    * The input bias current is also roughly half of the actual circuit.
    * This discrepancy also comes from the Parts program.
    *
    * Simulations involving capacitive load drive are approximate. In the
    * actual circuit, the output stage characteristics change more
    * with the type of load. Swing to the rails are also modeled with 
    * approximations for the same reasons.
    *
    * While using the simulation in single supply, the simulation may not
    * give the correct result for the current coming out of the supplies
    * due to the nature of the model. The model was designed for dual
    * supply operation.
    *
    * For further information see the INA132 data sheet and the Burr-Brown
    * *** Based Macromodels Applications Bulletin.
    *
    * connections:   non-inverting input
    *                | inverting input
    *                | | positive power supply
    *                | | | negative power supply
    *                | | | | output
    *                | | | | |
    .subckt A3_132E  1 2 3 4 5
    *
    c1   11 12 7.279E-12
    c2    6  7 40.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 1.326E9 -1E9 1E9 1E9 -1E9
    ga    6  0 11 12 75.40E-6
    gcm   0  6 10 99 377.0E-12
    iee   3 10 dc 4.730E-6
    hlim 90  0 vlim 1K
    q1   11  2 13 qx
    q2   12 64 14 qx          
    r2    6  9 100.0E3
    rc1   4 11 13.26E3
    rc2   4 12 13.26E3
    re1  13 10 .9k           
    re2  14 10 .9k       
    ree  10 99 42.28E6
    ro1   8  5  200           
    ro2   7 99  200           
    vb    9  0 dc 0
    vc    3 53 dc 1.350
    ve   54  4 dc .80
    vlim  7  8 dc 0
    vlp  91  0 dc 12
    vln   0 92 dc 12
    **********************************
    *                                *
    * Additions for the              *
    * INA132E (enhanced) macro model *
    *                                *
    **********************************
    rp    3  4     5E6        ; replace rp w/ rp and ip to
                              ; get correct Iq change w/supply
    dq1  20   21   dx
    dq2  22   20   dx
    vq1  21    0   0
    vq2  22    0   0
    fq1   3    0   poly(1) vq1  149u  1      ; Models current from
    fq2   0    4   poly(1) vq2  149u  -1     ; supplies with load
    fq3   0   20   poly(1) vlim 0     1
    vn1  61    0   .6                        ; Noise model (1/f portion)
    vn2   0   62   .6
    dn1  61   63   dy
    dn2  63   62   dy
    en   64    1   63  0  .6
    *
    .model dx D(Is=800.0E-18)
    .model dy D(Is=1.9E-16 AF=1 KF=2.258E-17)
    .model qx PNP(Is=800.0E-18 Bf=300)
    .ENDS 
    *$
    **************************************************************************
    *  ISO120X *** MACROMODEL-- Copyright 1990 Burr-Brown Corp.
    *  REV.B   6/11/92 BCB, adjusted Iq to PDS typ, added Vos, adjusted output
    *          swing to PDS typ, adjusted barrier impedance
    *
    * Users should very carefully note the following factors regarding this
    * model:
    *
    * To help designers working with the IS0120 isolation amplifiers,
    * a *** listing for an equivalent circuit was developed (the listing
    * for the actual circuit is extremely long). Also, owing to the digital
    * transmission of the signal across the barrier, the listing for the
    * actual circuit could only be run with transient analysis, which would
    * be impractical for an application circuit. The equivalent circuit
    * listing, though, should be helpful.
    *
    * The equivalent circuit simulates both quiescent and output loading.
    * The model includes the output voltage swing and current limit, the
    * bandwidth, and the input and output impedance limits. It doesn't
    * simulate synchronization, though, nor the notched response. The macro
    * circuit may be run with ac, dc, or transient analysis.
    *
    * CONNECTIONS:     +VS1
    *                  |  -VS1
    *                  |  |  COM2
    *                  |  |  |  VOUT
    *                  |  |  |  |  VOUT SENSE
    *                  |  |  |  |  |  GND2
    *                  |  |  |  |  |  |  C2H
    *                  |  |  |  |  |  |  |  C2L
    *                  |  |  |  |  |  |  |  |  +VS2
    *                  |  |  |  |  |  |  |  |  |  -VS2
    *                  |  |  |  |  |  |  |  |  |  |  COM1
    *                  |  |  |  |  |  |  |  |  |  |  |  VIN
    *                  |  |  |  |  |  |  |  |  |  |  |  |  GND1
    *                  |  |  |  |  |  |  |  |  |  |  |  |  |
    .SUBCKT ISO120X/BB 3  4  9 10 11 12 13 14 15 16 21 23 24
    *
    *NOTE PINS 1, 2, AND 22 (C1H. C1L AND EXT OSC ARE NOT USED
    *POWER SUPPLY OUIESCENT CURRENTS
    *
    I1   3 24 4.0E-3
    I2  24  4 4.0E-3
    I3  15 12 4.5E-3
    I4  12 16 4.5E-3
    *INPUT SECTION
    VOS 23 60 5E-3
    R1  60 50 200E3
    R2  50 51 200E3
    E1  51 21 21 50 100E3
    E2  52  9 51 21 1
    *OUTPUT SECTION
    R3 52 13 200E3
    R4 13 11 200E3
    R5 10 12 20E3
    C1 13 14 150E-12
    E3 14 12 9 13 1.6E3
    E4 54 12 14 12 6.28
    Q1 55 55 54 N
    Q2 56 56 54 P
    Q3 57 55 10 N
    Q4 58 56 10 P
    *
    .MODEL N NPN BF=100
    .MODEL P PNP BF=100
    V1 15 57 2.5
    V2 58 16 2.5
    I5 15 55 250E-6
    I6 56 16 250E-6
    *BARRIER IMPEDANCE
    R6 24 12 100E12
    C2 24 12 2E-12
    *REFERENCE TO NODE 0 NEEDED BY SOME VERSIONS OF ***
    R7 23 0 100E9
    .ENDS
    *$
    **************************************************************************
    *  ISO121X *** MODEL-- Copyright 1990 Burr-Brown Corp.
    * Rev.B  6/11/92 BCB, adjusted Iq to PDS typ, added Vos, adjusted output
    *        swing to PDS typ, adjusted barrier impedance
    *
    * Users should very carefully note the following factors regarding this
    * model:
    *
    * To help designers working with the IS0121 isolation amplifiers,
    * a *** listing for an equivalent circuit was developed (the listing
    * for the actual circuit is extremely long). Also, owing to the digital
    * transmission of the signal across the barrier, the listing for the
    * actual circuit could only be run with transient analysis, which would
    * be impractical for an application circuit. The equivalent circuit
    * listing, though, should be helpful.
    *
    * The equivalent circuit simulates both quiescent and output loading.
    * The model includes the output voltage swing and current limit, the
    * bandwidth, and the input and output impedance limits. It doesn't
    * simulate synchronization, though, nor the notched response. The macro
    * circuit may be run with ac, dc, or transient analysis.
    *
    *                  +VS1
    *                  |  -VS1
    *                  |  |  COM2
    *                  |  |  |  VOUT
    *                  |  |  |  |  VOUT SENSE
    *                  |  |  |  |  |  GND2
    *                  |  |  |  |  |  |  C2H
    *                  |  |  |  |  |  |  |  C2L
    *                  |  |  |  |  |  |  |  |  +VS2
    *                  |  |  |  |  |  |  |  |  |  -VS2
    *                  |  |  |  |  |  |  |  |  |  |  COM1
    *                  |  |  |  |  |  |  |  |  |  |  |  VIN
    *                  |  |  |  |  |  |  |  |  |  |  |  |  GND1
    *                  |  |  |  |  |  |  |  |  |  |  |  |  |
    .SUBCKT ISO121X/BB 3  4 17 18 19 20 21 22 23 24 37 39 40
    *
    *NOTE PINS 1, 2, AND 38 (C1H. C1L AND EXT OSC ARE NOT USED
    *POWER SUPPLY OUIESCENT CURRENTS
    *
    I1  3 40 4.0E-3
    I2 40  4 4.0E-3
    I3 23 20 4.5E-3
    I4 20 24 4.5E-3
    *INPUT SECTION
    VOS 39 60 5E-3
    R1  60 50 200E3
    R2  50 51 200E3
    E1  51 37 37 50 100E3
    E2  52 17 51 37 1
    *OUTPUT SECTION
    R3 52 21 200E3
    R4 21 19 200E3
    R5 18 20 20E3
    C1 21 22 150E-12
    E3 22 20 17 21 1.6E3
    E4 54 20 22 20 6.28
    Q1 55 55 54 N
    Q2 56 56 54 P
    Q3 57 55 18 N
    Q4 58 56 18 P
    *
    .MODEL N NPN BF=100
    .MODEL P PNP BF=100
    V1 23 57 2.5
    V2 58 24 2.5
    I5 23 55 250E-6
    I6 56 24 250E-6
    *BARRIER IMPEDANCE
    R6 40 20 100E12
    C2 40 20 2E-12
    *REFERENCE TO NODE 0 NEEDED BY SOME VERSIONS OF ***
    R7 39  0 100E9
    *
    .ENDS
    *$
    **************************************************************************
    * ISO130X   SIMPLIFIED CIRCUIT MODEL
    * CREATED   12/19/94  SB
    * REV. A
    *
    * CONNECTIONS:      VS1
    *                   |  VIN+
    *                   |  |  VIN-
    *                   |  |  |  GND1
    *                   |  |  |  |  GND2
    *                   |  |  |  |  |  VOUT-
    *                   |  |  |  |  |  |  VOUT+
    *                   |  |  |  |  |  |  |  VS2
    .SUBCKT ISO130X/BB  1  2  3  4  5  6  7  8
    *
    * INPUT STAGE
    D1   2     1   DMOD
    D2   3     1   DMOD
    R1   2     9   530
    R2   3    10   530
    D3   4     9   DMOD
    D4   4    10   DMOD
    R3   4     9   530k
    R4   4    10   530k
    I1   4     9   670n
    I2   4    10   670n
    GVS1 1     4   POLY(1) (22,23) 4.37M 0 -445U 0 69.1U 0 -6.34U
    R5   1     4   790
    E1   11    5   POLY(1) (9,10) -3.6M 4
    V2   13   11   2.395
    V3   12    5   3.61
    Q1   13   11   14   QMOD
    Q2   17    5   16   QMOD
    RE1  14   15   31k
    RE2  15   16   31k
    I3   15    5   37.356U
    R6   12   17   65.7k
    TDELAY 17 5 18 5 Z0=65.7k TD=970n
    C1   18    5   6.3p
    R7   18   19   65.7k
    C2   19    5   6.3p
    R8   19   20   52.7k
    C3   20   22   15.2p
    R9   20   21   52.7k
    C4   21    5   6.52p
    E2   22    5   21  5  1
    E3   23    5   POLY(1) (22,5) 4.79 -1
    R10  22    7   11
    R11  23    6   11            
    R12  8     5   2.2k
    GVS2 8     5   POLY(1) (22,23) 8.71M 145U 189U -1.22U -15.8U -127N 1.43U
    *
    .MODEL  DMOD  D  IS=8E-13
    .MODEL  QMOD  NPN
    .ENDS
    *$
    **************************************************************************
    * IVC102M (switched integrator) MULTIPLE POLE/ZERO MACROMODEL
    * REV. A  Created 5-30-96 BCB
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    * 
    * NOTES : 
    *    1.  The transient time for the input to the switches (HOLD and 
    *        RESET) should be programmed to 6V/usec.  
    *        Complying with this requirment will give you greater
    *        success in convergence during transient analysis and
    *        a more accurate simulation of the effect of the 200nsec
    *        switching speed of the actual switching transistors in 
    *        the IVC102.  This is easily implemented with the PULSE
    *        command in ***.  If your input signal to the switches
    *        is faster than recommended above, the R-C, low-pass filter
    *        on the input of the switch will slow the signal down some-
    *        what, however not enough to comply with the data sheet stated
    *        switching speeds of 200nsec.
    *    2.  To insure proper operation, always establish the initial 
    *        bias point for the transient analysis with RESET and 
    *        HOLD equal to the potential at COM
    *
    *                   AGND
    *                   |  SWIN (SWITCH IN)
    *                   |  |  INM
    *                   |  |  |  C1
    *                   |  |  |  |  C2
    *                   |  |  |  |  |  C3
    *                   |  |  |  |  |  |  VM (NEGATIVE SUPPLY)
    *                   |  |  |  |  |  |  |  VOUT
    *                   |  |  |  |  |  |  |  |  S1 (HOLD)
    *                   |  |  |  |  |  |  |  |  |  S2 (RESET)
    *                   |  |  |  |  |  |  |  |  |  |  DGND
    *                   |  |  |  |  |  |  |  |  |  |  |  VP (POSITIVE SUPPLY)
    *                   |  |  |  |  |  |  |  |  |  |  |  |
    .SUBCKT  IVC102M/BB 1  2  3  4  5  6  9  10 11 12 13 14
    *
    X1  3 1 10 9 14 OPA_102
    *Integration Capacitors
    C1 10 4 CC 10E-12
    C2 10 5 CC 30E-12
    C3 10 6 CC 60E-12
    * Switches
    SH1  2  3 11 13 SWH
    SH2  2  3  2 13 SWT
    SR   3 10 12 13 SWR
    *
    .MODEL SWH VSWITCH(RON=1000G ROFF=1.7E3 VON=2 VOFF=0.8)
    .MODEL SWR VSWITCH(RON=1000G ROFF=1.5E3 VON=2 VOFF=0.8)
    .MODEL SWT VSWITCH(RON=1000G ROFF=10 VON=0.45 VOFF=0.55)
    .MODEL CC CAP(VC1=25E-6 TC1=-25E-6)
    .ENDS
    *
    *                 INM
    *                 |  INP
    *                 |  |  OUT
    *                 |  |  |  VM
    *                 |  |  |  |  VP
    *                 |  |  |  |  |
    .SUBCKT  OPA_102  2  3  6  4  7
    *
    * Amp input stage (2nd pole @ 35M Hz)
    J11 15  2 14 JX
    J12 16 13 14 JX
    C12 15 16 18.2E-12
    R13 15  7 796
    R14 16  7 796
    ISS 14  4 1.11E-3
    VOS 13  3 0.5E-3
    G1   2 30 POLY(3) (15,2) (14,2) (30,2) 0 1E-12 1E-12 1E-12
    G2  13 30 POLY(3) (16,13) (14,13) (30,13) 0 1E-12 1E-12 1E-12
    * Amp gain stage (130dB) and first pole (@ 4.20K HZ)
    R27  7 21 2.45E9
    R28  4 21 2.45E9
    C22  7 21 100E-12
    C23  4 21 100E-12
    G21  7 21 POLY(1) 15 16 1.451E-3 1.256E-3
    G22 21  4 POLY(1) 16 15 1.451E-3 1.256E-3
    I22  7 13 2.2E-3
    V21  7 22 1.885
    V22 23  4 1.885
    D21 21 22 DX
    D22 23 21 DX
    * Amp correction current and output stage
    IPS  7 30 9E-3
    RPS  7 30 100E3
    R9   7 71 100E3
    R10  4 71 100E3
    D91 21  6 DX
    D92  6 21 DX
    D93  7 94 DX
    D94  7 95 DX
    D95  4 94 DY
    D96  4 95 DY
    G91  7  6 21 7 .020387
    G92  4  6 21 4 .020387
    G95 94  4 6 21 .020387
    G96 95  4 21 6 .020387
    R91  7  6 49.051
    R92  4  6 49.051
    * Models
    .MODEL JX NJF(BETA=.788E-3 VTO=-2 IS=5E-14)
    .MODEL DX D(IS=1E-15)
    .MODEL DY D(IS=1E-15  BV=50)
    .ENDS 
    *$
    **************************************************************************
    * MPC100X1 4X1 VIDEO MULTIPLEXER MACROMODEL
    * REV.A   7/6/92   KL
    * REV.B   2/14/96  SB  changed node assignments
    *
    * CONNECTIONS:      IN 1
    *                   | IN 2
    *                   | | IN 3
    *                   | | | IN 4
    *                   | | | | SELECT 4
    *                   | | | | | SELECT 3
    *                   | | | | | |  POSITIVE SUPPLY
    *                   | | | | | |  |  OUPUT
    *                   | | | | | |  |  |  NEGATIVE SUPPLY
    *                   | | | | | |  |  |  |  SELECT 2
    *                   | | | | | |  |  |  |  |  SELECT 1
    *                   | | | | | |  |  |  |  |  |
    .SUBCKT MPC100X1/BB 1 3 5 7 8 9 10 11 12 13 14
    *
    X1  1 12 11 10 14  MUX1 ; One of four muxes
    X2  3 12 11 10 13  MUX1 ; One of four muxes
    X3  5 12 11 10  9  MUX1 ; One of four muxes
    X4  7 12 11 10  8  MUX1 ; One of four muxes
    *
    C208    8  0   2E-12
    C209    9  0   2E-12
    C211   11  0   2E-12
    C213   13  0   2E-12
    C214   14  0   2E-12
    *
    .ENDS 
    *
    * ONE OF FOUR CHANNELS OF THE VIDEO SIGNAL MULTIPLEXER
    *            INPUT
    *            |  NEGATIVE SUPPLY
    *            |  |  OUTPUT
    *            |  |  |  POSITIVE SUPPLY
    *            |  |  |  |  SELECT
    *            |  |  |  |  |
    *            |  |  |  |  |
    .SUBCKT MUX1 1 10 11 12 14
    *
    V22  22  0  1.5
    V27  12 27  1.5
    V28  28 10  1.5
    G21  25 26  14 22  -87E-6
    C23  23  0  2.0E-12
    C24  23 11  0.1E-12
    C25  25  0  0.6E-12
    C26  26  0  0.6E-12
    R21  14  0  40E3
    R22  22  0  1E9
    R23  23  0  1.3E6
    R24  23  1  145
    Q22  10 10  25  NI
    Q21  26 26  12  NI
    Q23  10 23  25  PI
    Q24  12 23  26  NI
    Q25  27 25  11  NI 4
    Q26  28 26  11  PI 4
    *
    .MODEL NI NPN
    .MODEL PI PNP
    .ENDS
    *$
    **************************************************************************
    * MPC100X2   4X1 VIDEO MULTIPLEXER MACROMODEL
    * REV.A   7/6/92  KL
    * REV.B   2/14/96 SB  changed node assignments
    *
    * NOTE: CHANNELS THAT ARE DISABLED DURING DC CONVERGENCE REQUIRE A NODESET.
    *       BRIEFLY, THE NODES FOR THE MUX2 SUBCIRCUIT SHOULD BE SET AS FOLLOWS:
    *          V(27)=+4.61943527 V(28)=-4.61934561
    *          V(35)=-2.80931530 V(36)=+2.80931527
    *          V(39)=-1.30810853 V(40)=+1.30803889
    *          V(41)=-34.818621E-6
    *       THE FILE THAT CONTAINS THE COMMAND TO ACCESS THIS MACRO MODEL SHOULD
    *       CONTAIN THIS NODE SET FOR THE DISABLED CHANNELS OF THE MPC100. FOR 
    *       EXAMPLE, IF CHANNEL A IS ON AND CHANNEL B, C, AND D ARE OFF DURING
    *       DC CONVERGENCE AND THE DEVICE NAME FOR THE MPC100X2 MODEL IS IS X1, 
    *       THE REQUIRED NODESET WOULD BE:
    *
    * Channel B = OFF
    *  .NODESET  V(X1.X2.27)=+4.61943527 V(X1.X2.28)=-4.61934561
    *  .NODESET  V(X1.X2.35)=-2.80931530 V(X1.X2.36)=+2.80931527
    *  .NODESET  V(X1.X2.39)=-1.30810853 V(X1.X2.40)=+1.30803889
    *  .NODESET  V(X1.X2.41)=-34.818621E-6
    *
    *Channel C = OFF
    *  .NODESET  V(X1.X3.27)=+4.61943527 V(X1.X3.28)=-4.61934561
    *  .NODESET  V(X1.X3.35)=-2.80931530 V(X1.X3.36)=+2.80931527
    *  .NODESET  V(X1.X3.39)=-1.30810853 V(X1.X3.40)=+1.30803889
    *  .NODESET  V(X1.X3.41)=-34.818621E-6
    *
    *Channel D = OFF
    *  .NODESET  V(X1.X4.27)=+4.61943527 V(X1.X4.28)=-4.61934561
    *  .NODESET  V(X1.X4.35)=-2.80931530 V(X1.X4.36)=+2.80931527
    *  .NODESET  V(X1.X4.39)=-1.30810853 V(X1.X4.40)=+1.30803889
    *  .NODESET  V(X1.X4.41)=-34.818621E-6
    *
    * CONNECTIONS:      IN 1
    *                   | IN 2
    *                   | | IN 3
    *                   | | | IN 4
    *                   | | | | SELECT 4
    *                   | | | | | SELECT 3
    *                   | | | | | |  POSITIVE SUPPLY
    *                   | | | | | |  |  OUPUT
    *                   | | | | | |  |  |  NEGATIVE SUPPLY
    *                   | | | | | |  |  |  |  SELECT 2
    *                   | | | | | |  |  |  |  |  SELECT 1
    *                   | | | | | |  |  |  |  |  |
    .SUBCKT MPC100X2/BB 1 3 5 7 8 9 10 11 12 13 14
    *
    X1  1 12 11 10 14  MUX2 ; One of four muxes
    X2  3 12 11 10 13  MUX2 ; One of four muxes
    X3  5 12 11 10  9  MUX2 ; One of four muxes
    X4  7 12 11 10  8  MUX2 ; One of four muxes
    *
    C201    1  0   2E-12
    C203    3  0   2E-12
    C205    5  0   2E-12
    C207    7  0   2E-12
    C208    8  0   2E-12
    C209    9  0   2E-12
    C211   11  0   2E-12
    C213   13  0   2E-12
    C214   14  0   2E-12
    *
    .ENDS 
    *
    * ONE OF FOUR CHANNELS OF THE VIDEO SIGNAL MULTIPLEXER
    *            INPUT
    *            |  NEGATIVE SUPPLY
    *            |  |  OUTPUT
    *            |  |  |  POSITIVE SUPPLY
    *            |  |  |  |  SELECT
    *            |  |  |  |  |
    *            |  |  |  |  |
    .SUBCKT MUX2 1 10 11 12 14
    *
    C24  24  0  3.0E-12
    C28  28 10  0.1E-12
    C33   1 11  0.1E-12
    *
    R21  21 14  40E3
    R23  23 24  22E3
    R29  29 12  100
    R30  30 10  100
    R31  31 12  100 
    R32  32 10  100
    R43  43 12  40E3
    R44  44 10  40E3
    R45  45 46  80E3
    *
    Q21  24 21 22  NI
    Q22  22 22  0  NI
    Q23  23 23 12  PI
    Q24  25 23 12  PI
    Q25  25 25 26  NI
    Q26   0  0 26  PI
    Q27  27 25 42  NI  8
    Q28  28  0 42  PI  8
    Q29  27 27 29  PIJ 6
    Q30  28 28 30  NIJ 6
    Q31  35 27 31  PIJ 6
    Q32  36 28 32  NIJ 6
    Q33  10  1 33  PIJ 2
    Q34  12  1 34  NIJ 2
    Q35  35 35 33  NIJ 2
    Q36  36 36 34  PIJ 2
    Q37  35 35 39  NIJ 6
    Q38  36 36 40  PIJ 6
    Q39  39 39 41  NIJ 6
    Q40  40 40 41  PIJ 6
    Q41  12 39 11  NIJ 10
    Q42  10 40 11  PIJ 10
    Q43  36 45 43  PI
    Q44  35 46 44  NI
    Q45  45 45 43  PI  5
    Q46  46 46 44  NI  5
    *
    .MODEL PI PNP
    .MODEL NI NPN
    .MODEL PIJ PNP
    +BF  = 110       IS  = 0.1567E-16
    +CJC = 0.029p    AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017p    EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050p    FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80p    MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00p    MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680
    *
    .MODEL NIJ NPN
    +BF  = 110       IS  = 0.1567E-16
    +CJC = 0.029p    AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017p    EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050p    FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80p    MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00p    MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680
    *
    .ENDS
    *$
    **************************************************************************
    * MPC102X1  DUAL 2X1 VIDEO MULTIPLEXER MACROMODEL
    * REV.A  1/10/95  KL/SB
    * REV.B  2/14/96  SB  changed node assignments
    *
    * CONNECTIONS:      IN 1
    *                   | IN 2
    *                   | | +Vcc
    *                   | | | IN 3
    *                   | | | | IN 4
    *                   | | | | | SELECT 4
    *                   | | | | | |  SELECT 3 
    *                   | | | | | |  |  OUT 2
    *                   | | | | | |  |  |  -Vcc
    *                   | | | | | |  |  |  |  OUT 1
    *                   | | | | | |  |  |  |  |  SELECT 2
    *                   | | | | | |  |  |  |  |  |  SELECT 1
    .SUBCKT MPC102X1/BB 1 3 4 5 7 8  9 10 11 12 13 14
    *
    X1  1  11  12  4  14  MUX3 ; Channel 1 into Out 1
    X2  3  11  12  4  13  MUX3 ; Channel 2 into Out 1
    X3  5  11  10  4   9  MUX3 ; Channel 3 into Out 2
    X4  7  11  10  4   8  MUX3 ; Channel 4 into Out 2
    *
    C208    8  0   2E-12
    C209    9  0   2E-12
    C210   10  0   2E-12
    C212   12  0   2E-12
    C213   13  0   2E-12
    C214   14  0   2E-12
    *
    .ENDS 
    *
    * ONE OUT OF FOUR CHANNELS OF THE MPC102X1 MODEL
    *            INPUT
    *            |  NEGATIVE SUPPLY
    *            |  |  OUTPUT
    *            |  |  |  POSITIVE SUPPLY
    *            |  |  |  |  SELECT
    *            |  |  |  |  |
    *            |  |  |  |  |
    .SUBCKT MUX3 1 10 11 12 14
    *
    V22  22  0  1.5
    V27  12 27  1.5
    V28  28 10  1.5
    *
    G21  25 26  14 22  -87E-6
    *
    C23  23  0  2.0E-12
    C24  23 11  0.1E-12
    C25  25  0  0.6E-12
    C26  26  0  0.6E-12
    *
    R21  14  0  40E3
    R22  22  0  1E9
    R23  23  0  1.3E6
    R24  23  1  145
    *
    Q22  10 10 25  NI
    Q21  26 26 12  NI
    Q23  10 23 25  PI
    Q24  12 23 26  NI
    Q25  27 25 11  NI 4
    Q26  28 26 11  PI 4
    *
    .MODEL NI NPN
    .MODEL PI PNP
    .ENDS
    *$
    **************************************************************************
    * MPC104X1  2X1 VIDEO MULTIPLEXER MACROMODEL
    * REV.A   1/10/95   KL/SB
    * REV.B   2/14/96   SB   changed node assignments
    *
    * CONNECTIONS:      IN1
    *                   |  +Vcc
    *                   |  |  IN2
    *                   |  |  |  SELECT2
    *                   |  |  |  |  OUT
    *                   |  |  |  |  |  -Vcc
    *                   |  |  |  |  |  |  SELECT 1
    *                   |  |  |  |  |  |  |
    .SUBCKT MPC104X1/BB 1  3  4  5  6  7  8 
    *
    X1  1  7  6  3  8  MUX4 ; One out of two channels
    X2  4  7  6  3  5  MUX4 ; One out of two channels
    *
    C208    8  0   2E-12
    C205    5  0   2E-12
    C206    6  0   2E-12
    *
    .ENDS 
    *
    * ONE OUT OF TWO CHANNELS OF THE VIDEO SIGNAL MULTIPLEXER
    *            INPUT
    *            |  NEGATIVE SUPPLY
    *            |  |  OUTPUT
    *            |  |  |  POSITIVE SUPPLY
    *            |  |  |  |  SELECT
    *            |  |  |  |  |
    *            |  |  |  |  |
    .SUBCKT MUX4 1 10 11 12 14
    *
    V22  22  0  1.5
    V27  12 27  1.5
    V28  28 10  1.5
    G21  25 26  14 22  -87E-6
    C23  23  0  2.0E-12
    C24  23 11  0.1E-12
    C25  25  0  0.6E-12
    C26  26  0  0.6E-12
    R21  14  0  40E3
    R22  22  0  1E9
    R23  23  0  1.3E6
    R24  23  1  145
    Q22  10 10 25  NI
    Q21  26 26 12  NI
    Q23  10 23 25  PI
    Q24  12 23 26  NI
    Q25  27 25 11  NI 4
    Q26  28 26 11  PI 4
    *
    .MODEL NI NPN
    .MODEL PI PNP
    *
    .ENDS
    *$
    **************************************************************************
    * OPA1013 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/09/90 AT 15:20
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA1013/BB  1 2 3 4 5
    *
    C1   11 12 6.062E-12
    C2    6  7 21.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 1.624E9 -2E9 2E9 2E9 -2E9
    GA    6  0 11 12 92.36E-6
    GCM   0  6 10 99 130.5E-12
    IEE   3 10 DC 8.418E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   4 11 10.83E3
    RC2   4 12 10.83E3
    RE1  13 10 4.659E3
    RE2  14 10 4.659E3
    REE  10 99 23.76E6
    RO1   8  5 120
    RO2   7 99 30
    RP    3  4 87.82E3
    VB    9  0 DC 0
    VC    3 53 DC 1
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 30
    VLN   0 92 DC 30
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX PNP(IS=800.0E-18 BF=466.7)
    .ENDS
    *$
    **************************************************************************
    * OPA1013E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/08/90 AT 16:35
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA1013E/BB 1 2 3 4 5
    *
    C1   11 12 6.062E-12
    C2    6  7 21.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 1.624E9 -2E9 2E9 2E9 -2E9
    GA    6  0 11 12 92.36E-6
    GCM   0  6 10 99 130.5E-12
    IEE   3 10 DC 8.418E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   4 11 10.83E3
    RC2   4 12 10.83E3
    RE1  13 10 4.659E3
    RE2  14 10 4.659E3
    REE  10 99 23.76E6
    RO1   8  5 120
    RO2   7 99 30
    *  RP    3  4 87.82E3
    VB    9  0 DC 0
    VC    3 53 DC 1
    VE   54  4 DC 1
    VLIM  7  8 DC 0
    VLP  91  0 DC 30
    VLN   0 92 DC 30
    ****************************
    * OPA1013 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  0.2814E-3  1
    FQ2   0  4 POLY(1) VQ2  0.2814E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  5.0E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX PNP(IS=800.0E-18 BF=466.7)
    .ENDS
    *$
    **************************************************************************
    * OPA111 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/12/90 AT 16:35
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA111/BB   1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.717E6 -5E6 5E6 5E6 -5E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 15.90E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=400.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA111E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/27/90 AT 11:56
    * REV.B 3/21/92 BCB: added input bias current correction and
    *                    current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA111E/BB  1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.717E6 -5E6 5E6 5E6 -5E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 15.90E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 400E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 400E-9
    R2    6  9 100.0E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    ****************************
    * OPA111 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.30E-3  1
    FQ2   0  4 POLY(1) VQ2  1.30E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  7.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  64  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  64  99 1.5E-12
    C2CM   2  99 1.5E-12
    * INPUT VOLTAGE NOISE
    VN1 61   4  0.6
    VN2  4  62 0.6
    DN1 61  63 DY
    DN2 63  62 DY
    EN  64   1  63 4 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=3.8E-16 AF=1 KF=1.175E-16)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=400.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA121 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 14:41
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA121/BB   1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E6 -3E6 3E6 3E6 -3E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 31.72E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA121E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/27/90 AT 11:56
    * REV.B 3/21/92 BCB: added input bias current correction and
    *                    current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA121E/BB  1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E6 -3E6 3E6 3E6 -3E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 31.72E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 800E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 800E-9
    R2    6  9 100.0E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    ****************************
    * OPA121 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.30E-3  1
    FQ2   0  4 POLY(1) VQ2  1.30E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  7.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT VOLTAGE NOISE
    VN1 61   4  0.6
    VN2  4  62 0.6
    DN1 61  63 DY
    DN2 63  62 DY
    EN  64   1  63 4 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=3.8E-16 AF=1 KF=2.089E-16)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA124 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED 11/8/93  BCB
    * REV. A
    *  
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   |  INVERTING INPUT
    *                   |  |  POSITIVE POWER SUPPLY
    *                   |  |  |  NEGATIVE POWER SUPPLY
    *                   |  |  |  |  OUTPUT
    *                   |  |  |  |  |
    .SUBCKT OPA124/BB   1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.717E6 -5E6 5E6 5E6 -5E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 15.90E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=400.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA124E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED 11/8/93 BCB
    * REV. A
    *  
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   |  INVERTING INPUT
    *                   |  |  POSITIVE POWER SUPPLY
    *                   |  |  |  NEGATIVE POWER SUPPLY
    *                   |  |  |  |  OUTPUT
    *                   |  |  |  |  |
    .SUBCKT OPA124E/BB  1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.717E6 -5E6 5E6 5E6 -5E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 15.90E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 400E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 400E-9
    R2    6  9 100E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    ****************************
    * OPA124 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.30E-3  1
    FQ2   0  4 POLY(1) VQ2  1.30E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  7.5E4
    * DIFF INPUT CAPACITANCE
    CDIF 64  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  64  99 1.5E-12
    C2CM   2  99 1.5E-12
    * INPUT VOLTAGE NOISE 
    VN1 61   4  0.6
    VN2  4  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 4 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=3.8E-16 AF=1 KF=1.175E-16)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=400.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA128 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 08:27
    * REV. A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA128/BB   1 2 3 4 5
    *
    C1   11 12 2.204E-12
    C2    6  7 25.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 106.6E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 314.2E-6
    GCM   0  6 10 99 395.5E-12
    ISS   3 10 DC 80.00E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 3.183E3
    RD2   4 12 3.183E3
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 33.33E3
    RSS  10 99 2.500E6
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 29
    VLN   0 92 DC 29
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=20.00E-15 BETA=616.8E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA128E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/28/90 AT 15:02
    * REV.B 3/21/92 BCB: added input bias current correction and
    *                    current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA128E/BB  1 2 3 4 5
    *
    C1   11 12 2.204E-12
    C2    6  7 25.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 106.6E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 314.2E-6
    GCM   0  6 10 99 395.5E-12
    ISS   3 10 DC 80.00E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 120E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 120E-9
    R2    6  9 100.0E3
    RD1   4 11 3.183E3
    RD2   4 12 3.183E3
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 33.33E3
    RSS  10 99 2.500E6
    VB    9  0 DC 0
    VC    3 53 DC 2
    VE   54  4 DC 2
    VLIM  7  8 DC 0
    VLP  91  0 DC 29
    VLN   0 92 DC 29
    ****************************
    * OPA128 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  0.700E-3  1
    FQ2   0  4 POLY(1) VQ2  0.700E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.0E-12
    C2CM  2  99 1.0E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=1.9E-16 AF=1 KF=5.643E-16)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=20.00E-15 BETA=616.8E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA129 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.2 on 12/15/94 at 14:58
    * REV.A    SB
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA129/BB   1 2 3 4 5
    *
    c1   11 12 4.000E-12
    c2    6  7 2.204E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 192.5E6 -20E6 20E6 20E6 -20E6
    ga    6  0 11 12 314.2E-6
    gcm   0  6 10 99 395.5E-12
    iss   3 10 dc 80.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 3.183E3
    rd2   4 12 3.183E3
    ro1   8  5 25
    ro2   7 99 75
    rp    3  4 25.00E3
    rss  10 99 2.500E6
    vb    9  0 dc 0
    vc    3 53 dc 2
    ve   54  4 dc 2
    vlim  7  8 dc 0
    vlp  91  0 dc 22.00E-3
    vln   0 92 dc 22.00E-3
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=20.00E-15 Beta=616.8E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA129E operational amplifier "macromodel" subcircuit
    * "E" is enhanced model
    * created using Parts release 5.2 on 12/15/94 at 14:58
    * REV. A   SB
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA129E/BB  1 2 3 4 5
    *
    c1   11 12 4.000E-12
    c2    6  7 2.204E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 192.5E6 -20E6 20E6 20E6 -20E6
    ga    6  0 11 12 314.2E-6
    gcm   0  6 10 99 395.5E-12
    iss   3 10 dc 80.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    g11   2  4 poly(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 100E-9
    g21   1  4 poly(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 100E-9
    r2    6  9 100.0E3
    rd1   4 11 3.183E3
    rd2   4 12 3.183E3
    ro1   8  5 25
    ro2   7 99 75
    rp    3  4 25.00E3
    rss  10 99 2.500E6
    vb    9  0 dc 0
    vc    3 53 dc 2
    ve   54  4 dc 2
    vlim  7  8 dc 0
    vlp  91  0 dc 22.00E-3
    vln   0 92 dc 22.00E-3
    *****************************
    * OPA129 "E" ENHANCEMENTS
    *****************************
    * Output Supply Mirror
    fq3     0  20  poly(1)  vlim 0 1
    dq1    20  21  dx
    dq2    22  20  dx
    vq1    21   0  0
    vq2    22   0  0
    fq1     3   0  poly(1) vq1  0.700E-3   1
    fq2     0   4  poly(1) vq2  0.700E-3  -1
    * Diff Input Capacitance
    cdif    1   2  1.0E-12
    * Common Mode Input Capacitance
    c1cm    1  99  1.0E-12
    c2cm    2  99  1.0E-12
    * Input Voltage Noise
    vn1    61   0  0.6
    vn2     0  62  0.6
    dn1    61  63  dy
    dn2    63  62  dy
    en     64   1  63  0  1
    * Input Current Noise
    rn1     0  65  60.3865
    rn2    65  66  60.3865
    rn3    66   0  120.773
    rn4     0  67  60.3865
    rn5    67  68  60.3865
    rn6    68   0  120.773
    *
    .model dy D(IS=1.9E-16 AF=1 KF=5.643E-16)   
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=20.00E-15 Beta=616.8E-6 Vto=-1)
    .ends 
    *$
    **************************************************************************
    * OPA130 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.2i on 04/03/96 at 16:48
    * Parts is a OrCAD product.
