OBSSCircuit DescriptionV1.1010/02/94 20:07 CET.Component & analysis parameters of a circuit.TINA 9.3.200.277 SF-TIB(c) Copyright 1993,94,95,96 DesignSoft Inc. All rights reserved. $Circuit$?[All]minx1=0 maxx1=0.0001 divsx1=10 scalex1=0 miny1=-2maxy1=2 divsy1=4 scaley1=0miny14=9.99999999999999E-11 maxy14=0.001 divsy14=7 scaley14=2minx7=1000000maxx7=100000000 divsx7=2 scalex7=2miny2=0 maxy2=150 divsy2=6 scaley2=1miny4=0 maxy4=150 divsy4=6 scaley4=1 minx2=10maxx2=10000000 divsx2=6 scalex2=2 minx4=10maxx4=10000000 divsx4=6 scalex4=2 miny7=-30 maxy7=90 divsy7=4 scaley7=0miny12=1.638096443E-15maxy12=2.193324758E-6 divsy12=2 scaley12=2 minx12=0.01maxx12=100000000 divsx12=10 scalex12=2[Vout] miny1=-0.01 maxy1=0.05 divsy1=6 scaley1=0 minx1=-0.005 maxx1=0.03 divsx1=7 scalex1=0 miny2=-20 maxy2=10 divsy2=3 scaley2=1 miny4=-20 maxy4=10 divsy4=3 scaley4=1 miny14=1E-14maxy14=0.0001 divsy14=5 scaley14=2 minx14=1maxx14=10000000 divsx14=7 scalex14=2miny12=1.592770114E-9maxy12=1.2931195121E-5 divsy12=2 scaley12=2 minx2=100maxx2=100000000 divsx2=6 scalex2=2 minx4=100maxx4=100000000 divsx4=6 scalex4=2 miny7=-360maxy7=0 divsy7=2 scaley7=0[iN] minx12=1maxx12=1000000000 divsx12=9 scalex12=2 miny12=0.001 maxy12=0.01 divsy12=1 scaley12=2 [Inoise] minx12=0.01maxx12=100000000 divsx12=10 scalex12=2 miny12=1E-14 maxy12=1E-10 divsy12=4 scaley12=2 miny13=0.001 maxy13=0.01 divsy13=1 scaley13=2 minx13=0.01maxx13=100000000 divsx13=10 scalex13=2[ICC] minx1=0.001 maxx1=10 divsx1=2 scalex1=0miny1=0 maxy1=10 divsy1=1 scaley1=0[IBB]miny1=0 maxy1=0.01 divsy1=1 scaley1=0minx1=2maxx1=5 divsx1=3 scalex1=0 [V_1p65v] miny1=1.64 maxy1=1.66 divsy1=1 scaley1=0 [V_2p50v] miny1=2.49 maxy1=2.51 divsy1=1 scaley1=0 [IREF_1uA]miny1=9.98000000000001E-7maxy1=1.001E-6 divsy1=1 scaley1=0 [Bandwidth] miny2=-100.1 maxy2=-99.9 divsy2=1 scaley2=1 miny4=-100.1 maxy4=-99.9 divsy4=1 scaley4=1[ZO]miny2=1 maxy2=1000 divsy2=3 scaley2=2miny4=1 maxy4=1000 divsy4=3 scaley4=2 minx2=0.1maxx2=10000000 divsx2=8 scalex2=2 minx4=0.1maxx4=10000000 divsx4=8 scalex4=2[AOL] minx7=0.01maxx7=100000000 divsx7=10 scalex7=2 miny2=-100 maxy2=150 divsy2=10 scaley2=1 miny4=-100 maxy4=150 divsy4=10 scaley4=1 miny7=-240 maxy7=180 divsy7=7 scaley7=0[PSRR] minx2=10maxx2=100000000 divsx2=7 scalex2=2 minx4=10maxx4=100000000 divsx4=7 scalex4=2miny2=0 maxy2=140 divsy2=7 scaley2=1miny4=0 maxy4=140 divsy4=7 scaley4=1 [Vnoise] miny13=1E-10 maxy13=1E-6 divsy13=4 scaley13=2 minx13=0.01maxx13=100000000 divsx13=10 scalex13=2 miny14=0.001 maxy14=0.002 divsy14=2 scaley14=2 miny12=1E-9 maxy12=1E-6 divsy12=3 scaley12=2 minx12=0.01maxx12=100000000 divsx12=10 scalex12=2[Vout-]miny1=7.806512972maxy1=3.523526751E27 divsy1=1 scaley1=2[PSRRn]miny2=0 maxy2=110 divsy2=5 scaley2=1miny4=0 maxy4=110 divsy4=5 scaley4=1 minx2=10maxx2=100000000 divsx2=7 scalex2=2 minx4=10maxx4=100000000 divsx4=7 scalex4=2[CMRR]miny2=0 maxy2=150 divsy2=5 scaley2=1miny4=0 maxy4=150 divsy4=5 scaley4=1 minx2=0.01maxx2=100000000 