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Holger Vogt 2021-08-20 20:19:03 +02:00
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438
examples/optran/OPA1611.LIB
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*$
* OPA1611
*************************************************************************************************
* (C) Copyright 2018 Texas Instruments Incorporated. All rights reserved.
*************************************************************************************************
** This model is designed as an aid for customers of Texas Instruments.
** TI and its licensors and suppliers make no warranties, either expressed
** or implied, with respect to this model, including the warranties of
** merchantability or fitness for a particular purpose. The model is
** provided solely on an "as is" basis. The entire risk as to its quality
** and performance is with the customer
*************************************************************************************************
*
* This model is subject to change without notice. Texas Instruments
* Incorporated is not responsible for updating this model.
*
*************************************************************************************************
*
** Released by: Online Design Tools, Texas Instruments Inc.
* Part: OPA1611
* Date: 07FEB2019
* Model Type: Generic (suitable for all analysis types)
* EVM Order Number: N/A
* EVM Users Guide: N/A
* Datasheet: SBOS450C -JULY 2009-REVISED AUGUST 2014
* Created with Green-Williams-Lis Op Amp Macro-model Architecture
*
* Model Version: Final 1.2
*
*****************************************************************************
*
* Updates:
*
* Final 1.2
* VOS drift feature is added
* Added Unique subckt name, removed Claw ABS.
*
* Final 1.1
* Release to Web.
*
****************************************************************************
* Model Usage Notes:
* 1. The following parameters are modeled:
* OPEN-LOOP GAIN AND PHASE VS. FREQUENCY WITH RL, CL EFFECTS (Aol)
* UNITY GAIN BANDWIDTH (GBW)
* INPUT COMMON-MODE REJECTION RATIO VS. FREQUENCY (CMRR)
* POWER SUPPLY REJECTION RATIO VS. FREQUENCY (PSRR)
* DIFFERENTIAL INPUT IMPEDANCE (Zid)
* COMMON-MODE INPUT IMPEDANCE (Zic)
* OPEN-LOOP OUTPUT IMPEDANCE VS. FREQUENCY (Zo)
* OUTPUT CURRENT THROUGH THE SUPPLY (Iout)
* INPUT VOLTAGE NOISE DENSITY VS. FREQUENCY (en)
* INPUT CURRENT NOISE DENSITY VS. FREQUENCY (in)
* OUTPUT VOLTAGE SWING vs. OUTPUT CURRENT (Vo)
* SHORT-CIRCUIT OUTPUT CURRENT (Isc)
* QUIESCENT CURRENT (Iq)
* SETTLING TIME VS. CAPACITIVE LOAD (ts)
* SLEW RATE (SR)
* SMALL SIGNAL OVERSHOOT VS. CAPACITIVE LOAD
* LARGE SIGNAL RESPONSE
* OVERLOAD RECOVERY TIME (tor)
* INPUT BIAS CURRENT (Ib)
* INPUT OFFSET CURRENT (Ios)
* INPUT OFFSET VOLTAGE (Vos)
* INPUT OFFSET VOLTAGE VS. TEMPERATURE (Vos Drift)
* INPUT COMMON-MODE VOLTAGE RANGE (Vcm)
* INPUT OFFSET VOLTAGE VS. INPUT COMMON-MODE VOLTAGE (Vos vs. Vcm)
* INPUT/OUTPUT ESD CELLS (ESDin, ESDout)
******************************************************
.subckt OPA1611 IN+ IN- VCC VEE OUT
******************************************************
.model R_NOISELESS RES (TCE=0 T_ABS=-273.15)
******************************************************
I_OS ESDn MID 3.5e-08
I_B 30 MID 6e-08
V_GRp 45 MID 48
V_GRn 46 MID -47
V_ISCp 39 MID 49.8
V_ISCn 40 MID -47
V_ORn 38 VCLP -13.759
V11 44 37 0
V_ORp 36 VCLP 13.6794
V12 43 35 0
V4 27 OUT 0
VCM_MIN 67 VEE_B 2
VCM_MAX 68 VCC_B -2
I_Q VCC VEE 0.0036
XV_OS 75 30 VOS_DRIFT_OPA1611
XU5 ESDp ESDn VCC VEE ESD_0_OPA1611
XU4 19 ESDp MID PSRR_CMRR_0_OPA1611
XU3 20 VEE_B MID PSRR_CMRR_1_OPA1611
XU2 21 VCC_B MID PSRR_CMRR_2_OPA1611
XU1 23 22 CLAMP VSENSE CLAW_CLAMP CL_CLAMP 24 26 27 MID AOL_ZO_0_OPA1611
C28 31 MID 1P
R77 32 31 R_NOISELESS 100