    * Rev. A  SB
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA130/BB   1 2 3 4 5
    *
    c1   11 12 4.330E-12
    c2    6  7 15.00E-12
    css  10 99 1.000E-30
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 2.386E9 -2E9 2E9 2E9 -2E9
    ga    6  0 11 12 94.25E-6
    gcm   0  6 10 99 530.1E-12
    iss   3 10 dc 30.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 10.61E3
    rd2   4 12 10.61E3
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 56.25E3
    rss  10 99 6.667E6
    vb    9  0 dc 0
    vc    3 53 dc 1.500
    ve   54  4 dc 1
    vlim  7  8 dc 0
    vlp  91  0 dc 18
    vln   0 92 dc 18
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=2.500E-12 Beta=296.1E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA131 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 01/14/95 at 21:25
    * REV. A    SB
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA131/BB   1 2 3 4 5
    *
    c1   11 12 4.197E-12
    c2    6  7 18.00E-12
    css  10 99 7.200E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 452.4E-6
    gcm   0  6 10 99 45.24E-9
    iss   3 10 dc 252.0E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 2.210E3
    rd2   4 12 2.210E3
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 20.00E3
    rss  10 99 793.7E3
    vb    9  0 dc 0
    vc    3 53 dc 2.500
    ve   54  4 dc 2.500
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=2.500E-12 Beta=812.1E-6 Vto=-1)
    .ends  OPA131/BB
    *$
    **************************************************************************
    * OPA131E "Enhanced" operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 01/14/95 at 21:25
    * REV.A     SB - model includes input bias current correction,
    *                voltage and current noise.
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA131E/BB  1 2 3 4 5
    *
    c1   11 12 4.197E-12
    c2    6  7 18.00E-12
    css  10 99 7.200E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 452.4E-6
    gcm   0  6 10 99 45.24E-9
    iss   3 10 dc 252.0E-6
    hlim 90  0 vlim 1K
    j1   11  2  10 jx
    j2   12 64  10 jx
    g11   2  4 Poly(4)  (10,2) (11,2) (4,2) (66,0) 0 1e-12 1e-12 1e-12 3e-6
    g12   1  4 Poly(4)  (10,1) (12,1) (4,1) (68,0) 0 1e-12 1e-12 1e-12 3e-6
    r2    6  9 100.0E3
    rd1   4 11 2.210E3
    rd2   4 12 2.210E3
    ro1   8  5 50
    ro2   7 99 25
    * rp    3  4 20.00E3
    rss  10 99 793.7E3
    vb    9  0 dc 0
    vc    3 53 dc 2.500
    ve   54  4 dc 2.500
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    **********************************
    * OPA131 "E" - Enhancements
    **********************************
    * Output Supply Mirror
    FQ3    0    20    Poly(1) Vlim 0   1
    DQ1   20    21    DX
    DQ2   22    20    DX
    VQ1   21     0    0
    VQ2   22     0    0
    FQ1    3     0    Poly(1) VQ1   1.06E-3   1
    FQ2    0     4    Poly(1) VQ2   1.06E-3  -1
    * Quiescent Current
    RQ     3     4    160E3 
    * Diff Input Capacitance
    CDIF   1     2    1E-12
    * Common Mode Input Capacitance
    C1CM   1    99    1.5E-12
    C2CM   2    99    1.5E-12
    * Input Voltage Noise
    VN1   61     0  0.6
    VN2    0    62  0.6
    DN1   61    63  DY
    DN2   63    62  DY
    EN    64     1    63   0    1
    * Input Current Noise
    RN1    0    65  60.3865
    RN2   65    66  60.3865
    RN3   66     0  120.773
    RN4    0    67  60.3865
    RN5   67    68  60.3865
    RN6   68     0  120.773
    *
    .model dy D(Is=1.9E-16 RS=2000 AF=1 KF=2.258E-17)
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=2.500E-12 Beta=812.1E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA132 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.2i on 02/23/96 at 08:48
    * Parts is a OrCAD product.
    * REV. A  SB 7/20/96
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .SUBCKT OPA132/BB   1 2 3 4 5
    *
    C1   11 12 3.240E-12
    C2    6  7 8.000E-12
    CSS  10 99 1.000E-30
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 248.0E6 -250E6 250E6 250E6 -250E6
    GA    6  0 11 12 402.0E-6
    GCM   0  6 10 99 4.020E-9
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 2.490E3
    RD2   4 12 2.490E3
    RO1   8  5 20
    RO2   7 99 20
    RP    3  4 7.500E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 1.200
    VE   54  4 DC .9
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-15 BETA=1.010E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA134 operational amplifier "macromodel" subcircuit
    * This model can also be used for OPA2134 (dual op amp)
    * created using Parts release 6.2i on 02/23/96 at 08:48
    * Parts is a OrCAD product.
    * REV. A  SB 7/20/96 adapted from OPA132 model 9/24/96  BCT
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .SUBCKT OPA134/BB   1 2 3 4 5
    *
    C1   11 12 3.240E-12
    C2    6  7 8.000E-12
    CSS  10 99 1.000E-30
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 248.0E6 -250E6 250E6 250E6 -250E6
    GA    6  0 11 12 402.0E-6
    GCM   0  6 10 99 4.020E-9
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 2.490E3
    RD2   4 12 2.490E3
    RO1   8  5 20
    RO2   7 99 20
    RP    3  4 7.500E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 1.200
    VE   54  4 DC .9
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.500E-15 BETA=1.010E-3 VTO=-1)
    .ENDS 
    *$
    **************************************************************************
    * OPA177 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 15:33
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA177/BB   1 2 3 4 5
    *
    C1   11 12 40.00E-12
    C2    6  7 80.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 1.326E9 -1E9 1E9 1E9 -1E9
    GA    6  0 11 12 301.6E-6
    GCM   0  6 10 99 30.16E-12
    IEE  10  4 DC 20.00E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 3.316E3
    RC2   3 12 3.316E3
    RE1  13 10 729.2
    RE2  14 10 729.2
    REE  10 99 9.999E6
    RO1   8  5 30
    RO2   7 99 30
    RP    3  4 15.15E3
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 22
    VLN   0 92 DC 22
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=10.00E3)
    .ENDS
    *$
    **************************************************************************
    * OPA177E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/20/90 AT 15:29
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   |   INVERTING INPUT
    *                   |   |  POSITIVE POWER SUPPLY
    *                   |   |  | NEGATIVE POWER SUPPLY
    *                   |   |  | | OUTPUT
    *                   |   |  | | |
    .SUBCKT OPA177E/BB INP INN 3 4 5
    *
    C1   11 12 40.00E-12
    C2    6  7 80.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 1.326E9 -1E9 1E9 1E9 -1E9
    GA    6  0 11 12 301.6E-6
    GCM   0  6 10 99 30.16E-12
    IEE  10  4 DC 20.00E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 3.316E3
    RC2   3 12 3.316E3
    RE1  13 10 729.2
    RE2  14 10 729.2
    REE  10 99 9.999E6
    RO1   8  5 30
    RO2   7 99 30
    *  RP    3  4 15.15E3
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 22
    VLN   0 92 DC 22
    ****************************
    * OPA177 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  0.976E-3  1
    FQ2   0  4 POLY(1) VQ2  0.976E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  3.0E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT PROTECTION
    R1IN  INP 1  500
    D1A    1 VD1 DX
    D1B   VD1 2  DX
    R2IN  INN 2  500
    D2A    2 VD2 DX
    D2B   VD2 1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=10.00E3)
    .ENDS
    *$
    **************************************************************************
    * OPA2107 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/17/90 AT 10:03
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA2107/BB  1 2 3 4 5
    *
    C1   11 12 7.764E-12
    C2    6  7 33.30E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.124E6 -2E6 2E6 2E6 -2E6
    GA    6  0 11 12 941.5E-6
    GCM   0  6 10 99 9.415E-9
    ISS   3 10 DC 599.4E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.062E3
    RD2   4 12 1.062E3
    RO1   8  5 50
    RO2   7 99 50
    RP    3  4 13.33E3
    RSS  10 99 333.7E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.000E-12 BETA=739.5E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2107E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/17/90 AT 10:03
    * REV.B 3/21/92 BCB:  added input bias current correction and
    *                     current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA2107E/BB 1 2 3 4 5
    *
    C1   11 12 7.764E-12
    C2    6  7 33.30E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.124E6 -2E6 2E6 2E6 -2E6
    GA    6  0 11 12 941.5E-6
    GCM   0  6 10 99 9.415E-9
    ISS   3 10 DC 599.4E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 900E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 900E-9
    R2    6  9 100.0E3
    RD1   4 11 1.062E3
    RD2   4 12 1.062E3
    RO1   8  5 50
    RO2   7 99 50
    *  RP    3  4 13.33E3
    RSS  10 99 333.7E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    ****************************
    * OPA2107 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.350E-3  1
    FQ2   0  4 POLY(1) VQ2  1.350E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.0E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.0E-12
    C2CM  2  99 2.0E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=1E-12 AF=1 KF=68.36E-15)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.000E-12 BETA=739.5E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2111 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 14:57
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA2111/BB  1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.717E6 -5E6 5E6 5E6 -5E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 15.90E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 4
    VE   54  4 DC 4
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2111E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/27/90 AT 11:56
    * REV.B 3/21/92 BCB:  added input bias current correction and
    *                     current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA2111E/BB 1 2 3 4 5
    *
    C1   11 12 72.79E-12
    C2    6  7 400.0E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 4.717E6 -5E6 5E6 5E6 -5E6
    GA    6  0 11 12 5.027E-3
    GCM   0  6 10 99 15.90E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 600E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 600E-9
    R2    6  9 100.0E3
    RD1   4 11 198.9
    RD2   4 12 198.9
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 12.00E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 4
    VE   54  4 DC 4
    VLIM  7  8 DC 0
    VLP  91  0 DC 40
    VLN   0 92 DC 40
    ****************************
    * OPA2111 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.30E-3  1
    FQ2   0  4 POLY(1) VQ2  1.30E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  7.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT VOLTAGE NOISE
    VN1 61   4  0.6
    VN2  4  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 4 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=2.25E-16 AF=1 KF=91E-18)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=15.79E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2131 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 01/14/95 at 21:25
    * REV. A    SB
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA2131/BB  1 2 3 4 5
    *
    c1   11 12 4.197E-12
    c2    6  7 18.00E-12
    css  10 99 7.200E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 452.4E-6
    gcm   0  6 10 99 45.24E-9
    iss   3 10 dc 252.0E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 2.210E3
    rd2   4 12 2.210E3
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 20.00E3
    rss  10 99 793.7E3
    vb    9  0 dc 0
    vc    3 53 dc 2.500
    ve   54  4 dc 2.500
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=2.500E-12 Beta=812.1E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA2131E "Enhanced" operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 01/14/95 at 21:25
    * REV.A     SB - model includes input bias current correction,
    *                voltage and current noise.
    *
    * connections:       non-inverting input
    *                    | inverting input
    *                    | | positive power supply
    *                    | | | negative power supply
    *                    | | | | output
    *                    | | | | |
    .subckt OPA2131E/BB  1 2 3 4 5
    *
    c1   11 12 4.197E-12
    c2    6  7 18.00E-12
    css  10 99 7.200E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 452.4E-6
    gcm   0  6 10 99 45.24E-9
    iss   3 10 dc 252.0E-6
    hlim 90  0 vlim 1K
    j1   11  2  10 jx
    j2   12  64 10 jx
    g11   2  4 Poly(4)  (10,2) (11,2) (4,2) (66,0) 0 1e-12 1e-12 1e-12 3e-6
    g12   1  4 Poly(4)  (10,1) (12,1) (4,1) (68,0) 0 1e-12 1e-12 1e-12 3e-6
    r2    6  9 100.0E3
    rd1   4 11 2.210E3
    rd2   4 12 2.210E3
    ro1   8  5 50
    ro2   7 99 25
    * rp    3  4 20.00E3
    rss  10 99 793.7E3
    vb    9  0 dc 0
    vc    3 53 dc 2.500
    ve   54  4 dc 2.500
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    **********************************
    * OPA2131 "E" - Enhancements
    **********************************
    * Output Supply Mirror
    FQ3    0    20    Poly(1) Vlim 0   1
    DQ1   20    21    DX
    DQ2   22    20    DX
    VQ1   21     0    0
    VQ2   22     0    0
    FQ1    3     0    Poly(1) VQ1   1.06E-3   1
    FQ2    0     4    Poly(1) VQ2   1.06E-3  -1
    * Quiescent Current
    RQ     3     4    160E3 
    * Diff Input Capacitance
    CDIF   1     2    1E-12
    * Common Mode Input Capacitance
    C1CM   1    99    1.5E-12
    C2CM   2    99    1.5E-12
    * Input Voltage Noise
    VN1   61     0    0.6
    VN2    0    62    0.6
    DN1   61    63    DY
    DN2   63    62    DY
    EN    64     1    63   0    1
    * Input Current Noise
    RN1    0    65  60.3865
    RN2   65    66  60.3865
    RN3   66     0  120.773
    RN4    0    67  60.3865
    RN5   67    68  60.3865
    RN6   68     0  120.773
    *
    .model dy D(Is=1.9E-16 RS=2000 AF=1 KF=2.258E-17)
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=2.500E-12 Beta=812.1E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA234 operational amplifier "macromodel" subcircuit
    * created using Parts release 6.1 on 06/20/96 at 16:06
    * Parts is a OrCAD product.
    * REV A. BB 7/20/96
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .SUBCKT OPA234/BB   1 2 3 4 5
    *
    C1   11 12 6.995E-12
    C2    6  7 30.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 479.3E6 -480E6 480E6 480E6 -480E6
    GA    6  0 11 12 65.97E-6
    GCM   0  6 10 99 1.046E-9
    IEE   3 10 DC 6.100E-6
    HLIM 90  0 VLIM 1E3
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   4 11 15.16E3
    RC2   4 12 15.16E3
    RE1  13 10 6.429E3
    RE2  14 10 6.429E3
    REE  10 99 50.00E6
    RO1   8  5 10
    RO2   7 99 10
    RP    3  4 20.49E3
    VB    9  0 DC 0
    VC    3 53 DC 1.3
    VE   54  4 DC .65
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX PNP(IS=800.0E-18 BF=60)
    .ends
    *$
    **************************************************************************
    * OPA234E operational amplifier enhanced "macromodel" subcircuit
    * created using Parts release 6.1 on 06/04/96 at 17:04
    * Parts is a OrCAD product.
    * REV A. BB 7/20/96
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .SUBCKT OPA234E/BB  1 2 3 4 5
    *
    C1   11 12 6.995E-12
    C2    6  7 30E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 479.3E6 -480E6 480E6 480E6 -480E6
    GA    6  0 11 12 65.97E-6
    GCM   0  6 10 99 1.046E-9
    IEE   3 10 DC 6.100E-6
    HLIM 90  0 VLIM 1E3
    Q1   11  2 13 QX
    Q2   12 64 14 QX
    R2    6  9 100.0E3
    RC1   4 11 15.16E3
    RC2   4 12 15.16E3
    RE1  13 10 6.429E3
    RE2  14 10 6.429E3
    REE  10 99 50.00E6
    RO1   8  5 10
    RO2   7 99 10
    VB    9  0 DC 0
    VC    3 53 DC 1.3
    VE   54  4 DC 0.65
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    **********************************
    * OPA234 "E" - Enhancements
    **********************************
    * Output Supply Mirror
    DQ1   20    21    DX
    DQ2   22    20    DX
    VQ1   21     0    0
    VQ2   22     0    0
    *adds quiescent plus positive output current
    FQ1    3     0    POLY(1) VQ1   235E-6   1
    *adds quiescent plus negative output current
    FQ2    0     4    POLY(1) VQ2   235E-6  -1
    *mirrors output current-used by FQ1 and FQ2
    FQ3    0    20    POLY(1) VLIM 0   1
    * delta Quiescent Current / delta Supplies
    * determines change in IQ with change in power supply voltages
    RQ     3     4    1E6
    * Diff Input Capacitance
    CDIF   1     2    5E-12
    * Common Mode Input Capacitance
    C1CM   1    99    6E-12
    C2CM   2    99    6E-12
    * Input Voltage Noise
    VN1   61     0  0.6
    VN2    0    62  0.6
    DN1   61    63  DY
    DN2   63    62  DY
    *adds 1/f noise to model. Adjusted to agree w/actual en
    EN    64     1  63   0    0.8
    RN1    0    65  60.3865
    RN2   65    66  60.3865
    RN3   66     0  120.773
    RN4    0    67  60.3865
    RN5   67    68  60.3865
    RN6   68     0  120.773
    *
    .MODEL DX D(IS=800.0E-18)
    *adds voltage noise
    .MODEL DY D(IS=1.9E-16 RS=2000 AF=1 KF=2.258E-17)
    .MODEL QX PNP(IS=800.0E-18 BF=60)
    .ENDS
    *$
    **************************************************************************
    * OPA237 operational amplifier circuit model subcircuit
    * Also can be used for OPA2237 (dual) and OPA4237 (quad) op amps
    * Rev. A  10/3/96  G.W.
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * OPA237 operational amplifier "macromodel" subcircuit
    *
    *  connections:      non-inverting input
    *                    | inverting input
    *                    | | positive power supply
    *                    | | | negative power supply
    *                    | | | | output
    *                    | | | | |
    .subckt OPA237/BB    1 2 3 4 5
    *
    J2       4  14  5    QJ 15
    R3      11  13  5.0K
    Q16     14  11  4    QN
    C1      13  14  15.5P
    R1       8  12  1.2K
    R2      12   9  1.2K
    Q6      11  10  4    QN
    Q5      10  10  4    QN
    Q3       4   2  6    QP
    I1       3   6  4U  
    I2       3   7  4U  
    I3       3  12  10U 
    I4       3  14  20U 
    ISUP     3   4  35U 
    Q4       4   1  7    QP
    DCLMPO  14  15  Dx
    VCLMPO   3  15  DC 0.65
    Q1      10   6  8    QP
    Q2      11   7  9    QP
    Q17      3  14  5    QN
    VCLMPI   3  16  DC 0.65
    DCLMPI  12  16  Dx
    CDIF     1   2  4P
    C2CM     0   2  2P
    C1CM     0   1  2P
    C2      10  11  15P
    *
    * Transistor Models
    .model Dx D(Is=1.0E-15)
    .model QN NPN(Is=1.0E-15 Bf=200)
    .model QP PNP(Is=800.0E-18 Bf=500 RB=4K KF=.6F)
    .model QJ PJF(Is=6.0E-15 VTO=-1.2 LAMBDA=40M BETA=20.0U)
    .ENDS 
    *$
    **************************************************************************
    * OPA2541 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 14:22
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA2541/BB  1 2 3 4 5
    *
    C1   11 12 10.71E-12
    C2    6  7 15.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E9 -3E9 3E9 3E9 -3E9
    GA    6  0 11 12 150.8E-6
    GCM   0  6 10 99 337.6E-12
    ISS   3 10 DC 120.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 6.631E3
    RD2   4 12 6.631E3
    RO1   8  5 .25
    RO2   7 99 .25
    RP    3  4 4.000E3
    RSS  10 99 1.667E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 8.000E3
    VLN   0 92 DC 8.000E3
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.000E-12 BETA=94.75E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2541E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/12/90 AT 09:50
    * REV.B 3/21/92 BCB: added input bias current correction
    *
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    | INVERTING INPUT
    *                    | | POSITIVE POWER SUPPLY
    *                    | | | NEGATIVE POWER SUPPLY
    *                    | | | | OUTPUT
    *                    | | | | |
    .SUBCKT OPA2541E/BB  1 2 3 4 5
    *
    C1   11 12 10.71E-12
    C2    6  7 15.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E9 -3E9 3E9 3E9 -3E9
    GA    6  0 11 12 150.8E-6
    GCM   0  6 10 99 337.6E-12
    ISS   3 10 DC 120.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 6.631E3
    RD2   4 12 6.631E3
    RO1   8  5 .25
    RO2   7 99 .25
    *  RP    3  4 4.000E3
    RSS  10 99 1.667E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 8.000E3
    VLN   0 92 DC 8.000E3
    ****************************
    * OPA2541 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  16.68E-3  1
    FQ2   0  4 POLY(1) VQ2  16.68E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.0E-12
    C2CM  2  99 2.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.000E-12 BETA=94.75E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2544 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 10/12/95 at 07:51
    * Parts is a OrCAD product.
    * REV.A   SB
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA2544/BB  1 2 3 4 5
    *
    c1   11 12 2.200E-12
    c2    6  7 10.00E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 9.446E9 -9E9 9E9 9E9 -9E9
    ga    6  0 11 12 87.96E-6
    gcm   0  6 10 99 440.9E-12
    iss  10  4 dc 80.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   3 11 11.37E3
    rd2   3 12 11.37E3
    ro1   8  5 .17
    ro2   7 99 .17
    rp    3  4 5.833E3
    rss  10 99 2.500E6
    vb    9  0 dc 0
    vc    3 53 dc 4.400
    ve   54  4 dc 3.800
    vlim  7  8 dc 0
    vlp  91  0 dc 4.000E3
    vln   0 92 dc 4.000E3
    *
    .model dx D(Is=800.0E-18)
    .model jx NJF(Is=7.500E-12 Beta=96.72E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA2604 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/11/90 AT 13:06
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA2604/BB  1 2 3 4 5
    *
    C1   11 12 22.85E-12
    C2    6  7 32.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 418.4E3 -40E3 40E3 40E3 -40E3
    GA    6  0 11 12 2.011E-3
    GCM   0  6 10 99 20.11E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 497.4
    RD2   4 12 497.4
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 6.294E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=12.50E-12 BETA=2.528E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2604E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/28/90 AT 16:46
    * REV.B 3/21/92 BCB:  added input bias current correction and
    *                     current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA2604E/BB 1 2 3 4 5
    *
    C1   11 12 22.85E-12
    C2    6  7 32.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 418.4E3 -40E3 40E3 40E3 -40E3
    GA    6  0 11 12 2.011E-3
    GCM   0  6 10 99 20.11E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 6E-6
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 6E-6
    R2    6  9 100.0E3
    RD1   4 11 497.4
    RD2   4 12 497.4
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 6.294E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    ****************************
    * OPA2604 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  3.45E-3  1
    FQ2   0  4 POLY(1) VQ2  3.45E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  6.0E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  8.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 5.0E-12
    C2CM  2  99 5.0E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=133.62E-18 AF=1 KF=11.726E-18)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=12.50E-12 BETA=2.528E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA2604M OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "M" IS  MULTIPLE POLE/ZERO TOPOLOGY
    * CREATED 7/8/92 BCB
    * REV.A
    *
    * CONNECTIONS:        NON-INVERTING INPUT
    *                     |  INVERTING INPUT
    *                     |  |  POSITIVE POWER SUPPLY
    *                     |  |  |  NEGATIVE POWER SUPPLY
    *                     |  |  |  |  OUTPUT
    *                     |  |  |  |  |
    .SUBCKT  OPA2604M/BB  3  2  7  4  6
    *
    * INPUT STAGE (pole=1.6MHz)
    J1  13   2  12  PJ
    J2  14  11  12  PJ
    G51  2   4  POLY(2) (13,2) (12,2) 0 1E-12 1E-12
    G52 11   4  POLY(2) (14,11) (12,11) 0 1E-12 1E-12
    R3   4  13  198.94
    R4   4  14  198.94
    C1  13  14  250E-12
    IEE  7  12  1.8E-3
    EOS 11   3  POLY(1)  (33,10)  3E-3  1
    R1   2  15  5E11
    R2   3  15  5E11
    CIN  2   3  8E-12
    IOS  2   3  4E-12
    * GAIN STAGE (gain=100dB, pole=200Hz)
    V21  7  21  3.236
    D21  23 21  DX
    V22  22  4  3.236
    D22  22 23  DX
    G21  7  23  POLY(1)  (13,14)   2.9238E-3 5.0265E-3
    G22  4  23  POLY(1)  (13,14)  -2.9238E-3 5.0265E-3
    R27  7  23  19.89E6
    R28  4  23  19.89E6
    C22  7  23  40E-12
    C23  4  23  40E-12
    * ZERO / POLE STAGE (zero=1.6MHz, pole=10MHz)
    R46  41  43  1E6
    R47  42  43  1E6
    R45   7  41  5.25E6
    R48   4  42  5.25E6
    L41   7  41  83.6E-3
    L42   4  42  83.6E-3
    G45   7  43  23  10  1E-6
    G46   4  43  23  10  1E-6
    * POLE / ZERO STAGE (pole=0.4MHz, zero=1.6MHz)
    R81   7  83  1E6
    R84   4  83  1E6
    R82  81  83  0.25E6
    R83  82  83  0.25E6
    C84  81   7  397.9E-15
    C85  82   4  397.9E-15
    G81   7  83  43  10  1E-6
    G82   4  83  43  10  1E-6
    * COMMON-MODE REJECTION STAGE (zero at 2kHz)
    R31  31  33  1E6
    R32  32  33  1E6
    G31   7  33  15  10  1E-11
    G32   4  33  15  10  1E-11
    L31  31   7  79.577
    L32  32   4  79.577
    * OUTPUT STAGE
    D3  83  71  DX
    D4  72  83  DX
    D5   7  73  DX
    D6   7  74  DX
    D7   4  73  DZ
    D8   4  74  DZ
    G14 73   4   6  83  20E-3
    G13 74   4  83   6  20E-3
    V3  71   6  0.38686
    V4   6  72  0.38686
    G11  6   7   7  83  20E-3
    G12  4   6  83   4  20E-3
    R23  7   6  50
    R24  4   6  50
    * CENTER OF SUPPLIES
    R9   7  10  31.304E3
    R10  4  10  31.304E3
    *
    .MODEL  DX  D(IS=1E-15)
    .MODEL  PJ  PJF(BETA=12.63285E-3 VTO=-2 IS=50E-12)
    .MODEL  DZ  D(IS=1E-15 BV=50)
    .ENDS
    *$
    **************************************************************************
    * OPA2650X  WIDEBAND, LOW POWER VOLTAGE FEEDBACK OP AMP MACROMODEL
    * CREATED  7/27/95   DY/SB
    * REV.A 
    *
    * CONNECTIONS:       INVERTING INPUT
    *                    |   NON-INVERTING INPUT
    *                    |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   OUTPUT
    *                    |   |   |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   |   |   
    .SUBCKT OPA2650X/BB  13  14  11  12  10 
    *
    * Input Stage and Current Source
    Q2       16   6   19  2 NPN1 4
    Q1       17   7   18  2 NPN1 4
    Q3       20   24  23  2 NPN1 2
    R3       18   20  300
    R5       19   20  300
    R4       23   22  500
    ISOUR    27   24  DC 370E-6
    Q6       27   26  28  3 PNP1 1
    Q7       24   24  25  2 NPN1 1
    Q10       2   27  26  3 PNP1 1
    R8       21   28  2K
    R9       25   22  1K
    R2        2   22  20
    R1        3   21  20
    C1       27   24  0.6E-12
    * Gain Stage
    Q11      29  26  17  3 PNP1 1
    Q15      30  32  31  2 NPN1 1
    Q16      46  26  16  3 PNP1 1
    Q17      47  30  32  2 NPN1 1
    Q18      32  32  33  2 NPN1 1
    R11      21  17  1K
    R13      21  16  1K
    R12      31  22  320
    R14      33  22  320
    R18      46  47  500
    V1       29  30  DC 2.4
    C2       32  22  0.4E-12
    C4       46  22  1.2E-12
    C3       47  22  0.42E-12
    * Output Stage
    Q19      35  26  34  3 PNP1 2
    Q20      35  35  44  2 NPN1 2
    Q21      38  47  44  3 PNP1 2
    Q22      39  46  45  2 NPN1 2
    Q23      36  36  45  3 PNP1 2
    Q24      36  24  37  2 NPN1 2
    Q25      21  17  39  2 NPN1 2
    Q26      22  31  38  3 PNP1 2
    Q27      43  40  42  3 PNP1 10
    Q28       3  35  42  2 NPN1 2
    Q29       2  36  43  3 PNP1 2
    Q30      42  40  43  2 NPN1 10
    Q31       3  42  41  2 NPN1 48
    Q32       2  43  41  3 PNP1 48
    R17      41  5   10
    R16      37  22  500
    R15      21  34  1K
    * Package Parasitics
    R11P     12  65  .1
    R10P     64  63  .01
    R9P      10  62  .1
    R8P      61  60  .01
    R7P      57  58  .01
    R6P      11  56  .1
    R5P      58  59  .01
    R4P      14  53  .1
    R3P      54  55  .01
    R2P      13  50  .1
    R1P      51  52  .01
    C3P      51  54  .05E-12
    C6P      54  58  .05E-12
    L7P       2  57  .7E-9
    L2P      50  51  1.08E-9
    L4P      53  54  1.08E-9
    L6P      56  58  1.5E-9
    L11P     65  64  1.08E-9
    L10P     63   5  .7E-9
    L9P      62  61  1.08E-9
    L8P      60   3  .7E-9
    L5P      59   2  .7E-9
    L1P      52   6  .7E-9
    C11P     61  64  .05E-12
    C10P     61   2  .0425E-12
    C9P       3   2  .15E-12
    C8P      58   2  .0125E-12
    C7P       2   2  .15E-12
    C5P      54   2  .0425E-12
    C4P       7   2  .15E-12
    C2P      51   2  .0425E-12
    L3P      55   7  .7E-9
    C1P       6   2  .15E-12
    C12P      5   2  .15E-12
    C13P     64   2  .0425E-12
    *
    * Models Used
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS 
    *
    ****************** OPA2650 TEST CIRCUIT ******************
    *
    *VCC      80    0   DC 5V
    *VEE       0   81   DC 5V
    *VIN      85    0   PWL ( 0N -2 1N 2 50N 2 51N -2 )
    *VIN      85    0 
    *+ SIN(  0 .5 5.000E6 0 0 0 )
    *Vin      85    0   DC 0  AC  1
    *RL       82    0   100
    *CL       82    0   5E-12
    *CFB      83   82   .15E-12
    *CFF1     83    0   0.75E-12
    *RIN      85   84   25
    *RFB      86   82   402
    *RFF      83    0   402
    *LFB      83   86   2.2E-9
    *X82      83   84   81  82  80  OPA2650X/BB
    *
    *.probe    ; *ipsp*
    *.options abstol = 1.000m reltol = .01  ; *ipsp*
    *.ac dec 11       10.000k   3.000g   ; *ipsp*
    *.four  5.000meg V(82)     ; *ipsp*
    *.tran    50.000n  4.000u   0        0         ; *ipsp*
    *
    *.ENDS
    *$
    **************************************************************************
    * OPA2658X   DUAL-WIDEBAND, LOW-POWER CURRENT-FEEDBACK OP AMP *MACROMODEL
    * CREATED 12/30/94  DY/SB
    * REV. A
    *
    * NOTE: THE FOLLOWING NETLIST REFLECTS ONLY ONE OUT OF THE TWO OP AMPS OF THE 
    * DUAL OPA2658. TO MODEL THE COMPLETE DEVICE PLEASE USE THIS MODEL TWICE.
