OBSSCircuit DescriptionV1.1010/02/94 20:07 CET.Component & analysis parameters of a circuit.TINA 9.3.150.328 SF-TIB(c) Copyright 1993,94,95,96 DesignSoft Inc. All rights reserved.; $Circuit$?@ ArialDACSymbol????333333??_@_ ArialADCSymbol????333333???T_0FE62E0020210405082620?T_0FE631C020210405082620?T_0FE6358020210405082620?T_0FE6394020210405082620?T_0FE63D0020210405082620?   T_0FE640C020210405082620?T_0FE6448020210405082620?   T_0FE6484020210405082620;T_0FE64C0020210405082620;xxT_0FE64FC020210405082620;T_0FE6538020210405082620;T_0FE6574020210405082620;((((T_0FE65B0020210405082620C@@((T_0FE65EC020210405082620?T_0FE6628020210405082620?((T_0FE6664020210405082620?```````T_0FE66A0020210405082620;`(`(T_0FE66DC020210405082620C(X((((XT_0FE6718020210405082620;P P T_0FE6754020210405082620;``T_0FE6790020210405082620;````T_0FE67CC020210405082620;`x`@`x`@T_0FE6808020210405082620C(`x((x`xT_0FE6844020210405082620;T_0FE6880020210405082620?hphhpT_0FE68BC020210405082620?X0pXXp0pT_0FE68F8020210405082620?xXxxXT_0FE6934020210405082620?XH@ XHX @ T_0FE6970020210405082620?xXXHxXxHXHT_0FE69AC020210405082620;xhxxhxT_0FE69E8020210405082620?T_0FE6A24020210405082620?@@@@@T_0FE6A60020210405082620?@X@@XT_0FE6A9C020210405082620?0 0  T_0FE6B50020210405082620;@H@8@H@8T_0FE6B8C020210405082620Cx0xx00T_0FE6BC8020210405082620;xxxxT_0FE6C04020210405082620?T_0FE6C40020210405082620;T_0FE6C7C020210405082620?HHHT_0FE6CB8020210405082620C8P8XXPT_0FE6CF4020210405082620;T_0FE6D30020210405082620;xxxxT_0FE6D6C020210405082620;x`xx`xT_0FE6DA8020210405082620;T_0FE6DE4020210405082620;HHT_0FE6E20020210405082620;X@X@T_0FE6E5C020210405082620;@@@@T_0FE6E98020210405082620CH(HXX(T_0FE6ED4020210405082620;T_0FE6F10020210405082620;T_0FE6F4C020210405082620?( (  T_0FE56DA020210405082620;xxT_0FE5716020210405082620;0x00x0T_0FE5752020210405082620;P@P@T_0FE578E020210405082620;0P0@0P0@T_0FE57CA020210405082620;PxPPxPT_0FE5806020210405082620;xxT_0FE5842020210405082620;PPP@PPP@T_0FE587E020210405082620;P@P@T_0FE58BA020210405082620CP0PXX0T_0FE58F6020210405082620;T_0FE5932020210405082620;T_0FE596E020210405082620CT_0FE59AA020210405082620?xxxT_0FE59E6020210405082620;T_0FE5A22020210405082620;    T_0FE5A5E020210405082620CP(8P0(0(8T_0FE5A9A020210405082620C(((T_0FE5AD6020210405082620;hhhhT_0FE5B12020210405082620;T_0FE5B4E020210405082620;    T_0FE5B8A020210405082620C X  XXT_0FE5BC6020210405082620;hhT_0FE5C02020210405082620;T_0FE5C3E020210405082620;@@T_0FE5C7A020210405082620;T_0FE5CB6020210405082620;T_0FE5CF2020210405082620?```T_0FE5D2E020210405082620;h0hh0hT_0FE5D6A020210405082620;hHhHT_0FE5DA6020210405082620;hXhxhXhxT_0FE5DE2020210405082620?hxhhxhxhT_0FE5E1E020210405082620?@X@XXT_0FE5E5A020210405082620?0`XH0`X`XHT_0FE5E96020210405082620?x`xx`T_0FE5ED2020210405082620?x8`@x8x@`@T_0FE5F0E020210405082620?`@(`@`((T_0FE5F4A020210405082620?phphhT_0FE5F86020210405082620?T_0FE5FC2020210405082620?```T_0FE5FFE020210405082620C``T_0FE603A020210405082620?```T_0FE6076020210405082620;T_11647BE020210405082620;T_11647FA020210405082620C  @ @T_1177118020210405082620?     T_1177154020210405082620?T_11700FB020210405082620C@@T_1170137020210405082620?T_116D851020210405082620?T_116C20A020210405082620;`8``8`T_062F523020210405082620;``T_062D3FB020210405082620BrPVM4T_06259FA020210129122749 Vmet (VM):B9U4T_062599C020210129122749 OPA810OPA1662RC:\Users\a0232073\AppData\Local\Temp\DesignSoft\{Tina9-TI-11032017-090321}\OPA810SCK#OPA1662Label+!PP(d*-IN @d*+IN fNDt<A  @d*V-alr fND4  @d*V+  @d*Vout ( @h 00g+Arial?g-Arial$I$I?gV+Arialm۶m?'h3{@'h3{@d* OPA810 - Rev. A%* Created by Sean Cashin; 2020-06-11M* Created with Green-Williams-Lis Current Sense Amp Macro-model Architecture2* Copyright 2020 by Texas Instruments Corporation7******************************************************$* MACRO-MODEL SIMULATED PARAMETERS:7******************************************************* AC PARAMETERS**********************>* CLOSED-LOOP OUTPUT IMPEDANCE VS. FREQUENCY (Zout vs. Freq.)P* CLOSED-LOOP GAIN AND PHASE VS. FREQUENCY WITH RL, CL EFFECTS (Acl vs. Freq.)=* COMMON-MODE REJECTION RATIO VS. FREQUENCY (CMRR vs. Freq.)>* POWER SUPPLY REJECTION RATIO VS. FREQUENCY (PSRR vs. Freq.);* INPUT VOLTAGE NOISE DENSITY VS. FREQUENCY (en vs. Freq.)