C27 33 MID 1P
R76 34 33 R_NOISELESS 100
R75 MID 35 R_NOISELESS 1
GVCCS8 35 MID 36 MID -1
R74 37 MID R_NOISELESS 1
GVCCS7 37 MID 38 MID -1
Xi_nn ESDn MID FEMT_0_OPA1611
Xi_np MID 30 FEMT_0_OPA1611
Xe_n ESDp 30 VNSE_0_OPA1611
XIQPos VIMON MID MID VCC VCCS_LIMIT_IQ_0_OPA1611
XIQNeg MID VIMON VEE MID VCCS_LIMIT_IQ_0_OPA1611
C_DIFF ESDp ESDn 8e-12
XCL_AMP 39 40 VIMON MID 41 42 CLAMP_AMP_LO_0_OPA1611
SOR_SWp CLAMP 43 CLAMP 43 S_VSWITCH_1
SOR_SWn 44 CLAMP 44 CLAMP S_VSWITCH_1
XGR_AMP 45 46 47 MID 48 49 CLAMP_AMP_HI_0_OPA1611
R39 45 MID R_NOISELESS 1G
R37 46 MID R_NOISELESS 1G
R42 VSENSE 47 R_NOISELESS 1M
C19 47 MID 1F
R38 48 MID R_NOISELESS 1
R36 MID 49 R_NOISELESS 1
R40 48 50 R_NOISELESS 1M
R41 49 51 R_NOISELESS 1M
C17 50 MID 1F
C18 MID 51 1F
XGR_SRC 50 51 CLAMP MID VCCS_LIM_GR_0_OPA1611
R21 41 MID R_NOISELESS 1
R20 MID 42 R_NOISELESS 1
R29 41 52 R_NOISELESS 1M
R30 42 53 R_NOISELESS 1M
C9 52 MID 1F
C8 MID 53 1F
XCL_SRC 52 53 CL_CLAMP MID VCCS_LIM_4_0_OPA1611
R22 39 MID R_NOISELESS 1G
R19 MID 40 R_NOISELESS 1G
XCLAWp VIMON MID 54 VCC_B VCCS_LIM_CLAW+_0_OPA1611
XCLAWn MID VIMON VEE_B 55 VCCS_LIM_CLAW-_0_OPA1611
R12 54 VCC_B R_NOISELESS 1K
R16 54 56 R_NOISELESS 1M
R13 VEE_B 55 R_NOISELESS 1K
R17 57 55 R_NOISELESS 1M
C6 57 MID 1F
C5 MID 56 1F
G2 VCC_CLP MID 56 MID -1M
R15 VCC_CLP MID R_NOISELESS 1K
G3 VEE_CLP MID 57 MID -1M
R14 MID VEE_CLP R_NOISELESS 1K
XCLAW_AMP VCC_CLP VEE_CLP VOUT_S MID 58 59 CLAMP_AMP_LO_0_OPA1611
R26 VCC_CLP MID R_NOISELESS 1G
R23 VEE_CLP MID R_NOISELESS 1G
R25 58 MID R_NOISELESS 1
R24 MID 59 R_NOISELESS 1
R27 58 60 R_NOISELESS 1M
R28 59 61 R_NOISELESS 1M
C11 60 MID 1F
C10 MID 61 1F
XCLAW_SRC 60 61 CLAW_CLAMP MID VCCS_LIM_3_0_OPA1611
H2 34 MID V11 -1
H3 32 MID V12 1
C12 SW_OL MID 100P
R32 62 SW_OL R_NOISELESS 100
R31 62 MID R_NOISELESS 1
XOL_SENSE MID 62 33 31 OL_SENSE_0_OPA1611
S1 24 26 SW_OL MID S_VSWITCH_3
H1 63 MID V4 1K
S7 VEE OUT VEE OUT S_VSWITCH_4
S6 OUT VCC OUT VCC S_VSWITCH_4
R11 MID 64 R_NOISELESS 1G
R18 64 VOUT_S R_NOISELESS 100
C7 VOUT_S MID 10P
E5 64 MID OUT MID 1
C13 VIMON MID 10P
R33 63 VIMON R_NOISELESS 100
R10 MID 63 R_NOISELESS 1G
R47 65 VCLP R_NOISELESS 100
C24 VCLP MID 10P
E4 65 MID CL_CLAMP MID 1
C4 23 MID 1F
R9 23 66 R_NOISELESS 1M
R7 MID 67 R_NOISELESS 1G
R6 68 MID R_NOISELESS 1G
R8 MID 66 R_NOISELESS 1
XVCM_CLAMP 69 MID 66 MID 68 67 VCCS_EXT_LIM_0_OPA1611
E1 MID 0 70 0 1
R89 VEE_B 0 R_NOISELESS 1
R5 71 VEE_B R_NOISELESS 1M
C3 71 0 1F
R60 70 71 R_NOISELESS 1MEG
C1 70 0 1
R3 70 0 R_NOISELESS 1G
R59 72 70 R_NOISELESS 1MEG
C2 72 0 1F
R4 VCC_B 72 R_NOISELESS 1M
R88 VCC_B 0 R_NOISELESS 1
G17 VEE_B 0 VEE 0 -1
G16 VCC_B 0 VCC 0 -1
R_PSR 73 69 R_NOISELESS 1K
G_PSR 69 73 21 20 -1M
R2 22 ESDn R_NOISELESS 1M
R1 73 74 R_NOISELESS 1M
R_CMR 75 74 R_NOISELESS 1K
G_CMR 74 75 19 MID -1M
C_CMn ESDn MID 2e-12
C_CMp MID ESDp 2e-12
R53 ESDn MID R_NOISELESS 1T
R52 MID ESDp R_NOISELESS 1T
R35 IN- ESDn R_NOISELESS 10M
R34 IN+ ESDp R_NOISELESS 10M
.MODEL S_VSWITCH_1 VSWITCH (RON=10e-3 ROFF=1e9 VON=10e-3 VOFF=0)
.MODEL S_VSWITCH_3 VSWITCH (RON=1e-3 ROFF=1e9 VON=900e-3 VOFF=800e-3)
.MODEL S_VSWITCH_4 VSWITCH (RON=50 ROFF=1e12 VON=500e-3 VOFF=450e-3)
.ENDS OPA1611
*
.SUBCKT VOS_DRIFT_OPA1611 VOS+ VOS-
.PARAM DC = 9.729e-05
.PARAM POL = 1
.PARAM DRIFT = 1E-06
E1 VOS+ VOS- VALUE={DC+POL*DRIFT*(TEMP-27)}
.ENDS
*
.SUBCKT ESD_0_OPA1611 ESDp ESDn VCC VEE
SW6 ESDn ESDp ESDn ESDp S_VSWITCH_1
SW5 ESDp ESDn ESDp ESDn S_VSWITCH_1
SW4 ESDn VCC ESDn VCC S_VSWITCH_3
SW3 VEE ESDn VEE ESDn S_VSWITCH_3
SW2 ESDp VCC ESDp VCC S_VSWITCH_3
SW1 VEE ESDp VEE ESDp S_VSWITCH_3
.MODEL S_VSWITCH_1 VSWITCH (RON=50 ROFF=1e12 VON=700e-3 VOFF=650e-3)
.MODEL S_VSWITCH_3 VSWITCH (RON=50 ROFF=1e12 VON=500e-3 VOFF=450e-3)
.ENDS
*
.SUBCKT PSRR_CMRR_0_OPA1611 psrr_in psrr_vccb mid