    *
    * CONNECTIONS:       INVERTING INPUT
    *                    |   NON-INVERTING INPUT
    *                    |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   OUTPUT
    *                    |   |   |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   |   |   
    .SUBCKT OPA2658X/BB  8   9   7   10  6  
    *
    * Input Stage
    ISOUR1   11  13  DC 0.5MA
    ISOUR2   14  12  DC 0.5MA
    Q2       14  14  4   1 PNP1 2
    Q4       18  14  3   1 PNP1 2
    Q1       13  13  4   2 NPN1 2
    Q3       15  13  3   2 NPN1 2
    R5       11  12  20K
    C3       13  0   0.3E-12
    C4       14  0   0.1E-12
    R16       1  11  10
    R17       2  12  10
    C1       11  12  1E-12
    * Gain Stage
    Q7       24  15  37  1 PNP1 6
    Q6       37  17  20  1 PNP1 6
    Q5       15  37  16  1 PNP1 6
    Q8       18  19  22  2 NPN1 3
    Q9       19  23  21  2 NPN1 3
    Q10      26  18  19  2 NPN1 3
    R1       11  16  300
    R2       11  20  300
    R3       22  12  100
    R4       21  12  100
    R12      37  17  600
    R6       19  23  200
    C2       25  12  0.5E-12
    * Output Stage
    Q21      1   33  36  2 NPN1 48
    Q22      2   35  36  1 PNP1 48
    Q11      12  26  28  1 PNP1 3
    Q12      11  24  30  2 NPN1 3
    Q20      35  34  33  1 PNP1 10
    Q19      33  34  35  2 NPN1 10
    Q13      29  29  28  2 NPN1 3
    Q17      1   29  33  2 NPN1 2
    Q14      31  31  30  1 PNP1 3
    Q18      2   31  35  1 PNP1 2
    Q15      29  37  27  1 PNP1 6
    Q16      31  19  32  2 NPN1 3
    R9       11  27  300
    R10      32  12  100
    R7       24  25  80
    R8       25  26  80
    R11      36  5   10
    * Package Parasitics
    CINV     8   0   .75E-12
    L6P      49  48  1.5E-9
    L4P      46  45  1.08E-9
    L2P      43  42  1.08E-9
    C8P      55  2   .0425E-12
    L3P      44  4   .7E-9
    C1P      42  2   .0425E-12
    C2P      42  45  .05E-12
    C3P      45  2   .0425E-12
    C4P      45  48  .05E-12
    C5P      48  2   .0125E-12
    C6P      52  2   .0425E-12
    C7P      52  55  .05E-12
    L1P      41  3   .7E-9
    L5P      47  2   .7E-9
    L7P      51  1   .7E-9
    L8P      53  52  1.08E-9
    L9P      54  5   .7E-9
    L10P     56  55  1.08E-9
    L11P     2   50  .7E-9
    R1P      42  41  .1
    R2P      8   43  .1
    R3P      45  44  .1
    R4P      9   46  .1
    R5P      48  47  .1
    R6P      7   49  .1
    R11P     50  48  .025
    R7P      52  51  .1
    R8P      6   53  .1
    R9P      55  54  .1
    R10P     10  56  .1
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *
    ****************** OPA2658 TEST CIRCUIT ******************
    *
    *X1       60  61  63  65  62  OPA2658X/BB
    *VCC      62  0   DC 5V
    *VEE      0   63  DC 5V
    *RFB      66  65  400
    *VIN      67  0   PWL ( 0N -1 1N 1 20N 1 21N -1 )
    *RL       65  0   100
    *LFB      60  66  2.2E-9
    *CL       65  0   5E-12
    *CFB      60  65  0.15E-12
    *RSOUR    67  61  50
    *CFF      60  0   0.15E-12
    *RFF      60  64  400
    *LFF      64  0   2.2E-9
    *.ENDS
    *$
    **************************************************************************
    * OPA2662 WIDE-BAND, DUAL, OPERATIONAL TRANSCONDUCTANCE AMPLIFIER
    * CREATED 9/6/95  SB
    * REV.A
    *
    * CONNECTIONS:           BASE
    *                        |  EMITTER
    *                        |  |  COLLECTOR
    *                        |  |  |  POSITIVE VCC
    *                        |  |  |  |  NEGATIVE VCC
    *                        |  |  |  |  |  POSITIVE VCCOUT
    *                        |  |  |  |  |  |  NEGATIVE VCCOUT
    *                        |  |  |  |  |  |  |  IQ ADJUST
    *                        |  |  |  |  |  |  |  |   ENABLE
    .SUBCKT OPA2662X1/BB     2  10 11 1  8  16 9  5  EN 
    *
    * Bias Circuit
    I1  20  21  1E-6
    Q1  20  20 1   PIJ
    Q2  21  20 1   PIJ 
    Q4  20  21 22  NIJ 9
    Q3  21  21 8   NIJ
    R4   5  22    60
    R5  22   8  50E3
    C4   5   0    2pF
    *Enable Circuit
    Q40  20  40  1  PIJ
    R40  40   1   10k
    G1    0  40  VALUE={-20uA*((-1*V(EN,0))+5V)}
    Q45  21  45  8  NIJ
    R45  45   8   10k
    G2    0  45  VALUE={20uA*((-1*V(EN,0))+5V)}
    *Input 
    Q73  6  6  3 NIJ 
    Q12 20 20  1 PIJ 
    Q7   3  3 76 NIJ 
    Q6   4  4 76 PIJ  
    Q5   6 20  1 PIJ 2.3
    Q8  21  2  3 PIJ
    Q9  20  2  4 NIJ
    Q74 23 23  4 PIJ 
    Q10 23 21  8 NIJ 2.3
    Q11 21 21  8 NIJ 
    CB  2  0  1pF 
    *OTA (Collector Output)
    Q17 24 24 41  PIJ  4
    R17 16 41     15
    R18 16 32     3.5
    Q18 33 24 32  PIJ  18
    Q13 24 13 26  NIJ  1.5
    Q14 25 14 27  PIJ  1.5
    Q15 25 25 42  NIJ  4
    R15  9 42     15
    R16  9 31     3.5
    Q16 33 25 31  NIJ  18
    Q19 26 30 27  NIJ 
    Q20 27 30 26  PIJ 
    Q21 24 26 10  NIJ  3
    Q22 25 27 10  PIJ  3
    C12  24  0   10pF 
    C16  25  0   10pF 
    C13  13  0   3pF
    R13  13  6   220
    C14  23  0   3pF
    R14  23  14  220
    RC   33  34  0.05
    LC   34  11  1E-9
    CC   11  0   6.5pF
    CE   10  0   1.7pF 
    *
    .MODEL NIJ NPN (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *
    .MODEL PIJ PNP (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *
    .ENDS
    *
    * OPA2662 Macromodel Test
    *
    *X1 B  E  C  1  8  11  18  IQ  TTL  OPA2662X1/BB
    *Vcc1+   1   0    +5V
    *Vcc1-   8   0    -5V
    *Vcc2+  11   0    +5V
    *Vcc2-  18   0    -5V 
    *Cb1    1    0   1uF
    *Cb2    8    0   1uF
    *Cb3    11   0   2.2uF
    *Cb4    18   8   2.2uF
    *RQ  IQ   8    750
    *RC   C   0    40
    *RE   E   0    100
    *CE  E   0    5.6pF
    *.NODESET  V(X1.20)=4.18V  V(X1.21)=-4.18V
    *.ENDS
    *$
    **************************************************************************
    * OPA27 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 09/20/90 AT 16:00
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA27/BB    1 2 3 4 5
    *
    C1   11 12 20.79E-12
    C2    6  7 114.3E-12
    CEE  10 99 5.713E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 10.95E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 4.638E-3
    GCM   0  6 10 99 2.608E-9
    IEE  10  4 DC 240.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 215.6
    RC2   3 12 215.6
    RE1  13 10 5.395E-3
    RE2  14 10 5.395E-3
    REE  10 99 833.5E3
    RO1   8  5 35
    RO2   7 99 35
    RP    3  4 10.87E3
    VB    9  0 DC 0
    VC    3 53 DC 1.200
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=7.998E3)
    .ENDS
    *$
    **************************************************************************
    * OPA27E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/05/90 AT 10:27
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA27E/BB   1 2 3 4 5
    *
    C1   11 12 20.79E-12
    C2    6  7 114.3E-12
    CEE  10 99 5.713E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 10.95E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 4.638E-3
    GCM   0  6 10 99 2.608E-9
    IEE  10  4 DC 240.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 215.6
    RC2   3 12 215.6
    RE1  13 10 5.395E-3
    RE2  14 10 5.395E-3
    REE  10 99 833.5E3
    RO1   8  5 35
    RO2   7 99 35
    *  RP    3  4 10.87E3
    VB    9  0 DC 0
    VC    3 53 DC 1.200
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    ****************************
    * OPA27 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.56E-3  1
    FQ2   0  4 POLY(1) VQ2  1.56E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  5.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.5E-12
    C2CM  2  99 2.5E-12
    * INPUT PROTECTION
    DIN1   1  2  DX
    DIN2   2  1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=7.998E3)
    .ENDS
    *$
    **************************************************************************
    * OPA27M OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "M" IS  MULTIPLE POLE/ZERO TOPOLOGY
    * CREATED 7/8/92 BCB
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   |  INVERTING INPUT
    *                   |  |  POSITIVE POWER SUPPLY
    *                   |  |  |  NEGATIVE POWER SUPPLY
    *                   |  |  |  |  OUTPUT
    *                   |  |  |  |  |
    .SUBCKT  OPA27M/BB  3  2  7  4  6
    *
    * INPUT STAGE (pole @ 2M Hz)
    Q1  13   2  15  N
    Q2  14  11  16  N
    R3   7  13  42.513
    R4   7  14  42.513
    C1  13  14  935.92E-12
    R5  15  12  -9.187
    R6  16  12  -9.187
    IEE  12  4  1E-3
    EOS  11  3  POLY(1)  (33,9)  25E-6  1
    R1  2  10  5E11
    R2  3  10  5E11
    CIN  2  3  5E-12
    IOS  2  3  35E-9
    * GAIN STAGE (pole @ 4 Hz)
    V21  7  21  1.8336
    D21  23  21  DX
    V22  22  4  1.8336
    D22  22  23  DX
    G21  7  23  POLY(1)  (13,14)   2.721E-3 17.41E-3
    G22  4  23  POLY(1)  (13,14)  -2.721E-3 17.41E-3
    R27  7  23  75.6E6
    R28  4  23  75.6E6
    C22  7  23  526.3E-12
    C23  4  23  526.3E-12
    * ZERO / POLE STAGE (zero @ 2.91M Hz, pole @ 10.91M Hz)
    R46  41  43  1E6
    R47  42  43  1E6
    R45  7  41  2.75E6
    R48  4  42  2.75E6
    L41  7  41  14.589E-3
    L42  4  42  14.589E-3
    G45  7  43  23  9  1E-6
    G46  4  43  23  9  1E-6
    * ZERO / POLE STAGE (zero @ 2.91M Hz, pole @ 10.91M Hz)
    R59  51  53  1E6
    R50  52  53  1E6
    R51  7  51  2.75E6
    R52  4  52  2.75E6
    L51  7  51  14.589E-3
    L52  4  52  14.589E-3
    G57  7  53  43  9  1E-6
    G58  4  53  43  9  1E-6
    * ZERO / POLE STAGE (zero @ 910k Hz, pole @ 6.37M Hz)
    R69  61  63  1E6
    R68  62  63  1E6
    R61  7  61  6E6
    R62  4  62  6E6
    L61  7  61  25E-3
    L62  4  62  25E-3
    G67  7  63  53  9  1E-6
    G68  4  63  53  9  1E-6
    * COMMON-MODE REJECTION STAGE (zero @ 1k Hz)
    R31  31  33  1E6
    R32  32  33  1E6
    G31  7  33  10  9  1.99526E-12
    G32  4  33  10  9  1.99526E-12
    L31  31  7  159.1549
    L32  32  4  159.1549
    * OUTPUT STAGE
    D3  63  71  DX
    D4  72  63  DX
    D5  7  73  DX
    D6  7  74  DX
    D7  4  73  DZ
    D8  4  74  DZ
    G14  73  4  6  63  7.14286E-3
    G13  74  4  63  6  7.14286E-3
    V3  71  6  3.58686
    V4  6  72  3.58686
    G11  6  7  7  63  7.14286E-3
    G12  4  6  63   4  7.14286E-3
    R23  7  6  140
    R24  4  6  140
    * CENTER OF SUPPLIES
    R9  7  9  16.359E3
    R10  4  9  16.359E3
    *
    .MODEL  DX  D(IS=1E-15)
    .MODEL  N  NPN(BF=12.5E3)
    .MODEL  DZ  D(IS=1E-15 BV=50)
    .ENDS
    *$
    **************************************************************************
    * SUBCIRCUIT MACROMODEL OPA336  
    * PSpice ver. 6.3
    * REV A. CREATED Wednesday, June 18, 1997 RH
    * REV B. 25 JUNE 97 NPA: COMPILED INTO OPA336.MOD  
    * REV C. 26 JUNE 97 NPA: EDITED NODE SYNTAX AND ADDED .OPTION NOTES
    *
    *  Notes concerning using macromodel to simulate OPA336:
    *  1) Model is actually a simplified schematic of OPA336.
    *  2) Model was created with PSpice ver. 6.3, level 3 device models.
    *  3) Operation of the circuit is assumed to be single supply
    * 
    *  Example:  X_U1   1    2   3  0  5  OPA336/BB
    *
    *  Where U is the subcircuit name and 
    *  connections:          non-inverting input
    *      		       |  inverting input
    *		             |  |  positive power supply
    *		             |  |  |   negative power supply
    *		             |  |  |   |   output
    *		             |  |  |   |   |
    *  .subckt OPA336/BB     1  2  3   4   5
    *
    *  Note that node "4" may be connected to ground "0", i.e., single supply operation.
    *
    *  4) ADD .OPTION ITL=40 AND .OPTION GMIN=10p TO NET LIST IF SIMULATION DOES NOT
    *     CONVERGE
    *  5) ADDING .NODESET STATEMENT (BELOW) TO NET LIST MAY HELP CONVERGENCE IS CASES
    *     WHERE V+=5V AND V-=0V ; SINGLE SUPPLY OPERATION. ASSUMES SUBCIRCUIT IS "U1". 
    *
    * .NODESET
    * +V(2)    = 2.5  V(1)    = 2.5  V(5)    = 2.5   V(3)   = 5.0
    * +V(X_U1.20)= 3.8  V(X_U1.23)= 3.8  V(X_U1.25)= .834  V(X_U1.27)= .833 V(X_U1.29)= .834
    * +V(X_U1.32)= 2.03 V(X_U1.34)= 2.03 V(X_U1.43)= 4.065 V(X_U1.44)= 2.51 V(X_U1.45)= 1.93 
    * +V(X_U1.47)= 1.93 V(X_U1.51)= .848  V(X_U1.53)= 4.07 V(X_U1.54)= 1.58 V(X_U1.55)= 4.02 
    * +V(X_U1.60)= 1.94 V(X_U1.62)= .855  V(X_U1.64)= 3.17 V(X_U1.67)= 4.98 V(X_U1.76)= 2.51 
    * +V(X_U1.GNDS)= 0.0 V(0)= 0.0
    *
    * connections:      non-inverting input
    *                   |  inverting input
    *                   |  |  positive power supply
    *                   |  |  |   negative power supply
    *                   |  |  |   |   output
    *                   |  |  |   |   |
    .subckt OPA336/BB  1 2 3 4 5
    *
    M61      4 64 55 55  PCH W=20U L=0.8U     M=1  
    M59      55 53 3  3 PCH W=15U L=5U     M=4  
    M55      55 60 51  GNDS NCH W=5U L=0.8U     M=1  
    M53      53 45 51  GNDS NCH W=5U L=0.8U     M=1  
    M57      53 53 3  3 PCH W=15U L=5U     M=2  
    C55      55 60  CP1P2 2P
    M67      55 55 67  3 PCH W=5U L=5U     M=1  
    M74      45 51 62  GNDS NCH W=5U L=1U     M=1  
    R67      3 67  RNW 200K
    R47      45 47  RPO2 2K
    ITAIL    3 23  DC 6U AC 0
    ITAIL2   27 4  DC 1.6U AC 0
    ITAIL3   51 4  DC 0.8U AC 0
    I60      3 60  DC 0.4U AC 0
    RGNDS    GNDS 4  0.01
    M24      29 1  23 3  PCH W=90U L=2U AD=2560P PD=3328U AS=2688P PS=3494U M=1  
    M26      29 27 4  GNDS NCH W=500U L=2U AD=1142P PD=1670U AS=1142P PS=1670U M=1  
    I20      20 4  DC 1U AC 0
    R20      3 20  1.2MEG
    M20      4 20 23  3 PCH W=5U L=2U     M=1  
    R32      32 25  1.2MEG
    R34      34 29  1.2MEG
    I34      3 34  DC 1U AC 0
    I32      3 32  DC 1U AC 0
    V64      3 64  DC 1.8302
    V60      60 62  DC 1.0897
    V62      62 4  DC .8547
    M23      25 2  23 3  PCH W=90U L=2U AD=2560P PD=3328U AS=2688P PS=3494U M=1  
    M47      43 43 3  3 PCH W=60U L=4U     M=1  
    M43      43 34 27  GNDS NCH W=4U L=4U     M=1  
    M45      45 32 27  GNDS NCH W=4U L=4U     M=1  
    M73      76 51 4  GNDS NCH W=5U L=0.8U     M=20  
    M25      25 27 4  GNDS NCH W=500U L=2U AD=1142P PD=1670U AS=1142P PS=1670U M=1  
    M71      76 55 3  3 PCH W=20U L=0.8U     M=20  
    M49      45 43 3  3 PCH W=60U L=4U     M=1  
    RC1      44 76  RPO2 10K
    R76      76 5   RPO2 100
    CM1      29 44  CP1P2 200P
    C45      47 76  CP1P2 22P
    RC2      54 4  RPO2 10K
    CM2      25 54  CP1P2 200P
    *
    * MODELS for LEVEL 3 PSpice
    .MODEL PCH PMOS (LEVEL=3 TOX=30E-9 CGDO=1.80e-10 CGSO=1.80e-10 CJ=7.199E-4 CJSW=3.40E-10
    +AF=1.05 KF=1.0e-31 JS=4.0e-7 JSSW=3.0e-13 RSH=117 MJ=.47 MJSW=.16 VFB=-0.34 PHI=0.71 VTO=-.892
    +LD=12E-9 WD=43E-9 TPG=+1 GAMMA=0.6)
    *
    .MODEL NCH NMOS (LEVEL=3 TOX=30E-9 CGDO=1.55e-10 CGSO=1.55e-10 CJ=6.300E-4 CJSW=3.83E-10
    +AF=1.05 KF=2.6e-31 JS=2.0e-7 JSSW=5e-13 RSH=68 MJ=.25 MJSW=.11 VFB=-0.784 PHI=0.792 VTO=.81
    +LD=34E-9 WD=17E-9 TPG=-1 GAMMA=0.6)
    *
    .MODEL RPO2 RES (R=1 TC1=6.3e-4 TC2= 1.1e-6)
    .MODEL RNW  RES (R=1 TC1=5.5e-3 TC2=-1.3e-5)
    .MODEL CP1P2 CAP (C=1)
    .ENDS
    *$
    **************************************************************************
    * OPA37 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/16/90 AT 10:32
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA37/BB    1 2 3 4 5
    *
    C1   11 12 21.45E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 10.64E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 4.775E-3
    GCM   0  6 10 99 2.685E-9
    IEE  10  4 DC 250.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 209.4
    RC2   3 12 209.4
    RE1  13 10 2.501
    RE2  14 10 2.501
    REE  10 99 799.9E3
    RO1   8  5 35
    RO2   7 99 35
    RP    3  4 10.91E3
    VB    9  0 DC 0
    VC    3 53 DC 1.200
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=8.333E3)
    .ENDS
    *$
    **************************************************************************
    * OPA37E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/02/90 AT 09:06
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA37E/BB   1 2 3 4 5
    *
    C1   11 12 21.45E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 10.64E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 4.775E-3
    GCM   0  6 10 99 2.685E-9
    IEE  10  4 DC 250.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 209.4
    RC2   3 12 209.4
    RE1  13 10 2.501
    RE2  14 10 2.501
    REE  10 99 799.9E3
    RO1   8  5 35
    RO2   7 99 35
    *  RP    3  4 10.91E3
    VB    9  0 DC 0
    VC    3 53 DC 1.200
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    ****************************
    * OPA37 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.55E-3  1
    FQ2   0  4 POLY(1) VQ2  1.55E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  5.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.5E-12
    C2CM  2  99 2.5E-12
    * INPUT PROTECTION
    DIN1   1  2  DX
    DIN2   2  1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=8.333E3)
    .ENDS
    *$
    **************************************************************************
    * OPA404 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/11/90 AT 10:49
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA404/BB   1 2 3 4 5
    *
    C1   11 12 6.850E-12
    C2    6  7 13.70E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.213E6 -2E6 2E6 2E6 -2E6
    GA    6  0 11 12 602.6E-6
    GCM   0  6 10 99 6.026E-9
    ISS   3 10 DC 479.5E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.660E3
    RD2   4 12 1.660E3
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 13.33E3
    RSS  10 99 417.1E3
    VB    9  0 DC 0
    VC    3 53 DC 1.800
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 18
    VLN   0 92 DC 18
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=3.785E-4 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA404E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/11/90 AT 10:13
    * REV.B 3/21/92 BCB: added input bias current correction and
    *                    current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA404E/BB  1 2 3 4 5
    *
    C1   11 12 6.850E-12
    C2    6  7 13.70E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.213E6 -2E6 2E6 2E6 -2E6
    GA    6  0 11 12 602.6E-6
    GCM   0  6 10 99 6.026E-9
    ISS   3 10 DC 479.5E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 600E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (66,0) 0 1E-12 1E-12 1E-12 600E-9
    R2    6  9 100.0E3
    RD1   4 11 1.660E3
    RD2   4 12 1.660E3
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 13.33E3
    RSS  10 99 417.1E3
    VB    9  0 DC 0
    VC    3 53 DC 1.800
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 18
    VLN   0 92 DC 18
    ****************************
    * OPA404 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.47E-3  1
    FQ2   0  4 POLY(1) VQ2  1.47E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.0E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=1.8E-16 AF=1 KF=34.45E-18)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=3.785E-4 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA4131 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 01/14/95 at 21:25
    * REV. A    SB
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .subckt OPA4131/BB  1 2 3 4 5
    *
    c1   11 12 4.197E-12
    c2    6  7 18.00E-12
    css  10 99 7.200E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 452.4E-6
    gcm   0  6 10 99 45.24E-9
    iss   3 10 dc 252.0E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 2.210E3
    rd2   4 12 2.210E3
    ro1   8  5 50
    ro2   7 99 25
    rp    3  4 20.00E3
    rss  10 99 793.7E3
    vb    9  0 dc 0
    vc    3 53 dc 2.500
    ve   54  4 dc 2.500
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=2.500E-12 Beta=812.1E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA4131E "Enhanced" operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 01/14/95 at 21:25
    * REV.A     SB - model includes input bias current correction,
    *                voltage and current noise.
    *
    * connections:       non-inverting input
    *                    | inverting input
    *                    | | positive power supply
    *                    | | | negative power supply
    *                    | | | | output
    *                    | | | | |
    .subckt OPA4131E/BB  1 2 3 4 5
    *
    c1   11 12 4.197E-12
    c2    6  7 18.00E-12
    css  10 99 7.200E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 127.3E6 -130E6 130E6 130E6 -130E6
    ga    6  0 11 12 452.4E-6
    gcm   0  6 10 99 45.24E-9
    iss   3 10 dc 252.0E-6
    hlim 90  0 vlim 1K
    j1   11  2  10 jx
    j2   12  64 10 jx
    g11   2  4 Poly(4)  (10,2) (11,2) (4,2) (66,0) 0 1e-12 1e-12 1e-12 3e-6
    g12   1  4 Poly(4)  (10,1) (12,1) (4,1) (68,0) 0 1e-12 1e-12 1e-12 3e-6
    r2    6  9 100.0E3
    rd1   4 11 2.210E3
    rd2   4 12 2.210E3
    ro1   8  5 50
    ro2   7 99 25
    * rp    3  4 20.00E3
    rss  10 99 793.7E3
    vb    9  0 dc 0
    vc    3 53 dc 2.500
    ve   54  4 dc 2.500
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    **********************************
    * OPA4131 "E" - Enhancements
    **********************************
    * Output Supply Mirror
    FQ3    0    20    Poly(1) Vlim 0   1
    DQ1   20    21    DX
    DQ2   22    20    DX
    VQ1   21     0    0
    VQ2   22     0    0
    FQ1    3     0    Poly(1) VQ1   1.06E-3   1
    FQ2    0     4    Poly(1) VQ2   1.06E-3  -1
    * Quiescent Current
    RQ     3     4    160E3 
    * Diff Input Capacitance
    CDIF   1     2    1E-12
    * Common Mode Input Capacitance
    C1CM   1    99    1.5E-12
    C2CM   2    99    1.5E-12
    * Input Voltage Noise
    VN1   61     0  0.6
    VN2    0    62  0.6
    DN1   61    63  DY
    DN2   63    62  DY
    EN    64     1    63   0    1
    * Input Current Noise
    RN1    0    65  60.3865
    RN2   65    66  60.3865
    RN3   66     0  120.773
    RN4    0    67  60.3865
    RN5   67    68  60.3865
    RN6   68     0  120.773
    *
    .model dy D(Is=1.9E-16 RS=2000 AF=1 KF=2.258E-17)
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=2.500E-12 Beta=812.1E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPA445 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/12/90 AT 11:04
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA445/BB   1 2 3 4 5
    *
    C1   11 12 5.252E-12
    C2    6  7 15.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 37.74E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 3.352E-9
    ISS   3 10 DC 202.5E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 5.305E3
    RD2   4 12 5.305E3
    RO1   8  5 25
    RO2   7 99 25
    RP    3  4 21.05E3
    RSS  10 99 987.7E3
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 26
    VLN   0 92 DC 26
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=10.00E-12 BETA=87.73E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA445E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/04/90 AT 14:31
    * REV.B 3/21/92 BCB: adding input bias current correction
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA445E/BB  1 2 3 4 5
    *
    C1   11 12 5.252E-12
    C2    6  7 15.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 37.74E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 188.5E-6
    GCM   0  6 10 99 3.352E-9
    ISS   3 10 DC 202.5E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 5.305E3
    RD2   4 12 5.305E3
    RO1   8  5 25
    RO2   7 99 25
    *  RP    3  4 21.05E3
    RSS  10 99 987.7E3
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 26
    VLN   0 92 DC 26
    ****************************
    * OPA445 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  2.795E-3  1
    FQ2   0  4 POLY(1) VQ2  2.795E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.0E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=10.00E-12 BETA=87.73E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA4658X   QUAD-WIDEBAND, LOW-POWER CURRENT-FEEDBACK OP AMP MACROMODEL
    * CREATED 12/30/94  DY/SB
    * REV. A
    *
    * NOTE: THIS NETLIST REFLECTS ONLY ONE OUT OF THE FOUR OP AMP SECTIONS OF THE
    * OPA4658. TO MODEL THE COMPLETE DEVICE PLEASE USE MULTIPLE SUBCIRCUIT CALLS 
    * IN YOUR CIRCUIT NETLIST.
    *
    * CONNECTIONS:        INVERTING INPUT
    *                     |   NON-INVERTING INPUT
    *                     |   |   NEGATIVE POWER SUPPLY
    *                     |   |   |   OUTPUT
    *                     |   |   |   |   POSITIVE POWER SUPPLY
    *                     |   |   |   |   |   
    .SUBCKT OPA4658X/BB   8   9   7   10  6  
    *
    * Input Stage
    ISOUR1   11  13  DC 0.5MA
    ISOUR2   14  12  DC 0.5MA
    Q2       14  14  4   1 PNP1 2
    Q4       18  14  3   1 PNP1 2
    Q1       13  13  4   2 NPN1 2
    Q3       15  13  3   2 NPN1 2
    R5       11  12  20K
    C3       13  0   0.3E-12
    C4       14  0   0.1E-12
    R16      1   11  10
    R17      2   12  10
    C1       11  12  1E-12
    * Gain Stage
    Q7       24  15  37  1 PNP1 6
    Q6       37  17  20  1 PNP1 6
    Q5       15  37  16  1 PNP1 6
    Q8       18  19  22  2 NPN1 3
    Q9       19  23  21  2 NPN1 3
    Q10      26  18  19  2 NPN1 3
    R1       11  16  300
    R2       11  20  300
    R3       22  12  100
    R4       21  12  100
    R12      37  17  600
    R6       19  23  200
    C2       25  12  0.55E-12
    * Output Stage
    Q21      1   33  36  2 NPN1 48
    Q22      2   35  36  1 PNP1 48
    Q11      12  26  28  1 PNP1 3
    Q12      11  24  30  2 NPN1 3
    Q20      35  34  33  1 PNP1 10
    Q19      33  34  35  2 NPN1 10
    Q13      29  29  28  2 NPN1 3
    Q17      1   29  33  2 NPN1 2
    Q14      31  31  30  1 PNP1 3
    Q18      2   31  35  1 PNP1 2
    Q15      29  37  27  1 PNP1 6
    Q16      31  19  32  2 NPN1 3
    R9       11  27  300
    R10      32  12  100
    R7       24  25  80
    R8       25  26  80
    R11      36  5   10
    * Package Parasitics
    CINV     8   0   .75E-12
    L6P      49  48  1.5E-9
    L4P      46  45  1.08E-9
    L2P      43  42  1.08E-9
    C8P      55  2   .0425E-12
    L3P      44  4   .7E-9
    C1P      42  2   .0425E-12
    C2P      42  45  .05E-12
    C3P      45  2   .0425E-12
    C4P      45  48  .05E-12
    C5P      48  2   .0125E-12
    C6P      52  2   .0425E-12
    C7P      52  55  .05E-12
    L1P      41  3   .7E-9
    L5P      47  2   .7E-9
    L7P      51  1   .7E-9
    L8P      53  52  1.08E-9
    L9P      54  5   .7E-9
    L10P     56  55  1.08E-9
    L11P     2   50  .7E-9
    R1P      42  41  .1
    R2P      8   43  .1
    R3P      45  44  .1
    R4P      9   46  .1
    R5P      48  47  .1
    R6P      7   49  .1
    R11P     50  48  .025
    R7P      52  51  .1
    R8P      6   53  .1
    R9P      55  54  .1
    R10P     10  56  .1
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *
    ****************** OPA4658 TEST CIRCUIT ******************
    *
    *X1       60  61  63  65  62  OPA4658X/BB
    *VCC      62  0   DC 5V
    *VEE      0   63  DC 5V
    *RFB      66  65  402
    *VIN      67  0   PWL ( 0N -1 1N 1 20N 1 21N -1 )
    *VIN      67  0   AC  1
    *RL       65  0   100
    *LFB      60  66  2.2E-9
    *CL       65  0   5E-12
    *CFB      60  65  0.15E-12
    *RSOUR    67  61  50
    *CFF      60  0   0.15E-12
    *RFF      60  64  402
    *LFF      64  0   2.2E-9
    *.PROBE 
    *.ENDs
    *$
    **************************************************************************
    * OPA501 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 10:36
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA501/BB   1 2 3 4 5
    *
    C1   11 12 20.00E-12
    C2    6  7 40.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 12.64E9 -10E9 10E9 10E9 -10E9
    GA    6  0 11 12 251.3E-6
    GCM   0  6 10 99 794.8E-12
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 3.979E3
    RD2   4 12 3.979E3
    RO1   8  5 .25
    RO2   7 99 .25
    RP    3  4 26.12E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 12.00E3
    VLN   0 92 DC 12.00E3
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=7.500E-9 BETA=197.4E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA501E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/11/90 AT 11:33
    * REV.B 3/21/92 BCB: added input bias current correction
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA501E/BB  1 2 3 4 5
    *
    C1   11 12 20.00E-12
    C2    6  7 40.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 12.64E9 -10E9 10E9 10E9 -10E9
    GA    6  0 11 12 251.3E-6
    GCM   0  6 10 99 794.8E-12
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 3.979E3
    RD2   4 12 3.979E3
    RO1   8  5 .25
    RO2   7 99 .25
    *  RP    3  4 26.12E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 12.00E3
    VLN   0 92 DC 12.00E3
    ****************************
    * OPA501 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  1.987E-3  1
    FQ2   0  4 POLY(1) VQ2  1.987E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.5E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.0E-12
    C2CM  2  99 2.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=7.500E-9 BETA=197.4E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA502 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 07/06/92 AT 10:32
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA502/BB   1 2 3 4 5
    *
    C1   11 12 21.45E-12
    C2    6  7 12.00E-12
    CSS  10 99 10.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 886.3E6 -90E6 90E6 90E6 -90E6
    GA    6  0 11 12 113.1E-6
    GCM   0  6 10 99 1.131E-9
    ISS   3 10 DC 240.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 8.842E3
    RD2   4 12 8.842E3
    RO1   8  5 5
    RO2   7 99 1.5
    RP    3  4 4.000E3
    RSS  10 99 833.3E3
    VB   9  0 DC 0
    VC    3 53 DC 4
    VE   54  4 DC 4
    VLIM  7  8 DC 0
    VLP  91  0 DC 15.00E3
    VLN   0 92 DC 15.00E3
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=6.000E-12 BETA=106.6E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA502E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 07/06/92 AT 10:32
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA502E/BB  1 2 3 4 5
    *
    C1   11 12 21.45E-12
    C2    6  7 12.00E-12
    CSS  10 99 10.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 886.3E6 -90E6 90E6 90E6 -90E6
    GA    6  0 11 12 113.1E-6
    GCM   0  6 10 99 1.131E-9
    ISS   3 10 DC 240.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 8.842E3
    RD2   4 12 8.842E3
    RO1   8  5 5
    RO2   7 99 1.5
    RP    3  4 4.000E3
    RSS  10 99 833.3E3
    VB    9  0 DC 0
    VC    3 53 DC 4
    VE   54  4 DC 4
    VLIM  7  8 DC 0
    VLP  91  0 DC 15.00E3
    VLN   0 92 DC 15.00E3
    ****************************
    * OPA512 "E" - enhancements
    ****************************
    * output supply mirror
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  19.44E-3  1
    FQ2   0  4 POLY(1) VQ2  19.44E-3 -1
    * quiescient current
    RQ    3  4  2.5E5
    * diff input capacitance
    CDIFF  1  2  5.0E-12
    * common mode input capacitance
    C1CM  1  99 4.0E-12
    C2CM  2  99 4.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=6.000E-12 BETA=106.6E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA511 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 11:36
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA511/BB   1 2 3 4 5
    *
    C1   11 12 20.00E-12
    C2    6  7 40.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 8.950E9 -9E9 9E9 9E9 -9E9
    GA    6  0 11 12 251.3E-6
    GCM   0  6 10 99 794.8E-12
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 3.979E3
    RD2   4 12 3.979E3
    RO1   8  5 .25
    RO2   7 99 .25
    RP    3  4 2.800E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 5.000E3
    VLN   0 92 DC 5.000E3
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=7.500E-9 BETA=197.4E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA511E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/11/90 AT 13:16
    * REV.A 3/21/92 BCB: added input bias current correction
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA511E/BB  1 2 3 4 5
    *
    C1   11 12 20.00E-12
    C2    6  7 40.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 8.950E9 -9E9 9E9 9E9 -9E9
    GA    6  0 11 12 251.3E-6
    GCM   0  6 10 99 794.8E-12
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 3.979E3
    RD2   4 12 3.979E3
    RO1   8  5 .25
    RO2   7 99 .25
    *  RP    3  4 2.800E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 5.000E3
    VLN   0 92 DC 5.000E3
    ****************************
    * OPA511 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  19.62E-3  1
    FQ2   0  4 POLY(1) VQ2  19.62E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.0E-12
    C2CM  2  99 2.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=7.500E-9 BETA=197.4E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA512 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 11:58
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA512/BB   1 2 3 4 5
    *
    C1   11 12 27.47E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.516E9 -3E9 3E9 3E9 -3E9
    GA    6  0 11 12 502.7E-6
    GCM   0  6 10 99 5.027E-9
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.989E3
    RD2   4 12 1.989E3
    RO1   8  5 .25
    RO2   7 99 .25
    RP    3  4 3.200E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 15.00E3
    VLN   0 92 DC 15.00E3
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=6.000E-9 BETA=789.5E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA512E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/11/90 AT 12:32
    * REV.B 3/21/92 BCB: added input bias current correction
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA512E/BB  1 2 3 4 5
    *
    C1   11 12 27.47E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.516E9 -3E9 3E9 3E9 -3E9
    GA    6  0 11 12 502.7E-6
    GCM   0  6 10 99 5.027E-9
    ISS   3 10 DC 160.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 1.989E3
    RD2   4 12 1.989E3
    RO1   8  5 .25
    RO2   7 99 .25
    *  RP    3  4 3.200E3
    RSS  10 99 1.250E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 15.00E3
    VLN   0 92 DC 15.00E3
    ****************************
    * OPA512 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  24.52E-3  1
    FQ2   0  4 POLY(1) VQ2  24.52E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.0E-12
    C2CM  2  99 2.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=6.000E-9 BETA=789.5E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA541 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 14:05
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA541/BB   1 2 3 4 5
    *
    C1   11 12 10.71E-12
    C2    6  7 15.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E9 -3E9 3E9 3E9 -3E9
    GA    6  0 11 12 150.8E-6
    GCM   0  6 10 99 337.6E-12
    ISS   3 10 DC 120.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 6.631E3
    RD2   4 12 6.631E3
    RO1   8  5 .25
    RO2   7 99 .25
    RP    3  4 4.000E3
    RSS  10 99 1.667E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 14.00E3
    VLN   0 92 DC 14.00E3
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.000E-12 BETA=94.75E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA541E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/12/90 AT 09:50
    * REV.B 3/21/92 BCB: added input bias current correction
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA541E/BB  1 2 3 4 5
    *
    C1   11 12 10.71E-12
    C2    6  7 15.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.653E9 -3E9 3E9 3E9 -3E9
    GA    6  0 11 12 150.8E-6
    GCM   0  6 10 99 337.6E-12
    ISS   3 10 DC 120.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 6.631E3
    RD2   4 12 6.631E3
    RO1   8  5 .25
    RO2   7 99 .25
    *  RP    3  4 4.000E3
    RSS  10 99 1.667E6
    VB    9  0 DC 0
    VC    3 53 DC 5
    VE   54  4 DC 5
    VLIM  7  8 DC 0
    VLP  91  0 DC 14.00E3
    VLN   0 92 DC 14.00E3
    ****************************
    * OPA541 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  16.68E-3  1
    FQ2   0  4 POLY(1) VQ2  16.68E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 2.0E-12
    C2CM  2  99 2.0E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=2.000E-12 BETA=94.75E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA544 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.4 on 10/12/95 at 07:51
    * Parts is a OrCAD product.
    * REV.A   SB   7/20/96
    * REV.B 6 June 97 NPA: added Note: Current Limit not modeled.
    * REV.C  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * connections:      non-inverting input
    *                   | inverting input
    *                   | | positive power supply
    *                   | | | negative power supply
    *                   | | | | output
    *                   | | | | |
    .SUBCKT OPA544/BB   1 2 3 4 5
    *
    C1   11 12 2.200E-12
    C2    6  7 10.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 9.446E9 -9E9 9E9 9E9 -9E9
    GA    6  0 11 12 87.96E-6
    GCM   0  6 10 99 440.9E-12
    ISS  10  4 DC 80.00E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   3 11 11.37E3
    RD2   3 12 11.37E3
    RO1   8  5 .17
    RO2   7 99 .17
    RP    3  4 5.833E3
    RSS  10 99 2.500E6
    VB    9  0 DC 0
    VC    3 53 DC 4.400
    VE   54  4 DC 3.800
    VLIM  7  8 DC 0
    VLP  91  0 DC 4.000E3
    VLN   0 92 DC 4.000E3
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX NJF(IS=7.500E-12 BETA=96.72E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA547 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * REV.A 2 June 97 GG
    * REV.B 6 June 97 NPA: added Note: Current Limit & E/S ARE modeled.