divsx2=10 scalex2=2 minx4=0.01maxx4=100000000 divsx4=10 scalex4=2[IB-] miny1=-1E-14 maxy1=1E-14 divsy1=4 scaley1=0[IB+] miny1=-1E-14 maxy1=1E-14 divsy1=4 scaley1=0[Vos]miny1=0 maxy1=7E-7 divsy1=7 scaley1=0 minx1=-50 maxx1=125 divsx1=7 scalex1=0[IBP] miny1=-5E-15 maxy1=5E-15 divsy1=4 scaley1=0[IBN] miny1=0.001 maxy1=0.002 divsy1=1 scaley1=2[IQ+]miny1=0.000274maxy1=0.000276 divsy1=2 scaley1=0[IQ-]miny1=0.000274maxy1=0.000276 divsy1=2 scaley1=0[Ib] miny1=1E-15 maxy1=1E-14 divsy1=1 scaley1=2[I_TIA]miny1=9.981704352E-11maxy1=9.83845893644E-10 divsy1=1 scaley1=2 [I_Zener]miny1=9.09513518833E-13maxy1=0.001005348849 divsy1=1 scaley1=2 [Vguard]miny1=6.10008892E-6maxy1=0.79095568086 divsy1=1 scaley1=2[Vn]miny1=2.111362614E-6maxy1=3.022432943E-6 divsy1=1 scaley1=2[V_IN] miny1=-0.49 maxy1=0.51 divsy1=1 scaley1=0 [eN_Ch_B]miny12=4.464613169E-9maxy12=2.004853372E-6 divsy12=1 scaley12=2 [en_Ch_A]miny12=4.464613169E-9maxy12=2.004853372E-6 divsy12=1 scaley12=2[eN_A] miny12=1E-9 maxy12=1E-5 divsy12=4 scaley12=2[eN_B] miny12=1E-9 maxy12=1E-5 divsy12=4 scaley12=2[iN_A] miny12=1E-13 maxy12=1E-11 divsy12=2 scaley12=2[iN_B] miny12=1E-13 maxy12=1E-11 divsy12=2 scaley12=2 [Vin_Ccm] minx2=0.01 maxx2=100000 divsx2=7 scalex2=2 minx4=0.01 maxx4=100000 divsx4=7 scalex4=2 miny2=-40maxy2=0 divsy2=4 scaley2=1 miny4=-40maxy4=0 divsy4=4 scaley4=1[Vfb] miny2=-35maxy2=0 divsy2=5 scaley2=1 miny4=-35maxy4=0 divsy4=5 scaley4=1 minx2=100maxx2=10000000 divsx2=5 scalex2=2 minx4=100maxx4=10000000 divsx4=5 scalex4=2#<??ƚN3*l N3 EMF~ DpRpMS Sans Serif"`"JL""" cc MS Sans Serif!uu cP    "P ""(! " I"(! (! ɢ uu""C !l"" !u"ou!""dv%  '%   TT UAA LPT % RpArial?1w?893'"wX?wqmX89?Arialu "AC((''!l"" !u"u"989?nA?89,"WT[!"(''dv%  % RpArial t"DwHuArial0000000u," 33 HkѮZ0100000000000000000dv%  % %  % %  % %  % %  % %  % %  % %  % %  % % %  %   +% %   +% 55&%  656% nn&%  6n6% n@n@%  6@nn6nznz6z% nn%  6nn6% nn&%  6% %  &%    T|UAAL\Time (s)  % %    TdeUAAeLT0.00  % nn%  6n6666666  6 !!6!% %    Tl,XUAA,LX1.00m  Y% 55%  65II6I]]6]qq6q666666% %    TlUAALX2.00m   % %  66$$6$8868LL6L``6`ss6s666% %    TlUAALX3.00m  % %  6% nn6n% %  %    % Rp Arial"3F!F""?uFH!FiѮp,",":@u3pۏ?upL(("Cul"D",čv!Fl"NAI"'C!Fl"B ) 'C"#/@"2]@-EMdv%  TpUAALXOutput  3% ( %  % %    Tl9\UAA9LX-1.00  ]% ``%  6nkk6nkk6nkk6nk{k{6n{hqhq6nqkgkg6ngk]k]6n]kSkS6nSkIkI6nI% %    T|5\GUAA5L\-500.00m  ]5% `@`@%  6n@k6k66n6k,k,6n,k"k"6n"kk6nhh6nkk6nkk6nkk6nkk6n% %    Td>\UAA>LT0.00  ]% ``%  6nkk6nkk6nkk6nkk6nhh6nkk6nkk6nkk6nkk6n% %    Txp\UAApL\500.00m  ]p% `z`z%  6nzkqkq6nqkgkg6ngk]k]6n]kSkS6nShIhI6nIk?k?6n?k6k66n6k,k,6n,k"k"6n"% %    Td> \UAA> LT1.00  ] % ``%  6n% % nn& %  6qq6uu6xx6{{6zz6ii6YY6KK6>>6226))6""666666""6))6226>>6KK6YY6ii6{{666666666--6@@6QQ6aa6oo6||66666666  6  666||6oo6aa6!Q!Q6$?