*********************** DC PARAMETERS**********************(* INPUT COMMON-MODE VOLTAGE RANGE (Vcm)* GAIN ERROR (Eg)@* INPUT BIAS CURRENT VS. INPUT COMMON-MODE VOLTAGE (Ib vs. Vcm)6* INPUT OFFSET VOLTAGE VS. TEMPERATURE (Vos vs. Temp):* OUTPUT VOLTAGE SWING vs. OUTPUT CURRENT (Vout vs. Iout)%* SHORT-CIRCUIT OUTPUT CURRENT (Isc)* QUIESCENT CURRENT (Iq)*********************** TRANSIENT PARAMETERS*********************** SLEW RATE (SR))* SETTLING TIME VS. CAPACITIVE LOAD (ts)* OVERLOAD RECOVERY TIME (tor)7******************************************************#.subckt OPA810 IN+ IN- OUT VCC VEE7******************************************************.MODEL R_NOISE RES (T_ABS=0)'.MODEL R_NOISELESS RES (T_ABS=-273.15)#C_C12 MID N45892 1E-15 #C_C13 N45974 MID 1E-15 #C_C17 MID N68747 1E-12 #C_C18 MID N68594 1E-12 )C_C19 MID SW_OL_OPA810 1E-12 +C_C1A N725398 N725428 15.92E-6 *C_C1A1 N701935 N701965 3.537P +C_C1A10 N789898 N789912 342.3F *C_C1A4 N709083 N709113 63.66N *C_C1A9 N704975 N705005 83.77N ,C_C1C1 N821901 N725762 159.2E-9 -C_C1C3 N725214 N725836 26.53E-15 (C_C1D MID N725708 93.62E-15 &C_C1_0 MID N79181 23.5E-9 %C_C2 MID N694641 740E-12 %C_C3 MID N694487 740E-12 "C_C33 N406634 0 1E-15 C_C34 N317950 0 1 "C_C35 N406794 0 1E-15 ,C_C36 N894736 N892256 227.4E-12 "C_C7 N31014 MID 1E-15 "C_C8 MID N35813 1E-15 "C_C9 MID N38096 1E-15 %C_C_CMN MID ESDN 2.5E-12 %C_C_CMP ESDP MID 2.5E-12 'C_C_DIFF ESDN ESDP 0.5E-12 $C_C_VCLP VCLP MID 1E-12 %C_C_VIMON MID VIMON 1E-9 'C_C_VOUT_S MID VOUT_S 1E-9 'E_E2 N91498 MID CL_CLAMP MID 1#E_E3 N112292 MID OUT MID 1E_E6 MID 0 N317950 0 11G_G1 N725398 MID CL_CLAMP N516723 -90.91'G_G10 N73852 MID N55875 MID -1'G_G11 N55050 MID N56119 MID -1-G_G16 CL_CLAMP MID N894736 MID -1E-3-G_G2 N10570 N10561 N701965 MID -1E-3G_G36 VCC_B 0 VCC 0 -1G_G37 VEE_B 0 VEE 0 -1(G_G54 N694641 MID N79181 MID -1.G_G55 N701935 MID N789912 MID -222.22+G_G56 N709083 MID VCC_B MID -1.265+G_G58 N704975 MID VEE_B MID -1.664+G_G59 N789898 MID ESDP MID -29.75M1G_G6 N25816 N11984 N709113 N705005 -1E-3,G_G60 N06456 MID N799160 MID -10E-6*G_G61 ESDN MID N804105 MID -10E-6+G_G62 N821901 MID N725428 MID -100+G_G63 N892256 MID N694487 MID -1.3(G_G7 N694487 MID N694641 MID -1*G_G8 VCC_CLP MID N35813 MID -1E-3*G_G9 VEE_CLP MID N38096 MID -1E-3)G_GB N725346 MID N725762 MID -25+G_GD4 N725214 MID N725574 MID -0.3-G_GD5 N725936 MID N725836 MID -166.7$I_I_B N06456 MID DC 2E-12 #I_I_OS ESDN MID DC 1E-12 "I_I_Q VCC VEE DC 1.9E-3 (R_R1 ESDP IN+ R_NOISELESS 10E-3+R_R10 ESDN N11991 R_NOISELESS 1E-3%R_R107 VCC_B 0 R_NOISELESS 1*R_R108 N317950 0 R_NOISELESS 1E12%R_R109 VEE_B 0 R_NOISELESS 1(R_R11 MID N725346 R_NOISELESS 1.R_R110 VCC_B N406634 R_NOISELESS 1E-3/R_R111 N406634 N317950 R_NOISELESS 1E6/R_R112 N317950 N406794 R_NOISELESS 1E6.R_R113 N406794 VEE_B R_NOISELESS 1E-3)R_R133 N694487 MID R_NOISELESS 1)R_R134 N694641 MID R_NOISELESS 1)R_R135 N701935 MID R_NOISELESS 1)R_R136 N704975 MID R_NOISELESS 1)R_R137 MID N725398 R_NOISELESS 1)R_R139 MID N725214 R_NOISELESS 1)R_R140 MID N725936 R_NOISELESS 1)R_R141 N789898 MID R_NOISELESS 1)R_R145 MID N821901 R_NOISELESS 1)R_R149 N892256 MID R_NOISELESS 1,R_R150 N894736 MID R_NOISELESS 33.3.R_R151 N892256 N894736 R_NOISELESS 10/R_R1A N725428 N725398 R_NOISELESS 10E3/R_R1A1 N701935 N701965 R_NOISELESS 1E40R_R1A10 N789898 N789912 R_NOISELESS 1E8'R_R1A11 MID N799160 R_NOISE 15'R_R1A12 MID N804105 R_NOISE 15/R_R1A3 N704975 N705005 R_NOISELESS 1E8/R_R1A4 N709083 N709113 R_NOISELESS 1E80R_R1C1 N725762 N821901 R_NOISELESS 10E3/R_R1C2 N725836 N725214 R_NOISELESS 1E40R_R1D1 N725708 N725574 R_NOISELESS 10E3(R_R2 ESDN IN- R_NOISELESS 10E-3,R_R21 N11984 N25816 R_NOISELESS 1E3)R_R25 MID N28602 R_NOISELESS 1E9)R_R26 N30136 MID R_NOISELESS 1E9'R_R27 MID N30913 R_NOISELESS 1-R_R28 N31014 N30913 R_NOISELESS 1E-3+R_R29 N35669 VCC_B R_NOISELESS 1E3,R_R2A1 N701965 MID R_NOISELESS 45.2,R_R2A10 N705005 MID R_NOISELESS 19M,R_R2A11 N789912 MID R_NOISELESS 465,R_R2A13 MID N725428 R_NOISELESS 101+R_R2A4 N709113 MID R_NOISELESS 25M-R_R2C1 MID N725762 R_NOISELESS 416.7-R_R2C3 MID N725836 R_NOISELESS 60.362R_R2D N725574 N725346 R_NOISELESS 367.8E3'R_R3 MID ESDP R_NOISELESS 1E12-R_R30 N35813 N35669 R_NOISELESS 1E-3*R_R31 VCC_CLP MID R_NOISELESS 1E3+R_R32 N38050 VEE_B R_NOISELESS 1E3-R_R33 N38096 N38050 R_NOISELESS 1E-3*R_R34 VEE_CLP MID R_NOISELESS 1E3'R_R4 ESDN MID R_NOISELESS 1E12)R_R41 MID N50645 R_NOISELESS 1E9'R_R42 N45856 MID R_NOISELESS 1-R_R43 N45892 N45856 R_NOISELESS 1E-3-R_R44 N45974 N45986 R_NOISELESS 1E-3'R_R45 MID N45986 R_NOISELESS 1)R_R46 MID N48550 R_NOISELESS 1E9'R_R47 MID N73852 R_NOISELESS 1'R_R48 MID N55050 R_NOISELESS 1'R_R5 N709083 MID R_NOISELESS 1)R_R56 N68747 OLN R_NOISELESS 100)R_R57 N68594 OLP R_NOISELESS 100'R_R58 N69264 MID R_NOISELESS 12R_R59 N69264 SW_OL_OPA810 R_NOISELESS 100)R_R60 MID AOLNET R_NOISELESS 1E6+R_R66 MID CL_CLAMP R_NOISELESS 1E3+R_R8 N10561 N10570 R_NOISELESS 1E3*R_R81 MID N110431 R_NOISELESS 1E9*R_R83 MID N112292 R_NOISELESS 1E9,R_R9 N10570 N11984 