    * REV.C  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    * 
    * CONNECTIONS:     NON-INVERTING INPUT
    *                  | INVERTING INPUT
    *                  | | CURRENT LIMIT ADJUST
    *                  | | | NEGATIVE POWER SUPPLY
    *                  | | | | POSITIVE POWER SUPPLY
    *                  | | | | | OUTPUT
    *                  | | | | | | ENABLE/STATUS
    *                  | | | | | | |
    .SUBCKT OPA547/BB  1 2 3 4 5 6 7
    *
    Q2       18  16  14   PSUB
    R3       13  14   8.4K
    Q1       13  12  11   LAT5
    R15      40  4    .4
    Q9       5   34  35   NMIN 480
    Q4       25  26  4    NMAX 2
    HCCVSP   47  36   V475 -2000
    HCCVSN   42  4    V475 -2000
    GNEGDRV  5   37  31  36   -.00025
    R4       13  15   8.4K
    GAINBLK  26  4   18  19   .00175
    R8       19  4    1K
    R6       17  1    1K
    R5       2   16   1K
    R7       18  4    1K
    C2       37  36   11PF
    C1       26  25   31PF
    Q3       19  17  15   PSUB
    Q7       5   37  38   NMIN 24
    R17      38  4    690
    D6       32  31   DIODE 18
    D3       27  26   DIODE 1
    D5       27  37   DIODE 10
    D2       23  22   DIODE 6
    D1       10  12   DIODE 6
    VCLMP    27  4    DC .8
    VDUM     20  4    DC 0
    R9       21  20   35K
    C3       21  32   15PF
    FICOMP   37  4    VDUM 1
    D4       29  28   DIODE 1
    R13      28  4    750
    Q6       31  29  30   NMIN 2
    R14      30  4    300
    R18      39  38   100
    DCLAMP   37  36   DIODE 1
    R12      25  33   1K
    R0       32  34   25
    V475     43  4    DC 4.75
    GCLPGAIN 5   51  35  47   .00015
    Q11      33  51  36   NMIN 1
    C5       51  33   20PF
    D7       48  51   DIODE 1
    VDP      48  36   DC .65
    R21      3   43   31600
    D8       49  41   DIODE 1
    Q12      37  41  4    NMIN 1
    GCLNGAIN 5   41  40  42   .00015
    V1I459   49  4    DC .65
    C6       41  37   20PF
    DZ1      31  36   ZEN
    VCM      5   9    DC 1.4
    D9       45  46   DIODE 1
    D10      45  7    DIODE 1
    IBES     5   45   60UA
    R22      7   4    250K
    VBES     46  4    DC 3.6
    R16      34  36   2K
    R1       35  36   .4
    VTHES    44  4    DC 2.0
    DP2      4   1    DIODE 1
    DP1      1   5    DIODE 1
    DP4      4   2    DIODE 1
    DP3      2   5    DIODE 1
    DP5      3   5    DIODE 10
    DP6      4   3    DIODE 50
    DP8      4   6    DIODE 1
    DP7      6   5    DIODE 1
    DP9      7   5    DIODE 1
    DP10     4   7    DIODE 1
    SVCS1    36  6   45  44   VSM
    SVCS2    32  31  45  44   VSM2
    CS2      4   2    3PF
    CS1      4   1    3PF
    CS3      2   1    2.5PF
    Q5       25  22  24   LAT5
    R11      5   24   300
    R10      5   23   300
    I2       22  29   200UA
    Q10      36  39  40   NMIN 480
    Q8       5   33  32   NMIN 16
    I1       12  4    100UA
    R2       9   11   1K
    R19      9   10   1K
    *
    * DEVICE MODELS
    .MODEL ZEN D(IS=6E-16 CJO=1E-15 RS=1 BV=.2) 
    .MODEL LAT5 PNP(IS=4E-15 BF=80 VAF=80 CJE=1E-13 CJC=6E-13  TF=3.5E-8 RC=1.2E3 ) 
    + 
    .MODEL PSUB PNP(IS=6E-16 BF=360 VAF=140 CJE=5E-13 CJC=2.5E-13 TF=2.5E-10 
    + RC=1.2E3) 
    .MODEL NMAX NPN(IS=6E-16 BF=1200 VAF=140 CJE=5E-13 CJC=2.5E-13 TF=2.5E-10 
    + RC=1.0E3) 
    .MODEL NMIN NPN(IS=6E-16 BF=300 VAF=140 CJE=5E-13 CJC=2.5E-13 TF=2.5E-10 
    + RC=1.0E3) 
    .MODEL DIODE D(IS=6E-16 CJO=1E-15 RS=1) 
    .MODEL VSM2 VSWITCH(RON=1500 ROFF=1E7 VON=1.9 VOFF=2.1) 
    .MODEL VSM VSWITCH(RON=.1 ROFF=5E5 VON=2.1 VOFF=1.9) 
    .ENDS
    *$
    **************************************************************************
    * OPA602 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/11/90 AT 13:48
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA602/BB   1 2 3 4 5
    *
    C1   11 12 6.850E-12
    C2    6  7 13.70E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.213E6 -2E6 2E6 2E6 -2E6
    GA    6  0 11 12 602.6E-6
    GCM   0  6 10 99 6.026E-9
    ISS   3 10 DC 479.5E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.660E3
    RD2   4 12 1.660E3
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 10.00E3
    RSS  10 99 417.1E3
    VB    9  0 DC 0
    VC    3 53 DC 2.100
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=3.785E-4 VTO=-1)
    .ENDS
    *$
    ************************************************************************** 
    * OPA602E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/11/90 AT 10:13
    * REV.B 3/21/92 BCB: added input bias current correction and
    *                    current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA602E/BB  1 2 3 4 5
    *
    C1   11 12 6.850E-12
    C2    6  7 13.70E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 2.213E6 -2E6 2E6 2E6 -2E6
    GA    6  0 11 12 602.6E-6
    GCM   0  6 10 99 6.026E-9
    ISS   3 10 DC 479.5E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 600E-9
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 600E-9
    R2    6  9 100.0E3
    RD1   4 11 1.660E3
    RD2   4 12 1.660E3
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 10.00E3
    RSS  10 99 417.1E3
    VB    9  0 DC 0
    VC    3 53 DC 2.100
    VE   54  4 DC 1.200
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    ****************************
    * OPA602 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  2.221E-3  1
    FQ2   0  4 POLY(1) VQ2  2.221E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.0E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=1.7424E-16 AF=1 KF=24.597E-18)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=3.785E-4 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA603X CURRENT-FEEDBACK AMPLIFIER "CIRCUIT MODEL" SUBCIRCUIT
    * CREATED USING BLOOD,SWEAT AND TEARS ON 10/12/90 AT 09:03AM
    * REV.B   5/23/91
    * REV.C  10/20/92 - SYNTAX ERRORS BCB
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT  OPA603X/BB 3 4 1 2 5
    *
    R0A   3  6 100
    R0B   3  7 100
    R0EA 10  8 21
    R0EB 11  9 21
    R1A  10 12 100
    R1B  11 13 100
    R1EA 14  4 21
    R1EB 15  4 21
    R2AT  1 16 1213.22365
    R2BT  2 17 1200
    R3   22 23 16.25
    R4A  24  5 3.25
    R4B  25  5 3.25
    X0A   2  6 8 2 XP4LC
    X0B   1  7 9 2 XN4LC
    X1A  16 12 14 2 XN4LC
    X1B  17 13 15 2 XP4LC
    X2A  20 16 18 2 XP4LC
    X2B  21 17 19 2 XN4LC
    C2B  17 21 0.75PF
    X3A  20 20 22 2 XN16HC
    X3B  21 21 23 2 XP16HC
    X4A1  1 20 24 2 XN16HC
    X4A2  1 20 24 2 XN16HC
    X4A3  1 20 24 2 XN16HC
    X4B1  2 21 25 2 XP16HC
    X4B2  2 21 25 2 XP16HC
    X4B3  2 21 25 2 XP16HC
    X6A1 18 18 26 2 XP16HC 
    X6A2 18 18 26 2 XP16HC 
    X6B1 19 19 27 2 XN16HC 
    X6B2 19 19 27 2 XN16HC 
    V6A   1 26  0
    V6B  27  2  0
    FB    1 28 POLY(2) V6A V6B 15UA -0.0025 -0.0025
    RB   28  2 500MEG
    CB   28  2 350PF
    DB1  28  2 DCLAMP
    DB2   2 28 DCLAMP
    GC   36 37 28 2 0.01
    R5A  30 32 21
    R5B  31 33 21
    R8A  34 36 21
    R8B  35 37 21
    X5A  10 36 32 2 XP4LC
    X5B  11 37 33 2 XN4LC
    X8A   1 30 34 2 XN4LC
    X8B   2 31 35 2 XP4LC
    X9A   1  1 30 2 XN4LC
    X9B   2  2 31 2 XP4LC
    IS    1  2 290UA
    RPS   1  2 21.6K
    XSCA  5 22 22 2 XN4LC
    XSCB  5 23 23 2 XP4LC
    .ENDS 
    ********************************
    .MODEL DCLAMP D
    ********************************
    .SUBCKT XN4LC 1 2 3 SUB
    Q1 4 2 3 SUB N4
    RCDC 1 4 250
    RCAC 1 5 85
    CRC  4 5 1NF
    CS   1 0 0.45PF
    *
    .MODEL N4 NPN IS=4.4FA BF=250 VA=100 IKF=14MA BR=0.1 
    +RE=1.5 RB=200 RBM=75 IRB=22MA RC=0 CJE=2.2PF VJE=0.77 MJE=0.3
    +CJC=0.98PF VJC=0.64 MJC=0.425 XCJC=0.2 CCS=0 VJS=0.75 MJS=0
    +FC=0.9 TF=65P XTF=20 VTF=10 ITF=300MA TR=1US EG=1.20561 XTB=6M
    +XTI=2.33 KF=0.16F
    .ENDS 
    *
    .SUBCKT XN16HC 1 2 3 SUB
    Q1 4 2 3 SUB N16HC 1
    RCDC 1 4 62.5
    RCAC 1 5 20
    CRC 5 4 100N
    CS 1 0 0.80PF
    *
    .MODEL N16HC NPN IS=16FA BF=250 VA=100 IKF=56MA BR=0.1 
    +RE=187.5M RB=50 RBM=9 IRB=176MA RC=0 CJE=11.2PF VJE=0.77 MJE=0.3
    +CJC=2.929PF VJC=0.64 MJC=0.36 XCJC=0.2 CCS=0 VJS=0.75 MJS=0
    +FC=0.8 TF=150P XTF=80 VTF=50 ITF=1.6 TR=1US EG=1.20561 XTB=6M
    +XTI=2.33  KF=0.16F
    .ENDS 
    *
    .SUBCKT XP4LC 1 2 3 SUB
    Q1 4 2 3 SUB P4
    RCDC 1 4 300
    RCAC 1 5 100
    CRC  4 5 1NF
    CS   1 0 0.54PF
    *
    .MODEL P4 PNP IS=4.4FA BF=100 VA=60 IKF=14MA BR=0.1 
    +RE=3 RB=100 RBM=15 IRB=1.93MA RC=0 CJE=2PF VJE=0.77 MJE=0.3
    +CJC=1.6PF VJC=0.64 MJC=0.425 XCJC=0.21 CCS=0 VJS=0.75 MJS=0
    +FC=0.9 TF=150P XTF=20 ITF=160MA TR=1US EG=1.205612 XTB=6M
    +XTI=2.33 KF=0.16F
    .ENDS 
    *
    .SUBCKT XP16HC 1 2 3 SUB
    Q1 4 2 3 SUB P16HC 1
    RCDC 1 4 75
    RCAC 1 5 75
    CRC 5 4 100N
    CS 1 0 0.93PF
    *
    .MODEL P16HC PNP IS=16FA BF=100 VA=60 IKF=40MA BR=0.1 
    +RE=0.3 RB=25 RBM=5 IRB=68MA RC=0 CJE=9.6PF VJE=0.6 MJE=0.3
    +CJC=4.383PF VJC=0.64 MJC=0.3 XCJC=0.2 CCS=0 VJS=0.75 MJS=0
    +FC=0.95 TF=100P XTF=25 VTF=100 ITF=500MA TR=1US EG=1.20561 XTB=6M
    +XTI=2.33 KF=0.16F
    .ENDS 
    *$
    **************************************************************************
    * OPA604 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 6/10/92
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA604/BB   1 2 3 4 5
    *
    C1   11 12 22.85E-12
    C2    6  7 32.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 418.4E3 -40E3 40E3 40E3 -40E3
    GA    6  0 11 12 2.011E-3
    GCM   0  6 10 99 20.11E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 497.4
    RD2   4 12 497.4
    RO1   8  5 25
    RO2   7 99 75
    RP    3  4 6.294E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=12.50E-12 BETA=2.528E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA604E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 6/10/92
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA604E/BB  1 2 3 4 5
    *
    C1   11 12 22.85E-12
    C2    6  7 32.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 418.4E3 -40E3 40E3 40E3 -40E3
    GA    6  0 11 12 2.011E-3
    GCM   0  6 10 99 20.11E-9
    ISS   3 10 DC 800.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 6E-6
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 6E-6
    R2    6  9 100.0E3
    RD1   4 11 497.4
    RD2   4 12 497.4
    RO1   8  5 25
    RO2   7 99 75
    *  RP    3  4 6.294E3
    RSS  10 99 250.0E3
    VB    9  0 DC 0
    VC    3 53 DC 3
    VE   54  4 DC 3
    VLIM  7  8 DC 0
    VLP  91  0 DC 50
    VLN   0 92 DC 50
    ****************************
    * OPA2604 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  3.45E-3  1
    FQ2   0  4 POLY(1) VQ2  3.45E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  6.0E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  8.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 5.0E-12
    C2CM  2  99 5.0E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=133.62E-18 AF=1 KF=11.726E-18)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=12.50E-12 BETA=2.528E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA604M OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "M" IS  MULTIPLE POLE/ZERO TOPOLOGY
    * CREATED 7/8/92 BCB
    * REV.A
    *
    *  -------------------------------------------------------------
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |                                                             |
    * |  Neither this library nor any part may be copied without    |
    * |  the express written consent of Burr-Brown Corporation.     |
    * |                                                             |
    * |  The users should carefully note the following factors      |
    * |  regarding this model.                                      |
    *   -------------------------------------------------------------
    *
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |  INVERTING INPUT
    *                    |  |  POSITIVE POWER SUPPLY
    *                    |  |  |  NEGATIVE POWER SUPPLY
    *                    |  |  |  |  OUTPUT
    *                    |  |  |  |  |
    .SUBCKT  OPA604M/BB  3  2  7  4  6
    *
    * INPUT STAGE (pole=1.6MHz)
    J1   13   2  12  PJ
    J2   14  11  12  PJ
    G51   2   4  POLY(2) (13,2) (12,2) 0 1E-12 1E-12
    G52  11   4  POLY(2) (14,11) (12,11) 0 1E-12 1E-12
    R3    4  13  198.94
    R4    4  14  198.94
    C1   13  14  250E-12
    IEE   7  12  1.8E-3
    EOS  11   3  POLY(1)  (33,10)  3E-3  1
    R1    2  15  5E11
    R2    3  15  5E11
    CIN   2   3  8E-12
    IOS   2   3  4E-12
    * GAIN STAGE (gain=100dB, pole=200Hz)
    V21   7  21  3.236
    D21  23  21  DX
    V22  22   4  3.236
    D22  22  23  DX
    G21   7  23  POLY(1)  (13,14)   2.9238E-3 5.0265E-3
    G22   4  23  POLY(1)  (13,14)  -2.9238E-3 5.0265E-3
    R27   7  23  19.89E6
    R28   4  23  19.89E6
    C22   7  23  40E-12
    C23   4  23  40E-12
    * ZERO / POLE STAGE (zero=1.6MHz, pole=10MHz)
    R46  41  43  1E6
    R47  42  43  1E6
    R45   7  41  5.25E6
    R48   4  42  5.25E6
    L41   7  41  83.6E-3
    L42   4  42  83.6E-3
    G45   7  43  23  10  1E-6
    G46   4  43  23  10  1E-6
    * POLE / ZERO STAGE (pole=0.4MHz, zero=1.6MHz)
    R81   7  83  1E6
    R84   4  83  1E6
    R82  81  83  0.25E6
    R83  82  83  0.25E6
    C84  81   7  397.9E-15
    C85  82   4  397.9E-15
    G81   7  83  43  10  1E-6
    G82   4  83  43  10  1E-6
    * COMMON-MODE REJECTION STAGE (zero at 2kHz)
    R31  31  33  1E6
    R32  32  33  1E6
    G31   7  33  15  10  1E-11
    G32   4  33  15  10  1E-11
    L31  31   7  79.577
    L32  32   4  79.577
    * OUTPUT STAGE
    D3   83  71  DX
    D4   72  83  DX
    D5    7  73  DX
    D6    7  74  DX
    D7    4  73  DZ
    D8    4  74  DZ
    G14  73   4  6  83  20E-3
    G13  74   4  83  6  20E-3
    V3   71   6  0.38686
    V4    6  72  0.38686
    G11   6   7  7  83  20E-3
    G12   4   6  83   4  20E-3
    R23   7   6  50
    R24   4   6  50
    * CENTER OF SUPPLIES
    R9    7  10  31.304E3
    R10   4  10  31.304E3
    *
    .MODEL  DX  D(IS=1E-15)
    .MODEL  PJ  PJF(BETA=12.63285E-3 VTO=-2 IS=50E-12)
    .MODEL  DZ  D(IS=1E-15 BV=50)
    .ENDS
    *$
    **************************************************************************
    * OPA606 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/11/90 AT 15:00
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA606/BB   1 2 3 4 5
    *
    C1   11 12 4.195E-12
    C2    6  7 10.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 35.80E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 785.4E-6
    GCM   0  6 10 99 13.97E-9
    ISS   3 10 DC 300.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 1.273E3
    RD2   4 12 1.273E3
    RO1   8  5 20
    RO2   7 99 20
    RP    3  4 4.615E3
    RSS  10 99 666.7E3
    VB    9  0 DC 0
    VC    3 53 DC 2.800
    VE   54  4 DC 2.800
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=3.500E-12 BETA=1.028E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA606E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/28/90 AT 11:39
    * REV.B 3/21/92 BCB:  added input bias current correction and
    *                     current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA606E/BB  1 2 3 4 5
    *
    C1   11 12 4.195E-12
    C2    6  7 10.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 35.80E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 785.4E-6
    GCM   0  6 10 99 13.97E-9
    ISS   3 10 DC 300.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 1.3E-6
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 1.3E-6
    R2    6  9 100.0E3
    RD1   4 11 1.273E3
    RD2   4 12 1.273E3
    RO1   8  5 20
    RO2   7 99 20
    *  RP    3  4 4.615E3
    RSS  10 99 666.7E3
    VB    9  0 DC 0
    VC    3 53 DC 2.800
    VE   54  4 DC 2.800
    VLIM  7  8 DC 0
    VLP  91  0 DC 20
    VLN   0 92 DC 20
    ****************************
    * OPA606 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  5.00E-3  1
    FQ2   0  4 POLY(1) VQ2  5.00E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  2.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=1.85E-16 AF=1 KF=53.291E-18)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=3.500E-12 BETA=1.028E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA620 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/05/90 AT 16:04
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA620/BB   1 2 3 4 5
    *
    C1   11 12 577.4E-15
    C2    6  7 2.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 53.05E3 -50E3 50E3 50E3 -50E3
    GA    6  0 11 12 3.770E-3
    GCM   0  6 10 99 670.4E-9
    IEE  10  4 DC 830.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 265.3
    RC2   3 12 265.3
    RE1  13 10 193.3
    RE2  14 10 193.3
    REE  10 99 241.0E3
    RO1   8  5 5
    RO2   7 99 5
    RP    3  4 495.4
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 150
    VLN   0 92 DC 150
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=26.67)
    .ENDS
    *$
    **************************************************************************
    * OPA620E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/05/90 AT 14:07
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA620E/BB  1 2 3 4 5
    *
    C1   11 12 577.4E-15
    C2    6  7 2.000E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 53.05E3 -50E3 50E3 50E3 -50E3
    GA    6  0 11 12 3.770E-3
    GCM   0  6 10 99 670.4E-9
    IEE  10  4 DC 830.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 265.3
    RC2   3 12 265.3
    RE1  13 10 193.3
    RE2  14 10 193.3
    REE  10 99 241.0E3
    RO1   8  5 5
    RO2   7 99 5
    *  RP    3  4 495.4
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 150
    VLN   0 92 DC 150
    ****************************
    * OPA620 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  17.7E-3  1
    FQ2   0  4 POLY(1) VQ2  17.7E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  4.0E3
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 0.5E-12
    C2CM  2  99 0.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=26.67)
    .ENDS
    *$
    **************************************************************************
    * OPA620X OPERATIONAL AMPLIFIER SUBCIRCUIT
    * "X" IS SIMPLIFIED CIRCUIT MODEL
    * REV.B   3/16/90  PWT
    *
    * USERS SHOULD VERY CAREFULLY NOTE THE FOLLOWING FACTORS REGARDING THESE
    * MODELS:
    *	THE MODELS ARE VALID ONLY AT AN AMBIENT TEMPERATURE OF 25 DEGREES
    *	CENTIGRADE, AND AT SUPPLY VOLTAGES OF +/-5VDC.
    *
    *	THIS SIMPLIFIED CIRCUIT USES ACTUAL TRANSISTORS INSTEAD OF
    *	MATHEMATICAL MODELING IN ORDER TO MORE CLOSELY MODEL DEVICE
    *	PERFORMANCE.  AS SUCH, REASONABLY ACCURATE SIMULATIONS OF GAIN/PHASE,
    *	PULSE RESPONSE, DISTORTION, AND NOISE ARE POSSIBLE.  THIS CAPABILITY
    *	CAN BE ESPECIALLY VALUABLE TO DESIGNERS OF VIDEO AND RF SYSTEMS.
    *
    *	THIS SIMPLIFIED CIRCUIT IS BEING SUPPLIED TO USERS AS AN AID TO
    *	CIRCUIT DESIGNS.  WHILE IT REFLECTS REASONABLY CLOSE SIMILARITY
    *	TO THE ACTUAL DEVICE IN TERMS OF PERFORMANCE, IT IS NOT SUGGESTED
    *	AS A REPLACEMENT FOR BREADBOARDING.  SIMULATION SHOULD BE USED AS
    *	A FORERUNNER OR A SUPPLEMENT TO TRADITIONAL LAB TESTING.
    *
    *	MODEL USERS ARE HEREBY NOTIFIED THAT THESE MODELS ARE SUPPLIED
    *	"AS IS", WITH NO DIRECT OR IMPLIED RESPONSIBILITY ON THE PART OF
    *	BURR-BROWN FOR THEIR OPERATION WITHIN A CUSTOMER CIRCUIT OR SYSTEM.
    *	FURTHER, BURR-BROWN CORPORATION RESERVES THE RIGHT TO CHANGE THESE
    *	MODELS WITHOUT PRIOR NOTICE.
    *
    *	IN ALL CASES, THE CURRENT DATA SHEET INFORMATION FOR A GIVEN REAL
    *	DEVICE IS YOUR FINAL DESIGN GUIDELINE, AND IS THE ONLY ACTUAL
    *	PERFORMANCE GUARANTEE.
    *
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    | INVERTING INPUT
    *                    | | POSITIVE POWER SUPPLY
    *                    | | | NEGATIVE POWER SUPPLY
    *                    | | | | OUTPUT
    *                    | | | | |
    .SUBCKT OPA620X/BB   1 2 3 4 5
    *
    C1       20  4   10PF
    I1       18  15  1.1MA
    I2       24  4   4.0MA
    I3       3   25  2.0MA
    Q1       9   1   11  4 NPN 2
    Q2       10  2   12  4 NPN 2
    Q3       13  15  14  4 NPN 4
    Q4       15  15  16  4 NPN 1
    Q5       18  18  17  3 PNP 0.5
    Q6       19  18  9   3 PNP
    Q7       20  18  10  3 PNP
    Q8       20  19  21  4 NPN 2
    Q9       19  21  22  4 NPN 2
    Q10      21  21  23  4 NPN 2
    Q11      3   20  24  4 NPN 20
    Q12      4   20  25  3 PNP 20
    Q13      3   25  5   4 NPN 40
    Q14      4   24  5   3 PNP 40
    R1       3   9   250
    R2       3   10  250
    R3       11  13  35
    R4       12  13  35
    R5       14  4   62.5
    R6       16  4   250
    R7       3   17  1K
    R8       22  4   250
    R9       23  4   250
    *
    *DEVICE MODELS COPYRIGHT 1989, AT&T. REPRINTED WITH PERMISSION.
    .MODEL NPN NPN RB=63.71 IRB=0 RBM=29.0 RC=16.67 RE=1.667
    +IS=111E-18 EG=1.206 XTI=2 XTB=2.363 BF=234.2
    +IKF=5.838E-3 NF=1.0 VAF=30.00 ISE=35.1E-16 NE=1.999
    +BR=4 IKR=10E6 NR=1.0 VAR=3.00 ISC=2.34E-20 NC=1.653
    +TF=32.4E-12 TR=32.4E-11 CJE=.2E-12 VJE=1.104
    +MJE=0.495 CJC=0.286E-13 VJC=0.508 MJC=0.3345 XCJC=1.00
    +CJS=0.505E-12 VJS=0.793 MJS=0.167 FC=0.5 AF=1 KF=15F
    *
    .MODEL PNP PNP RB=25.87 IRB=0 RBM=11.98 RC=126.32 RE=1.667
    +IS=285.3E-18 EG=1.206 XTI=1.5 XTB=2.053 BF=119.3
    +IKF=7.254E-3 NF=1 VAF=28.0 ISE=88E-16 NE=1.557
    +BR=4 IKR=10E6 NR=1 VAR=1.4 ISC=4.01E-16 NC=1.634
    +TF=48E-12 TR=65E-11 CJE=.186E-12 VJE=0.892
    +MJE=0.493 CJC=.518E-13 VJC=0.611 MJC=0.335 XCJC=1.00
    +CJS=1.072PF VJS=0.469 MJS=0.1875 FC=0.5 AF=1 KF=15F
    .ENDS
    *$
    **************************************************************************
    * OPA621 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/05/90 AT 16:10
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA621/BB   1 2 3 4 5
    *
    C1   11 12 433.0E-15
    C2    6  7 500.0E-15
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 106.1E3 -10E3 10E3 10E3 -10E3
    GA    6  0 11 12 1.885E-3
    GCM   0  6 10 99 335.2E-9
    IEE  10  4 DC 330.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 530.5
    RC2   3 12 530.5
    RE1  13 10 325.5
    RE2  14 10 325.5
    REE  10 99 606.1E3
    RO1   8  5 5
    RO2   7 99 5
    RP    3  4 389.3
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 150
    VLN   0 92 DC 150
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=10)
    .ENDS
    *$
    **************************************************************************
    * OPA621E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/05/90 AT 14:07
    * REV.A
    * USERS SHOULD VERY CAREFULLY NOTE THE FOLLOWING FACTORS REGARDING THESE
    * MODELS:
    *
    *	THE MODELS ARE VALID ONLY AT AN AMBIENT TEMPERATURE OF 25 DEGREES
    *	CENTIGRADE, AND AT SUPPLY VOLTAGES OF +/-5VDC.
    *
    *	THIS SIMPLIFIED CIRCUIT USES ACTUAL TRANSISTORS INSTEAD OF
    *	MATHEMATICAL MODELING IN ORDER TO MORE CLOSELY MODEL DEVICE
    *	PERFORMANCE.  AS SUCH, REASONABLY ACCURATE SIMULATIONS OF GAIN/PHASE,
    *	PULSE RESPONSE, DISTORTION, AND NOISE ARE POSSIBLE.  THIS CAPABILITY
    *	CAN BE ESPECIALLY VALUABLE TO DESIGNERS OF VIDEO AND RF SYSTEMS.
    *
    *	FOR FURTHER TECHNICAL INFORMATION REFER APPLICATION NOTE AN-167
    *	"*** MODELS FOR OPA620 AND OPA621".
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA621E/BB  1 2 3 4 5
    *
    C1   11 12 433.0E-15
    C2    6  7 500.0E-15
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 106.1E3 -10E3 10E3 10E3 -10E3
    GA    6  0 11 12 1.885E-3
    GCM   0  6 10 99 335.2E-9
    IEE  10  4 DC 330.0E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 530.5
    RC2   3 12 530.5
    RE1  13 10 325.5
    RE2  14 10 325.5
    REE  10 99 606.1E3
    RO1   8  5 5
    RO2   7 99 5
    *  RP    3  4 389.3
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 150
    VLN   0 92 DC 150
    ****************************
    * OPA621 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  22.37E-3  1
    FQ2   0  4 POLY(1) VQ2  22.37E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  3.0E3
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 0.5E-12
    C2CM  2  99 0.5E-12
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=10)
    .ENDS
    *$
    **************************************************************************
    * OPA621X OPERATIONAL AMPLIFIER SUBCIRCUIT
    * "X" IS SIMPLIFIED CIRCUIT MODEL
    * REV.B  3/16/90   PWT
    *
    * USERS SHOULD VERY CAREFULLY NOTE THE FOLLOWING FACTORS REGARDING THESE
    * MODELS:
    *
    *	THE MODELS ARE VALID ONLY AT AN AMBIENT TEMPERATURE OF 25 DEGREES
    *	CENTIGRADE, AND AT SUPPLY VOLTAGES OF +/-5VDC.
    *
    *	THIS SIMPLIFIED CIRCUIT USES ACTUAL TRANSISTORS INSTEAD OF
    *	MATHEMATICAL MODELING IN ORDER TO MORE CLOSELY MODEL DEVICE
    *	PERFORMANCE.  AS SUCH, REASONABLY ACCURATE SIMULATIONS OF GAIN/PHASE,
    *	PULSE RESPONSE, DISTORTION, AND NOISE ARE POSSIBLE.  THIS CAPABILITY
    *	CAN BE ESPECIALLY VALUABLE TO DESIGNERS OF VIDEO AND RF SYSTEMS.
    *
    *	THIS SIMPLIFIED CIRCUIT IS BEING SUPPLIED TO USERS AS AN AID TO
    *	CIRCUIT DESIGNS.  WHILE IT REFLECTS REASONABLY CLOSE SIMILARITY
    *	TO THE ACTUAL DEVICE IN TERMS OF PERFORMANCE, IT IS NOT SUGGESTED
    *	AS A REPLACEMENT FOR BREADBOARDING.  SIMULATION SHOULD BE USED AS
    *	A FORERUNNER OR A SUPPLEMENT TO TRADITIONAL LAB TESTING.
    *
    *	MODEL USERS ARE HEREBY NOTIFIED THAT THESE MODELS ARE SUPPLIED
    *	"AS IS", WITH NO DIRECT OR IMPLIED RESPONSIBILITY ON THE PART OF
    *	BURR-BROWN FOR THEIR OPERATION WITHIN A CUSTOMER CIRCUIT OR SYSTEM.
    *	FURTHER, BURR-BROWN CORPORATION RESERVES THE RIGHT TO CHANGE THESE
    *	MODELS WITHOUT PRIOR NOTICE.
    *
    *	IN ALL CASES, THE CURRENT DATA SHEET INFORMATION FOR A GIVEN REAL
    *	DEVICE IS YOUR FINAL DESIGN GUIDELINE, AND IS THE ONLY ACTUAL
    *	PERFORMANCE GUARANTEE.
    *
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    | INVERTING INPUT
    *                    | | POSITIVE POWER SUPPLY
    *                    | | | NEGATIVE POWER SUPPLY
    *                    | | | | OUTPUT
    *                    | | | | |
    .SUBCKT OPA621X/BB   1 2 3 4 5
    *
    C1       20  4   2PF
    I1       18  15  1.3MA
    I2       24  4   3.5MA
    I3       3   25  3.5MA
    Q1       9   1   11  4 NPN 2
    Q2       10  2   12  4 NPN 2
    Q3       13  15  14  4 NPN 4
    Q4       15  15  16  4 NPN 1
    Q5       18  18  17  3 PNP 0.5
    Q6       19  18  9   3 PNP
    Q7       20  18  10  3 PNP
    Q8       20  19  21  4 NPN 2
    Q9       19  21  22  4 NPN 2
    Q10      21  21  23  4 NPN 2
    Q11      3   20  24  4 NPN 20
    Q12      4   20  25  3 PNP 20
    Q13      3   25  5   4 NPN 40
    Q14      4   24  5   3 PNP 40
    R1       3   9   250
    R2       3   10  250
    R3       11  13  35
    R4       12  13  35
    R5       14  4   62.5
    R6       16  4   250
    R7       3   17  1K
    R8       22  4   250
    R9       23  4   250
    *
    *DEVICE MODELS COPYRIGHT 1989, AT&T. REPRINTED WITH PERMISSION.
    .MODEL NPN NPN RB=63.71 IRB=0 RBM=29.0 RC=16.67 RE=1.667
    +IS=111E-18 EG=1.206 XTI=2 XTB=2.363 BF=234.2
    +IKF=5.838E-3 NF=1.0 VAF=30.00 ISE=35.1E-16 NE=1.999
    +BR=4 IKR=10E6 NR=1.0 VAR=3.00 ISC=2.34E-20 NC=1.653
    +TF=32.4E-12 TR=32.4E-11 CJE=.2E-12 VJE=1.104
    +MJE=0.495 CJC=0.286E-13 VJC=0.508 MJC=0.3345 XCJC=1.00
    +CJS=0.505E-12 VJS=0.793 MJS=0.167 FC=0.5 AF=1 KF=15F
    *
    .MODEL PNP PNP RB=25.87 IRB=0 RBM=11.98 RC=126.32 RE=1.667
    +IS=285.3E-18 EG=1.206 XTI=1.5 XTB=2.053 BF=119.3
    +IKF=7.254E-3 NF=1 VAF=28.0 ISE=88E-16 NE=1.557
    +BR=4 IKR=10E6 NR=1 VAR=1.4 ISC=4.01E-16 NC=1.634
    +TF=48E-12 TR=65E-11 CJE=.186E-12 VJE=0.892
    +MJE=0.493 CJC=.518E-13 VJC=0.611 MJC=0.335 XCJC=1.00
    +CJS=1.072PF VJS=0.469 MJS=0.1875 FC=0.5 AF=1 KF=15F
    .ENDS
    *$
    **************************************************************************
    * OPA622X1 - WIDE-BANDWIDTH OPERATIONAL AMPLIFIER MACROMODEL SIMPLIFIED VERSION
    * CREATED 8/92 KL
    * REV.B  7/9/93 BCB:  CLARIFICATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : FOR QUICKER CONVERSION PLACE THE NODESET 
    *        V(Xyour.X1.131)=+4.2798 AND
    *        V(Xyour.X1.141)=-4.2808 IN THE ROOT SIMULATION FILE.
    *        ("Xyour" IS DEVICE NAME CALLED OUT IN THE ROOT FILE.)
    *
    * CONNECTIONS:       Iq ADJUST
    *                    | INVERTING INPUT
    *                    | | NON-INVERTING INPUT
    *                    | | | NEGATIVE POWER SUPPLY
    *                    | | | | NEGATIVE OUTPUT POWER SUPPLY
    *                    | | | | | BUFFER -
    *                    | | | | | | VOLTAGE OUT
    *                    | | | | | | | OTA
    *                    | | | | | | | |  POSITIVE OUTPUT POWER SUPPLY
    *                    | | | | | | | |  |  POSITIVE POWER SUPPLY
    *                    | | | | | | | |  |  |  BUFFER +
    *                    | | | | | | | |  |  |  |
    .SUBCKT OPA622X1/BB  2 3 4 5 6 8 9 10 11 12 13
    *
    X1  2 5 12 131 141                BC/OPA622x1 ; Biasing Circuit BC
    X2  4 5 10 12 13 111 121 131 141  DT/OPA622x1 ; Diamond Transistor DT
    X3  6 9 11 111 121                CB/OPA622x1 ; Current-Buffer CB
    X4  3 5 8 12 131 141              DB/OPA622x1 ; Diamond-Buffer DB
    *
    C202    2  0   2E-12
    C208    8  0   2E-12
    C209    9  0   2E-12
    C210   10  0   2E-12
    C213   13  0   2E-12
    *
    .ENDS
    *
    *Diamond Buffer DB
    .SUBCKT DB/OPA622x1 3 5 8 12 131 141
    *
    R63  63 3  40
    C61  61 0  0.02E-12
    C62  62 0  0.02E-12
    C63  63 0  2E-12
    Q61  61 131 12 12  PI/OPA622x1
    Q62  62 141  5  5  NI/OPA622x1
    Q63   5 63  61 12  PI/OPA622x1
    Q64  12 63  62  5  NI/OPA622x1
    Q65  12 61   8  5  NI/OPA622x1 6
    Q66   5 62   8 12  PI/OPA622x1 6
    *
    .ENDS
    *
    *Diamond Transistor DT
    .SUBCKT DT/OPA622x1 4 5 10 12 13 111 121 131 141
    *
    R23   23   4  40
    C10   10   0  2.0E-12
    C21   21   0  0.02E-12
    C22   22   0  0.02E-12
    C23   23   0  2E-12
    C27   27   0  14E-12
    C28   28   0  14E-12
    Q21   21 131  12 12  PI/OPA622x1
    Q22   22 141   5  5  NI/OPA622x1
    Q23    5  23  21 12  PI/OPA622x1
    Q24   12  23  22  5  NI/OPA622x1
    Q25   27  21  13  5  NI/OPA622x1 6
    Q26   28  22  13 12  PI/OPA622x1 6
    Q27   27  27  12 12  PIM/OPA622x1
    Q28   28  28   5  5  NIM/OPA622x1
    Q29  111  27  12 12  PIM/OPA622x1
    Q30  121  28   5  5  NIM/OPA622x1
    Q31  111 111  33  5  NI/OPA622x1
    Q32  121 121  34 12  PI/OPA622x1
    Q33   33  33  10  5  NI/OPA622x1
    Q34   34  34  10 12  PI/OPA622x1
    *
    .ENDS
    *
    *Current Buffer CB
    .SUBCKT CB/OPA622x1 6 9 11 111 121
    *
    Q35  11 111  37  6  NI/OPA622x1
    Q36   6 121  38 11  PI/OPA622x1
    Q37  37  37  39  6  NI/OPA622x1
    Q38  38  38  39 11  PI/OPA622x1
    Q39  11  37   9  6  NI/OPA622x1 2.2
    Q40   6  38   9 11  PI/OPA622x1 2.2
    *
    .ENDS
    *
    *Biasing Circuit BC
    .SUBCKT BC/OPA622x1 2 5 12 131 141
    *
    R122  122   5  100k
    R123  122   2  200
    Q121  131 131  12 12  PI/OPA622x1
    Q122  131 141 122  5  NI/OPA622x1 10
    Q123  141 131  12 12  PI/OPA622x1
    Q124  141 141   5  5  NI/OPA622x1
    *
    .ENDS
    *
    .MODEL NI/OPA622x1 NPN
    .MODEL PI/OPA622x1 PNP
    .MODEL NIM/OPA622x1 NPN (VAF=18)
    .MODEL PIM/OPA622x1 PNP (VAF=18)
    *$
    **************************************************************************
    * OPA622X2 WIDE-BANDWIDTH OPERATIONAL AMPLIFIER MACROMODEL COMPLEX VERSION
    * CREATED 8/92 BY KL
    * REV.B 7/9/93 BCB: CLARIFICATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    *  NOTE : FOR QUICKER CONVERSIONS PLACE THE NODESET 
    *         V(Xyour.X1.121)=+4.2833 AND
    *         V(Xyour.X1.124)=-4.2838 INTO THE ROOT SIMULATION FILE.