$?6(-(-6++6..6226556886<<6??6BB6F{F{6IiIi6LYLY6PKPK6S>S>6V2V26Y)Y)6]"]"6``6cc6gg6jj6mm6q"q"6t)t)6w2w26{>{>6~K~K6YY6ii6zz666666666--6??6QQ6aa6oo6||666666666666||6oo6aa6QQ6@@6--66666666  6 { {6ii6YY6KK6>>6226 ) )6$"$"6''6**6..61164468"8"6;);)6>2>26B>B>6EKEK6HYHY6LiLi6OzOz6RR6VV6YY6\\6__6cc6ff6ii6m-m-6p?p?6sQsQ6wawa6zozo6}|}|666666666666||6oo6aa6QQ6@@6--6666% nn& %  6ss6uu6xx6}}6kk6SS6??6..6""6666!!6,,6<<6PP6gg6666666--6HH6aa6vv666666  666pp6YY6$@$@6)$)$6..6336886==6BB6GrGr6LYLY6QDQD6V3V36[%[%6``6ee6jj6oo6t)t)6y8y86~J~J6aa6zz666666--6HH6aa6vv666666666xx6cc6JJ6//666666 } }6cc6LL6996 * *6#"#"6((6--62267!7!6<,<,6A<A<6FPFP6KgKg6PP6UU6ZZ6__6cc6hh6m.m.6rIrI6wawa6|w|w666666666oo6XX6??6##666% nn& %  6ss6uu6xx6}}6kk6SS6??6..6""6666!!6,,6<<6PP6gg6666666--6HH6aa6vv666666  666pp6YY6$@$@6)$)$6..6336886==6BB6GrGr6LYLY6QDQD6V3V36[%[%6``6ee6jj6oo6t)t)6y8y86~J~J6aa6zz666666--6HH6aa6vv666666666xx6cc6JJ6//666666 } }6cc6LL6996 * *6#"#"6((6--62267!7!6<,<,6A<A<6FPFP6KgKg6PP6UU6ZZ6__6cc6hh6m.m.6rIrI6wawa6|w|w666666666oo6XX6??6##666% % %  % %  % %  % %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  & %  %   +B`% % ( % %  % %  % %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!FP"C1 Fp"@u "CSymbol "CI ""Dw1 w "CIP"DwX) 1wB "P1 "CX) ,C4CII"CSymboldv%  % ( %  %  %   +B`% %   % '%  6 '% %   Tx 3/UAA L\ Vin " 4% Rp SymbolC!F0"C1 Fp"@u"CSymbol "CI""Dw1 w"CIP"DwX) 1wB"P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!F0"C1 Fp"@u"CSymbol "CI""Dw1 w"CIP"DwX) 1wB"P1 "CX) ,C4CII"CSymboldv%  % ( %  % =%  6 =% %   Tx 48EUAA 4L\ Vos " 94% Rp SymbolC!F0"C1 Fp"@u"CSymbol "CI""Dw1 w"CIP"DwX) 1wB"P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!F0"C1 Fp"@u"CSymbol "CI""Dw1 w"CIP"DwX) 1wB"P1 "CX) ,C4CII"CSymboldv%  % ( %  % S%  6 S% %   T| J<[UAA JL\ Vout  =J% Rp SymbolC!F0"C1 Fp"@u"CSymbol "CI""Dw1 w"CIP"DwX) 1wB"P1 "CX) ,C4CII"CSymboldv%  % ( %  % Rp SymbolC!F0"C1 Fp"@u"CSymbol "CI""Dw1 w"CIP"DwX) 1wB"P1 "CX) ,C4CII"CSymboldv%  % ( %  % % % G#VER=1.0Font0=Verdana,14Font1=Verdana,14,BRect0=2,0,0,85,22Rect1=1,0,0,85,10Rect2=1,0,10,10,17Rect3=1,10,10,75,17Rect4=1,75,10,85,17Rect5=1,0,17,50,22Rect6=1,50,17,85,22Text0=0,2,2,TitleText1=0,2,11,SizeText2=0,2,18,DateText3=0,12,11,Document No.Text4=0,77,11,RevText5=0,52,18,SheetText6=0,70,18,ofField0=1,T,11,2,80Field1=1,T,11,5,80Field2=1,S,4,13,5Field3=1,T,14,13,40Field4=1,R,78,13,6Field5=1,D,12,18,30Field6=1,P,64,18,3Field7=1,A,77,18,3FF0=TLV916x 16V, 11MHz, Rail-to-Rail Input/Output, Low Offset Voltage,9F3=Datasheet: SBOSA68D - NOV '21 - Rev MAR '24 EVM: N/AF4=1.1F5=NOV 06 2025F6=1F7=1(F1=Low Noise Op- Amp (GWL Architecture) 1Y@1Y Arial46******************************************************<** Released by: Online Design Tools, Texas Instruments Inc.8* Model Type: Generic (suitable for all analysis types)* EVM Order Number: NA* EVM Users Guide: NA.