R_NOISELESS 1E-3/R_RDUMMY1 MID N516723 R_NOISELESS 10E30R_RX1 N516723 N725936 R_NOISELESS 100E3-R_R_VCLP N91498 VCLP R_NOISELESS 1000R_R_VIMON VIMON N110431 R_NOISELESS 1002R_R_VOUT_S VOUT_S N112292 R_NOISELESS 100$V_VCM_MAX N30136 VCC_B 0.15$V_VCM_MIN N28602 VEE_B -0.2!V_V_ISCN N48550 MID -120 V_V_ISCP N50645 MID 120"V_V_ORN N55875 VCLP -68.5"V_V_ORP N56119 VCLP 37.137X_AOL_1 N31014 N11991 MID AOLNET AOL_1_OPA810 4X_AOL_2 AOLNET MID MID N79181 AOL_2_OPA810 5X_CLAWN MID VIMON VEE_B N38050 CLAWN_OPA810 5X_CLAWP VIMON MID N35669 VCC_B CLAWP_OPA810 LX_CL_AMP N50645 N48550 VIMON MID N45856 N45986 CLAMP_AMP_LO_OPA810 ;X_CL_SRC N45892 N45974 CL_CLAMP MID CL_SRC_OPA810 .X_ESD_OUT OUT VCC VEE ESD_OUT_OPA810 'X_E_N ESDP N06456 VNSE_OPA810 =X_H1 N73852 N166377 OLN MID 08_OP_AMP_COMPLETE_H1_OPA810 =X_H2 N55050 N166817 OLP MID 08_OP_AMP_COMPLETE_H2_OPA810 >X_H3 OUT N516723 N110431 MID 08_OP_AMP_COMPLETE_H3_OPA810 0X_IQ_N MID VIMON MID VEE IQ_SRC_OPA810 0X_IQ_P VIMON MID VCC MID IQ_SRC_OPA810 =X_OL_SENSE MID N69264 N68747 N68594 OL_SENSE_OPA810 =X_S1 OUT VCC_CLP N79181 MID 08_OP_AMP_COMPLETE_S1_OPA810 =X_S2 VEE_CLP OUT N79181 MID 08_OP_AMP_COMPLETE_S2_OPA810 ?X_SW_OL SW_OL_OPA810 MID N725398 N725428 SW_OL_OPA810 4X_SW_OR CLAMP N166377 N166817 SW_OR_OPA810 JX_VCM_CLAMP N25816 MID N30913 MID N30136 N28602 VCM_CLAMP_OPA810 5X_VOS_DRIFT N749288 N06456 VOS_DRIFT_OPA810 ?X_VOS_VS_VCM N10561 N749288 VCC VEE VOS_VS_VCM_OPA810 .ENDS OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_H1_OPA810 1 2 3 4 H_H1 3 4 VH_H1 1VH_H1 1 2 0V$.ENDS 08_OP_AMP_COMPLETE_H1_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_H2_OPA810 1 2 3 4 H_H2 3 4 VH_H2 -1VH_H2 1 2 0V$.ENDS 08_OP_AMP_COMPLETE_H2_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_H3_OPA810 1 2 3 4 H_H3 3 4 VH_H3 -1E3VH_H3 1 2 0V$.ENDS 08_OP_AMP_COMPLETE_H3_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_S1_OPA810 1 2 3 4 S_S1 3 4 1 2 _S1RS_S1 1 2 1G>.MODEL _S1 VSWITCH ROFF=200E3 RON=0.5 VOFF=-1 VON=0.4$.ENDS 08_OP_AMP_COMPLETE_S1_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_S2_OPA810 1 2 3 4 S_S2 3 4 1 2 _S2RS_S2 1 2 1G>.MODEL _S2 VSWITCH ROFF=200E3 RON=0.5 VOFF=-1 VON=0.4$.ENDS 08_OP_AMP_COMPLETE_S2_OPA810*).SUBCKT AOL_1_OPA810 VC+ VC- IOUT+ IOUT-.PARAM GAIN = 1E-2.PARAM IPOS = .5.PARAM INEG = -.58G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS AOL_1_OPA810*).SUBCKT AOL_2_OPA810 VC+ VC- IOUT+ IOUT-.PARAM GAIN = 1E-3.PARAM IPOS = 5.6.PARAM INEG = -5.68G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS AOL_2_OPA810*4.SUBCKT CLAMP_AMP_LO_OPA810 VC+ VC- VIN COM VO+ VO- .PARAM G=1OGVO+ COM VO+ VALUE = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}OGVO- COM VO- VALUE = {IF(V(VIN,COM)10E-3 | V(4,1)>10E-3),1,0)}.ENDS OL_SENSE_OPA810*2.SUBCKT SW_OL_OPA810 SW_OL_OPA810 MID CAP_L CAP_R?.MODEL OL_SW VSWITCH(RON=1E-3 ROFF=1E9 VON=900E-3 VOFF=800E-3)&S1 CAP_L CAP_R SW_OL_OPA810 MID OL_SW.ENDS SW_OL_OPA810*#.SUBCKT SW_OR_OPA810 CLAMP OLN OLP:.MODEL OR_SW VSWITCH(RON=10E-3 ROFF=1E9 VON=10E-3 VOFF=0)S1 OLP CLAMP CLAMP OLP OR_SWS2 CLAMP OLN OLN CLAMP OR_SW.ENDS SW_OR_OPA810*7.SUBCKT VCM_CLAMP_OPA810 VIN+ VIN- IOUT- IOUT+ VP+ VP-.PARAM GAIN = 1IG1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VIN+,VIN-),V(VP-,VIN-), V(VP+,VIN-))}.ENDS VCM_CLAMP_OPA810*.SUBCKT VNSE_OPA810 1 2.PARAM FLW=0.1.PARAM NLF=1190.PARAM NVR=5.7$.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 DVNE1 3 6 7 8 {GLF} R1 3 0 1E9 R2 3 0 1E9 R3 3 6 1E9E2 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 VNSE_OPA810*#.SUBCKT VOS_DRIFT_OPA810 VOS+ VOS-.PARAM DC = 76.1E-6.PARAM POL = 1.PARAM DRIFT = 2.5E-6,E1 VOS+ VOS- VALUE={DC+POL*DRIFT*(TEMP-27)}.ENDS VOS_DRIFT_OPA810**.SUBCKT VOS_VS_VCM_OPA810 V+ V- REF+ REF- E1 V+ 1 TABLE {(V(REF+, V-))} =+(0.35, 450E-6)+(0.4, 435E-6)+(0.55, 275E-6)+(0.65, 150E-6)+(0.75, 75E-6)+(0.85, 25E-6)+(1, 0) V1 1 V- 0.ENDS VOS_VS_VCM_OPA810*+IN-INVoutV+V-:B9U3T_062593E020210129122749 OPA810OPA1662RC:\Users\a0232073\AppData\Local\Temp\DesignSoft\{Tina9-TI-11032017-090321}\OPA810SCK#OPA1662Label+!PP(d*-IN @d*+IN fNDt<A  @d*V-alr fND4  @d*V+  @d*Vout ( @h 00g+Arial?g-Arial$I$I?gV+Arialm۶m?'h3{@'h3{@d* OPA810 - Rev. A%* Created by Sean Cashin; 2020-06-11M* Created with Green-Williams-Lis Current Sense Amp Macro-model Architecture2* Copyright 2020 by Texas Instruments Corporation7******************************************************$* MACRO-MODEL SIMULATED PARAMETERS:7******************************************************* AC PARAMETERS**********************>* CLOSED-LOOP OUTPUT IMPEDANCE VS. FREQUENCY (Zout vs. Freq.)P* CLOSED-LOOP GAIN AND PHASE VS. FREQUENCY WITH RL, CL EFFECTS (Acl vs. Freq.)