    *         ("Xyour" IS THE DEVICE NAME CALLED OUT IN THE ROOT FILE.)
    *
    * CONNECTIONS :      Iq ADJUST
    *                    | INVERTING INPUT
    *                    | | NON-INVERTING INPUT
    *                    | | | NEGATIVE POWER SUPPLY
    *                    | | | | NEGATIVE OUTPUT POWER SUPPLY
    *                    | | | | | BUFFER -
    *                    | | | | | | VOLTAGE OUT
    *                    | | | | | | |  OTA
    *                    | | | | | | |  |  POSITIVE OUTPUT POWER SUPPLY
    *                    | | | | | | |  |  |  POSITIVE POWER SUPPLY
    *                    | | | | | | |  |  |  |  BUFFER +
    *                    | | | | | | |  |  |  |  |
    .SUBCKT OPA622X2/BB  2 3 4 5 6 8 9 10 11 12 13
    *
    X1  2 5 12 131 141                BC/OPA622x2 ; Biasing Circuit BC
    X2  4 5 10 12 13 111 125 131 141  DT/OPA622x2 ; Diamond Transistor DT
    X3  6 9 11 111 125                CB/OPA622x2 ; Current-Buffer CB
    X4  3 5 8 12 131 141              DB/OPA622x2 ; Diamond-Buffer DB
    *
    C202    2  0   2E-12
    C203    3  0   2E-12
    C204    4  0   2E-12
    C208    8  0   2E-12
    C209    9  0   2E-12
    C210   10  0   2E-12
    C213   13  0   2E-12
    *
    .ENDS
    *
    *Diamond Buffer DB
    .SUBCKT DB/OPA622x2 3 5 8 12 131 141
    *
    Q61  64 131 12 12  PI/OPA622x2
    Q62  63 141  5  5  NI/OPA622x2
    Q63  63 63  12 12  PIJ/OPA622x2 10
    Q64  64 64   5  5  NIJ/OPA622x2 10
    Q65  69 63  12 12  PIJ/OPA622x2 10
    Q66  70 64   5  5  NIJ/OPA622x2 10
    Q67  64  3  69 12  PIJ/OPA622x2
    Q68  63  3  70  5  NIJ/OPA622x2
    Q69  69 69  68  5  NIJ/OPA622x2
    Q70  70 70  68 12  PIJ/OPA622x2
    Q71  73 69   8  5  NIJ/OPA622x2 6
    Q72  74 70   8 12  PIJ/OPA622x2 6
    Q73  73 73  12 12  PIJ/OPA622x2 4
    Q74  74 74   5  5  NIJ/OPA622x2 4
    *
    .ENDS
    *
    *Diamond Transistor DT
    .SUBCKT DT/OPA622x2 4 5 10 12 13 111 125 131 141
    *
    Q21  24 131 12 12  PI/OPA622x2
    Q22  23 141  5  5  NI/OPA622x2
    Q23  23 23  12 12  PIJ/OPA622x2 10
    Q24  24 24   5  5  NIJ/OPA622x2 10
    Q25  29 23  12 12  PIJ/OPA622x2 10
    Q26  30 24   5  5  NIJ/OPA622x2 10
    Q27  24  4  29 12  PIJ/OPA622x2
    Q28  23  4  30  5  NIJ/OPA622x2
    Q29  29 29  28  5  NIJ/OPA622x2
    Q30  30 30  28 12  PIJ/OPA622x2
    Q31  33 29  13  5  NIJ/OPA622x2 6
    Q32  34 30  13 12  PIJ/OPA622x2 6
    Q33  33 33  12 12  PIJ/OPA622x2 8
    Q34  34 34   5  5  NIJ/OPA622x2 8
    Q35  111 33 12 12  PIJ/OPA622x2 8
    Q36  125 34  5  5  NIJ/OPA622x2 8
    Q37  111 37 10  5  NIJ/OPA622x2 5
    Q38  10 38 125  5  NIJ/OPA622x2 5
    Q39  10 37 111 12  PIJ/OPA622x2 5
    Q40  125 38 10 12  PIJ/OPA622x2 5
    *
    .ENDS
    *
    *Current Buffer CB
    .SUBCKT CB/OPA622x2 6 9 11 111 125
    *
    Q43  11 111 45  6  NIJ/OPA622x2 4
    Q44   6 125 46 11  PIJ/OPA622x2 4
    Q45  45 45  47  6  NIJ/OPA622x2 12
    Q46  46 46  47 11  PIJ/OPA622x2 12
    Q47  11 45   9  6  NIJ/OPA622x2 48
    Q48   6 46   9 11  PIJ/OPA622x2 48
    *
    .ENDS
    *
    *Biasing Circuit BC
    .SUBCKT BC/OPA622x2 2 5 12 131 141
    *
    E13  131 0  121 0  1
    E14  141 0  124 0  1
    I121  121 124  0.1E-6
    R122  122  5  100E3
    R123  122  2  200
    C121  121  12 10E-12
    C124  124   5 10E-12
    Q121  121 121  12 12  PI/OPA622x2
    Q122  121 124 122  5  NI/OPA622x2 6
    Q123  124 121  12 12  PI/OPA622x2
    Q124  124 124   5  5  NI/OPA622x2
    Q125   5  131  12 12  PI/OPA622x2 11
    *
    .ENDS
    *
    .MODEL NIJ/OPA622x2 NPN (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *
    .MODEL PIJ/OPA622x2 PNP (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *
    .MODEL NI/OPA622x2 NPN
    .MODEL PI/OPA622x2 PNP
    *$
    **************************************************************************
    * OPA623X1 WIDE BANDWIDTH, CURRENT FEEDBACK, SIMPLIFIED VERSION MACROMODEL
    * CREATED 8/92 KL
    * REV.B 7/9/93 BCB: CLARIFICATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : FOR QUICKER CONVERGENCE ADD THE NODESET 
    *        V(Xyour.X1.131)=+4.2885 AND
    *        V(Xyour.X1.141)=-4.2893 IN THE ROOT SIMULATION FILE.
    *        ("Xyour" IS THE DEVICE NAME CALLED OUT IN THE ROOT FILE.)
    *
    * CONNECTIONS:       INVERTING INPUT
    *                    | NON-INVERTING INPUT
    *                    | | NEGATIVE POWER SUPPLY
    *                    | | | OUTPUT
    *                    | | | | POSITIVE POWER SUPPLY
    *                    | | | | |
    .SUBCKT OPA623X1/BB  2 3 4 6 7
    *
    X1  4 7 131 141              BC/OPA623X1 ; Biasing Circuit BC
    X2  2 3 4 7 111 121 131 141  DT/OPA623X1 ; Diamond Transistor DT
    X3  4 6 7 111 121            CB/OPA623X1 ; Current-Buffer CB
    *
    C202    2  0   2E-12
    C206    6  0   2E-12
    *
    .ENDS
    *
    *Diamond Transistor DT
    .SUBCKT DT/OPA623X1 2 3 4 7 111 121 131 141
    *
    R23  23 3  40
    C21  21 0  0.02E-12
    C22  22 0  0.02E-12
    C23  23 0  2E-12
    C27  27 0  14E-12
    C28  28 0  14E-12
    C35  35 0  3.1E-12
    Q21  21  131  7  7  PI/OPA623X1
    Q22  22  141  4  4  NI/OPA623X1
    Q23   4  23  21  7  PI/OPA623X1
    Q24   7  23  22  4  NI/OPA623X1
    Q25  27  21   2  4  NI/OPA623X1 6
    Q26  28  22   2  7  PI/OPA623X1 6
    Q27  27  27   7  7  PIM/OPA623X1
    Q28  28  28   4  4  NIM/OPA623X1
    Q29  111 27   7  7  PIM/OPA623X1
    Q30  121 28   4  4  NIM/OPA623X1
    Q31  111 111 33  4  NI/OPA623X1
    Q32  121 121 34  7  PI/OPA623X1
    Q33  33  33  35  4  NI/OPA623X1
    Q34  34  34  35  7  PI/OPA623X1
    *
    .ENDS
    *
    *Current Buffer CB
    .SUBCKT CB/OPA623X1 4 6 7 111 121
    *
    Q35   7 111 37  4  NI/OPA623X1
    Q36   4 121 38  7  PI/OPA623X1
    Q37  37 37  39  4  NI/OPA623X1
    Q38  38 38  39  7  PI/OPA623X1
    Q39   7 37   6  4  NI/OPA623X1 2.2
    Q40   4 38   6  7  PI/OPA623X1 2.2
    *
    .ENDS
    *
    *Biasing Circuit BC
    .SUBCKT BC/OPA623X1 4 7 131 141
    *
    RQC  122 4  630 ; 745
    Q121  131 131   7 7  PI/OPA623X1
    Q122  131 141 122 4  NI/OPA623X1 10
    Q123  141 131   7 7  PI/OPA623X1
    Q124  141 141   4 4  NI/OPA623X1
    *
    .ENDS
    *
    .MODEL NI/OPA623X1 NPN
    .MODEL PI/OPA623X1 PNP
    .MODEL PIM/OPA623X1 PNP (VAF=18)
    .MODEL NIM/OPA623X1 NPN (VAF=18)
    *$
    **************************************************************************
    * OPA623X2 WIDE BANDWIDTH, CURRENT FEEDBACK, MACROMODEL, COMPLEX VERSION
    * CREATED 8/92 KL
    * REV.B 7/9/93 BCB: CLARIFICATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : FOR QUICKER CONVERSIONS INCLUDE THE NODESET 
    *        V(Xyour.X1.121)=+4.2990 AND 
    *        V(Xyour.X1.124)=-4.2995 IN THE ROOT SIMULATION FILE.
    *        ("Xyour" IS THE DEVICE NAME USED IN THE ROOT FILE.)
    *
    * CONNECTIONS:       INVERTING INPUT
    *                    | NON-INVERTING INPUT
    *                    | | NEGATIVE POWER SUPPLY
    *                    | | | VOLTAGE OUTPUT
    *                    | | | | POSITIVE POWER SUPPLY
    *                    | | | | |
    .SUBCKT OPA623X2/BB  2 3 4 6 7
    *
    X1  4 7 131 141              BC/OPA623X2 ; Biasing Circuit BC
    X2  2 3 4 7 111 123 131 141  DT/OPA623X2 ; Diamond Transistor DT
    X3  4 6 7 111 123            CB/OPA623X2 ; Current-Buffer CB
    *
    C202    2  0   2E-12
    C203    3  0   2E-12
    C206    6  0   2E-12
    *
    .ENDS
    *
    *Diamond Transistor DT
    .SUBCKT DT/OPA623X2 2 3 4 7 111 123 131 141
    *
    C39  39 0   0.6E-12
    Q21  24 131  7  7  PI/OPA623X2
    Q22  23 141  4  4  NI/OPA623X2
    Q23  23 23   7  7  PIJ/OPA623X2 10
    Q24  24 24   4  4  NIJ/OPA623X2 10
    Q25  29 23   7  7  PIJ/OPA623X2 10
    Q26  30 24   4  4  NIJ/OPA623X2 10
    Q27  24  3  29  7  PIJ/OPA623X2
    Q28  23  3  30  4  NIJ/OPA623X2
    Q29  29 29  28  4  NIJ/OPA623X2
    Q30  30 30  28  7  PIJ/OPA623X2
    Q31  33 29   2  4  NIJ/OPA623X2 6
    Q32  34 30   2  7  PIJ/OPA623X2 6
    Q33  33 33   7  7  PIJ/OPA623X2 10
    Q34  34 34   4  4  NIJ/OPA623X2 10
    Q35  111 33  7  7  PIJ/OPA623X2 10
    Q36  123 34  4  4  NIJ/OPA623X2 10
    Q37  111 37 39  4  NIJ/OPA623X2 5
    Q38  39 38 123  4  NIJ/OPA623X2 5
    Q39  39 37 111  7  PIJ/OPA623X2 5
    Q40  123 38 39  7  PIJ/OPA623X2 5
    *
    .ENDS
    *
    *Current Buffer CB
    .SUBCKT CB/OPA623X2 4 6 7 111 123
    *
    Q43   7 111 45  4  NIJ/OPA623X2 4
    Q44   4 123 46  7  PIJ/OPA623X2 4
    Q45  45 45  47  4  NIJ/OPA623X2 12
    Q46  46 46  47  7  PIJ/OPA623X2 12
    Q47   7 45   6  4  NIJ/OPA623X2 48
    Q48   4 46   6  7  PIJ/OPA623X2 48
    *
    .ENDS
    *
    *Biasing Circuit BC
    .SUBCKT BC/OPA623X2 4 7 131 141
    *
    E13  131 0  121 0  1
    E14  141 0  124 0  1
    * I121  121 124  0.1E-6
    RQC   122  4  745
    C121  121  7  10E-12
    C124  124  4  10E-12
    Q121  121 121   7  7  PI/OPA623X2
    Q122  121 124 122  4  NI/OPA623X2 6
    Q123  124 121   7  7  PI/OPA623X2
    Q124  124 124   4  4  NI/OPA623X2
    Q125    4 131   7  7  PI/OPA623X2 11
    *
    .ENDS
    *
    .MODEL PI/OPA623X2 PNP
    .MODEL NI/OPA623X2 NPN
    .MODEL PIJ/OPA623X2 PNP (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *
    .MODEL NIJ/OPA623X2 NPN (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *$
    **************************************************************************
    * OPA627 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/12/90 AT 07:59
    * REV.B  5/22/91 TK
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA627/BB   1 2 3 4 5
    *
    C1   11 12 3.182E-12
    C2    6  7 23.00E-12
    CSS  10 99 40.45E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 419.4E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 2.432E-3
    GCM   0  6 10 99 3.779E-9
    ISS   3 10 DC 1.840E-3
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 419.4
    RD2   4 12 419.4
    RO1   8  5 54
    RO2   7 99 1
    RP    3  4 4.286E3
    RSS  10 99 108.7E3
    VB    9  0 DC 0
    VC    3 53 DC 2.700
    VE   54  4 DC 2.700
    VLIM  7  8 DC 0
    VLP  91  0 DC 55
    VLN   0 92 DC 55
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=1.545E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA627E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/04/90 AT 09:30
    * REV.B  5/22/91 TK
    * REV.C  3/21/92 BCB:added input bias current correction and
    *                    current and voltage noise
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA627E/BB  1 2 3 4 5
    *
    C1   11 12 3.182E-12
    C2    6  7 23.00E-12
    CSS  10 99 40.45E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 419.4E6 -40E6 40E6 40E6 -40E6
    GA    6  0 11 12 2.432E-3
    GCM   0  6 10 99 3.779E-9
    ISS   3 10 DC 1.840E-3
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 1.6E-6
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 1.6E-6
    R2    6  9 100.0E3
    RD1   4 11 419.4
    RD2   4 12 419.4
    RO1   8  5 54
    RO2   7 99 1
    *  RP    3  4 4.286E3
    RSS  10 99 108.7E3
    VB    9  0 DC 0
    VC    3 53 DC 2.700
    VE   54  4 DC 2.700
    VLIM  7  8 DC 0
    VLP  91  0 DC 55
    VLN   0 92 DC 55
    ****************************
    * OPA627 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  4.76E-3  1
    FQ2   0  4 POLY(1) VQ2  4.76E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  7.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  8.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 7.0E-12
    C2CM  2  99 7.0E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=1E-12 AF=1 KF=71.89E-15)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=1.545E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA628M OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "M" IS  MULTIPLE POLE/ZERO TOPOLOGY
    * CREATED 7/16/93 BCB
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   |  INVERTING INPUT
    *                   |  |  POSITIVE POWER SUPPLY
    *                   |  |  |  NEGATIVE POWER SUPPLY
    *                   |  |  |  |  OUTPUT
    *                   |  |  |  |  |
    .SUBCKT  OPA628M/BB 3  2  7  4  6
    *
    * INPUT STAGE (pole @ 220M Hz)
    Q1   13   2  15  N
    Q2   14  11  16  N
    R3    7  13  47.75
    R4    7  14  47.75
    C1   13  14  6E-12
    R5   15  12  42.55
    R6   16  12  42.55
    IEE  12   4  5.5E-3
    EOS  11   3  POLY(1)  (33,9)  500E-6  1
    R1    2  10  16E3
    R2    3  10  16E3
    CIN   2   3  2E-12
    IOS   2   3  0.3E-6
    * GAIN STAGE (pole @ 2K Hz)
    V21   7  21  2.736
    D21  23  21  DX
    V22  22   4  2.736
    D22  22  23  DX
    G21   7  23  POLY(1)  (13,14)   26.706E-3 20.94E-3
    G22   4  23  POLY(1)  (13,14)  -26.706E-3 20.94E-3
    R27   7  23  4.77E6
    R28   4  23  4.77E6
    C22   7  23  16.68E-12
    C23   4  23  16.68E-12
    * COMMON-MODE REJECTION STAGE (zero @ 300K Hz)
    R31  31  33  1E6
    R32  32  33  1E6
    G31   7  33  10  9  3.1623E-12
    G32   4  33  10  9  3.1623E-12
    L31  31   7  530.5E-3
    L32  32   4  530.5E-3
    * OUTPUT STAGE
    D3   23  71  DX
    D4   72  23  DX
    D5    7  73  DX
    D6    7  74  DX
    D7    4  73  DZ
    D8    4  74  DZ
    G14  73   4   6  23  1000
    G13  74   4  23   6  1000
    V3   71   6  -.9125
    V4    6  72  -.9125
    G11   6   7   7  23  1000
    G12   4   6  23   4  1000
    R23   7   6  0.001
    R24   4   6  0.001
    * CENTER OF SUPPLIES
    R9    7   9  16.359E3
    R10   4   9  16.359E3
    *
    .MODEL  DX  D(IS=1E-15)
    .MODEL  N  NPN(BF=183)
    .MODEL  DZ  D(IS=1E-15 BV=50)
    .ENDS
    *$
    **************************************************************************
    * OPA637 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/04/90 AT 11:11
    * REV.B   5/22/91 TK
    * REV.C    1/8/93 Changed nodes on J2 BCB
    *   
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA637/BB   1 2 3 4 5
    *
    C1   11 12 8.221E-12
    C2    6  7 3.600E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 552.6E6 -20E6 20E6 20E6 -20E6
    GA    6  0 11 12 1.810E-3
    GCM   0  6 10 99 2.868E-9
    ISS   3 10 DC 486.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 552.6
    RD2   4 12 552.6
    RO1   8  5 54
    RO2   7 99 1
    RP    3  4 4.286E3
    RSS  10 99 411.5E3
    VB    9  0 DC 0
    VC    3 53 DC 2.700
    VE   54  4 DC 2.700
    VLIM  7  8 DC 0
    VLP  91  0 DC 55
    VLN   0 92 DC 55
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=3.37E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA637E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 10/04/90 AT 11:11
    * REV.B  5/22/91 TK
    * REV.C  3/21/92 BCB added input bias current correction and
    *                     current and voltage noise
    * REV.D  2/05/93 BCB Changed parameters of FB
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA637E/BB  1 2 3 4 5
    *
    C1   11 12 8.221E-12
    C2    6  7 3.600E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 552.6E6 -60E6 60E6 60E6 -60E6
    GA    6  0 11 12 1.810E-3
    GCM   0  6 10 99 2.868E-9
    ISS   3 10 DC 486.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12 64 10 JX
    G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 1.6E-6
    G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 1.6E-6
    R2    6  9 100.0E3
    RD1   4 11 552.6
    RD2   4 12 552.6
    RO1   8  5 54
    RO2   7 99 1
    *  RP    3  4 4.286E3
    RSS  10 99 411.5E3
    VB    9  0 DC 0
    VC    3 53 DC 2.700
    VE   54  4 DC 2.700
    VLIM  7  8 DC 0
    VLP  91  0 DC 55
    VLN   0 92 DC 55
    ****************************
    * OPA637 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  5.38E-3  1
    FQ2   0  4 POLY(1) VQ2  5.38E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  7.5E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  8.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 7.0E-12
    C2CM  2  99 7.0E-12
    * INPUT VOLTAGE NOISE
    VN1 61   0  0.6
    VN2  0  62  0.6
    DN1 61  63  DY
    DN2 63  62  DY
    EN  64   1  63 0 1
    * INPUT CURRENT NOISE
    RN1  0 65 60.3865
    RN2 65 66 60.3865
    RN3 66  0 120.773
    RN4  0 67 60.3865
    RN5 67 68 60.3865
    RN6 68  0 120.773
    *
    .MODEL DY D(IS=1E-15 AF=1 KF=73.4E-18)
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=3.37E-3 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPA640X - WIDEBAND VOLTAGE FEEDBACK OPERATIONAL AMPLIFIER MACROMODEL
    * CREATED 11/21/93     DS
    * REV.A
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : SUGGESTED TEST CIRCUIT
    *          X1       83  84  81  81  82  80  80  OPA640X/BB
    *          VCC      80  0   DC 5V
    *          VEE      0   81  DC 5V
    *          CFB      83  82  .15E-12
    *          RFB      86  82  25
    *          LFB      83  86  2.2E-9
    *          VIN      85  0   AC 1 DC 0 PWL ( 0N -1 1N 1 20N 1 21N -1 )
    *          RSOURCE  85  84  25
    *          RL       82  0   100
    *          CL       82  0   2E-12
    *
    * CONNECTIONS:      INVERTING INPUT
    *                   |   NON-INVERTING INPUT
    *                   |   |   NEGATIVE POWER SUPPLY
    *                   |   |   |   NEGATIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   OUTPUT
    *                   |   |   |   |   |   POSITIVE POWER SUPPLY
    *                   |   |   |   |   |   |   POSITIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   |   |   |
    .SUBCKT OPA640X/BB 13  14  11   9  12  10   8
    *
    Q34      41  43  4   2 NPN1 10
    Q33      41  42  1   1 PNP1 10
    Q32      43  43  4   2 NPN1 20
    Q31      43  40  41  1 PNP1 36
    Q30      42  37  41  2 NPN1 36
    Q29      42  42  1   1 PNP1 20
    Q28      40  39  38  2 NPN1 2
    Q15      29  30  31  2 NPN1 4
    Q27      1   33  40  2 NPN1 24
    Q26      4   33  37  1 PNP1 24
    Q25      37  36  35  1 PNP1 2
    Q24      39  38  4   2 NPN1 1
    Q23      36  35  1   1 PNP1 1
    Q14      28  26  17  3 PNP1 4
    Q7       24  24  25  2 NPN1 1
    Q18      15  26  16  3 PNP1 4
    Q21      21  15  33  2 NPN1 2
    Q22      33  24  34  2 NPN1 2
    Q20      30  30  32  2 NPN1 4
    Q19      15  29  30  2 NPN1 4
    Q1       17  7   18  2 NPN1 12
    Q10      26  26  44  3 PNP1 1
    Q3       20  24  23  2 NPN1 8
    Q2       16  6   19  2 NPN1 12
    Q6       27  26  45  3 PNP1 1
    Q11      22  27  26  3 PNP1 1
    R3       18  20  60
    R5       19  20  60
    C2       21  22  20E-12
    C3       1   4   28E-12
    R11      21  44  2E3
    R8       21  45  2E3
    R12      21  17  250
    R22      2   4   20
    R2       2   22  20
    R4       23  22  125
    ISOUR    27  24  450E-6
    V1       28  29  3.26
    R13      31  22  80
    R15      32  22  80
    C8       30  22  1.0E-12
    C6       15  22  4.6E-12
    R16      34  22  320
    R14      21  16  250
    R9       25  22  1E3
    R18      1   35  450
    R19      38  4   450
    R20      41  5   10
    R21      1   3   20
    R1       3   21  20
    I1       36  39  500E-6
    *
    * PACKAGE PARASITICS
    CINV     13  0   0.75E-12
    L10P     66  68  1.5E-9
    L6P      63  64  1.08E-9
    L2P      60  61  1.08E-9
    C1P      15  2   .15E-12
    C30P     77  2   .0425E-12
    C29P     5   2   .15E-12
    C2P      6   2   .15E-12
    L5P      65  7   .7E-9
    C3P      61  2   .0425E-12
    C4P      61  64  .05E-12
    C8P      7   2   .15E-12
    C9P      64  2   .0425E-12
    C10P     64  68  .05E-12
    C14P     2   2   .15E-12
    C15P     68  2   .0125E-12
    C16P     1   2   .15E-12
    C17P     71  2   .0125E-12
    C18P     71  74  .05E-12
    C22P     3   2   .15E-12
    C23P     74  2   .0425E-12
    C24P     74  77  .05E-12
    C31P     77  80  .05E-12
    C35P     4   2   .15E-12
    C36P     80  2   .0125E-12
    L1P      62  6   .7E-9
    L9P      69  2   .7E-9
    L14P     70  1   .7E-9
    L15P     72  71  1.5E-9
    L18P     73  3   .7E-9
    L19P     75  74  1.08E-9
    L22P     76  5   .7E-9
    L23P     78  77  1.08E-9
    L27P     79  4   .7E-9
    L28P     81  80  1.5E-9
    L31P     82  2   .7E-9
    L13P     2   67  .7E-9
    R1P      61  62  .01
    R2P      13  60  .1
    R6P      64  65  .01
    R7P      14  63  .1
    R11P     68  69  .01
    R12P     11  66  .1
    R16P     67  68  .01
    R17P     71  70  .01
    R18P     8   72  .1
    R22P     74  73  .01
    R23P     10  75  .1
    R27P     77  76  .01
    R28P     12  78  .1
    R33P     80  79  .01
    R34P     9   81  .1
    R38P     80  82  .01
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *$
    **************************************************************************
    * OPA641X - WIDEBAND VOLTAGE FEEDBACK OPERATIONAL AMPLIFIER MACROMODEL
    *CREATED  7/11/94  DY
    * REV. A
    *
    * CONNECTIONS:       INVERTING INPUT
    *                    |   NON-INVERTING INPUT
    *                    |   |   NEGATIVE POWER SUPPLY
    *                    |   |   |   NEGATIVE OUTPUT POWER SUPPLY
    *                    |   |   |   |   OUTPUT
    *                    |   |   |   |   |   POSITIVE POWER SUPPLY
    *                    |   |   |   |   |   |   POSITIVE OUTPUT POWER SUPPLY
    *                    |   |   |   |   |   |   |
    .SUBCKT OPA641X/BB  13  14  11   9  12  10   8
    *
    Q34      41  43  4   2 NPN1 10
    Q33      41  42  1   1 PNP1 10
    Q32      43  43  4   2 NPN1 20
    Q31      43  40  41  1 PNP1 36
    Q30      42  37  41  2 NPN1 36
    Q29      42  42  1   1 PNP1 20
    Q28      40  39  38  2 NPN1 2
    Q15      29  30  31  2 NPN1 4
    Q27      1   33  40  2 NPN1 24
    Q26      4   33  37  1 PNP1 24
    Q25      37  36  35  1 PNP1 2
    Q24      39  38  4   2 NPN1 1
    Q23      36  35  1   1 PNP1 1
    Q14      28  26  17  3 PNP1 4
    Q7       24  24  25  2 NPN1 1
    Q18      15  26  16  3 PNP1 4
    Q21      21  15  33  2 NPN1 2
    Q22      33  24  34  2 NPN1 2
    Q20      30  30  32  2 NPN1 4
    Q19      15  29  30  2 NPN1 4
    Q1       17  7   18  2 NPN1 12
    Q10      26  26  44  3 PNP1 1
    Q3       20  24  23  2 NPN1 8
    Q2       16  6   19  2 NPN1 12
    Q6       27  26  45  3 PNP1 1
    Q11      22  27  26  3 PNP1 1
    R3       18  20  60
    R5       19  20  60
    C2       21  22  20E-12
    C3       1   4   28E-12
    R11      21  44  2K
    R8       21  45  2K
    R12      21  17  250
    R22      2   4   20
    R2       2   22  20
    R4       23  22  125
    ISOUR    27  24  DC 450E-6
    V1       28  29  DC 3.2
    R13      31  22  80
    R15      32  22  80
    C8       30  22  0.6E-12
    C6       15  22  2.3E-12
    R16      34  22  320
    R14      21  16  250
    R9       25  22  1K
    R18      1   35  500
    R19      38  4   500
    R20      41  5   10
    R21      1   3   20
    R1       3   21  20
    I1       36  39  DC 500E-6
    C4       6   5   2.0E-12
    * PACKAGE PARASITICS
    CINV     13  0   0.75E-12
    L10P     56  58  1.5E-9
    L6P      53  54  1.08E-9
    L2P      50  51  1.08E-9
    C1P      15  2   .15E-12
    C30P     67  2   .0425E-12
    C29P     5   2   .15E-12
    C2P      6   2   .15E-12
    L5P      55  7   .7E-9
    C3P      51  2   .0425E-12
    C4P      51  54  .05E-12
    C8P      7   2   .15E-12
    C9P      54  2   .0425E-12
    C10P     54  58  .05E-12
    C14P     2   2   .15E-12
    C15P     58  2   .0125E-12
    C16P     1   2   .15E-12
    C17P     61  2   .0125E-12
    C18P     61  64  .05E-12
    C22P     3   2   .15E-12
    C23P     64  2   .0425E-12
    C24P     64  67  .05E-12
    C31P     67  70  .05E-12
    C35P     4   2   .15E-12
    C36P     70  2   .0125E-12
    L1P      52  6   .7E-9
    L9P      59  2   .7E-9
    L14P     60  1   .7E-9
    L15P     62  61  1.5E-9
    L18P     63  3   .7E-9
    L19P     65  64  1.08E-9
    L22P     66  5   .7E-9
    L23P     68  67  1.08E-9
    L27P     69  4   .7E-9
    L28P     71  70  1.5E-9
    L31P     72  2   .7E-9
    L13P     2   57  .7E-9
    R1P      51  52  .01
    R2P      13  50  .1
    R6P      54  55  .01
    R7P      14  53  .1
    R11P     58  59  .01
    R12P     11  56  .1
    R16P     57  58  .01
    R17P     61  60  .01
    R18P     8   62  .1
    R22P     64  63  .01
    R23P     10  65  .1
    R27P     67  66  .01
    R28P     12  68  .1
    R33P     70  69  .01
    R34P     9   71  .1
    R38P     70  72  .01
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS 
    *
    ****************** OPA641X TEST CIRCUIT ******************
    *
    *X1       83  84  81  81  82  80  80  OPA641X/BB
    *VCC      80  0   DC 5V
    *VEE      0   81  DC 5V
    *CFB      83  82  .15E-12
    *RFB      86  82  400
    *LFB      83  86  2.2E-9
    *RFF      83  87  400
    *LFF      87  0   2.2E-9
    *CFF      83  0   .15E-12
    *VIN      85  0   PWL ( 0N -1 1N 1 49N 1 50N -1 )
    *RSOURCE  85  84  25
    *RL       82  0   100
    *CL       82  0   5E-12
    *.ENDS
    *$
    **************************************************************************
    * OPA642X - WIDEBAND LOW DISTORTION OPERATIONAL AMPLIFIER MACROMODEL
    * CREATED 11/21/93  DS
    * REV. A
    *
    * NOTE : SUGGESTED TEST CIRCUIT
    *          X1       93  94  91  91  92  90  90  OPA642/BB
    *          VCC      90  0   5V
    *          VEE      0   91  5V
    *          RL       92  0   100
    *          CL       92  0   5E-12
    *          VIN      96  0   AC 1 DC 0 PWL ( 0NS -1 1N 1 20N 1 21N -1 )
    *          RSOURCE  96  94  20
    *          RFB      95  92  20
    *          LFB      93  95  2.2E-9
    *          CFB      93  92  .19E-12
    * 
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:      INVERTING INPUT
    *                   |   NON-INVERTING INPUT
    *                   |   |   NEGATIVE POWER SUPPLY
    *                   |   |   |   NEGATIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   OUTPUT
    *                   |   |   |   |   |   POSITIVE POWER SUPPLY
    *                   |   |   |   |   |   |   POSITIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   |   |   |
    .SUBCKT OPA642X/BB 13  14  11   9  12  10   8
    *
    Q1       16  35  40  3 PNP1 4
    Q3       17  35  41  3 PNP1 4
    Q34      54  51  53  1 PNP1 36
    Q30      1   15  51  2 NPN1 20
    Q14      34  27  30  3 PNP1 1
    Q15      22  17  34  3 PNP1 2
    Q17      42  34  37  3 PNP1 4
    Q21      15  36  38  3 PNP1 4
    Q25      22  16  36  3 PNP1 2
    Q19      42  43  44  2 NPN1 4
    Q16      37  27  31  3 PNP1 3
    Q20      38  27  32  3 PNP1 3
    Q23      43  43  45  2 NPN1 4
    Q22      15  42  43  2 NPN1 4
    Q32      52  52  1   1 PNP1 20
    Q26      47  46  1   1 PNP1 1
    Q28      50  47  46  1 PNP1 2
    Q24      36  27  33  3 PNP1 1
    Q31      51  48  49  2 NPN1 2
    Q27      48  49  4   2 NPN1 1
    Q29      4   15  50  1 PNP1 20
    Q36      53  52  1   1 PNP1 20
    Q37      53  54  4   2 NPN1 20
    Q9       24  25  23  3 PNP1 2
    Q13      23  26  27  3 PNP1 1
    Q35      54  54  4   2 NPN1 20
    Q5       20  23  24  2 NPN1 8
    Q4       17  6   19  2 NPN1 12
    Q2       16  7   18  2 NPN1 12
    Q33      52  50  53  2 NPN1 36
    Q8       26  27  29  3 PNP1 1
    Q12      27  27  28  3 PNP1 1
    R26      1   3   20
    R24      3   21  20
    R1       21  40  250
    R4       21  41  250
    R2       18  20  75
    R5       19  20  75
    R27      2   4   20
    R25      2   22  20
    R3       24  22  125
    C2       21  22  18E-12
    C3       1   4   18E-12
    R23      53  5   5
    ISOUR    26  25  500E-6
    R11      21  28  500
    R8       21  29  500
    R9       25  22  1250
    R12      21  30  500
    R13      21  31  166
    R17      21  32  166
    R15      37  35  160
    R16      35  38  160
    R19      21  33  500
    R14      44  22  320
    R18      45  22  320
    C8       43  22  0.5E-12
    C6       15  22  0.56E-12
    R21      1   46  400
    C7       16  5   11E-12
    R22      49  4   400
    C1       17  22  11E-12
    I1       47  48  500E-6
    CA4      5   2   8.8E-12
    CA1      22  2   8.8E-12
    CA2      22  2   14.4E-12