* Datasheet: SBOSA68D - NOV '21 - REV MAR '24B* Created with Green-Williams-Lis Op Amp Macro-model Architecture'* Released by: Srivatsan Sathyamoorthy* Date: 11/06/2025* Part: TLV916x** Top Level Model: TLV916x* Model Version: 1.1*7******************************************************$* 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******************************************************* PARAMETERS NOT MODELED7******************************************************<* (1) Variations in Process, Temperature and Supply voltage* (2) Min &/ Max specs*7******************************************************Symbol????333333?? @ Arial+TLV916x TINA-TI Reference Design based on *Green-Williams-Lis SPICE simulation modelSymbol????333333??M]P@]P Arial SIMULATION EXAMPLES:ACircuit configurations altered as needed for the particular test@eAY@? B08C2T_03C675B020200812152745CP_CYL300_D700_L1400 (C) Iz>@eAY@?DBX*VnT_03C66FD020200812152745 JP100 (V) @Bq`VosT_03C6585020200812152745 NOPCB (VF) BCLT_03C6527020200812152745CP_CYL300_D700_L1400 (C) dy=@eAY@?B %VinT_0CFAC02020241002133534 JP100 (VG)?@@V BR1T_0CFA7F8020241002133701R_AX600_W200 (R)@@?Y@:BT(pU1T_0E17508020251106105434 TLV916x OpAmp5-TISC:\Users\a0870489\AppData\Local\Temp\DesignSoft\{Tina9-TI-09222022-121705}\TLV916xSCK# OpAmp5-TILabel#PP(d*18  @d*2 @d*5TabOr  @d*3nd0 @d*4[0 @h 00g"- Courier New?g"+ Courier New ?g"+ Courier New?'q@'q@ * TLV916xy************************************************************************************************************************O* (C) Copyright 2025 Texas Instruments Incorporated. All rights reserved. y************************************************************************************************************************N** This model is designed as an aid for customers of Texas Instruments. N** TI and its licensors and suppliers make no warranties, either expressed N** or implied, with respect to this model, including the warranties of M** merchantability or fitness for a particular purpose. The model is M** provided solely on an "as is" basis. The entire risk as to its quality (** and performance is with the customery*************************************************************************************************************************y*************************************************************************************************************************<** Released by: Online Design Tools, Texas Instruments Inc.8* Model Type: Generic (suitable for all analysis types)* EVM Order Number: NA* EVM Users Guide: NA.* Datasheet: SBOSA68D - NOV '21 - REV MAR '24B* Created with Green-Williams-Lis Op Amp Macro-model Architecture'* Released by: Srivatsan Sathyamoorthy* Date: 11/06/2025* Part: TLV916x** Top Level Model: TLV916x* Model Version: 1.1*y************************************************************************************************************************* * Updates:* * Final 1.1m* 1. Uniquify the sub-circuit calls to prevent overlapping with existing models and/or PSpice keywords.** 2. No changes to the model itself.