.model R_NOISELESS RES ( TCE=0 T_ABS=-273.15)
R74 mid psrr_in R_NOISELESS 1
G_2 psrr_in mid 4 mid -140.513
R2b mid 4 R_NOISELESS 716778.969
C2a 4 5 2.2044e-14
R73 5 4 R_NOISELESS 100MEG
R49 mid 5 R_NOISELESS 1
GVCCS7 5 mid 6 mid -1
R2a mid 6 R_NOISELESS 716778.969
C1a 6 7 2.2044e-14
R48 7 6 R_NOISELESS 100MEG
G_1 7 mid psrr_vccb mid -0.00016265
Rsrc mid 7 R_NOISELESS 1
.ENDS
*
.SUBCKT PSRR_CMRR_1_OPA1611 psrr_in psrr_vccb psrr_mid
.model R_NOISELESS RES ( TCE=0 T_ABS=-273.15)
R80 psrr_mid psrr_in R_NOISELESS 79.383
C27 psrr_in 4 2.1432e-10
R79 4 psrr_in R_NOISELESS 100MEG
GVCCS8 4 psrr_mid psrr_vccb psrr_mid -0.11572
R78 psrr_mid 4 R_NOISELESS 1
.ENDS
*
.SUBCKT PSRR_CMRR_2_OPA1611 psrr_in psrr_vccb psrr_mid
.model R_NOISELESS RES ( TCE=0 T_ABS=-273.15)
R80 psrr_mid psrr_in R_NOISELESS 74.0813
C27 psrr_in 4 3.1831e-10
R79 4 psrr_in R_NOISELESS 100MEG
GVCCS8 4 psrr_mid psrr_vccb psrr_mid -0.12195
R78 psrr_mid 4 R_NOISELESS 1
.ENDS
*
.SUBCKT VCCS_LIM_2_0_OPA1611 VC+ VC- IOUT+ IOUT-
.PARAM GAIN = 0.0053649
.PARAM IPOS = 0.028032
.PARAM INEG = -0.027711
G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}
.ENDS
*
.SUBCKT VCCS_LIM_1_0_OPA1611 VC+ VC- IOUT+ IOUT-
.PARAM GAIN = 1E-4
.PARAM IPOS = .5
.PARAM INEG = -.5
G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}
.ENDS
*
.SUBCKT AOL_ZO_0_OPA1611 AOL_INP AOL_INN CLAMP VSENSE CLAW_CLAMP CL_CLAMP ZO_CLEFT ZO_CRIGHT ZO_OUT MID
.MODEL R_NOISELESS RES ( TCE=0 T_ABS=-273.15)
C1_A0 CLAMP MID 9.2525e-10
R4_A0 MID CLAMP R_NOISELESS 1MEG
XVCCS_LIM_2_A0 4_A0 MID MID CLAMP VCCS_LIM_2_0_OPA1611
R3_A0 MID 4_A0 R_NOISELESS 1MEG
XVCCS_LIM_1_A0 AOL_INP AOL_INN MID 4_A0 VCCS_LIM_1_0_OPA1611
R4_VS VSENSE MID R_NOISELESS 1K
GVCCS4_VS VSENSE MID CLAMP MID -1M
C2_A2 out2 MID 2.316e-14
R3_A2 out2 MID R_NOISELESS 1MEG
GVCCS3_A2 out2 MID VSENSE MID -1U
C3_A3 4_A3 out3 1.061e-13
GVCCS4_A3 4_A3 MID out2 MID -21.5263
R4_A3 4_A3 MID R_NOISELESS 1
R5_A3 out3 4_A3 R_NOISELESS 10K
R6_A3 out3 MID R_NOISELESS 487.1795
C3_A4 4_A4 out4 1.4283e-12
GVCCS4_A4 4_A4 MID out3 MID -21.5263
R4_A4 4_A4 MID R_NOISELESS 1
R5_A4 out4 4_A4 R_NOISELESS 10K
R6_A4 out4 MID R_NOISELESS 487.1795
R4_CC CLAW_CLAMP MID R_NOISELESS 1K
GVCCS4_CC CLAW_CLAMP MID out4 MID -1M
R4_CL CL_CLAMP MID R_NOISELESS 1K
GVCCS4_CL CL_CLAMP MID CLAW_CLAMP MID -1M
G_Aol_Zo Zo_Cleft MID CL_CLAMP ZO_OUT -89.0524
GVCCS1_1 outz1 MID Zo_Cright MID -270.7824
C1_1 Zo_Cleft Zo_Cright 1.1766e-07
R2_1 Zo_Cright MID R_NOISELESS 37.0669
R1_1 Zo_Cright Zo_Cleft R_NOISELESS 10K
Rdc_1 Zo_Cleft MID R_NOISELESS 1
GVCCS2_2 outz2 MID net2 MID -1
C2_2 5_2 MID 1.1756e-12
R5_2 net2 5_2 R_NOISELESS 10K
R4_2 net2 outz1 R_NOISELESS 1312633.434
R7_2 outz1 MID R_NOISELESS 1
R1_3 2_3 MID R_NOISELESS 1
R11_3 5_3 MID R_NOISELESS 9.2681
C4_3 5_3 outz2 4.138e-13
R10_3 5_3 outz2 R_NOISELESS 10K
XVCVS_LIM_1 5_3 MID MID 2_3 VCCS_LIM_ZO_0_OPA1611
R9_3 outz2 MID R_NOISELESS 1
Rdummy MID ZO_OUT R_NOISELESS 1410
Rx ZO_OUT 2_3 R_NOISELESS 14100
.ENDS
*
.SUBCKT VCCS_LIM_ZO_0_OPA1611 VC+ VC- IOUT+ IOUT-
.PARAM GAIN = 1079.9748
.PARAM IPOS = 1551
.PARAM INEG = -1748.4
G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}
.ENDS
*
.SUBCKT FEMT_0_OPA1611 1 2
.PARAM FLWF=0.1
.PARAM NLFF=39529.1
.PARAM NVRF=1683.74
.PARAM GLFF={PWR(FLWF,0.25)*NLFF/1164}
.PARAM RNVF={1.184*PWR(NVRF,2)}
.MODEL DVNF D KF={PWR(FLWF,0.5)/1E11} IS=1.0E-16
I1 0 7 10E-3
I2 0 8 10E-3
D1 7 0 DVNF
D2 8 0 DVNF
E1 3 6 7 8 {GLFF}
R1 3 0 1E9
R2 3 0 1E9
R3 3 6 1E9
E2 6 4 5 0 10
R4 5 0 {RNVF}
R5 5 0 {RNVF}
R6 3 4 1E9
R7 4 0 1E9
G1 1 2 3 4 1E-6
.ENDS
*
.SUBCKT VNSE_0_OPA1611 1 2
.PARAM FLW=0.1
.PARAM NLF=23.8513
.PARAM NVR=1.24
.PARAM GLF={PWR(FLW,0.25)*NLF/1164}
.PARAM RNV={1.184*PWR(NVR,2)}
.MODEL DVN D KF={PWR(FLW,0.5)/1E11} IS=1.0E-16
I1 0 7 10E-3
I2 0 8 10E-3
D1 7 0 DVN