    CA3      4   2   14.4E-12
    * PACKAGE PARASITICS
    CINV     13  0   0.75E-12
    L10P     66  68  1.5E-9
    L6P      63  64  1.08E-9
    L2P      60  61  1.08E-9
    C1P      15  2   .15E-12
    C30P     77  2   .0425E-12
    C29P     5   2   .15E-12
    C2P      6   2   .15E-12
    L5P      65  7   .7E-9
    C3P      61  2   .0425E-12
    C4P      61  64  .05E-12
    C8P      7   2   .15E-12
    C9P      64  2   .0425E-12
    C10P     64  68  .05E-12
    C14P     2   2   .15E-12
    C15P     68  2   .0125E-12
    C16P     1   2   .15E-12
    C17P     71  2   .0125E-12
    C18P     71  74  .05E-12
    C22P     3   2   .15E-12
    C23P     74  2   .0425E-12
    C24P     74  77  .05E-12
    C31P     77  80  .05E-12
    C35P     4   2   .15E-12
    C36P     80  2   .0125E-12
    L1P      62  6   .7E-9
    L9P      69  2   .7E-9
    L14P     70  1   .7E-9
    L15P     72  71  1.5E-9
    L18P     73  3   .7E-9
    L19P     75  74  1.08E-9
    L22P     76  5   .7E-9
    L23P     78  77  1.08E-9
    L27P     79  4   .7E-9
    L28P     81  80  1.5E-9
    L31P     82  2   .7E-9
    L13P     2   67  .7E-9
    R1P      61  62  .01
    R2P      13  60  .1
    R6P      64  65  .01
    R7P      14  63  .1
    R11P     68  69  .01
    R12P     11  66  .1
    R16P     67  68  .01
    R17P     71  70  .01
    R21P     8   72  .1
    R22P     74  73  .01
    R26P     10  75  .1
    R27P     77  76  .01
    R31P     12  78  .1
    R33P     80  79  .01
    R37P     9   81  .1
    R38P     80  82  .01
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *$
    **************************************************************************
    * OPA643X -  WIDEBAND LOW DISTORTION OPERATIONAL AMPLIFIER MACROMODEL
    * CREATED 11/21/93 DS
    * REV.A
    *
    * NOTE : SUGGESTED TEST CIRCUIT
    *            X1       93  94  91  91  92  90  90  OPA643/BB
    *            VCC      90  0   5V
    *            VEE      0   91  5V
    *            RL       92  0   100
    *            CL       92  0   5E-12
    *            VIN      96  0   AC 1 DC 0 PWL ( 0NS -0.2 1N 0.2 20N 0.2 21N -0.2 )
    *            RSOURCE  96  94  20
    *            RFB      95  92  400
    *            LFB      93  95  2.2E-9
    *            CFB      93  92  .19E-12
    *            RFF      93  97  100
    *            LFF      97  0   2.2E-9
    *            CFF      93  0   .19E-12
    *            .END
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:      INVERTING INPUT
    *                   |   NON-INVERTING INPUT
    *                   |   |   NEGATIVE POWER SUPPLY
    *                   |   |   |   NEGATIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   OUTPUT
    *                   |   |   |   |   |   POSITIVE POWER SUPPLY
    *                   |   |   |   |   |   |   POSITIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   |   |   |
    .SUBCKT OPA643X/BB 13  14  11   9  12  10   8
    *
    Q1       16  35  40  3 PNP1 4
    Q3       17  35  41  3 PNP1 4
    Q34      54  51  53  1 PNP1 36
    Q30      1   15  51  2 NPN1 20
    Q14      34  27  30  3 PNP1 1
    Q15      22  17  34  3 PNP1 2
    Q17      42  34  37  3 PNP1 4
    Q21      15  36  38  3 PNP1 4
    Q25      22  16  36  3 PNP1 2
    Q19      42  43  44  2 NPN1 4
    Q16      37  27  31  3 PNP1 3
    Q20      38  27  32  3 PNP1 3
    Q23      43  43  45  2 NPN1 4
    Q22      15  42  43  2 NPN1 4
    Q32      52  52  1   1 PNP1 20
    Q26      47  46  1   1 PNP1 1
    Q28      50  47  46  1 PNP1 2
    Q24      36  27  33  3 PNP1 1
    Q31      51  48  49  2 NPN1 2
    Q27      48  49  4   2 NPN1 1
    Q29      4   15  50  1 PNP1 20
    Q36      53  52  1   1 PNP1 20
    Q37      53  54  4   2 NPN1 20
    Q9       24  25  23  3 PNP1 2
    Q13      23  26  27  3 PNP1 1
    Q35      54  54  4   2 NPN1 20
    Q5       20  23  24  2 NPN1 8
    Q4       17  6   19  2 NPN1 12
    Q2       16  7   18  2 NPN1 12
    Q33      52  50  53  2 NPN1 36
    Q8       26  27  29  3 PNP1 1
    Q12      27  27  28  3 PNP1 1
    R26      1   3   20
    R24      3   21  20
    R1       21  40  250
    R4       21  41  250
    R2       18  20  45
    R5       19  20  45
    R27      2   4   20
    R25      2   22  20
    R3       24  22  125
    C2       21  22  20E-12
    C3       1   4   20E-12
    R23      53  5   5
    ISOUR    26  25  500E-6
    R11      21  28  500
    R8       21  29  500
    R9       25  22  1250
    R12      21  30  500
    R13      21  31  166
    R17      21  32  166
    R15      37  35  160
    R16      35  38  160
    R19      21  33  500
    R14      44  22  320
    R18      45  22  320
    C8       43  22  0.75E-12
    C6       15  22  0.55E-12
    R21      1   46  400
    C7       16  5   3.5E-12
    R22      49  4   400
    C1       17  22  3.5E-12
    I1       47  48  500E-6
    CA4      5   2   2.8E-12
    CA1      22  2   2.8E-12
    CA2      22  2   16E-12
    CA3      4   2   16E-12
    * PACKAGE PARASITICS
    CINV     13  0   0.75E-12
    L10P     66  68  1.5E-9
    L6P      63  64  1.08E-9
    L2P      60  61  1.08E-9
    C1P      15  2   .15E-12
    C30P     77  2   .0425E-12
    C29P     5   2   .15E-12
    C2P      6   2   .15E-12
    L5P      65  7   .7E-9
    C3P      61  2   .0425E-12
    C4P      61  64  .05E-12
    C8P      7   2   .15E-12
    C9P      64  2   .0425E-12
    C10P     64  68  .05E-12
    C14P     2   2   .15E-12
    C15P     68  2   .0125E-12
    C16P     1   2   .15E-12
    C17P     71  2   .0125E-12
    C18P     71  74  .05E-12
    C22P     3   2   .15E-12
    C23P     74  2   .0425E-12
    C24P     74  77  .05E-12
    C31P     77  80  .05E-12
    C35P     4   2   .15E-12
    C36P     80  2   .0125E-12
    L1P      62  6   .7E-9
    L9P      69  2   .7E-9
    L14P     70  1   .7E-9
    L15P     72  71  1.5E-9
    L18P     73  3   .7E-9
    L19P     75  74  1.08E-9
    L22P     76  5   .7E-9
    L23P     78  77  1.08E-9
    L27P     79  4   .7E-9
    L28P     81  80  1.5E-9
    L31P     82  2   .7E-9
    L13P     2   67  .7E-9
    R1P      61  62  .01
    R2P      13  60  .1
    R6P      64  65  .01
    R7P      14  63  .1
    R11P     68  69  .01
    R12P     11  66  .1
    R16P     67  68  .01
    R17P     71  70  .01
    R21P     8   72  .1
    R22P     74  73  .01
    R26P     10  75  .1
    R27P     77  76  .01
    R31P     12  78  .1
    R33P     80  79  .01
    R37P     9   81  .1
    R38P     80  82  .01
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *$
    **************************************************************************
    * OPA644X - LOW DISTORTION CURRENT FEEDBACK OPERATIONAL AMPLIFIER MACROMODEL
    * CREATED 12/21/93 DS
    * REV.A
    * 
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : SUGGESTED TEST CIRCUIT
    *
    *X1       93  94  91  91  92  90  90  OPA644X/BB
    *VEE      0   91  DC 5V
    *VCC      90  0   DC 5V
    *VIN      96  0   PWL ( 0NS -2 1N 2 49N 2 50N -2 )
    *V0       96  0   AC 1 DC 0 SIN ( 0 1 1MEG 0 0 0 )
    *RIN      96  94  50
    *CLOAD    92  0   5E-12
    *RLOAD    92  0   100
    *RFB      95  92  400
    *LFB      93  95  2.2E-9
    *CFB      93  92  .19E-12
    *.END
    *
    * CONNECTIONS:      INVERTING INPUT
    *                   |   NON-INVERTING INPUT
    *                   |   |   NEGATIVE POWER SUPPLY
    *                   |   |   |   NEGATIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   OUTPUT
    *                   |   |   |   |   |   POSITIVE POWER SUPPLY
    *                   |   |   |   |   |   |   POSITIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   |   |   |
    .SUBCKT OPA644X/BB 13  14  11   9  12  10   8
    *
    Q11      29  21  26  3 PNP1 2
    Q14      30  24  28  2 NPN1 2
    Q41      1   48  16  2 NPN2 3
    Q42      4   49  16  1 PNP2 3
    Q6       19  24  27  2 NPN1 2
    Q9       17  19  24  2 NPN1 1
    Q8       18  20  22  3 PNP1 1
    Q44      51  48  52  2 NPN2 36
    Q45      50  49  52  1 PNP2 36
    Q10      18  22  21  3 PNP1 1
    Q38      4   36  48  1 PNP1 20
    Q17      32  30  54  3 PNP1 2
    Q39      1   36  49  2 NPN1 20
    Q12      29  29  7   2 NPN1 2
    Q13      30  30  7   3 PNP1 2
    Q16      31  29  54  2 NPN1 2
    Q43      51  51  1   1 PNP2 20
    Q46      50  50  4   2 NPN2 20
    Q47      52  51  1   1 PNP2 20
    Q48      52  50  4   2 NPN2 20
    Q3       20  21  25  3 PNP1 2
    C2       1   4   20E-12
    C1       17  18  28E-12
    ISOUR    20  19  DC 700E-6
    R34      2   4   20
    R2       2   18  20
    R33      1   3   20
    R1       3   17  20
    R7       27  18  1E3
    R28      24  18  10E3
    R10      28  18  1E3
    R26      52  5   10
    R5       17  25  1E3
    R27      17  21  10E3
    R9       17  26  1E3
    R18      38  39  266
    C8       15  16  2.0E-12
    C3       17  20  1.5E-12
    C4       17  19  1.5E-12
    C12      36  18  0.3E-12
    C1PP     18  2   22.4E-12
    C2PP     4   2   16E-12
    C4PP     19  2   1.2E-12
    C3PP     20  2   1.2E-12
    C8PP     16  2   1.6E-12
    C12PP    18  2   0.24E-12
    F1       17  33  V1 1
    V1       17  31  DC 2.1V
    V2       32  18  DC 2.1V
    F2       33  18  V2 1
    V3       33  59  DC 0
    F3       15  59  V3 1
    IOUT1    1   48  DC 1.8E-3
    IOUT2    49  4   DC 1.8E-3
    RE30     39  59  33.7
    RE29     37  38  2950
    CE29     37  38  0.42E-12
    CU29     37  35  32.32E-15
    G1       35  38  37 38 0.0305
    R029     35  38  39.84E3
    CO29     35  2   6.69E-15
    RB29     15  37  160
    RB33     59  40  6.2E3
    CS33     36  2   0.195E-12
    RO33     36  35  30.67E3
    G2       36  35  34 35 0.0188
    CE33     34  35  0.405E-12
    RE33     34  35  2364
    CU33     34  36  32.5E-15
    RBB33    40  34  120
    RE31     46  59  35.1
    RE32     44  45  1300
    CE32     44  45  0.613E-12
    G3       43  45  44 45 0.0295
    CU32     44  43  37.83E-15
    RO32     43  45  19.12E3
    CO32     43  2   0.15E-12
    RO34     36  43  65.36E3
    CO34     36  2   8.57E-15
    CU34     42  36  27.82E-15
    RE34     42  43  5319
    CE34     42  43  0.279E-12
    G4       36  43  42 43 0.0194
    RB34     59  41  6.2E3
    RB32     15  44  120
    R19      45  46  266
    RBB34    41  42  160
    R20      59  35  500
    R21      59  43  500
    C6       38  59  20E-15
    C7       45  59  20E-15
    R3       1   58  1080
    R4       58  4   1080
    E1       59  4   58 4 1
    R6       6   54  10
    * PACKAGE PARASITICS
    CINV     13  0   0.75E-12
    L10P     66  68  1.5E-9
    L6P      63  64  1.08E-9
    L2P      60  61  1.08E-9
    C1P      15  2   .15E-12
    C30P     77  2   .0425E-12
    C29P     5   2   .15E-12
    C2P      6   2   .15E-12
    L5P      65  7   .7E-9
    C3P      61  2   .0425E-12
    C4P      61  64  .05E-12
    C8P      7   2   .15E-12
    C9P      64  2   .0425E-12
    C10P     64  68  .05E-12
    C14P     2   2   .15E-12
    C15P     68  2   .0125E-12
    C16P     1   2   .15E-12
    C17P     71  2   .0125E-12
    C18P     71  74  .05E-12
    C22P     3   2   .15E-12
    C23P     74  2   .0425E-12
    C24P     74  77  .05E-12
    C31P     77  80  .05E-12
    C35P     4   2   .15E-12
    C36P     80  2   .0125E-12
    L1P      62  6   .7E-9
    L9P      69  2   .7E-9
    L14P     70  1   .7E-9
    L15P     72  71  1.5E-9
    L18P     73  3   .7E-9
    L19P     75  74  1.08E-9
    L22P     76  5   .7E-9
    L23P     78  77  1.08E-9
    L27P     79  4   .7E-9
    L28P     81  80  1.5E-9
    L31P     82  2   .7E-9
    L13P     2   67  .7E-9
    R1P      61  62  .01
    R2P      13  60  .1
    R6P      64  65  .01
    R7P      14  63  .1
    R11P     68  69  .01
    R12P     11  66  .1
    R16P     67  68  .01
    R17P     71  70  .01
    R18P     8   72  .1
    R22P     74  73  .01
    R23P     10  75  .1
    R27P     77  76  .01
    R28P     12  78  .1
    R33P     80  79  .01
    R34P     9   81  .1
    R38P     80  82  .01
    C37P     16  2   .15E-12
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL NPN2 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 1.831E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 1.065E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .MODEL PNP2 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 3.053E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 0.571E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *$
    **************************************************************************
    * OPA646X - LOW POWER, WIDE BANDWIDTH OPERATIONAL AMPLIFIER MACROMODEL
    * CREATED 11/21/93 DS
    * REV.A
    *
    * NOTE : SUGGESTED TEST CIRCUIT
    *            X1       83  84  81  81  82  80  80  OPA646X/BB
    *            VCC      80  0   5V
    *            VEE      0   81  5V
    *            VIN      85  0   AC 1 DC 0 PWL ( 0N -1 1N 1 20N 1 21N -1 )
    *            RSOURCE  85  84  25
    *            RL       82  0   100
    *            CL       82  0   5E-12
    *            CFB      83  82  .15E-12
    *            RFB      86  82  25
    *            LFB      83  86  2.2E-9
    *           .END
    * 
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:      INVERTING INPUT
    *                   |   NON-INVERTING INPUT
    *                   |   |   NEGATIVE POWER SUPPLY
    *                   |   |   |   NEGATIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   OUTPUT
    *                   |   |   |   |   |   POSITIVE POWER SUPPLY
    *                   |   |   |   |   |   |   POSITIVE OUTPUT POWER SUPPLY
    *                   |   |   |   |   |   |   |
    .SUBCKT OPA646X/BB 13  14  11   9  12  10   8
    *
    Q31      1   42  41  1 NPN1 36
    Q32      4   43  41  1 PNP1 36
    Q30      42  40  43  2 NPN1 20
    Q29      4   36  43  1 PNP1 1
    Q28      1   35  42  2 NPN1 1
    Q27      43  40  42  1 PNP1 20
    Q24      36  24  37  2 NPN1 2
    Q15      30  32  31  2 NPN1 1
    Q22      39  15  45  2 NPN1 2
    Q21      38  15  44  1 PNP1 2
    Q19      35  26  34  1 PNP1 2
    Q11      29  26  17  3 PNP1 1
    Q7       24  24  25  2 NPN1 1
    Q16      15  26  16  3 PNP1 1
    Q23      36  36  45  1 PNP1 4
    Q20      35  35  44  2 NPN1 4
    Q25      21  17  39  2 NPN1 2
    Q26      22  30  38  3 PNP1 2
    Q18      32  32  33  2 NPN1 1
    Q17      15  30  32  2 NPN1 1
    Q10      22  27  26  3 PNP1 1
    Q3       20  24  23  2 NPN1 2
    Q2       16  6   19  2 NPN1 4
    Q1       17  7   18  2 NPN1 4
    Q6       27  26  28  3 PNP1 1
    R3       18  20  350
    R5       19  20  350
    R19      2   4   20
    R2       2   22  20
    R4       23  22  500
    R8       21  28  2.2E3
    R11      21  17  1E3
    R13      21  16  1E3
    R17      41  5   10
    R12      31  22  320
    R14      33  22  320
    R16      37  22  400
    R15      21  34  400
    R18      1   3   20
    R1       3   21  20
    C2       21  22  28E-12
    C3       1   4   28E-12
    C6       32  22  0.65E-12
    C7       15  22  0.75E-12
    R9       25  22  1E3
    ISOUR    27  24  200E-6
    V1       29  30  2.352
    * PACKAGE PARASITICS
    CINV     13  0   0.75E-12
    R38P     80  82  .01
    R33P     80  79  .01
    R28P     12  78  .1
    R27P     77  76  .01
    R23P     10  75  .1
    R22P     74  73  .01
    R18P     8   72  .1
    R17P     71  70  .01
    R16P     67  68  .01
    R14P     11  66  .1
    R11P     68  69  .01
    R9P      14  63  .1
    R6P      64  65  .01
    R4P      13  60  .1
    R1P      61  62  .01
    C6P      61  64  .05E-12
    C12P     64  68  .05E-12
    L13P     2   67  .7E-9
    L4P      60  61  1.08E-9
    L8P      63  64  1.08E-9
    L12P     66  68  1.5E-9
    L31P     82  2   .7E-9
    L28P     81  80  1.5E-9
    L27P     79  4   .7E-9
    L23P     78  77  1.08E-9
    L22P     76  5   .7E-9
    L19P     75  74  1.08E-9
    L18P     73  3   .7E-9
    L15P     72  71  1.5E-9
    L14P     70  1   .7E-9
    L9P      69  2   .7E-9
    L1P      62  6   .7E-9
    C36P     80  2   .0125E-12
    C35P     4   2   .15E-12
    C31P     77  80  .05E-12
    C24P     74  77  .05E-12
    C23P     74  2   .0425E-12
    C22P     3   2   .15E-12
    C18P     71  74  .05E-12
    C17P     71  2   .0125E-12
    C16P     1   2   .15E-12
    C15P     68  2   .0125E-12
    C14P     2   2   .15E-12
    C9P      64  2   .0425E-12
    C8P      7   2   .15E-12
    C3P      61  2   .0425E-12
    L5P      65  7   .7E-9
    C2P      6   2   .15E-12
    C29P     5   2   .15E-12
    C30P     77  2   .0425E-12
    C1P      15  2   .15E-12
    R34P     9   81  .1
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *$
    **************************************************************************
    * OPA648X ULTRA WIDE-BAND CURRENT FEEDBACK AMPLIFIER
    * CREATED 8/24/94  DY
    *  REV. A
    *
    * CONNECTIONS:      INVERTING INPUT
    *                   |   NON-INVERTING INPUT
    *                   |   |   NEGATIVE POWER SUPPLY
    *                   |   |   |   OUTPUT
    *                   |   |   |   |   POSITIVE POWER SUPPLY
    *                   |   |   |   |   |   
    .SUBCKT OPA648X/BB  9  10   8  11   7  
    *
    Q14      19  20  21  2 NPN1 2
    Q15      20  20  22  2 NPN1 2
    Q16      23  19  20  2 NPN1 2
    Q2       23  23  4   1 PNP1 2
    Q4       28  23  3   1 PNP1 2
    Q1       18  18  4   2 NPN1 2
    Q3       27  18  3   2 NPN1 2
    Q7       33  27  26  1 PNP1 2
    Q6       26  26  25  1 PNP1 2
    Q5       27  26  24  1 PNP1 2
    Q8       28  31  29  2 NPN1 2
    Q9       31  31  30  2 NPN1 2
    Q10      32  28  31  2 NPN1 2
    Q28      37  36  35  1 PNP1 2
    Q30      40  38  39  2 NPN1 2
    Q42      43  42  13  2 NPN1 36
    Q40      43  41  12  1 PNP1 36
    Q31      13  34  37  1 PNP1 20
    Q32      12  34  40  2 NPN1 20
    Q41      42  42  13  2 NPN1 20
    Q39      41  41  12  1 PNP1 20
    Q33      41  37  43  2 NPN1 20
    Q35      42  40  43  1 PNP1 20
    Q29      38  39  13  2 NPN1 2
    Q27      36  35  12  1 PNP1 2
    Q38      40  42  13  2 NPN1 1
    Q37      37  41  12  1 PNP1 1
    Q22      33  33  6   2 NPN1 4
    Q23      12  33  34  2 NPN1 2
    Q25      13  32  34  1 PNP1 2
    Q24      32  32  6   1 PNP1 4
    Q11      17  16  14  1 PNP1 2
    Q13      18  17  16  1 PNP1 2
    Q12      16  16  15  1 PNP1 2
    ISOUR    17  19  DC 0.7E-3
    R19      2   13  10
    R18      1   12  10
    R5       12  14  1K
    R6       12  15  1K
    R7       21  13  1K
    R8       22  13  1K
    R1       12  24  240
    R2       12  25  240
    R3       29  13  240
    R4       30  13  240
    CCOMP    6   13  0.7E-12
    R24      43  5   10
    I2       36  38  DC 0.5E-3
    R22      12  35  400
    R23      39  13  400
    C3       1   2   56E-12
    * Package Parasitics
    CINV     9   0   0.75E-12
    L6P      61  62  1.5E-9
    L4P      58  59  1.08E-9
    L2P      55  56  1.08E-9
    C1P      6   2   .15E-12
    C14P     68  2   .0425E-12
    C13P     5   2   .15E-12
    C2P      3   2   .15E-12
    L3P      60  4   .7E-9
    C3P      56  2   .0425E-12
    C4P      56  59  .05E-12
    C5P      4   2   .15E-12
    C6P      59  2   .0425E-12
    C7P      59  62  .05E-12
    C8P      2   2   .15E-12
    C9P      62  2   .0125E-12
    C10P     1   2   .15E-12
    C11P     65  2   .0425E-12
    C12P     65  68  .05E-12
    L1P      57  3   .7E-9
    L5P      63  2   .7E-9
    L7P      64  1   .7E-9
    L8P      66  65  1.08E-9
    L9P      67  5   .7E-9
    L10P     69  68  1.08E-9
    L11P     2   70  .7E-9
    R1P      56  57  .01
    R2P      9   55  .1
    R3P      59  60  .01
    R4P      10  58  .1
    R5P      62  63  .01
    R6P      8   61  .1
    R16P     70  62  .01
    R7P      65  64  .01
    R8P      7   66  .1
    R9P      68  67  .01
    R10P     11  69  .1
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS 
    *
    ****************** OPA648X TEST CIRCUIT ******************
    *
    *X1       80  81  84  82  83  OPA648X/BB
    *VCC      83  0   DC 5V
    *VEE      0   84  DC 5V
    *RFB      85  82  250
    *VIN      87  0   PWL ( 0N -1 1N 1 20N 1 21N -1 )
    *vin      87 0 ac 1
    *RL0AD    82  0   100
    *LFB      80  85  2.2E-9
    *CLOAD    82  0   5E-12
    *CFB      80  82  0.15E-12
    *RSOUR    87  81  50
    *RFF      80  86  250
    *CFF      80  0   0.15E-12
    *LFF      86  0   2.2E-9
    *.ENDS
    *$
    **************************************************************************
    * OPA650X  WIDEBAND, LOW POWER VOLTAGE FEEDBACK OP AMP MACROMODEL
    * CREATED  1/12/95   DY
    * REV.A 
    *
    * CONNECTIONS:        INVERTING INPUT
    *                     |   NON-INVERTING INPUT
    *                     |   |   NEGATIVE POWER SUPPLY
    *                     |   |   |   OUTPUT
    *                     |   |   |   |   POSITIVE POWER SUPPLY
    *                     |   |   |   |   |   
    .SUBCKT OPA650X/BB   13  14  11  12  10 
    *
    * Input Stage and Current Source
    Q2       16  6   19  2 NPN1 4
    Q1       17  7   18  2 NPN1 4
    Q3       20  24  23  2 NPN1 2
    R3       18  20  300
    R5       19  20  300
    R4       23  22  500
    ISOUR    27  24  DC 370E-6
    Q6       27  26  28  3 PNP1 1
    Q7       24  24  25  2 NPN1 1
    Q10      2   27  26  3 PNP1 1
    R8       21  28  2K
    R9       25  22  1K
    R2       2   22  20
    R1       3   21  20
    C1       27  24  .6E-12
    * Gain Stage
    Q11      29  26  17  3 PNP1 1
    Q15      30  32  31  2 NPN1 1
    Q16      46  26  16  3 PNP1 1
    Q17      47  30  32  2 NPN1 1
    Q18      32  32  33  2 NPN1 1
    R11      21  17  1K
    R13      21  16  1K
    R12      31  22  320
    R14      33  22  320
    R18      46  47  500
    V1       29  30  DC 2.4
    C2       32  22  0.4E-12
    C4       46  22  1.0E-12
    C3       47  22  0.35E-12
    * Output Stage
    Q19      35  26  34  3 PNP1 2
    Q20      35  35  44  2 NPN1 2
    Q21      38  47  44  3 PNP1 2
    Q22      39  46  45  2 NPN1 2
    Q23      36  36  45  3 PNP1 2
    Q24      36  24  37  2 NPN1 2
    Q25      21  17  39  2 NPN1 2
    Q26      22  31  38  3 PNP1 2
    Q27      43  40  42  3 PNP1 10
    Q28      3   35  42  2 NPN1 2
    Q29      2   36  43  3 PNP1 2
    Q30      42  40  43  2 NPN1 10
    Q31      3   42  41  2 NPN1 48
    Q32      2   43  41  3 PNP1 48
    R17      41  5   10
    R16      37  22  500
    R15      21  34  1K
    * Package Parasitics
    R11P     12  65  .1
    R10P     64  63  .01
    R9P      10  62  .1
    R8P      61  60  .01
    R7P      57  58  .01
    R6P      11  56  .1
    R5P      58  59  .01
    R4P      14  53  .1
    R3P      54  55  .01
    R2P      13  50  .1
    R1P      51  52  .01
    C3P      51  54  .05E-12
    C6P      54  58  .05E-12
    L7P      2   57  .7E-9
    L2P      50  51  1.08E-9
    L4P      53  54  1.08E-9
    L6P      56  58  1.5E-9
    L11P     65  64  1.08E-9
    L10P     63  5   .7E-9
    L9P      62  61  1.08E-9
    L8P      60  3   .7E-9
    L5P      59  2   .7E-9
    L1P      52  6   .7E-9
    C11P     61  64  .05E-12
    C10P     61  2   .0425E-12
    C9P      3   2   .15E-12
    C8P      58  2   .0125E-12
    C7P      2   2   .15E-12
    C5P      54  2   .0425E-12
    C4P      7   2   .15E-12
    C2P      51  2   .0425E-12
    L3P      55  7   .7E-9
    C1P      6   2   .15E-12
    C12P     5   2   .15E-12
    C13P     64  2   .0425E-12
    *
    * Models Used
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *
    ****************** OPA650 TEST CIRCUIT ******************
    *
    *VCC      80  0   DC 5V
    *VEE      0   81  DC 5V
    *VIN      85  0   PWL ( 0N -2 1N 2 50N 2 51N -2 )
    *RL       82  0   100
    *CL       82  0   5E-12
    *CFB      83  82  .15E-12
    *CFF1     83  0   0.75E-12
    *RIN      85  84  25
    *RFB      86  82  25
    *LFB      83  86  2.2E-9
    *X82      83  84  81  82  80  OPA650X/BB
    *.ENDS
    *$
    **************************************************************************
    * OPA651x  WIDEABND, LOW POWER VOLTAGE FEEDBACK OP AMP MACROMODEL
    * STABLE IN GAINS >=2V/V 
    * CREATED 5/4/95   DY
    * REV. A
    *
    * CONNECTIONS:      INVERTING INPUT
    *                   |   NON-INVERTING INPUT
    *                   |   |   NEGATIVE POWER SUPPLY
    *                   |   |   |   OUTPUT
    *                   |   |   |   |   POSITIVE POWER SUPPLY
    *                   |   |   |   |   |   
    .SUBCKT OPA651X/BB 13  14  11  12  10 
    *
    * Input Stage and Current Source
    Q1       17  7   18  2 NPN1 4
    Q2       16  6   19  2 NPN1 4
    Q3       20  24  23  2 NPN1 2
    Q6       27  26  28  3 PNP1 1
    Q7       24  24  25  2 NPN1 1
    Q10      2   27  26  3 PNP1 1
    ISOUR    27  24  DC 370E-6
    R1       3   21  20
    R2       2   22  20
    R3       18  20  100
    R5       19  20  100
    R4       23  22  500
    R8       21  28  2K
    R9       25  22  1K
    C1       27  24  .5E-12
    C5       21  22  .5E-12
    * Gain Stage
    Q11      29  26  17  3 PNP1 1
    Q15      30  32  31  2 NPN1 1
    Q16      46  26  16  3 PNP1 1
    Q17      47  30  32  2 NPN1 1
    Q18      32  32  33  2 NPN1 1
    V1       29  30  DC 2.4
    R11      21  17  1K
    R13      21  16  1K
    R12      31  22  320
    R14      33  22  320
    C2       32  22  0.1E-12
    C3       47  22  0.6E-12
    C4       46  22  0.6E-12
    C6       6   5   1.5E-12
    * Output Stage
    Q19      35  26  34  3 PNP1 2
    Q20      35  35  44  2 NPN1 2
    Q21      38  47  44  3 PNP1 2
    Q22      39  46  45  2 NPN1 2
    Q23      36  36  45  3 PNP1 2
    Q24      36  24  37  2 NPN1 2
    Q25      21  17  39  2 NPN1 2
    Q26      22  31  38  3 PNP1 2
    Q27      43  40  42  3 PNP1 10
    Q28      3   35  42  2 NPN1 2
    Q29      2   36  43  3 PNP1 2
    Q30      42  40  43  2 NPN1 10
    Q31      3   42  41  2 NPN1 48
    Q32      2   43  41  3 PNP1 48
    R15      21  34  1K
    R16      37  22  500
    R17      41  5   10
    R18      46  47  500
    * Package Parasitics
    R1P      51  52  .01
    R2P      13  50  .1
    R3P      54  55  .01
    R4P      14  53  .1
    R5P      58  59  .01
    R6P      11  56  .1
    R7P      57  58  .01
    R8P      61  60  .01
    R9P      10  62  .1
    R10P     64  63  .01
    R11P     12  65  .1
    L1P      52  6   .7E-9
    L2P      50  51  1.08E-9
    L3P      55  7   .7E-9
    L4P      53  54  1.08E-9
    L5P      59  2   .7E-9
    L6P      56  58  1.5E-9
    L7P      2   57  .7E-9
    L8P      60  3   .7E-9
    L9P      62  61  1.08E-9
    L10P     63  5   .7E-9
    L11P     65  64  1.08E-9
    C1P      6   2   .15E-12
    C2P      51  2   .0425E-12
    C3P      51  54  .05E-12
    C4P      7   2   .15E-12
    C5P      54  2   .0425E-12
    C6P      54  58  .05E-12
    C7P      2   2   .15E-12
    C8P      58  2   .0125E-12
    C9P      3   2   .15E-12
    C10P     61  2   .0425E-12
    C11P     61  64  .05E-12
    C12P     5   2   .15E-12
    C13P     64  2   .0425E-12
    CINV     6   0   .75E-12
    *
    * Models Used
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS 
    *
    ********************** OPA651X TEST CIRCUIT ************************
    *
    *X84      83  84  81  82  80  OPA651X/BB
    *VCC      80  0   DC 5V
    *VEE      0   81  DC 5V
    *VIN      85  0   PWL ( 0N -1 1N 1 50N 1 51N -1 )
    *RIN      85  84  25
    *RLOAD    82  0   100
    *CLOAD    82  0   5E-12
    *CFB      83  82  .15E-12
    *RFB      86  82  400
    *LFB      83  86  2.2E-9
    *RFF      83  87  400
    *LFF      87  0   2.2E-9
    *CFF      83  0   0.15E-12
    *.ENDS
    *$
    **************************************************************************
    * OPA655M  operational amplifier "macromodel" subscircuit
    * using Multiple pole-zero topology
    * created  5/28/96   sb
    * Rev.A    7/20/96   BB
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * Notes:
    * 1. The output stage includes a parasitic capacitance (C5=1pF) from the output
    *    node to ground.  