* * Final 1.01* Release to Web. [Created by: Carolina Walters]*y************************************************************************************************************************1* MODEL NOTES: MACRO-MODEL SIMULATED PARAMETERS:y*************************************************************************************************************************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)*y************************************************************************************************************************$.SUBCKT TLV916x IN+ IN- VCC VEE OUTy************************************************************************************************************************ * Models:.MODEL BB_SW VSWITCH (RON=50 ROFF=1E12 VON=700E-3 VOFF=0);.MODEL ESD_SW VSWITCH (RON=50 ROFF=1E12 VON=250E-3 VOFF=0)@.MODEL OL_SW VSWITCH (RON=1E-3 ROFF=1E9 VON=900E-3 VOFF=800E-3):.MODEL OR_SW VSWITCH (RON=10E-3 ROFF=1E9 VON=1E-3 VOFF=0)$.MODEL R_NOISELESS RES (T_ABS=-273)?.MODEL S_VSWITCH_1 VSWITCH (RON=50 ROFF=1T VON=500M VOFF=450M)?.MODEL S_VSWITCH_2 VSWITCH (RON=50 ROFF=1T VON=500M VOFF=450M)?.MODEL S_VSWITCH_3 VSWITCH (RON=50 ROFF=1T VON=500M VOFF=450M)?.MODEL S_VSWITCH_4 VSWITCH (RON=50 ROFF=1T VON=500M VOFF=450M)<.MODEL S_VSWITCH_5 VSWITCH (RON=10M ROFF=1G VON=10M VOFF=0)<.MODEL S_VSWITCH_6 VSWITCH (RON=10M ROFF=1G VON=10M VOFF=0)?.MODEL S_VSWITCH_7 VSWITCH (RON=1M ROFF=1G VON=900M VOFF=800M)?.MODEL S_VSWITCH_8 VSWITCH (RON=50 ROFF=1T VON=500M VOFF=450M)?.MODEL S_VSWITCH_9 VSWITCH (RON=50 ROFF=1T VON=500M VOFF=450M)y************************************************************************************************************************ * ComponentsC_CMN ESDN MID 1P C_CMP MID ESDP 1P C_DIFF ESDP ESDN 9P C_VCLP VCLP MID 100P C_VIMON VIMON MID 1N C_VOUT_S VOUT_S MID 1N C1 51 52 159.2P C1B 49 50 159F C2 CLAMP MID 184.6N IC=0C3 27 MID 5F IC=0C4 46 47 176.8P C5 44 45 3.183P C6 41 42 159.2P C7 29 MID 1F C8 MID 78 1F C9 79 MID 1F C10 82 MID 1F C11 MID 83 1F C12 74 MID 1F C13 MID 75 1F C14 58 MID 1F C15 MID 59 1F C16 55 MID 1F C17 62 MID 1P C18 60 MID 1P C19 SW_OL MID 1P C21 38 39 90N IC=0C22 34 MID 75.07F IC=0C23 31 MID 8P IC=0 C33 94 0 1F C34 92 0 100N C35 93 0 1F E2 87 MID CL_CLAMP MID 1E3 86 MID OUT MID 1E6 MID 0 92 0 1G_1 52 MID ESDP MID -7.924MG_2 48 MID 49 MID -6"G_ADJUST 42 MID VEE_B MID -802.1MG_ADJUST1 33 MID 39 MID 22.58G_ADJUST2 36 MID 32 MID 1$G_AOL_ZO 38 MID CL_CLAMP 40 -368.16G_CMR 96 25 48 MID -1MG6 91 95 43 41 -1MG8 VCC_CLP MID 78 MID -1MG9 VEE_CLP MID 79 MID -1MG10 66 MID 67 MID -1G11 64 MID 65 MID -1G12 VSENSE MID CLAMP MID -1MG15 CLAW_CLAMP MID 27 MID -1M$G16 CL_CLAMP MID CLAW_CLAMP MID -1MG36 VCC_B 0 VCC 0 -1G37 VEE_B 0 VEE 0 -1GVCCS1 50 MID 51 MID -1 GVCCS2 47 MID VCC_B MID -1.761MGVCCS3 45 MID 46 MID -1GVCCS4 43 MID 44 MID -400GVCCS5 27 MID VSENSE MID -1UH2 63 MID V11 -1H3 61 MID V12 1H3_2 85 MID V4 1KI_B 26 MID 10PI_OS ESDN MID 0I_Q VCC VEE 2.4MR_CMR 25 96 R_NOISELESS 1K R_VCLP 87 VCLP R_NOISELESS 100 "R_VIMON 85 VIMON R_NOISELESS 100 $R_VOUT_S 86 VOUT_S R_NOISELESS 100 R1 IN+ ESDP R_NOISELESS 10M R1B 50 49 R_NOISELESS 1MEG R2 IN- ESDN R_NOISELESS 10M R2B MID 49 R_NOISELESS 200K R3 MID ESDP R_NOISELESS 