D2 8 0 DVN
E1 3 6 7 8 {GLF}
R1 3 0 1E9
R2 3 0 1E9
R3 3 6 1E9
E2 6 4 5 0 10
R4 5 0 {RNV}
R5 5 0 {RNV}
R6 3 4 1E9
R7 4 0 1E9
E3 1 2 3 4 1
.ENDS
*
.SUBCKT VCCS_LIMIT_IQ_0_OPA1611 VC+ VC- IOUT+ IOUT-
.PARAM GAIN = 1E-3
G1 IOUT- IOUT+ VALUE={IF( (V(VC+,VC-)<=0),0,GAIN*V(VC+,VC-) )}
.ENDS
*
.SUBCKT CLAMP_AMP_LO_0_OPA1611 VC+ VC- VIN COM VO+ VO-
.PARAM G=1
GVO+ COM VO+ VALUE = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}
GVO- COM VO- VALUE = {IF(V(VIN,COM)<V(VC-,COM),((V(VC-,COM)-V(VIN,COM))*G),0)}
.ENDS
*
.SUBCKT CLAMP_AMP_HI_0_OPA1611 VC+ VC- VIN COM VO+ VO-
.PARAM G=10
GVO+ COM VO+ VALUE = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}
GVO- COM VO- VALUE = {IF(V(VIN,COM)<V(VC-,COM),((V(VC-,COM)-V(VIN,COM))*G),0)}
.ENDS
*
.SUBCKT VCCS_LIM_GR_0_OPA1611 VC+ VC- IOUT+ IOUT-
.PARAM GAIN = 1
.PARAM IPOS = 0.056064
.PARAM INEG = -0.056064
G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}
.ENDS
*
.SUBCKT VCCS_LIM_4_0_OPA1611 VC+ VC- IOUT+ IOUT-
.PARAM GAIN = 1
.PARAM IPOS = 0.2016
.PARAM INEG = -0.1974
G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}
.ENDS
*
.SUBCKT VCCS_LIM_CLAW+_0_OPA1611 VC+ VC- IOUT+ IOUT-
G1 IOUT+ IOUT- TABLE {(V(VC+,VC-))} =
+(0, 2.1334E-4)
+(48.1473, 0.001)
+(49.2541, 0.0012)
+(49.8, 0.0013)
.ENDS
*
.SUBCKT VCCS_LIM_CLAW-_0_OPA1611 VC+ VC- IOUT+ IOUT-
G1 IOUT+ IOUT- TABLE {(V(VC+,VC-))} =
+(0, 2.1349E-4)
+(45.4769, 0.0008314)
+(46.5224, 0.00085953)
+(47, 0.0010745)
.ENDS
*
.SUBCKT VCCS_LIM_3_0_OPA1611 VC+ VC- IOUT+ IOUT-
.PARAM GAIN = 1
.PARAM IPOS = 0.1008
.PARAM INEG = -0.0987
G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}
.ENDS
*
.SUBCKT OL_SENSE_0_OPA1611 COM SW+ OLN OLP
GSW+ COM SW+ VALUE = {IF((V(OLN,COM)>10E-3 | V(OLP,COM)>10E-3),1,0)}
.ENDS
*
.SUBCKT VCCS_EXT_LIM_0_OPA1611 VIN+ VIN- IOUT- IOUT+ VP+ VP-
.PARAM GAIN = 1
G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VIN+,VIN-),V(VP-,VIN-), V(VP+,VIN-))}
.ENDS
*

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examples/optran/TL072.301
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* TL072 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT
* CREATED USING PARTS RELEASE 4.01 ON 06/16/89 AT 13:08
* (REV N/A) SUPPLY VOLTAGE: +/-15V
* CONNECTIONS: NON-INVERTING INPUT
* | INVERTING INPUT
* | | POSITIVE POWER SUPPLY
* | | | NEGATIVE POWER SUPPLY
* | | | | OUTPUT
* | | | | |
.SUBCKT TL072 1 2 3 4 5
*
C1 11 12 3.498E-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 4.715E6 -5E6 5E6 5E6 -5E6
GA 6 0 11 12 282.8E-6
GCM 0 6 10 99 8.942E-9
ISS 3 10 DC 195.0E-6
HLIM 90 0 VLIM 1K
J1 11 2 10 JX
J2 12 1 10 JX
R2 6 9 100.0E3
RD1 4 11 3.536E3
RD2 4 12 3.536E3
RO1 8 5 150
RO2 7 99 150
RP 3 4 2.143E3
RSS 10 99 1.026E6
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 25
VLN 0 92 DC 25
.MODEL DX D(IS=800.0E-18)
.MODEL JX PJF(IS=15.00E-12 BETA=270.1E-6 VTO=-1)
.ENDS

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examples/optran/opa1656.lib
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* OPA1656 - Rev. A
* Created by Alexander Davis; February 01, 2019
* Created with Green-Williams-Lis Op Amp Macro-model Architecture
* Copyright 2019 by Texas Instruments Corporation
******************************************************
* MACRO-MODEL SIMULATED PARAMETERS:
******************************************************
* OPEN-LOOP GAIN AND PHASE VS. FREQUENCY WITH RL, CL EFFECTS (Aol)
* UNITY GAIN BANDWIDTH (GBW)
* INPUT COMMON-MODE REJECTION RATIO VS. FREQUENCY (CMRR)
* POWER SUPPLY REJECTION RATIO VS. FREQUENCY (PSRR)
* DIFFERENTIAL INPUT IMPEDANCE (Zid)
* COMMON-MODE INPUT IMPEDANCE (Zic)
* OPEN-LOOP OUTPUT IMPEDANCE VS. FREQUENCY (Zo)
* OUTPUT CURRENT THROUGH THE SUPPLY (Iout)
* INPUT VOLTAGE NOISE DENSITY VS. FREQUENCY (en)
* INPUT CURRENT NOISE DENSITY VS. FREQUENCY (in)