=* COMMON-MODE REJECTION RATIO VS. FREQUENCY (CMRR vs. Freq.)>* POWER SUPPLY REJECTION RATIO VS. FREQUENCY (PSRR vs. Freq.);* INPUT VOLTAGE NOISE DENSITY VS. FREQUENCY (en vs. Freq.)*********************** DC PARAMETERS**********************(* INPUT COMMON-MODE VOLTAGE RANGE (Vcm)* GAIN ERROR (Eg)@* INPUT BIAS CURRENT VS. INPUT COMMON-MODE VOLTAGE (Ib vs. Vcm)6* INPUT OFFSET VOLTAGE VS. TEMPERATURE (Vos vs. Temp):* OUTPUT VOLTAGE SWING vs. OUTPUT CURRENT (Vout vs. Iout)%* SHORT-CIRCUIT OUTPUT CURRENT (Isc)* QUIESCENT CURRENT (Iq)*********************** TRANSIENT PARAMETERS*********************** SLEW RATE (SR))* SETTLING TIME VS. CAPACITIVE LOAD (ts)* OVERLOAD RECOVERY TIME (tor)7******************************************************#.subckt OPA810 IN+ IN- OUT VCC VEE7******************************************************.MODEL R_NOISE RES (T_ABS=0)'.MODEL R_NOISELESS RES (T_ABS=-273.15)#C_C12 MID N45892 1E-15 #C_C13 N45974 MID 1E-15 #C_C17 MID N68747 1E-12 #C_C18 MID N68594 1E-12 )C_C19 MID SW_OL_OPA810 1E-12 +C_C1A N725398 N725428 15.92E-6 *C_C1A1 N701935 N701965 3.537P +C_C1A10 N789898 N789912 342.3F *C_C1A4 N709083 N709113 63.66N *C_C1A9 N704975 N705005 83.77N ,C_C1C1 N821901 N725762 159.2E-9 -C_C1C3 N725214 N725836 26.53E-15 (C_C1D MID N725708 93.62E-15 &C_C1_0 MID N79181 23.5E-9 %C_C2 MID N694641 740E-12 %C_C3 MID N694487 740E-12 "C_C33 N406634 0 1E-15 C_C34 N317950 0 1 "C_C35 N406794 0 1E-15 ,C_C36 N894736 N892256 227.4E-12 "C_C7 N31014 MID 1E-15 "C_C8 MID N35813 1E-15 "C_C9 MID N38096 1E-15 %C_C_CMN MID ESDN 2.5E-12 %C_C_CMP ESDP MID 2.5E-12 'C_C_DIFF ESDN ESDP 0.5E-12 $C_C_VCLP VCLP MID 1E-12 %C_C_VIMON MID VIMON 1E-9 'C_C_VOUT_S MID VOUT_S 1E-9 'E_E2 N91498 MID CL_CLAMP MID 1#E_E3 N112292 MID OUT MID 1E_E6 MID 0 N317950 0 11G_G1 N725398 MID CL_CLAMP N516723 -90.91'G_G10 N73852 MID N55875 MID -1'G_G11 N55050 MID N56119 MID -1-G_G16 CL_CLAMP MID N894736 MID -1E-3-G_G2 N10570 N10561 N701965 MID -1E-3G_G36 VCC_B 0 VCC 0 -1G_G37 VEE_B 0 VEE 0 -1(G_G54 N694641 MID N79181 MID -1.G_G55 N701935 MID N789912 MID -222.22+G_G56 N709083 MID VCC_B MID -1.265+G_G58 N704975 MID VEE_B MID -1.664+G_G59 N789898 MID ESDP MID -29.75M1G_G6 N25816 N11984 N709113 N705005 -1E-3,G_G60 N06456 MID N799160 MID -10E-6*G_G61 ESDN MID N804105 MID -10E-6+G_G62 N821901 MID N725428 MID -100+G_G63 N892256 MID N694487 MID -1.3(G_G7 N694487 MID N694641 MID -1*G_G8 VCC_CLP MID N35813 MID -1E-3*G_G9 VEE_CLP MID N38096 MID -1E-3)G_GB N725346 MID N725762 MID -25+G_GD4 N725214 MID N725574 MID -0.3-G_GD5 N725936 MID N725836 MID -166.7$I_I_B N06456 MID DC 2E-12 #I_I_OS ESDN MID DC 1E-12 "I_I_Q VCC VEE DC 1.9E-3 (R_R1 ESDP IN+ R_NOISELESS 10E-3+R_R10 ESDN N11991 R_NOISELESS 1E-3%R_R107 VCC_B 0 R_NOISELESS 1*R_R108 N317950 0 R_NOISELESS 1E12%R_R109 VEE_B 0 R_NOISELESS 1(R_R11 MID N725346 R_NOISELESS 1.R_R110 VCC_B N406634 R_NOISELESS 1E-3/R_R111 N406634 N317950 R_NOISELESS 1E6/R_R112 N317950 N406794 R_NOISELESS 1E6.R_R113 N406794 VEE_B R_NOISELESS 1E-3)R_R133 N694487 MID R_NOISELESS 1)R_R134 N694641 MID R_NOISELESS 1)R_R135 N701935 MID R_NOISELESS 1)R_R136 N704975 MID R_NOISELESS 1)R_R137 MID N725398 R_NOISELESS 1)R_R139 MID N725214 R_NOISELESS 1)R_R140 MID N725936 R_NOISELESS 1)R_R141 N789898 MID R_NOISELESS 1)R_R145 MID N821901 R_NOISELESS 1)R_R149 N892256 MID R_NOISELESS 1,R_R150 N894736 MID R_NOISELESS 33.3.R_R151 N892256 N894736 R_NOISELESS 10/R_R1A N725428 N725398 R_NOISELESS 10E3/R_R1A1 N701935 N701965 R_NOISELESS 1E40R_R1A10 N789898 N789912 R_NOISELESS 1E8'R_R1A11 MID N799160 R_NOISE 15'R_R1A12 MID N804105 R_NOISE 15/R_R1A3 N704975 N705005 R_NOISELESS 1E8/R_R1A4 N709083 N709113 R_NOISELESS 1E80R_R1C1 N725762 N821901 R_NOISELESS 10E3/R_R1C2 N725836 N725214 R_NOISELESS 1E40R_R1D1 N725708 N725574 R_NOISELESS 10E3(R_R2 ESDN IN- R_NOISELESS 10E-3,R_R21 N11984 N25816 R_NOISELESS 1E3)R_R25 MID N28602 R_NOISELESS 1E9)R_R26 N30136 MID R_NOISELESS 1E9'R_R27 MID N30913 R_NOISELESS 1-R_R28 N31014 N30913 R_NOISELESS 1E-3+R_R29 N35669 VCC_B R_NOISELESS 1E3,R_R2A1 N701965 MID R_NOISELESS 45.2,R_R2A10 N705005 MID R_NOISELESS 19M,R_R2A11 N789912 MID R_NOISELESS 465,R_R2A13 MID N725428 R_NOISELESS 101+R_R2A4 N709113 MID R_NOISELESS 25M-R_R2C1 MID N725762 R_NOISELESS 416.7-R_R2C3 MID N725836 R_NOISELESS 60.362R_R2D N725574 N725346 R_NOISELESS 367.8E3'R_R3 MID ESDP R_NOISELESS 1E12-R_R30 N35813 N35669 R_NOISELESS 1E-3*R_R31 VCC_CLP MID R_NOISELESS 1E3+R_R32 N38050 VEE_B R_NOISELESS 1E3-R_R33 N38096 N38050 R_NOISELESS 1E-3*R_R34 VEE_CLP MID R_NOISELESS 1E3'R_R4 ESDN MID R_NOISELESS 