1T R4 ESDN MID R_NOISELESS 1T R5 52 51 R_NOISELESS 1MEG R6 MID 51 R_NOISELESS 200 R7 37 MID 1 R8 MID 47 R_NOISELESS 1 R9 95 96 R_NOISELESS 1M R10 30 ESDN R_NOISELESS 1M R11 38 MID R_NOISELESS 1 &R12 INP_ESDN INP_ESDP R_NOISELESS 50 &R13 INN_ESDP INN_ESDN R_NOISELESS 50 R14 MID 50 R_NOISELESS 1 R15 MID 48 R_NOISELESS 1 R16 47 46 R_NOISELESS 1MEG R17 MID 46 R_NOISELESS 900.8 R18 MID 45 R_NOISELESS 1 R19 45 44 R_NOISELESS 1MEG R20 MID 44 R_NOISELESS 2.506K R21 95 91 R_NOISELESS 1K R22 MID 43 R_NOISELESS 1 R23 MID 42 R_NOISELESS 1 R24 42 41 R_NOISELESS 100MEG R25 MID 89 R_NOISELESS 1G R26 90 MID R_NOISELESS 1G R27 MID 88 R_NOISELESS 1 R28 29 88 R_NOISELESS 1M R29 76 VCC_B R_NOISELESS 1K R30 76 78 R_NOISELESS 1M R31 VCC_CLP MID R_NOISELESS 1K R32 VEE_B 77 R_NOISELESS 1K R33 79 77 R_NOISELESS 1M R34 MID VEE_CLP R_NOISELESS 1K R35 VCC_CLP MID R_NOISELESS 1G R36 80 MID R_NOISELESS 1 R37 80 82 R_NOISELESS 1M R38 81 83 R_NOISELESS 1M R39 MID 81 R_NOISELESS 1 R40 VEE_CLP MID R_NOISELESS 1G R41 68 MID R_NOISELESS 1G R42 70 MID R_NOISELESS 1 R43 70 74 R_NOISELESS 1M R44 71 75 R_NOISELESS 1M R45 MID 71 R_NOISELESS 1 R46 MID 69 R_NOISELESS 1G R47 66 MID R_NOISELESS 1 R48 MID 64 R_NOISELESS 1 R49 53 MID R_NOISELESS 1G R50 56 MID R_NOISELESS 1 R51 56 58 R_NOISELESS 1M R52 57 59 R_NOISELESS 1M R53 MID 57 R_NOISELESS 1 R54 54 MID R_NOISELESS 1G R55 VSENSE 55 R_NOISELESS 1M R56 63 62 R_NOISELESS 100 R57 61 60 R_NOISELESS 100 R58 84 MID R_NOISELESS 1 R59 84 SW_OL R_NOISELESS 100 R60 MID 28 R_NOISELESS 1MEG R61 MID CLAMP R_NOISELESS 1MEG R62 MID VSENSE R_NOISELESS 1K R63 MID 41 R_NOISELESS 111.1 R64 33 MID R_NOISELESS 1 #R65 MID CLAW_CLAMP R_NOISELESS 1K !R66 MID CL_CLAMP R_NOISELESS 1K R67 39 38 R_NOISELESS 10K R68 39 MID R_NOISELESS 463.4 R69 36 MID R_NOISELESS 1 R70 35 36 R_NOISELESS 18.38K R71 34 35 R_NOISELESS 10K R72 32 33 R_NOISELESS 352K R73 31 32 R_NOISELESS 10K R74 MID 27 R_NOISELESS 1MEG R81 MID 85 R_NOISELESS 1G R83 MID 86 R_NOISELESS 1G R107 VCC_B 0 R_NOISELESS 1 R108 92 0 R_NOISELESS 1T R109 VEE_B 0 R_NOISELESS 1 R110 VCC_B 94 R_NOISELESS 1M R111 94 92 R_NOISELESS 1MEG R112 92 93 R_NOISELESS 1MEG R113 93 VEE_B R_NOISELESS 1M !RDUMMY MID 40 R_NOISELESS 1.01K RSRC MID 52 R_NOISELESS 1 RX 40 37 R_NOISELESS 10.1K S1 38 39 SW_OL MID S_VSWITCH_7)S2 INN_ESDP VCC INN_ESDP VCC S_VSWITCH_3)S3 INP_ESDP VCC INP_ESDP VCC S_VSWITCH_4)S4 VEE INN_ESDN VEE INN_ESDN S_VSWITCH_2)S5 VEE INP_ESDN VEE INP_ESDN S_VSWITCH_1S6 OUT VCC OUT VCC S_VSWITCH_9S7 VEE OUT VEE OUT S_VSWITCH_8&SOR_SWN 73 CLAMP 73 CLAMP S_VSWITCH_6&SOR_SWP CLAMP 72 CLAMP 72 S_VSWITCH_5V_GRN 54 MID -35V_GRP 53 MID 50V_ISCN 69 MID -65V_ISCP 68 MID 65V_ORN 67 VCLP -3.84V_ORP 65 VCLP 4.32V_OS 25 26 -32U V4 40 OUT 0 V11 73 66 0 V12 72 64 0VCM_MAX 90 VCC_B 0VCM_MIN 89 VEE_B 05XCL_AMP 68 69 VIMON MID 70 71 CLAMP_AMP_LO_0_TLV916x0XCL_SRC 74 75 CL_CLAMP MID VCCS_LIM_4_0_TLV916xBXCLAW_AMP VCC_CLP VEE_CLP VOUT_S MID 80 81 CLAMP_AMP_LO_0_TLV916x4XCLAW_SRC 82 83 