* OUTPUT VOLTAGE SWING vs. OUTPUT CURRENT (Vo)
* SHORT-CIRCUIT OUTPUT CURRENT (Isc)
* QUIESCENT CURRENT (Iq)
* SETTLING TIME VS. CAPACITIVE LOAD (ts)
* SLEW RATE (SR)
* SMALL SIGNAL OVERSHOOT VS. CAPACITIVE LOAD
* LARGE SIGNAL RESPONSE
* OVERLOAD RECOVERY TIME (tor)
* INPUT BIAS CURRENT (Ib)
* INPUT OFFSET CURRENT (Ios)
* INPUT OFFSET VOLTAGE (Vos)
* INPUT OFFSET VOLTAGE VS. TEMPERATURE (Vos Drift)
* INPUT COMMON-MODE VOLTAGE RANGE (Vcm)
* INPUT OFFSET VOLTAGE VS. INPUT COMMON-MODE VOLTAGE (Vos vs. Vcm)
* INPUT/OUTPUT ESD CELLS (ESDin, ESDout)
******************************************************
.subckt OPA1656 IN+ IN- VCC VEE OUT
******************************************************
.MODEL R_NOISELESS RES (T_ABS=-273.15)
***
.MODEL R_OS RES (TC1=14.9E-3)
C_C10 MID N45892 1e-15 TC=0,0
C_C11 MID N61579 1e-15 TC=0,0
C_C12 MID N56659 1e-15 TC=0,0
C_C13 MID N42834 1e-15 TC=0,0
C_C14 N45974 MID 1e-15 TC=0,0
C_C15 N56721 MID 1e-15 TC=0,0
C_C16 MID N38096 1e-15 TC=0,0
C_C17 N44757 MID 1e-15 TC=0,0
C_C18 N31014 MID 1e-15 TC=0,0
C_C19 CLAMP MID 2.07e-7 TC=0,0
C_C1a3 N680862 N680892 1.03e-13 TC=0,0
C_C1a4 N704730 N704760 3.79e-13 TC=0,0
C_C1a5 N687495 N199178 1.06e-10 TC=0,0
C_C1b3 N680920 N680950 1.38e-14 TC=0,0
C_C1b4 N704788 N704818 1.83e-13 TC=0,0
C_C20 MID VIMON 1e-9 TC=0,0
C_C21 MID VOUT_S 1e-9 TC=0,0
C_C22 N716437 N716973 6.24E-15 TC=0,0
C_C23 MID N716729 4.24E-12 TC=0,0
C_C24 N573889 N573900 7.96e-7 TC=0,0
C_C25 N673376 N673398 3.18e-14 TC=0,0
C_C26 0 N673332 1.06e-11 TC=0,0
C_C27 0 N673526 1.59e-12 TC=0,0
C_C28 MID N716825 2.95E-16 TC=0,0
C_C29 MID N716679 2.95E-16 TC=0,0
C_C30 MID N576238 2.95E-16 TC=0,0
C_C31 MID N68747 1e-12 TC=0,0
C_C32 VCLP MID 4.613e-15 TC=0,0
C_C33 N406634 0 1e-15 TC=0,0
C_C34 N317950 0 1 TC=0,0
C_C35 N406794 0 1e-15 TC=0,0
C_C36 MID SW_OL 1e-12 TC=0,0
C_C37 MID N68594 1e-12
C_C9 MID N35813 1e-15 TC=0,0
C_C_CMn1 MID ESDN 1.9e-12 TC=0,0
C_C_CMp1 ESDP MID 1.9e-12 TC=0,0
C_C_DIFF1 ESDN ESDP 9.1e-12 TC=0,0
E_E1 N112292 MID OUT MID 1
E_E2 MID 0 N317950 0 0.5
E_E3 N91498 MID CL_CLAMP MID 1
E_E_VOS1 N10561 N06456 N637521 MID 1
G_G24 N680862 MID ESDP MID -4.84e-4
G_G25 N680920 MID N680892 MID -1
G_G26 CMR MID N680950 MID -6.52e1
G_G27 PSRP MID N704818 MID -1.72e3
G_G28 N704788 MID N704760 MID -1
G_G29 N704730 MID VCC_B MID -3.16e-4
G_G30 VCC_CLP MID N35813 MID -1E-3
G_G31 N73852 MID N55875 MID -1
G_G32 N55050 MID N56119 MID -1
G_G33 N10570 N10561 CMR MID -1e-3
G_G34 N687495 MID VEE_B MID -8.43e-1
G_G35 VEE_CLP MID N38096 MID -1E-3
G_G36 N25816 N11984 PSRP N199178 -1e-3
G_G37 VSENSE MID CLAMP MID -1e-3
G_G38 N716707 MID VSENSE MID -1
G_G39 N716973 MID N716721 MID -1.4386E+01
G_G40 N573889 0 CL_CLAMP N516723 -9.06e1
G_G41 N673298 0 N573900 0 -7e2
G_G42 N673376 0 N673518 0 -1
G_G43 N716679 MID N716825 MID -1e-6
G_G44 N716825 MID N716437 MID -1e-6
G_G45 N576238 MID N716679 MID -1e-6
G_G46 CLAW_CLAMP MID N576238 MID -1e-3
G_G47 CL_CLAMP MID CLAW_CLAMP MID -1e-3
G_G48 VCC_B 0 VCC 0 -1
G_G49 VEE_B 0 VEE 0 -1
G_Gc2 N673504 0 N673324 0 -1
I_I_B1 N06456 MID DC 5e-12
I_I_OS1 ESDN MID DC 3e-12
I_I_Q1 VCC VEE DC 4e-3
I_I_VOS1 MID N618113 DC 33.557u
R_R100 ESDN IN- R_NOISELESS 250
R_R101 N716973 MID R_NOISELESS 1
R_R102 N716437 MID R_NOISELESS 7.00E+04
R_R103 ESDN N11991 R_NOISELESS 1e-3
R_R104 N673518 N673504 R_NOISELESS 6.67e2
R_R105 ESDN MID R_NOISELESS 1e12
R_R106 N673332 N673324 R_NOISELESS 1e4
R_R107 N673526 N673518 R_NOISELESS 1e3
R_R108 N673398 N673376 R_NOISELESS 1e4
R_R109 0 N573889 R_NOISELESS 1
R_R110 0 N573900 R_NOISELESS 1.43e2
R_R111 0 N673298 R_NOISELESS 1
R_R112 0 N673504 R_NOISELESS 1
R_R113 0 N673376 R_NOISELESS 1
R_R114 0 N673398 R_NOISELESS 1.01e2
R_R115 0 N673446 R_NOISELESS 1
R_R116 N716825 MID R_NOISELESS 1e6