1E12)R_R41 MID N50645 R_NOISELESS 1E9'R_R42 N45856 MID R_NOISELESS 1-R_R43 N45892 N45856 R_NOISELESS 1E-3-R_R44 N45974 N45986 R_NOISELESS 1E-3'R_R45 MID N45986 R_NOISELESS 1)R_R46 MID N48550 R_NOISELESS 1E9'R_R47 MID N73852 R_NOISELESS 1'R_R48 MID N55050 R_NOISELESS 1'R_R5 N709083 MID R_NOISELESS 1)R_R56 N68747 OLN R_NOISELESS 100)R_R57 N68594 OLP R_NOISELESS 100'R_R58 N69264 MID R_NOISELESS 12R_R59 N69264 SW_OL_OPA810 R_NOISELESS 100)R_R60 MID AOLNET R_NOISELESS 1E6+R_R66 MID CL_CLAMP R_NOISELESS 1E3+R_R8 N10561 N10570 R_NOISELESS 1E3*R_R81 MID N110431 R_NOISELESS 1E9*R_R83 MID N112292 R_NOISELESS 1E9,R_R9 N10570 N11984 R_NOISELESS 1E-3/R_RDUMMY1 MID N516723 R_NOISELESS 10E30R_RX1 N516723 N725936 R_NOISELESS 100E3-R_R_VCLP N91498 VCLP R_NOISELESS 1000R_R_VIMON VIMON N110431 R_NOISELESS 1002R_R_VOUT_S VOUT_S N112292 R_NOISELESS 100$V_VCM_MAX N30136 VCC_B 0.15$V_VCM_MIN N28602 VEE_B -0.2!V_V_ISCN N48550 MID -120 V_V_ISCP N50645 MID 120"V_V_ORN N55875 VCLP -68.5"V_V_ORP N56119 VCLP 37.137X_AOL_1 N31014 N11991 MID AOLNET AOL_1_OPA810 4X_AOL_2 AOLNET MID MID N79181 AOL_2_OPA810 5X_CLAWN MID VIMON VEE_B N38050 CLAWN_OPA810 5X_CLAWP VIMON MID N35669 VCC_B CLAWP_OPA810 LX_CL_AMP N50645 N48550 VIMON MID N45856 N45986 CLAMP_AMP_LO_OPA810 ;X_CL_SRC N45892 N45974 CL_CLAMP MID CL_SRC_OPA810 .X_ESD_OUT OUT VCC VEE ESD_OUT_OPA810 'X_E_N ESDP N06456 VNSE_OPA810 =X_H1 N73852 N166377 OLN MID 08_OP_AMP_COMPLETE_H1_OPA810 =X_H2 N55050 N166817 OLP MID 08_OP_AMP_COMPLETE_H2_OPA810 >X_H3 OUT N516723 N110431 MID 08_OP_AMP_COMPLETE_H3_OPA810 0X_IQ_N MID VIMON MID VEE IQ_SRC_OPA810 0X_IQ_P VIMON MID VCC MID IQ_SRC_OPA810 =X_OL_SENSE MID N69264 N68747 N68594 OL_SENSE_OPA810 =X_S1 OUT VCC_CLP N79181 MID 08_OP_AMP_COMPLETE_S1_OPA810 =X_S2 VEE_CLP OUT N79181 MID 08_OP_AMP_COMPLETE_S2_OPA810 ?X_SW_OL SW_OL_OPA810 MID N725398 N725428 SW_OL_OPA810 4X_SW_OR CLAMP N166377 N166817 SW_OR_OPA810 JX_VCM_CLAMP N25816 MID N30913 MID N30136 N28602 VCM_CLAMP_OPA810 5X_VOS_DRIFT N749288 N06456 VOS_DRIFT_OPA810 ?X_VOS_VS_VCM N10561 N749288 VCC VEE VOS_VS_VCM_OPA810 .ENDS OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_H1_OPA810 1 2 3 4 H_H1 3 4 VH_H1 1VH_H1 1 2 0V$.ENDS 08_OP_AMP_COMPLETE_H1_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_H2_OPA810 1 2 3 4 H_H2 3 4 VH_H2 -1VH_H2 1 2 0V$.ENDS 08_OP_AMP_COMPLETE_H2_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_H3_OPA810 1 2 3 4 H_H3 3 4 VH_H3 -1E3VH_H3 1 2 0V$.ENDS 08_OP_AMP_COMPLETE_H3_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_S1_OPA810 1 2 3 4 S_S1 3 4 1 2 _S1RS_S1 1 2 1G>.MODEL _S1 VSWITCH ROFF=200E3 RON=0.5 VOFF=-1 VON=0.4$.ENDS 08_OP_AMP_COMPLETE_S1_OPA810*/.SUBCKT 08_OP_AMP_COMPLETE_S2_OPA810 1 2 3 4 S_S2 3 4 1 2 _S2RS_S2 1 2 1G>.MODEL _S2 VSWITCH ROFF=200E3 RON=0.5 VOFF=-1 VON=0.4$.ENDS 08_OP_AMP_COMPLETE_S2_OPA810*).SUBCKT AOL_1_OPA810 VC+ VC- IOUT+ IOUT-.PARAM GAIN = 1E-2.PARAM IPOS = .5.PARAM INEG = -.58G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS AOL_1_OPA810*).SUBCKT AOL_2_OPA810 VC+ VC- IOUT+ IOUT-.PARAM GAIN = 1E-3.PARAM IPOS = 5.6.PARAM INEG = -5.68G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS AOL_2_OPA810*4.SUBCKT CLAMP_AMP_LO_OPA810 VC+ VC- VIN COM VO+ VO- .PARAM G=1OGVO+ COM VO+ VALUE = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}OGVO- COM VO- VALUE = {IF(V(VIN,COM)10E-3 | V(4,1)>10E-3),1,0)}.ENDS OL_SENSE_OPA810*2.SUBCKT SW_OL_OPA810 SW_OL_OPA810 MID CAP_L CAP_R?.MODEL OL_SW VSWITCH(RON=1E-3 ROFF=1E9 VON=900E-3 VOFF=800E-3)&S1 CAP_L CAP_R SW_OL_OPA810 MID OL_SW.ENDS SW_OL_OPA810*#.SUBCKT SW_OR_OPA810 CLAMP OLN OLP:.MODEL OR_SW VSWITCH(RON=10E-3 ROFF=1E9 VON=10E-3 VOFF=0)S1 OLP CLAMP CLAMP OLP OR_SWS2 CLAMP OLN OLN CLAMP OR_SW.ENDS SW_OR_OPA810*7.SUBCKT VCM_CLAMP_OPA810 VIN+ VIN- IOUT- IOUT+ VP+ VP-.PARAM GAIN = 1IG1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VIN+,VIN-),V(VP-,VIN-), V(VP+,VIN-))}.ENDS VCM_CLAMP_OPA810*.SUBCKT VNSE_OPA810 1 2.PARAM FLW=0.1.PARAM NLF=1190.PARAM NVR=5.7$.