CLAW_CLAMP MID VCCS_LIM_3_0_TLV916x3XCLAWN MID VIMON VEE_B 77 VCCS_LIM_CLAW-_0_TLV916x3XCLAWP VIMON MID 76 VCC_B VCCS_LIM_CLAW+_0_TLV916xXE_N ESDP 26 VNSE_0_TLV916x2XGR_AMP 53 54 55 MID 56 57 CLAMP_AMP_HI_0_TLV916x.XGR_SRC 58 59 CLAMP MID VCCS_LIM_GR_0_TLV916xXI_N MID 26 FEMT_0_TLV916xXIN11 ESDN MID FEMT_0_TLV916x/XIQN MID VIMON VEE MID VCCS_LIMIT_IQ_0_TLV916x/XIQP VIMON MID MID VCC VCCS_LIMIT_IQ_0_TLV916x*XOL_SENSE MID 84 62 60 OL_SENSE_0_TLV916x.XVCCS_LIM_1 29 30 MID 28 VCCS_LIM_1_0_TLV916x2XVCCS_LIM_2 28 MID MID CLAMP VCCS_LIM_2_0_TLV916x1XVCCS_LIM_ZO 34 MID MID 37 VCCS_LIM_ZO_0_TLV916x6XVCM_CLAMP 91 MID 88 MID 90 89 VCCS_EXT_LIM_0_TLV916x.ENDS TLV916xy************************************************************************************************************************y************************************************************************************************************************7.SUBCKT CLAMP_AMP_HI_0_TLV916x VC+ VC- VIN COM VO+ VO-)**************************************** * Parameters .PARAM G=10)**************************************** * ComponentsOGVO- COM VO- VALUE = {IF(V(VIN,COM)V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}.ENDS CLAMP_AMP_HI_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************7.SUBCKT CLAMP_AMP_LO_0_TLV916x VC+ VC- VIN COM VO+ VO-)**************************************** * Parameters .PARAM G=1)**************************************** * ComponentsOGVO- COM VO- VALUE = {IF(V(VIN,COM)V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}.ENDS CLAMP_AMP_LO_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************.SUBCKT FEMT_0_TLV916x 1 2)**************************************** * Parameters.PARAM FLWF=1E-3'.PARAM GLFF={PWR(FLWF,0.25)*NLFF/1164}.PARAM NLFF=60.PARAM NVRF=60 .PARAM RNVF={1.184*PWR(NVRF,2)})**************************************** * Models3.MODEL DVNF D (KF={PWR(FLWF,0.5)/1E11} IS=1.0E-16))**************************************** * Components D1 7 0 DVNF D2 8 0 DVNF E1 3 6 7 8 {GLFF}E2 6 4 5 0 10G1 1 2 3 4 1E-6 I1 0 7 10E-3 I2 0 8 10E-3 R1 3 0 1E9 R2 3 0 1E9 R3 3 6 1E9 R4 5 0 {RNVF} R5 5 0 {RNVF} R6 3 4 1E9 R7 4 0 1E9 .ENDS FEMT_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************+.SUBCKT OL_SENSE_0_TLV916x COM SW+ OLN OLP)**************************************** * ComponentsCGSW+ COM SW+ VALUE = {IF((V(OLN,COM)>10E-3|V(OLP,COM)>10E-3),1,0)}.ENDS OL_SENSE_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************=.SUBCKT VCCS_EXT_LIM_0_TLV916x VIN+ VIN- IOUT- IOUT+ VP+ VP-)**************************************** * Parameters.PARAM GAIN=1)**************************************** * ComponentsHG1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VIN+,VIN-),V(VP-,VIN-),V(VP+,VIN-))}.ENDS VCCS_EXT_LIM_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************1.SUBCKT VCCS_LIM_1_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * Parameters.PARAM GAIN=1E-4.PARAM INEG=-.5.PARAM