R_R117 N716679 MID R_NOISELESS 1e6
R_R118 N576238 MID R_NOISELESS 1e6
R_R119 N68747 OLN R_NOISELESS 100
R_R120 MID CLAW_CLAMP R_NOISELESS 1e3
R_R121 MID CL_CLAMP R_NOISELESS 1e3
R_R122 N91498 VCLP R_NOISELESS 1e6
R_R123 VCC_B N406634 R_NOISELESS 1e-3
R_R124 N406634 N317950 R_NOISELESS 1e6
R_R125 N317950 N406794 R_NOISELESS 1e6
R_R126 N406794 VEE_B R_NOISELESS 1e-3
R_R127 N69264 SW_OL R_NOISELESS 100
R_R128 VCC_B 0 R_NOISELESS 1
R_R129 N317950 0 R_NOISELESS 1e12
R_R130 VEE_B 0 R_NOISELESS 1
R_R131 N68594 OLP R_NOISELESS 100
R_R132 N69264 MID R_NOISELESS 1
R_R1a3 N680862 N680892 R_NOISELESS 1e8
R_R1a4 N704730 N704760 R_NOISELESS 1e8
R_R1a5 N687495 N199178 R_NOISELESS 1e8
R_R1a6 N573900 N573889 R_NOISELESS 1e5
R_R1b3 N680920 N680950 R_NOISELESS 1e8
R_R1b4 N704788 N704818 R_NOISELESS 1e8
R_R2a3 N680892 MID R_NOISELESS 2.07e5
R_R2a4 N704760 MID R_NOISELESS 1e5
R_R2a5 N199178 MID R_NOISELESS 3.75e1
R_R2b3 N680950 MID R_NOISELESS 1.56e6
R_R2b4 N704818 MID R_NOISELESS 5.8e4
R_R2b5 N673324 N673298 R_NOISELESS 7.4e5
R_R46 N680862 MID R_NOISELESS 1
R_R47 N680920 MID R_NOISELESS 1
R_R48 CMR MID R_NOISELESS 1
R_R49 PSRP MID R_NOISELESS 1
R_R50 N704788 MID R_NOISELESS 1
R_R51 N704730 MID R_NOISELESS 1
R_R52 MID N50645 R_NOISELESS 1e9
R_R53 MID N56919 R_NOISELESS 1e9
R_R54 N35669 VCC_B R_NOISELESS 1e3
R_R55 VCC_CLP MID R_NOISELESS 1e3
R_R56 MID VCC_CLP R_NOISELESS 1e9
R_R57 N45856 MID R_NOISELESS 1
R_R58 N35813 N35669 R_NOISELESS 1e-3
R_R59 N42663 MID R_NOISELESS 1
R_R60 N61579 VSENSE R_NOISELESS 1e-3
R_R61 N42834 N42663 R_NOISELESS 1e-3
R_R62 N56635 MID R_NOISELESS 1
R_R63 N45892 N45856 R_NOISELESS 1e-3
R_R64 N45974 N45986 R_NOISELESS 1e-3
R_R65 N56659 N56635 R_NOISELESS 1e-3
R_R66 N38096 N38050 R_NOISELESS 1e-3
R_R67 N44757 N44799 R_NOISELESS 1e-3
R_R68 MID N73852 R_NOISELESS 1
R_R69 MID N45986 R_NOISELESS 1
R_R70 MID N55050 R_NOISELESS 1
R_R71 N56721 N56733 R_NOISELESS 1e-3
R_R72 MID N56733 R_NOISELESS 1
R_R73 N38050 VEE_B R_NOISELESS 1e3
R_R74 N10561 N10570 R_NOISELESS 1e3
R_R75 VEE_CLP MID R_NOISELESS 1e3
R_R76 MID N44799 R_NOISELESS 1
R_R77 N687495 MID R_NOISELESS 1
R_R78 MID N48550 R_NOISELESS 1e9
R_R79 MID N56891 R_NOISELESS 1e9
R_R80 N11984 N25816 R_NOISELESS 1e3
R_R81 MID VEE_CLP R_NOISELESS 1e9
R_R82 MID ESDP R_NOISELESS 1e12
R_R83 N30136 MID R_NOISELESS 1e9
R_R84 N31014 N30913 R_NOISELESS 1e-3
R_R85 ESDP IN+ R_NOISELESS 250
R_R86 N10570 N11984 R_NOISELESS 1e-3
R_R87 MID N30913 R_NOISELESS 1
R_R88 MID AOL_1 R_NOISELESS 1e6
R_R89 MID CLAMP R_NOISELESS 1e6
R_R90 MID VSENSE R_NOISELESS 1e3
R_R91 MID N28602 R_NOISELESS 1e9
R_R92 N716721 N716707 R_NOISELESS 1.64E+04
R_R93 N716729 N716721 R_NOISELESS 1e4
R_R94 VIMON N110431 R_NOISELESS 100
R_R95 VOUT_S N112292 R_NOISELESS 100
R_R96 N716973 N716437 R_NOISELESS 1e6
R_R97 MID N110431 R_NOISELESS 1e9
R_R98 MID N112292 R_NOISELESS 1e9
R_R99 MID N716707 R_NOISELESS 1
R_R_VOS1 N618113 MID R_OS 1
R_Rdummy2 0 N516723 R_NOISELESS 3.15e3
R_Rx2 N516723 N673446 R_NOISELESS 3.14e4
V_V5 N637521 N618113 455.087u
V_V_GRN1 N56891 MID -85
V_V_GRP1 N56919 MID 80
V_V_ISCN1 N48550 MID -130
V_V_ISCP1 N50645 MID 117
V_V_ORN1 N55875 VCLP -2.3
V_V_ORP1 N56119 VCLP 2.15
V_VCM_MAX1 N30136 VCC_B -2
V_VCM_MIN1 N28602 VEE_B 0
X_AOL_1_OPA1656 N31014 N11991 MID AOL_1 AOL_1_OPA1656
X_AOL_2_OPA1656 AOL_1 MID MID CLAMP AOL_2_OPA1656
X_CL_AMP1_OPA1656 N50645 N48550 VIMON MID N45856 N45986 CLAMP_AMP_LO_OPA1656
X_CL_SRC1_OPA1656 N45892 N45974 CL_CLAMP MID CL_SRC_OPA1656
X_CLAW_AMP1_OPA1656 VCC_CLP VEE_CLP VOUT_S MID N42663 N44799 CLAMP_AMP_LO_OPA1656
X_CLAW_SRC1_OPA1656 N42834 N44757 CLAW_CLAMP MID CLAW_SRC_OPA1656
X_CLAWN1_OPA1656 MID VIMON VEE_B N38050 CLAWN_OPA1656
X_CLAWP1_OPA1656 VIMON MID N35669 VCC_B CLAWP_OPA1656
X_e_n1_OPA1656 ESDP N06456 VNSE_OPA1656