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 DVNE1 3 6 7 8 {GLF} R1 3 0 1E9 R2 3 0 1E9 R3 3 6 1E9E2 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 VNSE_OPA810*#.SUBCKT VOS_DRIFT_OPA810 VOS+ VOS-.PARAM DC = 76.1E-6.PARAM POL = 1.PARAM DRIFT = 2.5E-6,E1 VOS+ VOS- VALUE={DC+POL*DRIFT*(TEMP-27)}.ENDS VOS_DRIFT_OPA810**.SUBCKT VOS_VS_VCM_OPA810 V+ V- REF+ REF- E1 V+ 1 TABLE {(V(REF+, V-))} =+(0.35, 450E-6)+(0.4, 435E-6)+(0.55, 275E-6)+(0.65, 150E-6)+(0.75, 75E-6)+(0.85, 25E-6)+(1, 0) V1 1 V- 0.ENDS VOS_VS_VCM_OPA810*+IN-INVoutV+V- BR11T_06258E0020210129122749R_AX600_W200 (R)j@=?Y@ B(R21T_0625882020210129122749R_AX600_W200 (R)@=?Y@ BpC2T_0625824020210129122749CP_CYL300_D700_L1400 (C) :0y5>@eAY@? BpR20T_06257C6020210129122749R_AX600_W200 (R)@=?Y@ BhR19T_0625768020210129122749R_AX600_W200 (R)@=?Y@Br`8VM3T_062570A020210129122749 Vmet (VM)<B SW-SPDT1T_06256AC020210129122749Switch_SPDT_White (SW-SPDT)eAB@8IG1T_062564E020210129122749Mb0?Mb0?j@V.AB0PVS1T_06255F0020210129122749 Voltgen (VS)@BPVS2T_0625592020210129122749 Voltgen (VS)BPVS3T_0625534020210129122749 Voltgen (VS)ffffff @BPPVS4T_06254D6020210129122749 Voltgen (VS)ffffff? BC1T_0625478020210129122749CP_CYL300_D700_L1400 (C) dy=?eAY@? BR4T_0B3B998020210129122749R_AX600_W200 (R)@@=?Y@ BxR6T_0B3B93A020210129122749R_AX600_W200 (R)@@=?Y@ BxR5T_0B3B8DC020210129122749R_AX600_W200 (R)@@=?Y@ BR3T_0B3B87E020210129122749R_AX600_W200 (R)@@=?Y@ BXR2T_0B3B820020210129122749R_AX600_W200 (R)Y@=?Y@ BXR1T_0B3B7C2020210129122749R_AX600_W200 (R)@@?Y@:B U1T_0B3B764020210129122749 OPA228OPA228,C:\SPICE\Burr Brn\BB Models- all\OPA228.MODOPA228OPA228Label+!PP(d*3  @d*28 @d*7  @d*4P  @d*6 ( @h 00g+Arial m۶m?g-Arialm۶m?g+Arialm۶m?939@939@ * OPA228N*****************************************************************************v* (C) Copyright 2011 Texas Instruments Incorporated. All rights reserved. N*****************************************************************************H** This model is designed as an aid for customers of Texas Instruments.K** TI and its licensors and suppliers make no warranties, either expressedH** or implied, with respect to this model, including the warranties of F** merchantability or fitness for a particular purpose. The model isK** provided solely on an "as is" basis. The entire risk as to its quality)** and performance is with the customer.N******************************************************************************D* This model is subject to change without notice. Texas Instruments;* Incorporated is not responsible for updating this model.*N******************************************************************************B** Released by: Analog eLab Design Center, Texas Instruments Inc.* Part: OPA228* Date: 01JUL2011* Model Type: ALL IN ONE* Simulator: TINA%* Simulator Version: 9.1.30.94 SF-TI* EVM Order Number: N/A* EVM Users Guide: N/A8* Datasheet: SBOS110A MAY 1998 REVISED JANUARY 2005** Model Version: 1.0*N****************************************************************************** * Updates:** Version 1.0 : * Release to Web*N****************************************************************************** BEGIN MODEL OPA228 * PINOUT 3 2 7 4 6!* PINOUT ORDER +IN -IN +V -V OUT* FEATURES MODELED ARE* OPEN LOOP GAIN AND PHASE* INPUT VOLTAGE NOISE W 1/F* INPUT CURRENT NOISE W 1/F* INPUT BIAS CURRENT* INPUT CAPACITANCE* INPUT COMMON MODE VOLT RANGE* INPUT DIFFERENTIAL CLAMPS* CMRR WITH FREQUENCY EFFECTS* PSRR WITH FREQUENCY EFFECTS * SLEW RATE* QUIESCENT CURRENT* QUIESCENT CURRENT VS VOLTAGE"* OUTPUT CURRENT THROUGH SUPPLIES* OUTPUT CURRENT LIMITING* OUTPUT CLAMPS TO RAILS!* OUTPUT SWING VS OUTPUT CURRENT* END OF FEATURES.SUBCKT OPA228 3 2 7 4 6Q26 8 9 10 QONQ27 11 9 12 QOPQ28 4 13 14 QOPQ29 7 15 16 QON I4 8 15 3E-3I5 13 11 3E-3 R34 17 16 1 R35 14 17 1C6 9 18 100E-12 R36 18 9 1E3G1 9 18 19 0 -1E-3G2 20 18 21 22 -0.5E-2R37 18 20 1E10C7 19 23 25E-12R38 19 20 1.9E3E1 24 18 19 18 1 D2 24 20 DD R39 18 23 77Q30 22 25 26 QINQ31 21 27 28 QINQ32 29 30 31 QNR40 11 31 4.499E3V6 30 32 1.2613R41 22 33 220R42 21 33 220 V7 8 34 2 R45 29 26 1 R46 29 28 1 R47 6 17 10 D1 34 33 DD D3 20 24 DD D4 35 8 DD D5 11 36 DD V8 35 20 1.6 V9 20 36 1.1E6 37 0 8 0 1E7 38 0 11 0 1E8 39 0 40 0 1R48 37 41 100E6R49 38 42 100E6R50 39 43 1000E6 R51 0 41 100 R52 0 42 100 R53 0 43 100E11 44 3 43 0 0.7R54 45 40 1E3R55 40 46 1E3C10 37 41 1E-9C11 38 42 1E-9C12 39 43 1E-12E12 47 44 42 0 0.3E13 48 47 41 0 0.3R60 47 48 1E9R61 44 47 1E9 R62 3 44 1E9E22 45 0 2 0 1E23 46 0 48 0 1E24 49 50 51 52 4.2E-3I7 0 52 100E-6 D6 52 0 DVNI8 0 51 100E-6 D7 51 0 DVN R63 25 48 5 R64 49 27 5Q33 25 25 53 QNQ34 53 53 27 QNQ35 54 54 25 QNQ36 27 27 54 QNE25 11 0 4 0 1E26 8 0 7 0 1I9 7 4 0.3E-3R65 4 7 41.67E3E27 18 0 8 11 0.001C13 2 0 3E-12C14 48 0 3E-12C15 48 2 12E-12 V10 50 2 0 R66 12 15 1 R67 13 10 1I13 48 0 -509.7E-9I14 2 0 -509.7E-9Q37 32 32 11 QNI15 11 30 286E-6 D8 6 7 DOC D9 4 6 DOC .MODEL DD D.MODEL DOC D RS=20.MODEL DVN D KF=1.6E-13.MODEL QN NPN.MODEL QON NPN BF=15 RC=70.MODEL QOP PNP BF=15 RC=95.MODEL QIN NPN BF=270 KF=8E-17.ENDS* END MODEL OPA22832746:BW U2T_0B3B706020210129122749 THS4561FDAp7bSC:\Users\a0232365\AppData\Local\Temp\DesignSoft\{Tina9-TI-09192018-151034}\THS4561SCK#FDAp7bLabelPPd*In+  @d*In- @d*V+  @d*V-t+?d  @d*Out-A @d*Out+?d@ @d*Vocmourier New @h 00g"- Courier New?g"+ Courier New ?g"+ Courier New?g"+ Courier New?g"- Courier New?gVocmArial%I$I?