    * 2. For better convergence during transient analysis set:
    *    .OPTIONS  ITL4=40
    *
    * Node assignments:
    *                   -In         
    *                   |   +In
    *                   |  |  Negative Supply
    *                   |  |  |  Output
    *                   |  |  |  |  Positive Supply
    *                   |  |  |  |  |
    .SUBCKT OPA655M/BB  2  3  4  6  7
    *                                                                  
    * Input Stage
    R1      1    2   5E11
    R2      1    3   5E11
    R3      7   15   19.2
    R4      7   16   19.2
    *2nd POLE at 260MHz
    C1     15   16   1.1E-11
    ISS    14    4   14E-3
    IOS     2    3   2E-12
    EOS    12    2   POLY(1)  70  9  0.5E-3  1
    J1     15   12   14    JX
    J2     16    3   14    JX
    * Second Stage
    R7      7   23   15385
    R8      4   23   15385
    *1st POLE at 300KHz
    C2      7   23   34.5E-12
    C3      4   23   34.5E-12
    G1      7   23   POLY(1) 15  16  10E-3  0.052
    G2     23    4   POLY(1) 16  15  10E-3  0.052
    V1      7    8   0.5V
    V2     10    4   0.5V
    D1     23    8   DX
    D2     10   23   DX
    R9      7    9   1E4
    R10     9    4   1E4
    *Pole at 800MHz
    R11     7    20  1E6
    R12    20     4  1E6
    C11     7    20  0.2E-16
    C12    20     4  0.2E-16
    G3      7    20  23   9   1E-6
    G4     20     4   9  23   1E-6
    *Pole at 2.5GHz
    R30    7     30  1E6
    R31    4     30  1E6
    C30    7     30  6.3E-17
    C31    4     30  6.3E-17
    G30    7     30  20   9  1E-6
    G31   30      4   9  20  1E-6
    *Common Mode Stage
    R19    71   70   1E6
    R20    70   72   1E6
    L3      7   71   0.851
    L4     72    4   0.851
    G7      7   70   1   9   5.623E-10
    G8     70    4   9   1   5.623E-10
    *Pole at 1500MHz
    R21     7   80   1E6
    R22     4   80   1E6
    C21     7   80   1.1E-16
    C22     4   80   1.1E-16
    G9      7   80   20    9   1E-6
    G10     80   4    9   20   1E-6
    *Output Stage
    R23     7   81   64
    R24    81    4   64
    L5     81   88   1.8E-9
    R5     88    6   1
    C5     6     0   1E-12
    G11    81    7    7   80  1.5625E-2
    G12     4   81   80    4  1.5625E-2
    G13    84    4   80   81  1.5625E-2
    G14    85    4   81   80  1.5625E-2
    V3     82   81   1.64
    V4     81   83   1.64
    D3     80   82   DX
    D4     83   80   DX
    D5      7   84   DX
    D6      7   85   DX
    D7      4   84   DY
    D8      4   85   DY
    *
    .MODEL JX  NJF(BETA=0.205  VTO=-1.55  IS=2.5E-12  CGD=5E-13 AF=3.5   KF=8E-10)
    .MODEL DX  D(IS=1E-15)
    .MODEL DY  D(IS=1E-15  BV=20)
    .ENDS
    *$
    **************************************************************************
    * OPA658X   WIDEBAND, LOW-POWER CURRENT-FEEDBACK OP AMP MACROMODEL
    * CREATED 11/24/94  DY
    * REV. A
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * CONNECTIONS:     INVERTING INPUT
    *                  |   NON-INVERTING INPUT
    *                  |   |   NEGATIVE POWER SUPPLY
    *                  |   |   |   OUTPUT
    *                  |   |   |   |   POSITIVE POWER SUPPLY
    *                  |   |   |   |   |   
    .SUBCKT OPA658X/BB 8   9   7   10  6  
    *
    * Input Stage
    ISOUR1   11  13  DC 0.5MA
    ISOUR2   14  12  DC 0.5MA
    Q2       14  14  4   1 PNP1 2
    Q4       18  14  3   1 PNP1 2
    Q1       13  13  4   2 NPN1 2
    Q3       15  13  3   2 NPN1 2
    R5       11  12  20K
    C3       13  0   0.3E-12
    C4       14  0   0.1E-12
    R16      1   11  10
    R17      2   12  10
    C1       11  12  1E-12
    * Gain Stage
    Q7       24  15  37  1 PNP1 6
    Q6       37  17  20  1 PNP1 6
    Q5       15  37  16  1 PNP1 6
    Q8       18  19  22  2 NPN1 3
    Q9       19  23  21  2 NPN1 3
    Q10      26  18  19  2 NPN1 3
    R1       11  16  300
    R2       11  20  300
    R3       22  12  100
    R4       21  12  100
    R12      37  17  600
    R6       19  23  200
    C2       25  12  0.4E-12
    * Output Stage
    Q21      1   33  36  2 NPN1 48
    Q22      2   35  36  1 PNP1 48
    Q11      12  26  28  1 PNP1 3
    Q12      11  24  30  2 NPN1 3
    Q20      35  34  33  1 PNP1 10
    Q19      33  34  35  2 NPN1 10
    Q13      29  29  28  2 NPN1 3
    Q17      1   29  33  2 NPN1 2
    Q14      31  31  30  1 PNP1 3
    Q18      2   31  35  1 PNP1 2
    Q15      29  37  27  1 PNP1 6
    Q16      31  19  32  2 NPN1 3
    R9       11  27  300
    R10      32  12  100
    R7       24  25  80
    R8       25  26  80
    R11      36  5   10
    * Package Parasitics
    CINV     8   0   .75E-12
    L6P      49  48  1.5E-9
    L4P      46  45  1.08E-9
    L2P      43  42  1.08E-9
    C8P      55  2   .0425E-12
    L3P      44  4   .7E-9
    C1P      42  2   .0425E-12
    C2P      42  45  .05E-12
    C3P      45  2   .0425E-12
    C4P      45  48  .05E-12
    C5P      48  2   .0125E-12
    C6P      52  2   .0425E-12
    C7P      52  55  .05E-12
    L1P      41  3   .7E-9
    L5P      47  2   .7E-9
    L7P      51  1   .7E-9
    L8P      53  52  1.08E-9
    L9P      54  5   .7E-9
    L10P     56  55  1.08E-9
    L11P     2   50  .7E-9
    R1P      42  41  .1
    R2P      8   43  .1
    R3P      45  44  .1
    R4P      9   46  .1
    R5P      48  47  .1
    R6P      7   49  .1
    R11P     50  48  .025
    R7P      52  51  .1
    R8P      6   53  .1
    R9P      55  54  .1
    R10P     10  56  .1
    *
    * MODELS USED
    .MODEL NPN1 NPN
    + IS  = 4.647E-17  BF   = 2.293E+02  NF  = 1.000E+00  VAF = 4.398E+01
    + IKF = 7.233E-03  ISE  = 1.222E-14  NE  = 2.000E+00  BR  = 3.695E+01
    + NR  = 1.000E+00  VAR  = 1.494E+00  IKR = 1.667E+05  ISC = 1.057E-14
    + NC  = 1.653E+00  RB   = 3.170E+02  IRB = 0.000E+00  RBM = 1.500E+02
    + RE  = 1.133E+01  RC   = 2.768E+01  CJE = 2.070E-14  VJE = 7.414E-01
    + MJE = 4.950E-01  TF   = 1.150E-11  XTF = 2.452E+01  VTF = 1.029E+00
    + ITF = 1.878E-02  PTF  = 0.000E+00  CJC = 3.661E-14  VJC = 6.465E-01
    + MJC = 4.509E-01  XCJC = 1.270E-01  TR  = 3.240E-10  CJS = 5.326E-14
    + VJS = 5.291E-01  MJS  = 4.389E-01  XTB = 1.218E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 8.614E-01
    *
    .MODEL PNP1 PNP
    + IS  = 2.628E-17  BF   = 1.478E+02  NF  = 1.000E+00  VAF = 3.106E+01
    + IKF = 3.115E-03  ISE  = 8.930E-17  NE  = 1.283E+00  BR  = 3.061E+03
    + NR  = 1.000E+00  VAR  = 1.448E+00  IKR = 5.000E-03  ISC = 1.061E-14
    + NC  = 1.634E+00  RB   = 2.794E+02  IRB = 0.000E+00  RBM = 1.544E+02
    + RE  = 7.452E+00  RC   = 1.142E+02  CJE = 2.038E-14  VJE = 7.470E-01
    + MJE = 4.930E-01  TF   = 1.434E-11  XTF = 2.216E+01  VTF = 1.072E+00
    + ITF = 2.397E-02  PTF  = 0.000E+00  CJC = 6.106E-14  VJC = 7.743E-01
    + MJC = 5.185E-01  XCJC = 8.499E-02  TR  = 6.500E-10  CJS = 2.855E-13
    + VJS = 9.063E-01  MJS  = 4.931E-01  XTB = 1.181E+00  EG  = 1.184E+00
    + XTI = 2.000E+00  KF   = 0.000E+00  AF  = 1.000E+00  FC  = 9.014E-01
    *
    .ENDS
    *
    ****************** OPA658 TEST CIRCUIT ******************
    *
    *X1       60  61  63  65  62  OPA658X/BB
    *VCC      62  0   DC 5V
    *VEE      0   63  DC 5V
    *RFB      66  65  400
    *VIN      67  0   PWL ( 0N -1 1N 1 20N 1 21N -1 )
    *RL       65  0   100
    *LFB      60  66  2.2E-9
    *CL       65  0   5E-12
    *CFB      60  65  0.15E-12
    *RSOUR    67  61  50
    *CFF      60  0   0.15E-12
    *RFF      60  64  400
    *LFF      64  0   2.2E-9
    *.ENDS
    *$
    **************************************************************************
    * OPA660X1 = MDB + MDT + MBC OPERATIONAL TRANSCONDUCTANCE AMPLIFIER
    *            AND BUFFER SIMPLIFIED MACROMODEL VERSION
    * CREATED 8/92 KL
    * REV.B  7/9/93 BCB: CLARIFCATION OF NODE SET INSTRUCTIONS
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * NOTE : FOR QUICKER CONVERSION USE THE NODESET V(Xyour.13)=+4.2758 AND
    *        V(Xyour.14)=-4.2774 IN THE ROOT SIMULATION FILE. ("Xyour" IS
    *        THE DEVICE NAME USED IN THE ROOT FILE.)
    *
    * CONNECTIONS:      IQ ADJUST
    *                   | E (EMITTER)
    *                   | | B (BASE)
    *                   | | | NEGATIVE SUPPLY
    *                   | | | | BUFFER IN
    *                   | | | | | BUFFER OUT
    *                   | | | | | | POSITIVE SUPPLY
    *                   | | | | | | | C (COLLECTOR)
    *                   | | | | | | | |
    .SUBCKT OPA660X1/BB 1 2 3 4 5 6 7 8
    *
    X1 4 5 6 7 13 14 MDB/OPA660X1   ; Diamond Buffer DB
    X2 2 3 4 7 8 13 14 MDT/OPA660X1 ; Diamond Transistor DT
    X3 1 4 7 13 14 MBC/OPA660X1     ; Biasing Circuit BC
    C201  1 0  2.0E-12
    C202  2 0  3.3E-12
    C206  6 0  2.0E-12
    C208  8 0  4.2E-12
    *
    .ENDS
    *
    *Diamond Buffer MDB
    .SUBCKT MDB/OPA660X1  4 5 6 7 13 14
    C71  71 0  0.06E-12
    C72  72 0  0.06E-12
    C73  73 0  2.00E-12
    R73  73 5  90
    Q71  71 13  7  PI/OPA660X1  2
    Q72  72 14  4  NI/OPA660X1  2
    Q73   4 73 71  PI/OPA660X1
    Q74   7 73 72  NI/OPA660X1
    Q75   7 71  6  NI/OPA660X1  7
    Q76   4 72  6  PI/OPA660X1  7
    *
    .ENDS
    *
    *Diamond Transistor MDT
    .SUBCKT MDT/OPA660X1  2 3 4 7 8 13 14
    R23  23 3  90
    C21  21 0  0.06E-12
    C22  22 0  0.06E-12
    C23  23 0  2.00E-12
    C25  25 0  28E-12
    C26  26 0  28E-12
    Q21  21 13  7  PI/OPA660X1  2
    Q22  22 14  4  NI/OPA660X1  2
    Q23   4 23 21  PI/OPA660X1
    Q24   7 23 22  NI/OPA660X1
    Q25  25 21  2  NI/OPA660X1  7
    Q26  26 22  2  PI/OPA660X1  7
    Q27  25 25  7  PIJ/OPA660X1
    Q28  26 26  4  NIJ/OPA660X1
    Q29   8 25  7  PIJ/OPA660X1
    Q30   8 26  4  NIJ/OPA660X1
    *
    .ENDS
    *
    * Biasing Circuit MBC
    .SUBCKT MBC/OPA660X1  1 4 7 13 14
    R122  122  4  50E3
    R123  122  1  100
    Q121  13 13   7  PI/OPA660X1
    Q122  13 14 122  NI/OPA660X1  9
    Q123  14 13   7  PI/OPA660X1
    Q124  14 14   4  NI/OPA660X1
    *
    .ENDS
    *
    .MODEL NI/OPA660X1  NPN
    .MODEL PI/OPA660X1  PNP
    .MODEL NIJ/OPA660X1  NPN (VAF=100)
    .MODEL PIJ/OPA660X1  PNP (VAF=100)
    *$
    **************************************************************************
    * OPA660X2 = MDB + MDT + MBC OPERATIONAL TRANSCONDUCTANCE AMPLIFIER
    *            AND BUFFER COMPLEX MACROMODEL VERSION
    *  CREATED  8/92   KL
    *  REV.A
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:      IQ ADJUST
    *                   | E (EMITTER)
    *                   | | B (BASE)
    *                   | | | NEGATIVE SUPPLY
    *                   | | | | BUFFER IN
    *                   | | | | | BUFFER OUT
    *                   | | | | | | POSITIVE SUPPLY
    *                   | | | | | | | C (COLLECTOR)
    *                   | | | | | | | |
    .SUBCKT OPA660X2/BB 1 2 3 4 5 6 7 8
    * 
    X1 4 5 6 7 13 14 MDB/OPA660X2    ; Diamond Buffer DB
    X2 2 3 4 7 8 13 14 MDT/OPA660X2  ; Diamond Transistor DT
    X3 1 4 7 13 14 MBC/OPA660X2      ; Biasing Circuit BC
    C201  1 0  2E-12
    C202  2 0  2E-12
    C203  3 0  2E-12
    C205  5 0  2E-12
    C206  6 0  2E-12
    C208  8 0  2E-12
    *
    .ENDS
    *
    *Diamond Buffer MDB
    .SUBCKT MDB/OPA660X2  4 5 6 7 13 14
    R77 77 5 25
    Q71 74 13  7 7 PI/OPA660X2  2.8
    Q72 73 14  4 4 NI/OPA660X2  2.8
    Q73 73 73  7 7 PIJ/OPA660X2  18
    Q74 74 74  4 4 NIJ/OPA660X2  18
    Q75 79 73  7 7 PIJ/OPA660X2  18
    Q76 80 74  4 4 NIJ/OPA660X2  18
    Q77 74 77 79 7 PIJ/OPA660X2 
    Q78 73 77 80 4 NIJ/OPA660X2 
    Q79 79 79 78 4 NIJ/OPA660X2  6
    Q80 80 80 78 7 PIJ/OPA660X2  6
    Q81  7 79  6 4 NIJ/OPA660X2  18
    Q82  4 80  6 7 PIJ/OPA660X2  18
    *
    .ENDS
    *
    *Diamond Transistor MDT
    .SUBCKT MDT/OPA660X2  2 3 4 7 8 13 14
    R27 27 3 25
    R33 33 7 50
    R34 34 4 50
    R35 35 7 50
    R36 36 4 50
    C38  2 0 2.2E-12
    Q21 24 13  7 7 PI/OPA660X2  2.8
    Q22 23 14  4 4 NI/OPA660X2  2.8
    Q23 23 23  7 7 PIJ/OPA660X2  18
    Q24 24 24  4 4 NIJ/OPA660X2  18
    Q25 29 23  7 7 PIJ/OPA660X2  18
    Q26 30 24  4 4 NIJ/OPA660X2  18
    Q27 24 27 29 7 PIJ/OPA660X2 
    Q28 23 27 30 4 NIJ/OPA660X2 
    Q29 29 29 28 4 NIJ/OPA660X2  6
    Q30 30 30 28 7 PIJ/OPA660X2  6
    Q31 31 29  2 4 NIJ/OPA660X2  18
    Q32 32 30  2 7 PIJ/OPA660X2  18
    Q33 31 31 33 7 PIJ/OPA660X2  18
    Q34 32 32 34 4 NIJ/OPA660X2  18
    Q35  8 31 35 7 PIJ/OPA660X2  18
    Q36  8 32 36 4 NIJ/OPA660X2  18
    *
    .ENDS
    *
    * Biasing Circuit MBC
    .SUBCKT MBC/OPA660X2  1 4 7 13 14
    R122 122 4 50E3
    R123 122 1 100
    C121 121 0 10E-12
    C124 124 0 10E-12 
    I121 121 124 0.1E-6
    E13  13 0  121 0  1
    E14  14 0  124 0  1
    Q121 121 121   7 7 PI/OPA660X2 
    Q122 121 124 122 4 NI/OPA660X2  27
    Q123 124 121   7 7 PI/OPA660X2 
    Q124 124 124   4 4 NI/OPA660X2 
    Q125   4  13   7 7 PI/OPA660X2  32
    *
    .ENDS
    *
    * BIPOLAR TRANSISTOR MODELS
    .MODEL NI/OPA660X2  NPN
    .MODEL PI/OPA660X2  PNP
    .MODEL NIJ/OPA660X2  NPN (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *
    .MODEL PIJ/OPA660X2  PNP (BF  = 110 IS  = 0.1567E-16
    +CJC = 0.029E-12 AF  = 1.000    NE  = 1.366    XTB = 2.452    BR  = 12.89
    +CJE = 0.017E-12 EG  = 1.183    NF  = 1.000    XTF = 9.000    IKF = 2.272E-3
    +CJS = 0.050E-12 FC  = 0.900    NR  = 1.000    XTI = 2.000    IKR = 16.67E-3
    +RB  = 228.0     IRB = 0.000    PTF = 0.000                   ISC = 5.248E-20
    +RC  = 48.83     KF  = 0.000    VAR = 1.771                   ISE = 8.040E-18
    +RE  = 5.065     MJC = 0.190    VJC = 0.526                   ITF = 6.683E-3
    +TF  = 29.80E-12 MJE = 0.493    VJE = 0.816                   RBM = 60.00
    +TR  = 65.00E-12 MJS = 0.348    VJS = 0.596                   XCJC= 0.0732
    +VAF = 39.00     NC  = 1.634    VTF = 2.680)
    *$
    **************************************************************************
    * *** MACRO MODEL  --  OPA671M
    * Created 1-8-92 BCB
    * REV.B  6-3-92 BCB (added TC for Aol, Is, PSR, and GBWP)
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |                                                             |
    * |  Neither this library nor any part may be copied without    |
    * |  the express written consent of Burr-Brown Corporation.     |
    * |                                                             |
    * |  The users should carefully note the following factors      |
    * |  regarding this model.                                      |
    * |                                                             |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   |  INVERTING INPUT
    *                   |  |  POSITIVE POWER SUPPLY
    *                   |  |  |  NEGATIVE POWER SUPPLY
    *                   |  |  |  |  OUTPUT
    *                   |  |  |  |  |
    *                   |  |  |  |  |
    *                   |  |  |  |  |
    *                   |  |  |  |  |
    *                   |  |  |  |  |
    .SUBCKT OPA671M/BB 31 32  7  4 36
    *
    * Input and output parasitics
    CINP1 31  4 1.1P
    CINP2  3  4 1.9P
    LINP   3 31 4N
    CINM1 32  4 1.1P
    CINM2  2  4 1.9P
    LINM   2 32 4N
    COUT1 36  4 2.2P
    COUT2  6  4 2.2P
    LOUT   6 36 75N
    CDIF1  2  3 4.5P
    R11    2 13 5E12
    R12   13  3 5E12
    * Input stage (2nd pole @ 56M Hz) and GBW product vs temperature
    J11 15  2 14 JX
    J12 16 12 14 JX
    G11  2  4 POLY(3) (15,2) (14,2) (4,2) 0 1E-12 1E-12 1E-12
    G12 12  4 POLY(3) (16,12) 14,12) (4,12) 0 1E-12 1E-12 1E-12
    C12 15 16 CX 3.336E-12
    R13 15  4 426
    R14 16  4 426
    EOS 12  3 POLY(2) 81 71 63 4 0.5E-3 1 1
    ISS  7 14 0.666E-3
    * Gain stage (80dB)[over temperature] and first pole (@ 6K HZ)
    R27  7 21 4.26E6 TC=-0.55E-2
    R28  4 21 4.26E6 TC=-0.55E-2
    C22  7 21 6.2267E-12
    C23  4 21 6.2267E-12
    G21  7 21 POLY(1) 15 16 9.35E-3 2.347E-3
    G22 21  4 POLY(1) 16 15 9.35E-3 2.347E-3
    V21  7 22 2.89
    V22 23  4 2.89
    D21 21 22 DX
    D22 23 21 DX
    * power supply voltage vs current and supply center reference
    * quiescent error current and supply current vs temperature
    R9  7 71 4.5E3
    R10 4 71 4.5E3
    R15 7  4 20.724E3 TC=-1E-3
    G10 7  4 7 4 -0.5
    * Power-supply rejection vs temperature
    GPSR1 63 4 7 22 207.1204E-6
    GPSR2 63 4 7 4 -19.9526E-6
    R61   63 4 1 TC=27.5E-3
    * Common-mode gain network -92dB, zero at 400kHz
    R82 82 81  1
    L82  7 82 .3979E-6
    R83 81 83  1
    L83 83  4 .3979E-6
    G82  7 81 13 71 25E-6
    G83 81  4 71 13 25E-6
    * correction current and output stage
    D91 21 92 DX
    D92 93 21 DX
    D93  7 94 DX
    D94  7 95 DX
    D95  4 94 DY
    D96  4 95 DY
    V93 92  6 1.39
    V94  6 93 1.05
    G91  7  6 21  7 25E-3
    G92  4  6 21  4 25E-3
    G95 94  4  6 21 25E-3
    G96 95  4 21  6 25E-3
    R91  7  6 40
    R92  4  6 40
    *
    .MODEL JX PJF(BETA=2E-3 VTO=-2 IS=2.5E-12 AF=1 KF=19E-18)
    .MODEL DX D(IS=1E-15)
    .MODEL DY D(IS=1E-15  BV=50)
    .MODEL CX CAP(TC1=-.008)
    .ENDS
    *$
    **************************************************************************
    * *** MACRO MODEL  --  OPA675M
    * Created 3-23-92 BCB
    * REV.A
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |								|
    * |  Neither this library nor any part may be copied without 	|
    * |  the express written consent of Burr-Brown Corporation.	|
    * |								|
    * |  The users should carefully note the following factors 	|
    * |  regarding this model.					|
    * |								|
    * |-------------------------------------------------------------|
    *
    *   	This model includes the device characteristics as well as
    *     package parasitics.  If you are using the product in die
    *	form, the package parasitics no longer apply.
    *
    * CONNECTIONS:        NON-INVERTING INPUT A
    *                       |  INVERTING INPUT A
    *                       |  |  COMPENSATION PIN (see note above)
    *                       |  |  |  OUTPUT
    *                       |  |  |  |  POSITIVE POWER SUPPLY
    *		            |  |  |  |  |  NEGATIVE POWER SUPPLY
    *                       |  |  |  |  |  |  NON-INVERTING INPUT B
    *                       |  |  |  |  |  |  |  INVERTING INPUT B
    *                       |  |  |  |  |  |  |  |  ECL
    *                       |  |  |  |  |  |  |  |  |  NOT ECL
    *                       |  |  |  |  |  |  |  |  |  |  GND
    *                       |  |  |  |  |  |  |  |  |  |  |
    .SUBCKT OPA675M/BB      1  2  5  8  7 10 16 15 13 12 11
    *
    * Output and comp cap bond pad and pin parasitics
    LOUT   3  8 2.5N
    COUT1  3 11 2.2P
    COUT2  8 11 2.2P
    CCPP1 19  0 1.1P
    CCPP2  5  0 1.1P
    LCPP  19  5 10N
    * common mode reference
    R11  7 99 382
    R12 10 99 382
    * Side A bond pad and pin parasitics
    LM    2 102 5N
    CM1   2  11 1.1P
    CM2 102  11 1.1P
    LP    1 101 5N
    CP1   1  11 1.1P
    CP2 101  11 1.1P
    * Side A input stage (2nd pole @ 569M Hz)
    Q1   110 102 114 QX
    Q2   111 113 115 QX
    R5   114 116 1065
    R6   115 116 1065
    RIN1 102   4 2.107E3
    RIN2 101   4 2.107E3
    CIN  102 101 2P
    IOS  101 102 0.8U
    VOS  113 101 250E-6
    * Side B bond pad and pin parasitics
    LM_2   15 202 5N
    CM1_2  15  11 1.1P
    CM2_2 202  11 1.1P
    LP_2   16 201 5N
    CP1_2  16  11 1.1P
    CP2_2 201  11 1.1P
    * Side B input stage (2nd pole @ 569M Hz)
    Q1_2   110 202 214 QX
    Q2_2   111 213 215 QX
    R5_2   214 216 1065
    R6_2   215 216 1065
    RIN1_2 202   6 2.107E3
    RIN2_2 201   6 2.107E3
    CIN_2  202 201 2P
    IOS_2  201 202 0.8U
    VOS_2  213 201 250E-6
    * SWOP AMP switch
    RSW1 995 997 1
    CSW1 997  11 1000P
    RSW2 996 998 1
    CSW2 998  11 1000P
    Q11  116 997 999 QY
    Q12  216 998 999 QY
    C11  116  10 1.1P
    C12  216  10 1.1P
    IEE  999  10 0.9452E-3
    VECL1 13 995 1
    VECL2 12 996 1
    * Common-input stage load for both sides
    C1 110 111 1.2485E-13
    R3   7 110 1120
    R4   7 111 1120
    * first gain stage (36dB)
    R9   7 118 18.11K
    R10 10 118 18.11K
    G1   7 118 110 111 3.4E-3
    G2  10 118 110 111 3.4E-3
    E1   7  22 POLY(1) 7 99 -1.847 1
    E2  23  10 POLY(1) 99 10 -1.847 1
    D1 118  22 DX
    D2  23 118 DX
    * second gain stage (1st pole @ 1.5M Hz {determined by device
    * and pad parasitics}, 34dB) and external compensation stage
    R7  7 19 56.14K
    R8 10 19 56.14K
    C3  7 19 0.791P
    C4 10 19 0.791P
    G3  7 19 POLY(1) 118 99 6.48E-3  0.8928E-3
    G4 19 10 POLY(1) 99 118 6.48E-3  0.8928E-3
    V3  7 20 2.667
    V4 21 10 2.352
    D3 19 20 DX
    D4 21 19 DX
    * pole stage @ 800 MHz
    G60  7 60 19 99 1E-6
    G61 10 60 19 99 1E-6
    R60  7 60 1E6
    R61 10 60 1E6
    C60  7 60 198.9E-18
    C61 10 60 198.9E-18
    * pole stage @ 2 GHz
    G80  7 80 60 99 1E-6
    G81 10 80 60 99 1E-6
    R80  7 80 1E6
    R81 10 80 1E6
    C80  7 80 795.8E-19
    C81 10 80 795.8E-19
    * pole stage @ 200 MHz
    G90  7 90 80 99 1E-6
    G91 10 90 80 99 1E-6
    R90  7 90 1E6
    R91 10 90 1E6
    C90  7 90 795.8E-18
    C91 10 90 795.8E-18
    * pole stage @ 20 GHz
    G100  7 100 90 99 1E-6
    G101 10 100 90 99 1E-6
    R100  7 100 1E6
    R101 10 100 1E6
    C100  7 100 795.8E-20
    C101 10 100 795.8E-20
    * pole stage @ 20 GHz
    G110  7 119 100 99 1E-6
    G111 10 119 100 99 1E-6
    R110  7 119 1E6
    R111 10 119 1E6
    C110  7 119 795.8E-20
    C111 10 119 795.8E-20
    * zero / pole pair @  (fz = 142 MHz ,  fp = 569 MHz)
    G120   7 120 119 99 1E-6
    G121  10 120 119 99 1E-6
    R120   7  81 3E6
    R123  82  10 3E6
    R121  81 120 1E6
    R122 120  82 1E6
    L120   7  81 839.1E-6
    L123  10  82 839.1E-6
    * correction current and output stage
    D5   7  51 DX
    D6   7  52 DX
    D7 120  53 DX
    D8  54 120 DX
    D9  10  51 DY
    D10 10  52 DY
    V5  53   3 -.05
    V6   3  54 -.05
    G7   7   3 120 7 .03333
    G8  10   3 120 10 .03333
    G9  51  10 3 120 .03333
    G10 52  10 120 3 .03333
    R15  7   3 30
    R16 10   3 30
    *
    .MODEL QY NPN(BF=400)
    .MODEL QX NPN(BF=41)
    .MODEL DX D(IS=1E-15)
    .MODEL DY D(IS=1E-15 BV=50)
    .ENDS
    *$
    **************************************************************************
    * *** MACRO MODEL  --  OPA676M
    * Created 1/13/92   BCB
    * REV.B   2/8/93 :  BCB: TTL switch overdrove into saturation. Reduced voltage
    *    			       amplitude to npn switch.
    *
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |							                      |
    * |  Neither this library nor any part may be copied without    |
    * |  the express written consent of Burr-Brown Corporation.	    |
    * |								                |
    * |  The users should carefully note the following factors 	    |
    * |  regarding this model.				  	          |
    * |								                |
    * |-------------------------------------------------------------|
    *
    * 1.	This model includes the device characteristics as well as
    *     package parasitics.  If you are using the product in die
    *	form, the package parasitics no longer apply.
    *
    * Your feedback and suggestions on this model will be appreciated!
    *
    * Bonnie Baker
    * Burr-Brown Corporation
    * 6730 S. Tucson Blvd.
    * Tucson, Arizona
    * (800) 548-6132   (WATS line)
    *
    *		        NON-INVERTING INPUT A
    *		        |  INVERTING INPUT A
    *		        |  |  COMPENSATION PIN (see note above)
    *		        |  |  |  OUTPUT
    *		        |  |  |  |  POSITIVE POWER SUPPLY
    *		        |  |  |  |  |  NEGATIVE POWER SUPPLY
    *		        |  |  |  |  |  |  NON-INVERTING INPUT B
    *		        |  |  |  |  |  |  |  INVERTING INPUT B
    *		        |  |  |  |  |  |  |  |  NOT TTL
    *		        |  |  |  |  |  |  |  |  |  GND
    *	       	  |  |  |  |  |  |  |  |  |  |
    .SUBCKT OPA676M/BB  1  2  5  8  7 10 16 15 12 11
    *
    * Output and comp cap bond pad and pin parasitics
    LOUT   3  8 2.5N
    COUT1  3 11 2.2P
    COUT2  8 11 2.2P
    CCPP1 19  0 1.1P
    CCPP2  5  0 1.1P
    LCPP  19  5 10N
    * common mode reference
    R11  7 99 382
    R12 10 99 382
    * Side A bond pad and pin parasitics
    LM    2 102 5N
    CM1   2  11 1.1P
    CM2 102  11 1.1P
    LP    1 101 5N
    CP1   1  11 1.1P
    CP2 101  11 1.1P
    * Side A input stage (2nd pole @ 569M Hz)
    Q1   110 102 114 QX
    Q2   111 113 115 QX
    R5   114 116 1065
    R6   115 116 1065
    RIN1 102   4 2.107E3
    RIN2 101   4 2.107E3
    CIN  102 101 2P
    IOS  101 102 0.8U
    VOS  113 101 250E-6
    * Side B bond pad and pin parasitics
    LM_2   15 202 5N
    CM1_2  15  11 1.1P
    CM2_2 202  11 1.1P
    LP_2   16 201 5N
    CP1_2  16  11 1.1P
    CP2_2 201  11 1.1P
    * Side B input stage (2nd pole @ 569M Hz)
    Q1_2   110 202 214 QX
    Q2_2   111 213 215 QX
    R5_2   214 216 1065
    R6_2   215 216 1065
    RIN1_2 202   6 2.107E3
    RIN2_2 201   6 2.107E3
    CIN_2  202 201 2P
    IOS_2  201 202 0.8U
    VOS_2  213 201 250E-6
    * SWOP AMP switch
    RSW1  13 997 1
    CSW1 997  11 1000P
    RSW2 996 998 1
    CSW2 998  11 1000P
    Q11  116 997 999 QY
    Q12  216 998 999 QY
    C11  116  10 2.75P
    C12  216  10 2.75P
    IEE  999  10 0.9452E-3
    ETTL1 13  11 POLY(1) 12,11 -1.8 -0.42
    ETTL2 996 11 POLY(1) 12,11 -3.9 0.42
    RTTL2 12  11 1E6
    * Common-input stage load for both sides
    C1 110 111 1.2485E-13
    R3  7  110 1120
    R4  7  111 1120
    * first gain stage (36dB)
    R9   7 118 18.11K
    R10 10 118 18.11K
    G1   7 118 110 111 3.4E-3
    G2  10 118 110 111 3.4E-3
    E1   7  22 POLY(1) 7 99 -1.847 1
    E2  23  10 POLY(1) 99 10 -1.847 1
    D1 118  22 DX
    D2  23 118 DX
    * second gain stage (1st pole @ 1.5M Hz {determined by device
    * and pad parasitics}, 34dB) and external compensation stage
    R7  7 19 56.14K
    R8 10 19 56.14K
    C3  7 19 0.791P
    C4 10 19 0.791P
    G3  7 19 POLY(1) 118 99 6.48E-3  0.8928E-3
    G4 19 10 POLY(1) 99 118 6.48E-3  0.8928E-3
    V3  7 20 2.667
    V4 21 10 2.352
    D3 19 20 DX
    D4 21 19 DX
    * pole stage @ 800 MHz
    G60  7 60 19 99 1E-6
    G61 10 60 19 99 1E-6
    R60  7 60 1E6
    R61 10 60 1E6
    C60  7 60 198.9E-18
    C61 10 60 198.9E-18
    * pole stage @ 2 GHz
    G80  7 80 60 99 1E-6
    G81 10 80 60 99 1E-6
    R80  7 80 1E6
    R81 10 80 1E6
    C80  7 80 795.8E-19
    C81 10 80 795.8E-19
    * pole stage @ 200 MHz
    G90  7 90 80 99 1E-6
    G91 10 90 80 99 1E-6
    R90  7 90 1E6
    R91 10 90 1E6
    C90  7 90 795.8E-18
    C91 10 90 795.8E-18
    * pole stage @ 20 GHz
    G100  7 100 90 99 1E-6
    G101 10 100 90 99 1E-6
    R100  7 100 1E6
    R101 10 100 1E6
    C100  7 100 795.8E-20
    C101 10 100 795.8E-20
    * pole stage @ 20 GHz
    G110  7 119 100 99 1E-6
    G111 10 119 100 99 1E-6
    R110  7 119 1E6
    R111 10 119 1E6
    C110  7 119 795.8E-20
    C111 10 119 795.8E-20
    * zero / pole pair @  (fz = 142 MHz ,  fp = 569 MHz)
    G120   7 120 119 99 1E-6
    G121  10 120 119 99 1E-6
    R120   7  81 3E6
    R123  82  10 3E6
    R121  81 120 1E6
    R122 120  82 1E6
    L120   7  81 839.1E-6
    L123  10  82 839.1E-6
    * correction current and output stage
    D5   7  51 DX
    D6   7  52 DX
    D7 120  53 DX
    D8  54 120 DX
    D9  10  51 DY
    D10 10  52 DY
    V5  53   3 -.05
    V6   3  54 -.05
    G7   7   3 120   7 .03333
    G8  10   3 120  10 .03333
    G9  51  10   3 120 .03333
    G10 52  10 120   3 .03333
    R15  7   3  30
    R16 10   3  30
    *
    .MODEL QY NPN(BF=400)
    .MODEL QX NPN(BF=41)
    .MODEL DX D(IS=1E-15)
    .MODEL DY D(IS=1E-15 BV=50)
    .ENDS
    *$
    **************************************************************************
    * OPA77 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * CREATED USING PARTS RELEASE 4.03 ON 10/15/90 AT 15:33
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   | INVERTING INPUT
    *                   | | POSITIVE POWER SUPPLY
    *                   | | | NEGATIVE POWER SUPPLY
    *                   | | | | OUTPUT
    *                   | | | | |
    .SUBCKT OPA77/BB    1 2 3 4 5
    *
    C1   11 12 40.00E-12
    C2    6  7 80.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 1.326E9 -1E9 1E9 1E9 -1E9
    GA    6  0 11 12 301.6E-6
    GCM   0  6 10 99 30.16E-12
    IEE  10  4 DC 20.00E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 3.316E3
    RC2   3 12 3.316E3
    RE1  13 10 729.2
    RE2  14 10 729.2
    REE  10 99 9.999E6
    RO1   8  5 30
    RO2   7 99 30
    RP    3  4 15.15E3
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 22
    VLN   0 92 DC 22
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=10.00E3)
    .ENDS
    *$
    **************************************************************************
    * OPA77E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * CREATED USING PARTS RELEASE 4.03 ON 09/20/90 AT 15:29
    * REV.A
    *
    * CONNECTIONS:      NON-INVERTING INPUT
    *                   |   INVERTING INPUT
    *                   |   |    POSITIVE POWER SUPPLY
    *                   |   |    |  NEGATIVE POWER SUPPLY
    *                   |   |    |  |  OUTPUT
    *                   |   |    |  |  |
    .SUBCKT OPA77E/BB  INP INN   3  4  5
    *
    C1   11 12 40.00E-12
    C2    6  7 80.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 1.326E9 -1E9 1E9 1E9 -1E9
    GA    6  0 11 12 301.6E-6
    GCM   0  6 10 99 30.16E-12
    IEE  10  4 DC 20.00E-6
    HLIM 90  0 VLIM 1K
    Q1   11  2 13 QX
    Q2   12  1 14 QX
    R2    6  9 100.0E3
    RC1   3 11 3.316E3
    RC2   3 12 3.316E3
    RE1  13 10 729.2
    RE2  14 10 729.2
    REE  10 99 9.999E6
    RO1   8  5 30
    RO2   7 99 30
    *  RP    3  4 15.15E3
    VB    9  0 DC 0
    VC    3 53 DC 1.500
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 22
    VLN   0 92 DC 22
    ****************************
    * OPA77 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  0.976E-3  1
    FQ2   0  4 POLY(1) VQ2  0.976E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  3.0E4
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  1.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 1.5E-12
    C2CM  2  99 1.5E-12
    * INPUT PROTECTION
    R1IN  INP 1  500
    D1A    1 VD1 DX
    D1B   VD1 2  DX
    R2IN  INN 2  500
    D2A    2 VD2 DX
    D2B   VD2 1  DX
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL QX NPN(IS=800.0E-18 BF=10.00E3)
    .ENDS
    *$
    **************************************************************************
    *  OPT101P,W *** MACROMODEL-- Copyright 1994 Burr-Brown Corp.
    *  Bandwidth: 14kHz,  Iq = 0.12mA, Single-Supply: +2.7 - +36V
    *  REV.A   12-13-94  EM
    *   
    * Users should very carefully note the following factors regarding this
    * model:
    *
    *      This macromodel, although similar to the commonly used
    *      Boyle model, has limitations on many characteristics.
    *
    *      Use this macromodel to model both OPT101P (PDIP), and OPT101W (SIP).
    *      The inverting input is used on the SIP to connect a current source to,
    *      much like the photodiode acts as a current source on the real devices.
    *
    *      Modeled behavior includes:
    *           Offset Voltage (initially set to 7.5mV)
    *           Input bias current (initially set to 200pA)
    *           Current limit and load-dependant output swing
    *           Quiescent Current, including the effect of Vpin3
    *           Input Impedance
    *           Open Loop Gain
    *           Large-signal dynamic behavior
    *           
    *      Behavior that is not modeled includes:
    *           Changes in parameters over temperature
    *           Noise
    *           Parameter variation for Monte Carlo analysis
    *           Over-voltage effects 
    *           Slew Rate
    *
    *      This macromodel may not accurately model all aforementioned behaviour
    *      with other than the internal 1meg-ohm feedback resistor, and feedback
    *      capacitors.