X_ESD_IN1_OPA1656 ESDN ESDP VCC VEE ESD_IN_OPA1656
X_ESD_OUT1_OPA1656 OUT VCC VEE ESD_OUT_OPA1656
X_GR_AMP1_OPA1656 N56919 N56891 N61579 MID N56635 N56733 CLAMP_AMP_HI_OPA1656
X_GR_SRC1_OPA1656 N56659 N56721 CLAMP MID GR_SRC_OPA1656
X_H2_OPA1656 N73852 N166377 OLN MID 08_Op_Amp_Complete_H2_OPA1656
X_H3_OPA1656 N55050 N166817 OLP MID 08_Op_Amp_Complete_H3_OPA1656
X_H4_OPA1656 OUT N516723 N110431 MID 08_Op_Amp_Complete_H4_OPA1656
X_i_nn1_OPA1656 ESDN MID FEMT_OPA1656
X_i_np1_OPA1656 N06456 MID FEMT_OPA1656
X_IQ_N1_OPA1656 MID VIMON MID VEE IQ_SRC_OPA1656
X_IQ_P1_OPA1656 VIMON MID VCC MID IQ_SRC_OPA1656
X_OL_SENSE1_OPA1656 MID N69264 N68747 N68594 OL_SENSE_OPA1656
X_SW_OL1_OPA1656 SW_OL MID N573889 N573900 SW_OL_OPA1656
X_SW_OR1_OPA1656 CLAMP N166377 N166817 SW_OR_OPA1656
X_U3_OPA1656 N673398 0 0 N673446 ZO_SRC_OPA1656
X_U4_OPA1656 ESDN ESDP ESD_BB_OPA1656
X_VCM_CLAMP1_OPA1656 N25816 MID N30913 MID N30136 N28602 VCM_CLAMP_OPA1656
.ENDS OPA1656
.subckt 08_Op_Amp_Complete_H4_OPA1656 1 2 3 4
H_H4 3 4 VH_H4 -1e3
VH_H4 1 2 0V
.ends 08_Op_Amp_Complete_H4_OPA1656
.subckt 08_Op_Amp_Complete_H3_OPA1656 1 2 3 4
H_H3 3 4 VH_H3 -1
VH_H3 1 2 0V
.ends 08_Op_Amp_Complete_H3_OPA1656
.subckt 08_Op_Amp_Complete_H2_OPA1656 1 2 3 4
H_H2 3 4 VH_H2 -1
VH_H2 1 2 0V
.ends 08_Op_Amp_Complete_H2_OPA1656
*$
.subckt AOL_1_OPA1656 VC+ VC- IOUT+ IOUT-
.param Gain = 1e-4
.param Ipos = .5
.param Ineg = -.5
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}
.ends
*$
*
.subckt AOL_2_OPA1656 VC+ VC- IOUT+ IOUT-
.param Gain = 6.5e-1
.param Ipos = 5.1957
.param Ineg = -5.1957
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}
.ends
*$
.subckt AOL_2_EN_OPA1656 VC+ VC- IOUT+ IOUT- EN MID
.param Gain = 2.03e-2
.param Ipos = 0.143
.param Ineg = -0.143
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(EN,MID)*V(VC+,VC-),Ineg,Ipos)}
.ends
*$
*
.subckt CLAMP_AMP_HI_OPA1656 VC+ VC- VIN COM VO+ VO-
.param G=10
* Output G(COM,0) when condition not met
GVo+ COM Vo+ Value = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}
GVo- COM Vo- Value = {IF(V(VIN,COM)<V(VC-,COM),((V(VC-,COM)-V(VIN,COM))*G),0)}
.ends
*$
*
.subckt CLAMP_AMP_LO_OPA1656 VC+ VC- VIN COM VO+ VO-
.param G=1
* Output G(COM,0) when condition not met
GVo+ COM Vo+ Value = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}
GVo- COM Vo- Value = {IF(V(VIN,COM)<V(VC-,COM),((V(VC-,COM)-V(VIN,COM))*G),0)}
.ends
*$
*
.subckt CLAWn_OPA1656 VC+ VC- IOUT+ IOUT-
G1 IOUT+ IOUT- TABLE {abs(V(VC+,VC-))} =
+(0,3.00E-05)
+(40,7.10E-04)
+(80,1.45E-03)
+(100,1.86E-03)
+(120,2.31E-03)
+(123,2.39E-03)
+(125,2.46E-03)
+(126,2.55E-03)
+(127,2.48E-02)
+(130,3.17E-02)
.ends
*$
*
.subckt CLAWp_OPA1656 VC+ VC- IOUT+ IOUT-
G1 IOUT+ IOUT- TABLE {abs(V(VC+,VC-))} =
+(000, 4.00E-05)
+(040, 9.10E-04)
+(080, 2.00E-03)
+(095, 2.57E-03)
+(105, 3.12E-03)
+(107, 3.28E-03)
+(110, 3.75E-03)
+(111, 4.37E-03)
+(112, 6.82E-03)
+(117, 3.08E-02)
.ends
*$
*
.subckt CLAW_SRC_OPA1656 VC+ VC- IOUT+ IOUT-
.param Gain = 1
.param Ipos = 0.180
.param Ineg = -0.180
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}
.ends
*$
*
.subckt CL_SRC_OPA1656 VC+ VC- IOUT+ IOUT-
.param Gain = 1
.param Ipos = 0.4
.param Ineg = -0.4
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}
.ends
*$
*
.SUBCKT CNTL EN_IN VCC VEE MID OUT GND
.param VSmax = 40
.param VSmin = 4
.param ENLH = 0.82
E1 N1 MID VALUE = {IF(V(VCC,VEE)<=VSmax & V(VCC,VEE)>=VSmin & V(EN_IN,GND)>=ENLH, 1, 0)}
RS1 N1 N2 5k
RS2 N1 N3 50
D1 N2 N3 DD
.MODEL DD D RS=0.001 N = 0.001
C1 N2 MID 3n
VREF NR MID 0.5
GCOMP MID OUT VALUE = {0.5*(SGN(V(N2,NR)) - ABS(SGN(V(N2,NR))) + 2)}
* .MODEL DD D RS=0.001 N = 0.001
.ends
*$
*
.subckt ESD_BB_OPA1656 ESDn ESDp
.model BB_SW VSWITCH(Ron=50 Roff=1e12 Von=700e-3 Voff=650e-3)
S1 ESDp ESDn ESDn ESDp BB_SW