ـk@ـk@* THS4561 - Rev. B.* Created by Hasan Babiker; February 07, 2020B* Created with Green-Williams-Lis Op Amp Macro-model Architecture2* Copyright 2020 by Texas Instruments Corporation7******************************************************$* MACRO-MODEL SIMULATED PARAMETERS:7******************************************************D* OPEN-LOOP GAIN AND PHASE VS. FREQUENCY WITH RL, CL EFFECTS (Aol)* UNITY GAIN BANDWIDTH (GBW)9* INPUT COMMON-MODE REJECTION RATIO VS. FREQUENCY (CMRR)4* POWER SUPPLY REJECTION RATIO VS. FREQUENCY (PSRR)%* DIFFERENTIAL INPUT IMPEDANCE (Zid)$* COMMON-MODE INPUT IMPEDANCE (Zic)0* OPEN-LOOP OUTPUT IMPEDANCE VS. FREQUENCY (Zo)+* OUTPUT CURRENT THROUGH THE SUPPLY (Iout)1* INPUT VOLTAGE NOISE DENSITY VS. FREQUENCY (en)1* 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)3* INPUT OFFSET VOLTAGE VS. TEMPERATURE (Vos Drift)(* INPUT COMMON-MODE VOLTAGE RANGE (Vcm)C* INPUT OFFSET VOLTAGE VS. INPUT COMMON-MODE VOLTAGE (Vos vs. Vcm))* INPUT/OUTPUT ESD CELLS (ESDin, ESDout)7******************************************************/.subckt THS4561 IN+ IN- VCC VEE OUT+ OUT- VOCM7******************************************************4.MODEL R_NOISELESS RES (T_ABS=-273.15)*** $C_C1 MID CLAMP 1.41n'C_C10 MID N2114979 1e-15'C_C11 N2115231 MID 1e-150C_C1a N2115327 N2114145 1.989e-14,C_C1a1 N2114885 N2114927 3e-15/C_C1a11 N2111955 N2111989 4.685e-60C_C1a12 N2113291 N2113331 7.958e-14%C_C1a13 MID VOCM 1.5e-12/C_C1a19 N2116903 N2116955 1.29e-140C_C1a2 N2115007 N2115121 2.375e-160C_C1a20 N2117625 N2117699 4.421e-150C_C1a21 N2119079 N2119089 4.421e-150C_C1a22 N2119415 N2119449 3.183e-150C_C1a23 N2119981 N2119991 2.653e-16+C_C1a24 MID N2120999 4.547e-12/C_C1a25 N2112817 N2112827 9.94e-170C_C1a26 N2113751 N2113777 7.234e-17+C_C1a27 MID N2117451 3.183e-140C_C1a28 N2117489 N2117499 1.768e-140C_C1a29 N2117779 N2117855 1.768e-14,C_C1a3 N2115243 N2115285 1e-160C_C1a30 N2118417 N2118441 3.183e-16-C_C1a31 N2118761 PSRR+ 3.537e-160C_C1a38 N2120785 N2120877 7.958e-14)C_C1a39 MID N2114057 2.5e-11+C_C1a4 MID N2115497 8.842e-14)C_C1a40 MID N2110735 1.2e-11+C_C1b MID N2112369 7.958e-14+C_C1b1 MID N2111543 7.958e-14+C_C1b2 MID N2111751 7.958e-14%C_C33 N2116699 0 1e-15!C_C34 N2116721 0 1%C_C35 N2116851 0 1e-15"C_C37 INN MID 1e-15&C_C38 MID N2113145 5.2p"C_C7 INP MID 1e-15'C_C8 MID N2113479 1e-15'C_C9 MID N2115707 1e-15&C_C_DIFF ESDN ESDP 2.4e-12$C_C_VIMON MID VIMON 1e-12%C_C_VOUT_S MID VOUT_S 1e-12-E_E3 N2119879 MID OUT+ OUT- 1'E_E6 MID 0 N2116721 0 1,E_E7 N2112217 MID ZO+ OUT- 13E_E8 N2115339 MID VEE_CLP VCC_CLP 13E_E9 N2114333 MID VCC_CLP VEE_CLP 14G_G1 N2115327 MID ESDP MID -2.665e-43G_G100 N2120785 MID N2113331 MID -3.5.G_G101 OUT- MID N2110735 MID -1m2G_G102 N2110735 MID N2114057 MID -1m-G_G103 N2110769 MID VOCM MID -1.G_G12 N2112911 MID CLAMP MID -19G_G2 N2116317 N2116311 N2115093 MID -1e-32G_G3 N2115007 MID N2114927 MID -21%G_G36 VCC_B 0 VCC 0 -1%G_G37 VEE_B 0 VEE 0 -15G_G4 N2115243 MID N2115121 MID -1.8338G_G6 N2110521 N2110513 PSRR+ PSRR- -1e-31G_G61 N2112285 MID N2111989 MID -15G_G68 N2114057 MID N2119693 VOUT_CM -1-G_G69 ZO+ MID N2110735 MID -1m1G_G74 N2115457 MID N2115285 MID -15G_G75 N2114885 MID N2114145 MID -2.1115G_G77 N2116903 MID VEE_B MID -4.381e-55G_G78 N2117625 MID N2116955 MID -4.1675G_G79 N2119079 MID N2117699 MID -5.5563G_G8 VCC_CLP MID N2113479 MID -1E-31G_G80 N2119415 MID N2119089 MID -25G_G81 N2119981 MID N2119449 MID -8.3331G_G82 N2120867 MID N2119991 MID -15G_G83 N2112817 MID N2113281 MID -3.1255G_G84 N2113751 MID N2112827 MID -2.2731G_G85 N2117393 MID N2113777 MID -15G_G86 N2117489 MID VCC_B MID -1.982e-65G_G87 N2117779 MID N2117499 MID -1.5e13G_G88 N2118417 MID N2117855 MID -3e17G_G89 N2118761 MID N2118441 MID -3.333e13G_G9 VEE_CLP MID N2115707 MID -1E-31G_G96 N2111501 MID N2111695 MID -11G_G97 N2111709 MID N2111511 MID -1X_S9 ZO+ VCC_CLP ZO+ MID 08_Op_Amp_Complete_S9/X_U1 ESDP N2116651 VNSE_THS4561ZX_VCM_CLAMP_THS4561 N2110521 MID N2116545 MID N2115829 N2113179 VCM_CLAMP_THS4561ZX_VCM_CLAMP_THS45611 N2121557 MID N2121501 MID N2121337 N2110359 VCM_CLAMP_THS4561ZX_VCM_CLAMP_THS45612 N2110725 MID N2119693 MID N2110797 N2110731 VCM_CLAMP_THS4561@X_VOS_DRIFT_THS4561 N2181261 N2116651 VOS_DRIFT_THS4561IX_VOS_VS_VCM_THS4561 N2116311 N2181261 VCC VEE VOS_VS_VCM_THS4561BX_W1 N2110619 ESDN ESDP ESDN 08_Op_Amp_Complete_W1BX_W2 N2110715 ESDP ESDP ESDN 08_Op_Amp_Complete_W2.ENDS THS4561).subckt 08_Op_Amp_Complete_S16 1 2 3 4 