    *
    *      While reasonable care has been taken in their preparation, we cannot
    *      be responsible for correct application on any and all computer
    *      systems.
    *
    *      Further, Burr-Brown Corporation reserves the right to change these
    *      models without prior notice.
    *
    *      In all cases, the current data sheet information for a given real
    *      device is your final design guideline, and is the only actual
    *      performance guarantee.
    *
    * Connections:       vs
    *                    |  inverting input
    *                    |  |  vpin3
    *                    |  |   |  feedback
    *                    |  |   |  |    vout
    *                    |  |   |  |     |  common
    *                    |  |   |  |     |    |
    .subckt OPT101/BB   vs in vpd feed vout com
    *
    c1   11 12 1E-12
    c2    6  7 1E-12
    cee  10 99 9E-12
    cpar in feed 5.5e-12
    cf   in vout 9e-12
    cphoto in com 1200e-12 ; photodiode capacitance
    dc   vout 53 dx
    de   54  vout dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4 vs dx
    egnd 99  0 poly(2) (vs,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 1.061E9 -1E9 1E9 1E9 -1E9
    ga    6  0 11 12 22.5E-6
    gcm   0  6 10 99 314.2E-12
    iee  vs 10 dc 10.00E-6
    hlim 90  0 vlim 1K
    q1   11  in 13 qx
    q2   12  1 14 qx
    jpd  ed vout vout jp ; JFET pulldown
    r2    6  9 100e3
    rc1  44 11 79.58E3
    rc2  44 12 79.58E3
    re1  13 10 74.40E3
    re2  14 10 74.40E3
    ree  10 99 20.00E6
    ro1   8 vout 3
    ro2   7 99 3
    rp   vs 4 2.8e6
    rf   in feed 1e6 ; internal 1meg
    vb    9  0 dc 0
    vc   vs 53 dc 1.815
    ve   54  4 dc 0
    vlim  7  8 dc 0
    vlp  91  0 dc 15
    vln   0 92 dc 15
    vls  4 44 dc 0.7
    vped 1 com dc 7.5e-3 ; offset voltage
    vbulk 4 0 dc 0
    vdrain ed vpd dc 0
    iq   vs 4 dc 100u
    fdrain vs 4 vdrain 1
    *
    .model dx D(Is=800.0E-18)
    .model qx PNP(Is=800.0E-18 Bf=25.00E3)
    .model jp PJF(VTO=-1.2 BETA=72U LAMBDA=7M)
    .ends
    *$
    **************************************************************************
    * OPT201 INTEGRATED PHOTODIODE AND AMPLIFIER MACROMODEL
    * CREATED USING PARTS 3/18/93 WM
    * REV.A
    * 
    *  ------------------------------------------------------------*
    * | NOTE: USE AN EXTERNAL CURRENT SOURCE BETWEEN PINS 2 AND 8  *
    * |       TO MODEL THE CURRENT GENERATED BY THE PHOTODIODE.    *
    *  ------------------------------------------------------------*
    *
    * connections:      COM
    *                   | -IN
    *                   | | +V
    *                   | | | -V
    *                   | | | | OUT
    *                   | | | | | 1MEG
    *                   | | | | | |
    .subckt OPT201KP/BB 8 2 1 3 5 4
    *
    X1               8 2 1 3 55  OPAMP_201
    *  PHOTODIODE AND FEEDBACK COMPONENTS
    RFB    2 4  1E6
    ROUT  55 5  75
    CFB   55 2  40E-12
    RPHOTO 2 8  100E6
    CPHOTO 2 8  4000E-12
    DPHOTO 2 8  DIODE
    *
    .MODEL DIODE  D
    .ENDS
    *  OPAMP MODEL
    .SUBCKT OPAMP_201  1 2 3 4 5
    C1   11 12 10.49E-12
    C2    6  7 45.00E-12
    CSS  10 99 61.36E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 29.43E9 -30E9 30E9 30E9 -30E9
    GA    6  0 11 12 107.4E-6
    GCM   0  6 10 99 1.074E-9
    ISS   3 10 DC 117.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 9.307E3
    RD2   4 12 9.307E3
    RO1   8  5 75
    RO2   7 99 2
    RP    3  4 75.00E3
    RSS  10 99 1.709E6
    VB    9  0 DC 0
    VC    3 53 DC 1.
    VE   54  4 DC .5
    VLIM  7  8 DC 0
    VLP  91  0 DC 15
    VLN   0 92 DC 15
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=58.E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * OPT202 INTEGRATED PHOTODIODE AND AMPLIFIER MACROMODEL 
    * Bandwidth 50KHz, Iq = 1.4mA
    * CREATED USING PARTS 4/15/94 WM
    * REV. A
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    *  ------------------------------------------------------------*
    * | NOTE: USE AN EXTERNAL CURRENT SOURCE BETWEEN PINS 2 AND 8  * 
    * |       TO MODEL THE CURRENT GENERATED BY THE PHOTODIODE.    *
    *  ------------------------------------------------------------*
    *
    * PHOTODIODE AND FEEDBACK COMPONENTS 
    *
    * connections:      COM
    *                   | -IN
    *                   | | V+
    *                   | | | V-
    *                   | | | | Vo
    *                   | | | | | RFB,1MEG
    *                   | | | | | |  
    .subckt OPT202/BB   8 2 1 3 5 4
    *
    X1               8 2 1 3 55  OPAMP_202
    RFB    2 4  1MEG
    ROUT  55 5  5
    CFB   55 2  3pF
    RPHOTO 2 8  100MEG
    CPHOTO 2 8  600pF
    DPHOTO 2 8  DIODE
    *
    .MODEL DIODE  D
    .ends
    *
    * OPAMP MODEL 
    .subckt OPAMP_202  1 2 3 4 5
    c1   11 12 5.715E-12
    c2    6  7 1.000E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 99.47E6 -99E6 99E6 99E6 -99E6
    ga    6  0 11 12 100.5E-6
    gcm   0  6 10 99 503.8E-12
    iss   3 10 dc 4.000E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 9.947E3
    rd2   4 12 9.947E3
    ro1   8  5 75
    ro2   7 99 100
    rp    3  4 75.00E3
    rss  10 99 50.00E6
    vb    9  0 dc 0
    vc    3 53 dc .6
    ve   54  4 dc .6
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=250.0E-15 Beta=2.527E-3 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPT209  INTEGRATED PHOTODIODE AND AMPLIFIER MACROMODEL 
    * Bandwidth 16kHz, Iq = 0.4mA
    * CREATED USING PARTS 4/27/94 WM
    * REV. A
    * REV. B 11 June 97 NPA: added missing period in .MODEL DIODE D
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    *  ------------------------------------------------------------*
    * | NOTE: USE AN EXTERNAL CURRENT SOURCE BETWEEN PINS 2 AND 8  * 
    * |       TO MODEL THE CURRENT GENERATED BY THE PHOTODIODE.    *
    *  ------------------------------------------------------------*
    *
    * PHOTODIODE AND FEEDBACK COMPONENTS 
    *
    * connections:      COM
    *                   | -IN
    *                   | | V+
    *                   | | | V-
    *                   | | | | Vo
    *                   | | | | | RFB,1MEG
    *                   | | | | | |  
    .subckt OPT209/BB   8 2 1 3 5 4
    *
    X1               8 2 1 3 55  OPAMP_209
    RFB    2 4  1MEG
    ROUT  55 5  5
    CFB   55 2  10pF
    RPHOTO 2 8  1000MEG
    CPHOTO 2 8  600pF
    DPHOTO 2 8  DIODE
    .MODEL DIODE  D
    .ends
    *
    * OPAMP MODEL 
    .subckt OPAMP_209  1 2 3 4 5
    c1   11 12 12.63E-12
    c2    6  7 4.000E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 99.7E6 -99E6 99E6 99E6 -99E6
    ga    6  0 11 12 100.5E-6
    gcm   0  6 10 99 1.005E-9
    iss   3 10 dc 16.00E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 9.947E3
    rd2   4 12 9.947E3
    ro1   8  5 75
    ro2   7 99 100
    rp    3  4 75.00E3
    rss  10 99 12.50E6
    vb    9  0 dc 0
    vc    3 53 dc .6
    ve   54  4 dc .6
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=250.0E-15 Beta=631.7E-6 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPT211 INTEGRATED PHOTODIODE AND AMPLIFIER MACROMODEL 
    * CREATED USING PARTS 12/6/94 WM
    * REV.A  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    *  ------------------------------------------------------------
    * | NOTE: USE AN EXTERNAL CURRENT SOURCE BETWEEN PINS 2 AND 8  | 
    * |       TO MODEL THE CURRENT GENERATED BY THE PHOTODIODE.    |
    *  ------------------------------------------------------------
    *      *  PHOTODIODE AND FEEDBACK COMPONENTS  *
    *
    * connections:         COM
    *                      | -IN
    *                      | | +V
    *                      | | | -V
    *                      | | | | OUT
    *                      | | | | | PHOTO
    *                      | | | | | | 
    .subckt OPT211/BB      8 2 1 3 5 7
    *
    X1               8 2 1 3 5   OPAMP_211
    *  Photodiode
    RPHOTO     2  7  1000GIG
    CPHOTO     2  7  600pF
    DPHOTO     2  7  DIODE
    CSUB       2  8  80pF
    .MODEL DIODE D
    .ENDS
    *
    *OPAMP MODEL  *
    .subckt OPAMP_211  1 2 3 4 5
    c1   11 12 5.715E-12
    c2    6  7 1.000E-12
    dc    5 53 dx
    de   54  5 dx
    dlp  90 91 dx
    dln  92 90 dx
    dp    4  3 dx
    egnd 99  0 poly(2) (3,0) (4,0) 0 .5 .5
    fb    7 99 poly(5) vb vc ve vlp vln 0 99E7 -99E7 99E7 99E7 -99E7
    ga    6  0 11 12 100.5E-6
    gcm   0  6 10 99 503.8E-12
    iss   3 10 dc 4.000E-6
    hlim 90  0 vlim 1K
    j1   11  2 10 jx
    j2   12  1 10 jx
    r2    6  9 100.0E3
    rd1   4 11 9.947E3
    rd2   4 12 9.947E3
    ro1   8  5 5
    ro2   7 99 5
    rp    3  4 75.00E3
    rss  10 99 50.00E6
    vb    9  0 dc 0
    vc    3 53 dc .6
    ve   54  4 dc .6
    vlim  7  8 dc 0
    vlp  91  0 dc 20
    vln   0 92 dc 20
    *
    .model dx D(Is=800.0E-18)
    .model jx PJF(Is=250.0E-15 Beta=2.527E-3 Vto=-1)
    .ends
    *$
    **************************************************************************
    * OPT301 INTEGRATED PHOTODIODE AND AMPLIFIER MACROMODEL 
    * CREATED USING PARTS 3/18/93 WM
    *  REV.A
    *  REV.B 7 June 97 NPA added text: Model optical input as an equivalent photodiode
    *                                  current into SJ (pin 2).
    *  REV.C  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    *  ------------------------------------------------------------*
    * | NOTE: USE AN EXTERNAL CURRENT SOURCE BETWEEN PINS 2 AND 8  * 
    * |       TO MODEL THE CURRENT GENERATED BY THE PHOTODIODE.    *
    *  ------------------------------------------------------------*
    *
    * connections:      COM
    *                   | -IN
    *                   | | +V
    *                   | | | -V
    *                   | | | | OUT
    *                   | | | | | 1MEG
    *                   | | | | | |  
    .subckt OPT301/BB   8 2 1 3 5 4
    *
    X1               8 2 1 3 55  OPAMP_301
    *  PHOTODIODE AND FEEDBACK COMPONENTS
    RFB    2 4  1E6
    ROUT  55 5  75
    CFB   55 2  40E-12
    RPHOTO 2 8  100E6
    CPHOTO 2 8  4000E-12
    DPHOTO 2 8  DIODE
    .MODEL DIODE  D
    .ENDS
    *
    *  OPAMP MODEL
    .SUBCKT OPAMP_301  1 2 3 4 5
    C1   11 12 10.49E-12
    C2    6  7 45.00E-12
    CSS  10 99 61.36E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 29.43E9 -30E9 30E9 30E9 -30E9
    GA    6  0 11 12 107.4E-6
    GCM   0  6 10 99 1.074E-9
    ISS   3 10 DC 117.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   4 11 9.307E3
    RD2   4 12 9.307E3
    RO1   8  5 75
    RO2   7 99 2
    RP    3  4 75.00E3
    RSS  10 99 1.709E6
    VB    9  0 DC 0
    VC    3 53 DC 1.
    VE   54  4 DC .5
    VLIM  7  8 DC 0
    VLP  91  0 DC 15
    VLN   0 92 DC 15
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=500.0E-15 BETA=58.E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * PGA206 HIGH SPEED PROGRAMMABLE GAIN AMPLIFIER
    * Rev. A   Created 5/30/96 BCB
    * REV. B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    * REV. C  24 JUNE 97 NPA: ADDED NOTE: DRIVE A0 & A1 INPUTS WITH VDC SOURCES
    *                         TO PREVENT POSSIBLE NON-CONVERGENCE.
    *
    * connections:        V01
    *                     |   VIN-
    *                     |   |   VIN+
    *                     |   |   |   V-
    *                     |   |   |   |   VO2
    *                     |   |   |   |   |   REF
    *                     |   |   |   |   |   |   VO
    *                     |   |   |   |   |   |   |   SENSE
    *                     |   |   |   |   |   |   |   |   V+
    *                     |   |   |   |   |   |   |   |   |   DIG GND
    *                     |   |   |   |   |   |   |   |   |   |   A0
    *                     |   |   |   |   |   |   |   |   |   |   |   A1
    *                     |   |   |   |   |   |   |   |   |   |   |   |
    .SUBCKT   PGA206/BB   1   4   5   8   9   10  11  12  13  14  15  16
    *
    XG1      51      50      14      59      55      NOR_206
    XG4      51      50      14      56      AND_206
    XG2      56      51      14      58      XOR_206
    XG3      56      50      14      57      XOR_206
    XA1      4      31      13      8      1      OPAMP_206
    XA2      5      30      13      8      9      OPAMP_206
    XA3      40      41      13      8      11      OPAMP_206
    R1A      27      26      625
    R2A      26      25      1.25E3
    R3A      25      24      2.5E3
    R4AB      24      23      1.25E3
    R1B      20      21      625
    R2B      21      22      1.25E3
    R3B      22      23      2.5E3
    R1C      27      41      10000
    R2C      41      12      10000
    R3C      20      40      10000.2
    R4C      40      10      10000
    CF3      41      12      3E-12
    CF4      40      10      3E-12
    CF1      31      1      10E-12
    CF2      30      9      10E-12
    RO1      1      27      15
    RO2      9      20      15
    S1      31      27      59      14      SW
    S2      31      26      57      14      SW
    S3      31      25      58      14      SW
    S4      31      24      55      14      SW
    S5      30      23      55      14      SW
    S6      30      22      58      14      SW
    S7      30      21      57      14      SW
    S8      30      20      59      14      SW
    GA0      15      14      15      50      -100
    GA1      16      14      16      51      -100
    RA0      15      50      0.01
    RA1      16      51      0.01
    IVPS      14      13      0.2E-3
    IVMS      8      14      1.5E-3
    *
    .MODEL SW VSWITCH(RON=1 ROFF=1000G VON=0.15 VOFF=0.1)
    .ENDS
    *
    .SUBCKT AND_206  16  15  14  75
    D71    71  16  DX
    D72    71  15  DX
    D73    71  72  DX
    D74    72  73  DX
    Q71    74  73  14  QX
    Q72    75  74  14  QX
    R71    80  71  4E3
    R72    80  74  8E3
    R73    73  76  7E3
    R74    80  75  1E3
    VBIAS  14  76   2
    VSUP   80  14   5
    *
    .MODEL  DX D(IS=1E-15)
    .MODEL  QX  NPN(IS=800E-18 BF=500)
    .ENDS
    *
    .SUBCKT   XOR_206 57 17 14 88
    * Logic cell - X-OR Gate
    R52     57      51      450
    R53     57      52      450
    Q50     55      51      14       QX
    Q52     53      52      14       QX
    R56     80      55      2000
    Q51     55      53      14       QX
    Q53     51      54      14       QX
    * A1 for switch 3, A0 for switch 2
    R54     53      17      450
    R55     54      17      450
    Q54     88   55      14       QX
    R57     80      88   2000
    VSUP    80      14     2.5
    *
    .MODEL QX NPN(IS=800E-18 BF=500)
    .ENDS
    *
    .SUBCKT NOR_206 16 15 14 85 86
    * Logic cell - NOR
    R61     16  61       450
    Q60     85  61        14       QX
    R62     15  63       450
    R60     80  85       3E3
    Q61     85  63        14       QX
    VSUP    80  14         2
    Q62     86  85        14       QX
    R63     86  80      2000
    *
    * Models
    .MODEL QX NPN(IS=800E-18 BF=500)
    .ENDS
    *
    * PGA206 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.2 on 05/30/96 at 07:47
    *
    * connections:       non-inverting input
    *                    | inverting input
    *                    | | positive power supply
    *                    | | | negative power supply
    *                    | | | | output
    *                    | | | | |
    .SUBCKT OPAMP_206    1 2 3 4 5
    *
    C1   11 12 7.002E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 265.3E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 754.0E-6
    GCM   0  6 10 99 754.0E-12
    ISS  10  4 DC 600.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   3 11 1.326E3
    RD2   3 12 1.326E3
    RO1   8  5 10
    RO2   7 99 5
    RP    3  4 8.036E3
    RSS  10 99 333.3E3
    VB    9  0 DC 0
    VC    3 53 DC 2.300
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX NJF(IS=1.000E-12 BETA=947.5E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * PGA207 HIGH SPEED PROGRAMMABLE GAIN AMPLIFIER
    * REV.A  Created 5/30/96 BCB
    * REV.B  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    * REV.C  24 JUNE 97 NPA: ADDED NOTE: DRIVE A0 & A1 INPUTS WITH VDC SOURCES
    *                         TO PREVENT POSSIBLE NON-CONVERGENCE.
    *
    *connections:         V01
    *                     |   VIN-
    *                     |   |   VIN+
    *                     |   |   |   V-
    *                     |   |   |   |   VO2
    *                     |   |   |   |   |   REF
    *                     |   |   |   |   |   |   VO
    *                     |   |   |   |   |   |   |   SENSE
    *                     |   |   |   |   |   |   |   |   V+
    *                     |   |   |   |   |   |   |   |   |   DIG GND
    *                     |   |   |   |   |   |   |   |   |   |   A0
    *                     |   |   |   |   |   |   |   |   |   |   |   A1
    *                     |   |   |   |   |   |   |   |   |   |   |   |
    .SUBCKT   PGA207/BB   1   4   5   8   9   10  11  12  13  14  15  16
    *
    XG1      51      50      14      59      55      NOR_207
    XG4      51      50      14      56              AND_207
    XG2      56      51      14      58              XOR_207
    XG3      56      50      14      57              XOR_207
    XA1      4       31      13      8       1       OPAMP_207
    XA2      5       30      13      8       9       OPAMP_207
    XA3      40      41      13      8       11      OPAMP_207
    R1A      27      26      625
    R2A      26      25      1.875E3
    R3A      25      24      3.125E3
    R4AB     24      23      1.25E3
    R1B      20      21      625
    R2B      21      22      1.875E3
    R3B      22      23      3.125E3
    R1C      27      41      10000
    R2C      41      12      10000
    R3C      20      40      10000.2
    R4C      40      10      10000
    CF3      41      12      3E-12
    CF4      40      10      3E-12
    CF1      31      1       10E-12
    CF2      30      9       10E-12
    RO1      1       27      15
    RO2      9       20      15
    S1       31      27      59      14      SW
    S2       31      26      57      14      SW
    S3       31      25      58      14      SW
    S4       31      24      55      14      SW
    S5       30      23      55      14      SW
    S6       30      22      58      14      SW
    S7       30      21      57      14      SW
    S8       30      20      59      14      SW
    GA0      15      14      15      50      -100
    GA1      16      14      16      51      -100
    RA0      15      50      0.01
    RA1      16      51      0.01
    IVPS     14      13      0.2E-3
    IVMS     8       14      1.5E-3
    *
    .MODEL SW VSWITCH(RON=1 ROFF=1000G VON=0.15 VOFF=0.1)
    .ENDS
    *
    .SUBCKT  AND_207  16  15  14  75
    D71  71 16 DX
    D72  71 15 DX
    D73  71 72 DX
    D74  72 73 DX
    Q71  74 73 14 QX
    Q72  75 74 14 QX
    R71  80 71 4E3
    R72  80 74 8E3
    R73  73 76 7E3
    R74  80 75 1E3
    VBIAS 14 76 2
    VSUP 80 14 5
    *
    .MODEL  DX D(IS=1E-15)
    .MODEL  QX NPN(IS=800E-18 BF=500)
    .ENDS
    *
    .SUBCKT   XOR_207 57 17 14 88
    * Logic cell - X-OR Gate
    R52     57      51      450
    R53     57      52      450
    Q50     55      51      14       QX
    Q52     53      52      14       QX
    R56     80      55      2000
    Q51     55      53      14       QX
    Q53     51      54      14       QX
    * A1 for switch 3, A0 for switch 2
    R54     53      17      450
    R55     54      17      450
    Q54     88      55      14       QX
    R57     80      88      2000
    VSUP    80      14      2.5
    *
    .MODEL QX NPN(IS=800E-18 BF=500)
    .ENDS
    *
    .SUBCKT NOR_207 16 15 14 85 86
    * Logic cell - NOR
    R61     16      61      450
    Q60     85      61      14       QX
    R62     15      63      450
    R60     80      85      3K
    Q61     85      63      14       QX
    VSUP    80      14      2
    Q62     86      85      14       QX
    R63     86      80      2000
    *
    * Models
    .MODEL QX NPN(IS=800E-18 BF=500)
    .ENDS
    *
    * PGA207 operational amplifier "macromodel" subcircuit
    * created using Parts release 5.2 on 05/30/96 at 07:47
    *
    * connections:       non-inverting input
    *                    | inverting input
    *                    | | positive power supply
    *                    | | | negative power supply
    *                    | | | | output
    *                    | | | | |
    .SUBCKT OPAMP_207    1 2 3 4 5
    *
    C1   11 12 7.002E-12
    C2    6  7 20.00E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 265.3E6 -30E6 30E6 30E6 -30E6
    GA    6  0 11 12 754.0E-6
    GCM   0  6 10 99 754.0E-12
    ISS  10  4 DC 600.0E-6
    HLIM 90  0 VLIM 1E3
    J1   11  2 10 JX
    J2   12  1 10 JX
    R2    6  9 100.0E3
    RD1   3 11 1.326E3
    RD2   3 12 1.326E3
    RO1   8  5 10
    RO2   7 99 5
    RP    3  4 8.036E3
    RSS  10 99 333.3E3
    VB    9  0 DC 0
    VC    3 53 DC 2.300
    VE   54  4 DC 1.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 10
    VLN   0 92 DC 10
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX NJF(IS=1.000E-12 BETA=947.5E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * UAF42 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * SUBCIRCUIT AMP_UAF CREATED USING PARTS RELEASE 4.03 ON 10/17/90 AT 14:54
    * UAF42 = 4x AMP_UAF + PRECISION RESISTORS AND CAPS
    * REV. B  1/3/94/JA CHANGED THE ENTIRE MACRO MODEL FILE TO BE A UAF42
    *                   INSTEAD OF A SINGLE OP AMP CONTAINED IN THE UAF42.
    *                   NODE ASSIGNMENTS OF SUBCKT UAF42 ARE THE SAME AS THE DIP
    *                   PACKAGE UAF42 PINOUT.
    * REV.C  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * UAF42 SUB-CIRCUIT
    * CONNECTIONS:      LOW-PASS OUTPUT
    *                   | V IN 3
    *                   | | V IN 2
    *                   | | | AUX AMP NON-INVERTING INPUT
    *                   | | | | AUX AMP INVERTING INPUT
    *                   | | | | | AUX AMP OUTPUT
    *                   | | | | | | BAND-PASS OUTPUT
    *                   | | | | | | | FREQUENCY ADJ1
    *                   | | | | | | | | NEGATIVE POWER SUPPLY
    *                   | | | | | | | | | POSITIVE POWER SUPPLY
    *                   | | | | | | | | | |  GROUND
    *                   | | | | | | | | | |  |  V IN 1
    *                   | | | | | | | | | |  |  |  HIGH-PASS OUTPUT
    *                   | | | | | | | | | |  |  |  |  FREQUENCY ADJ2
    *                   | | | | | | | | | |  |  |  |  |
    .SUBCKT UAF42/BB    1 2 3 4 5 6 7 8 9 10 11 12 13 14
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | |  POSITIVE POWER SUPPLY
    *                | |  |  NEGATIVE POWER SUPPLY
    *                | |  |  | OUTPUT
    *                | |  |  | |
    X1               3 12 10 9 13   AMP_UAF
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |  INVERTING INPUT
    *                |  | POSITIVE POWER SUPPLY
    *                |  | |  NEGATIVE POWER SUPPLY
    *                |  | |  | OUTPUT
    *                |  | |  | |
    X2               11 8 10 9 7   AMP_UAF
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |  INVERTING INPUT
    *                |  |  POSITIVE POWER SUPPLY
    *                |  |  |  NEGATIVE POWER SUPPLY
    *                |  |  |  | OUTPUT
    *                |  |  |  | |
    X3               11 14 10 9 1   AMP_UAF
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | |  NEGATIVE POWER SUPPLY
    *                | | |  | OUTPUT
    *                | | |  | |
    X4               4 5 10 9 6   AMP_UAF
    *
    R1 12  1 50K
    R2 12 13 50K
    R4  3  7 50K
    R3A 3  2 100K
    R3B 3  2 100K
    C1  7  8 1000P
    C2  1 14 1000P
    C3 13 14 1P
    *
    .ENDS
    *
    * AMP_UAF OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT AMP_UAF  1 2 3 4 5
    *
    C1   11 12 8.938E-12
    C2    6  7 15.00E-12
    CSS  10 99 8.077E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 99.42E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 424.1E-6
    GCM   0  6 10 99 6.722E-9
    ISS   3 10 DC 300.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 2.358E3
    RD2   4 12 2.358E3
    RO1   8  5 75
    RO2   7 99 75
    RP    3  4 20.00E3
    RSS  10 99 666.7E3
    VB    9  0 DC 0
    VC    3 53 DC 3.500
    VE   54  4 DC 3.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    *
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=299.8E-6 VTO=-1)
    .ENDS
    *$
    **************************************************************************
    * UAF42E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    * SUBCIRCUIT AMP_UAFE CREATED USING PARTS RELEASE 4.03 ON 10/17/90 AT 14:54
    * UAF42E = 4x AMP_UAFE + PRECISION RESISTORS AND CAPS
    * REV.B  3/21/92 BCB added input bias current error correction to AMP_UAFE
    * REV.C  1/3/94  JA  Changed the entire macro model file to be
    *                    a UAF42 instead of a single op amp contained in the UAF42
    * REV.D  20 JUNE 97 NPA: MOVED LEGAL DISCLAIMER TO BEGINNING OF FILE
    *
    * UAF42E SUB-CIRCUIT
    * CONNECTIONS:      LOW-PASS OUTPUT
    *                   | V IN 3
    *                   | | V IN 2
    *                   | | | AUX AMP NON-INVERTING INPUT
    *                   | | | | AUX AMP INVERTING INPUT
    *                   | | | | | AUX AMP OUTPUT
    *                   | | | | | | BAND-PASS OUTPUT
    *                   | | | | | | | FREQUENCY ADJ1
    *                   | | | | | | | | NEGATIVE POWER SUPPLY
    *                   | | | | | | | | | POSITIVE POWER SUPPLY
    *                   | | | | | | | | | |  GROUND
    *                   | | | | | | | | | |  |  V IN 1
    *                   | | | | | | | | | |  |  |  HIGH-PASS OUTPUT
    *                   | | | | | | | | | |  |  |  |  FREQUENCY ADJ2
    *                   | | | | | | | | | |  |  |  |  |
    .SUBCKT UAF42E/BB   1 2 3 4 5 6 7 8 9 10 11 12 13 14
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | |  POSITIVE POWER SUPPLY
    *                | |  | NEGATIVE POWER SUPPLY
    *                | |  |  | OUTPUT
    *                | |  |  | |
    X1               3 12 10 9 13   AMP_UAFE
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |  INVERTING INPUT
    *                |  | POSITIVE POWER SUPPLY
    *                |  | | NEGATIVE POWER SUPPLY
    *                |  | |  | OUTPUT
    *                |  | |  | |
    X2               11 8 10 9 7   AMP_UAFE
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                |  INVERTING INPUT
    *                |  |  POSITIVE POWER SUPPLY
    *                |  |  | NEGATIVE POWER SUPPLY
    *                |  |  |  | OUTPUT
    *                |  |  |  | |
    X3               11 14 10 9 1   AMP_UAFE
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | |  | OUTPUT
    *                | | |  | |
    X4               4 5 10 9 6   AMP_UAFE
    *
    R1 12 13 50K
    R2 12  1 50K
    R3  3  7 50K
    R4A 3  2 100K
    R4B 3  2 100K
    C1  7  8 1000P
    C2  1 14 1000P
    C3 13 14 1P
    *
    .ENDS
    *
    * AMP_UAFE OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "E" IS ENHANCED MODEL
    *
    * CONNECTIONS:   NON-INVERTING INPUT
    *                | INVERTING INPUT
    *                | | POSITIVE POWER SUPPLY
    *                | | | NEGATIVE POWER SUPPLY
    *                | | | | OUTPUT
    *                | | | | |
    .SUBCKT AMP_UAFE 1 2 3 4 5
    *
    C1   11 12 8.938E-12
    C2    6  7 15.00E-12
    CSS  10 99 8.077E-12
    DC    5 53 DX
    DE   54  5 DX
    DLP  90 91 DX
    DLN  92 90 DX
    DP    4  3 DX
    EGND 99  0 POLY(2) (3,0) (4,0) 0 .5 .5
    FB    7 99 POLY(5) VB VC VE VLP VLN 0 99.42E6 -10E6 10E6 10E6 -10E6
    GA    6  0 11 12 424.1E-6
    GCM   0  6 10 99 6.722E-9
    ISS   3 10 DC 300.0E-6
    HLIM 90  0 VLIM 1K
    J1   11  2 10 JX
    J2   12  1 10 JX
    G11 2 4 POLY(3) (10,2) (11,2) (4,2) 0 1E-12 1E-12 1E-12
    G21 1 4 POLY(3) (10,1) (12,1) (4,1) 0 1E-12 1E-12 1E-12
    R2    6  9 100.0E3
    RD1   4 11 2.358E3
    RD2   4 12 2.358E3
    RO1   8  5 75
    RO2   7 99 75
    *  RP    3  4 20.00E3
    RSS  10 99 666.7E3
    VB    9  0 DC 0
    VC    3 53 DC 3.500
    VE   54  4 DC 3.500
    VLIM  7  8 DC 0
    VLP  91  0 DC 25
    VLN   0 92 DC 25
    ****************************
    * UAF42 "E" - ENHANCEMENTS
    ****************************
    * OUTPUT SUPPLY MIRROR
    FQ3   0 20 POLY(1) VLIM 0  1
    DQ1  20 21 DX
    DQ2  22 20 DX
    VQ1  21  0 0
    VQ2  22  0 0
    FQ1   3  0 POLY(1) VQ1  0.950E-3  1
    FQ2   0  4 POLY(1) VQ2  0.950E-3 -1
    * QUIESCIENT CURRENT
    RQ    3  4  1.2E5
    * DIFF INPUT CAPACITANCE
    CDIF  1  2  2.0E-12
    * COMMON MODE INPUT CAPACITANCE
    C1CM  1  99 3.0E-12
    C2CM  2  99 3.0E-12
    ****************************
    .MODEL DX D(IS=800.0E-18)
    .MODEL JX PJF(IS=5.000E-12 BETA=299.8E-6 VTO=-1)
    .ENDS
    *$
    *----------------------------------------------------------------------------
    * VCA610M VOLTAGE CONTROLLED AMPLIFIER "MACROMODEL" SUBCIRCUIT
    * "M" IS  MULTIPLE POLE/ZERO TOPOLOGY
    * CREATED 6/16/93 BCB
    * REV.A
    *  
    * |-------------------------------------------------------------|
    * |  This macro model is being supplied as an aid to            |
    * |  circuit designs.  While it reflects reasonably close       |
    * |  similarity to the actual device in terms of performance,   |
    * |  it is not suggested as a replacement for breadboarding.    |
    * |  Simulation should be used as a forerunner or a supplement  |
    * |  to traditional lab testing.                                |
    * |                                                             |
    * |  Neither this library nor any part may be copied without    |
    * |  the express written consent of Burr-Brown Corporation.     |
    * |                                                             |
    * |  The users should carefully note the following factors      |
    * |  regarding this model.                                      |
    * |                                                             |
    * |-------------------------------------------------------------|
    *
    * CONNECTIONS:       NON-INVERTING INPUT
    *                    |  GROUND
    *                    |  |  GAIN CONTROL, VC
    *                    |  |  |  OUTPUT
    *                    |  |  |  |  POSITIVE SUPPLY VOLTAGE
    *                    |  |  |  |  |  NEGATIVE SUPPLY VOLTAGE
    *                    |  |  |  |  |  |  INVERTING INPUT
    *                    |  |  |  |  |  |  |
    .SUBCKT  VCA610M/BB  1  2  3  5  6  7  8
    * CONTROL VOLTAGE
    Q1   7   3  13  P
    C1   3   7  1E-12
    Q2   7   2  13  P
    I1   6  13  384E-6
    Q3  10  11  7  N
    R2   6  10  2
    E1  11   7  POLY(1) (3,0) 0.45  -0.11911
    G3  12   0  POLY(1) (10,6) 0 1
    R3  12   0  139
    C3  12   0  1.145E-9
    G1   6   7  POLY(1) (6,10) 13.5102E-3 -0.489
    G2   0   7  POLY(1) (6,10) 1.7958E-3 2.939E-3
    * INPUT STAGE
    Q01  20   1  26  N
    C01   1   0  1E-12
    Q02  21   8  26  N
    C02   8   0  1E-12
    R01  20  27  1E3
    D01  29  27  DX
    D03   6  29  DX
    R02  21  28  1E3
    D02  24  28  DX
    D04   6  24  DX
    IS   26   7  2.32E-3
    * GAIN STAGE 1
    R31  31   0  1E6
    G31  31   0  POLY(2) (8,1) (12,0) 0 0 0 0 1E-6 0
    * GAIN STAGE 2
    R41  41  44  20E3
    C41  41  44  265.25E-15
    G41  41  44  0  31  1E-3
    D41  41  43  DX
    E41  44  43  POLY(1) (3,0) 100.2 14.87
    R42  41  45  20E3
    C42  41  45  265.25E-15
    G42  41  45  0  31  1E-3
    D42  42  41  DX
    E42  42  45  POLY(1)  (3,0) 100.2 14.87
    E43  44   0  6  0  20
    E44   0  45  0  7  20
    * OUTPUT STAGE
    E51  55  0 41 0 50E-3
    D53  55  51  DX
    D54  52  55  DX
    D55   6  53  DX
    D56   6  54  DX
    D57   7  53  DZ
    D58   7  54  DZ
    G54  53   7  5  55  50E-3
    G53  54   7  55  5  50E-3
    V53  51   5  0.1833
    V54   5  52  0.1833
    G51   5   6  6  55  50E-3
    G52   7   5  55   7  50E-3
    R53   6   5  20
    R54   7   5  20
    .MODEL N NPN (IS=1E-12 BF=193)
    .MODEL P PNP (IS=1E-12 BF=96)
    .MODEL  DX  D(IS=1E-15 BV=200)
    .MODEL  DZ  D(IS=1E-15 BV=50)
    .ENDS
    *$
    

  • 这是很老的一款器件了,是TI收购的BB公司的产品,官网已经查不到相关资料了 ,也没有spice模型可参考。

    建议更换其他产品,或者把您的应用需求说一下,帮您选择替代产品。

  • 用于设计激光器的驱动电路的双宽带跨导运算放大器
  • 我需要用于设计激光器驱动电路的跨导运算放大器,希望电路驱动能力够高
  • TI的跨导放大器有OPA861,OPA860,OPA615,LMH6601. 可以参考下面这个页面查阅:
    www.ti.com/.../products.html