S2 ESDn ESDp ESDp ESDn BB_SW
.ends
*$
*
.subckt ESD_EN_OPA1656 EN_IN VCC VEE
.model ESD_SW VSWITCH(Ron=50 Roff=1e12 Von=500e-3 Voff=450e-3)
S1 VCC EN_IN EN_IN VCC ESD_SW
S2 EN_IN VEE VEE EN_IN ESD_SW
.ends
*$
*
.subckt ESD_IN_OPA1656 ESDn ESDp VCC VEE
.model ESD_SW VSWITCH(Ron=50 Roff=1e12 Von=500e-3 Voff=450e-3)
S1 VCC ESDn ESDn VCC ESD_SW
S2 VCC ESDp ESDp VCC ESD_SW
S3 ESDn VEE VEE ESDn ESD_SW
S4 ESDp VEE VEE ESDp ESD_SW
.ends
*$
*
.subckt ESD_OUT_OPA1656 OUT VCC VEE
.model ESD_SW VSWITCH(Ron=50 Roff=1e12 Von=500e-3 Voff=450e-3)
S1 VCC OUT OUT VCC ESD_SW
S2 OUT VEE VEE OUT ESD_SW
.ends
*$
*
.subckt FEMT_OPA1656 1 2
* Input variables
* Set up 1/f noise
* FLW = 1/f frequency in Hz
.param FLWF=1e-3
* NLF = voltage noise density at 1/f frequency in fA/rt(Hz)
.param NLFF=19
* Set up broadband noise
* NVR = broadband voltage noise density in fA/rt(Hz)
.param NVRF=19
* Calculated values
.param GLFF={PWR(FLWF,0.25)*NLFF/1164}
.param RNVF={1.184*PWR(NVRF,2)}
.model DVNF D KF={PWR(FLWF,0.5)/1E11} IS=1.0E-16
* Circuit connections
I1 0 7 10e-3
I2 0 8 10e-3
D1 7 0 DVNF
D2 8 0 DVNF
E1 3 6 7 8 {GLFF}
R1 3 0 1e9
R2 3 0 1e9
R3 3 6 1e9
E2 6 4 5 0 10
R4 5 0 {RNVF}
R5 5 0 {RNVF}
R6 3 4 1e9
R7 4 0 1e9
G1 1 2 3 4 1e-6
.ends
*$
*
.subckt GR_SRC_OPA1656 VC+ VC- IOUT+ IOUT-
.param Gain = 1
.param Ipos = 11
.param Ineg = -11
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}
.ends
*$
*
.SUBCKT IBN_EN EN MID IOUT
.param IB_EN = 1.19e-6
.param IB_DIS = 1.19e-6
G1 IOUT MID VALUE = {V(EN,MID)*IB_EN + (1 - V(EN,MID))*IB_DIS}
.ends
*$
*
.SUBCKT IBP_EN EN MID IOUT
.param IB_EN = 1.2e-6
.param IB_DIS = 1.2e-6
G1 IOUT MID VALUE = {V(EN,MID)*IB_EN + (1 - V(EN,MID))*IB_DIS}
.ends
*$
*
.SUBCKT IQ_EN VCC VEE MID EN
.param IQ_EN = 2.6e-3
.param IQ_DIS = 5e-6
G1 VCC VEE VALUE = {V(EN,MID)*IQ_EN + (1- V(EN,MID))*IQ_DIS}
.ends
*$
*
.subckt IQ_SRC_OPA1656 VC+ VC- IOUT+ IOUT-
.param Gain = 1e-3
G1 IOUT+ IOUT- VALUE={IF( (V(VC+,VC-)<=0),0,Gain*V(VC+,VC-) )}
.ends
*$
*
.subckt OL_SENSE_OPA1656 1 2 3 4
* pins COM SW+ OLN OLP
GSW+ 1 2 Value = {IF((V(3,1)>10e-3 | V(4,1)>10e-3),1,0)}
.ends
*$
*
.subckt SW_OL_OPA1656 SW_OL MID CAP_L CAP_R
.model OL_SW VSWITCH(Ron=1e-3 Roff=1e9 Von=900e-3 Voff=800e-3)
S1 CAP_L CAP_R SW_OL MID OL_SW
.ends
*$
*
.subckt SW_OR_OPA1656 CLAMP OLN OLP
.model OR_SW VSWITCH(Ron=10e-3 Roff=1e9 Von=10e-3 Voff=0)
S1 OLP CLAMP CLAMP OLP OR_SW
S2 CLAMP OLN OLN CLAMP OR_SW
.ends
*$
*
.subckt VCM_CLAMP_OPA1656 VIN+ VIN- IOUT- IOUT+ VP+ VP-
.param Gain = 1
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VIN+,VIN-),V(VP-,VIN-), V(VP+,VIN-))}
.ends
*$
*
.subckt VNSE_OPA1656 1 2
* Input variables
* Set up 1/f noise
* FLW = 1/f frequency in Hz
.param FLW=1
* NLF = voltage noise density at 1/f frequency in nV/rt(Hz)
.param NLF=193.3
* Set up broadband noise
* NVR = broadband voltage noise density in nV/rt(Hz)
.param NVR=2.32
* Calculated values
.param GLF={PWR(FLW,0.25)*NLF/1164}
.param RNV={1.184*PWR(NVR,2)}
.model DVN D KF={PWR(FLW,0.5)/1E11} IS=1.0E-16
* Circuit connections
I1 0 7 10E-3
I2 0 8 10E-3
D1 7 0 DVN
D2 8 0 DVN
E1 3 6 7 8 {GLF}
R1 3 0 1E9
R2 3 0 1E9
R3 3 6 1E9
E2 6 4 5 0 10
R4 5 0 {RNV}
R5 5 0 {RNV}
R6 3 4 1E9
R7 4 0 1E9
E3 1 2 3 4 1
.ends
*$
*
.subckt VOS_DRIFT_OPA1656 VOS- VOS+
.model R_OS RES(TC1=14.9e-3)
IS 1 0 33.5e-6
R1 0 1 R_OS 1
VNEG 1 2 -8.75e-6
E1 VOS+ VOS- 0 2 1
.ends
*$
.SUBCKT ZO_1_EN IOUT+ IOUT- VINP VINN EN MID
.param GAIN = 4.5e2
G1 IOUT+ IOUT- VALUE = {GAIN*V(EN,MID)*V(VINP,VINN)}
.ends
*$
*
.SUBCKT ZO_2_EN IOUT+ IOUT- VINP VINN EN MID
.param GAIN = 2
G1 IOUT+ IOUT- VALUE = {GAIN*V(EN,MID)*V(VINP,VINN)}
.ends
*$
*
.subckt ZO_SRC_OPA1656 VC+ VC- IOUT+ IOUT-
.param Gain = 1e2
.param Ipos = 7.4e3
.param Ineg = -8.2e3
G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}
.ends
*$