S_S16 3 4 1 2 _S16RS_S16 1 2 1G<.MODEL _S16 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S16(.subckt 08_Op_Amp_Complete_S9 1 2 3 4 S_S9 3 4 1 2 _S9RS_S9 1 2 1G;.MODEL _S9 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S9(.subckt 08_Op_Amp_Complete_W2 1 2 3 4 W_W2 3 4 VW_W2 _W2VW_W2 1 2 0V?.MODEL _W2 ISWITCH Roff=10Meg Ron=1 Ioff=6u Ion=6.667u.ends 08_Op_Amp_Complete_W2(.subckt 08_Op_Amp_Complete_H3 1 2 3 4 H_H3 3 4 VH_H3 -1e3VH_H3 1 2 0V.ends 08_Op_Amp_Complete_H3).subckt 08_Op_Amp_Complete_S14 1 2 3 4 S_S14 3 4 1 2 _S14RS_S14 1 2 1G;.MODEL _S14 VSWITCH Roff=270k Ron=1 Voff=11 Von=12.ends 08_Op_Amp_Complete_S14).subckt 08_Op_Amp_Complete_S17 1 2 3 4 S_S17 3 4 1 2 _S17RS_S17 1 2 1G<.MODEL _S17 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S17).subckt 08_Op_Amp_Complete_S15 1 2 3 4 S_S15 3 4 1 2 _S15RS_S15 1 2 1G<.MODEL _S15 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S15(.subckt 08_Op_Amp_Complete_W1 1 2 3 4 W_W1 3 4 VW_W1 _W1VW_W1 1 2 0V?.MODEL _W1 ISWITCH Roff=10Meg Ron=1 Ioff=6u Ion=6.667u.ends 08_Op_Amp_Complete_W1).subckt 08_Op_Amp_Complete_S13 1 2 3 4 S_S13 3 4 1 2 _S13RS_S13 1 2 1G;.MODEL _S13 VSWITCH Roff=270k Ron=1 Voff=11 Von=12.ends 08_Op_Amp_Complete_S13**.subckt AOL_1_THS4561 VC+ VC- IOUT+ IOUT-.param Gain = 0.95e-3.param Ipos = .5.param Ineg = -.58G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}.ends*$**.subckt AOL_2_THS4561 VC+ VC- IOUT+ IOUT-.param Gain = 601.5e-6.param Ipos = 0.37183.param Ineg = -0.3718358G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}.ends*$*5.subckt CLAMP_AMP_LO_THS4561 VC+ VC- VIN COM VO+ VO- .param G=1)* Output G(COM,0) when condition not metOGVo+ COM Vo+ Value = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}OGVo- COM Vo- Value = {IF(V(VIN,COM)X_S9 ZO+ VCC_CLP ZO+ MID 08_Op_Amp_Complete_S9/X_U1 ESDP N2116651 VNSE_THS4561ZX_VCM_CLAMP_THS4561 N2110521 MID N2116545 MID N2115829 N2113179 VCM_CLAMP_THS4561ZX_VCM_CLAMP_THS45611 N2121557 MID N2121501 MID N2121337 N2110359 VCM_CLAMP_THS4561ZX_VCM_CLAMP_THS45612 N2110725 MID N2119693 MID N2110797 N2110731 VCM_CLAMP_THS4561@X_VOS_DRIFT_THS4561 N2181261 N2116651 VOS_DRIFT_THS4561IX_VOS_VS_VCM_THS4561 N2116311 N2181261 VCC VEE VOS_VS_VCM_THS4561BX_W1 N2110619 ESDN ESDP ESDN 08_Op_Amp_Complete_W1BX_W2 N2110715 ESDP ESDP ESDN 08_Op_Amp_Complete_W2.ENDS THS4561).subckt 08_Op_Amp_Complete_S16 1 2 3 4 S_S16 3 4 1 2 _S16RS_S16 1 2 1G<.MODEL _S16 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S16(.subckt 08_Op_Amp_Complete_S9 1 2 3 4 S_S9 3 4 1 2 _S9RS_S9 1 2 1G;.MODEL _S9 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S9(.subckt 08_Op_Amp_Complete_W2 1 2 3 4 W_W2 3 4 VW_W2 _W2VW_W2 1 2 0V?.MODEL _W2 ISWITCH Roff=10Meg Ron=1 Ioff=6u Ion=6.667u.ends 08_Op_Amp_Complete_W2(.subckt 08_Op_Amp_Complete_H3 1 2 3 4 H_H3 3 4 VH_H3 -1e3VH_H3 1 2 0V.ends 08_Op_Amp_Complete_H3).subckt 08_Op_Amp_Complete_S14 1 2 3 4 S_S14 3 4 1 2 _S14RS_S14 1 2 1G;.MODEL _S14 VSWITCH Roff=270k Ron=1 Voff=11 Von=12.ends 08_Op_Amp_Complete_S14).subckt 08_Op_Amp_Complete_S17 1 2 3 4 S_S17 3 4 1 2 _S17RS_S17 1 2 1G<.MODEL _S17 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S17).subckt 08_Op_Amp_Complete_S15 1 2 3 4 S_S15 3 4 1 2 _S15RS_S15 1 2 1G<.MODEL _S15 VSWITCH Roff=2k Ron=1 Voff=-0.1 Von=0.1.ends 08_Op_Amp_Complete_S15(.subckt 08_Op_Amp_Complete_W1 1 2 3 4 W_W1 3 4 VW_W1 _W1VW_W1 1 2 0V?.MODEL _W1 ISWITCH Roff=10Meg Ron=1 Ioff=6u Ion=6.667u.ends 08_Op_Amp_Complete_W1).subckt 08_Op_Amp_Complete_S13 1 2 3 4 S_S13 3 4 1 2 _S13RS_S13 1 2 1G;.MODEL _S13 VSWITCH Roff=270k Ron=1 Voff=11 Von=12.ends 08_Op_Amp_Complete_S13**.subckt AOL_1_THS4561 VC+ VC- IOUT+ IOUT-.param Gain = 0.95e-3.param Ipos = .5.param Ineg = -.58G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}.ends*$**.subckt AOL_2_THS4561 VC+ VC- IOUT+ IOUT-.param Gain = 601.5e-6.param Ipos = 0.37183.param Ineg = -0.3718358G1 IOUT+ IOUT- VALUE={LIMIT(Gain*V(VC+,VC-),Ineg,Ipos)}.ends*$*5.subckt CLAMP_AMP_LO_THS4561 VC+ VC- VIN COM VO+ VO- .param G=1)* Output G(COM,0) when condition not metOGVo+ COM Vo+ Value = {IF(V(VIN,COM)>V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}OGVo- COM Vo- Value = {IF(V(VIN,COM)'dd?Y@[dddd$@?.AeAj@eAMbP?@@?,C6?ư> $ 4@D@ =B?& .>??ư>ư>ư>ư>ư>ư>?I@?I@?I@& .>#i;@& .>-q=ư>MbP?-q=MbP?vIh%<=@@D@& .>?MbP?4@?{Gz?ꌠ9Y>)F@?+= _BKH9$@Y@& .>ư>?.AMbP??????I@Default analysis parameters. These parameters establish convergence and sufficient accuracy for most circuits. In case of convergence or accuracy problems click on the "hand " button to Open other parameter sets.?Xd I@nMbP?{Gz?{Gz?MbP????|=Hz>}Ô%ITNoname