IPOS=.5)**************************************** * Components8G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS VCCS_LIM_1_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************1.SUBCKT VCCS_LIM_2_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * Parameters.PARAM GAIN=1.26E-1.PARAM INEG=-5.9.PARAM IPOS=6.64)**************************************** * Components8G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS VCCS_LIM_2_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************1.SUBCKT VCCS_LIM_3_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * Parameters.PARAM GAIN=1.PARAM INEG=-70E-3.PARAM IPOS=100E-3)**************************************** * Components8G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS VCCS_LIM_3_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************1.SUBCKT VCCS_LIM_4_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * Parameters.PARAM GAIN=1.PARAM INEG=-200E-3.PARAM IPOS=200E-3)**************************************** * Components8G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS VCCS_LIM_4_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************5.SUBCKT VCCS_LIM_CLAW-_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * ComponentspG1 IOUT+ IOUT- TABLE {(V(VC+,VC-))} =(0, 7.59E-5)(40, 1.21E-3)(60, 2E-3)(70, 2.61E-3)(80, 4.42E-3)(90, 9.61E-3).ENDS VCCS_LIM_CLAW-_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************5.SUBCKT VCCS_LIM_CLAW+_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * ComponentsuG1 IOUT+ IOUT- TABLE {(V(VC+,VC-))} =(0, 6.87E-5)(15, 4.04E-4)(30, 7.93E-4)(45, 1.27E-3)(60, 1.8E-3)(70, 2.4E-3)(80,+ 3.75E-3)(90, 9.83E-3).ENDS VCCS_LIM_CLAW+_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************2.SUBCKT VCCS_LIM_GR_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * Parameters.PARAM GAIN=1.PARAM INEG=-12.PARAM IPOS=14)**************************************** * Components8G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS VCCS_LIM_GR_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************2.SUBCKT VCCS_LIM_ZO_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * Parameters.PARAM GAIN=1.PARAM INEG=-2E3.PARAM IPOS=2E3)**************************************** * Components8G1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VC+,VC-),INEG,IPOS)}.ENDS VCCS_LIM_ZO_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************4.SUBCKT VCCS_LIMIT_IQ_0_TLV916x VC+ VC- IOUT+ IOUT-)**************************************** * Parameters.PARAM GAIN=1E-3)**************************************** * Components=G1 IOUT- IOUT+ VALUE={IF((V(VC+,VC-)<=0),0,GAIN*V(VC+,VC-))}.ENDS VCCS_LIMIT_IQ_0_TLV916xy************************************************************************************************************************y************************************************************************************************************************.SUBCKT VNSE_0_TLV916x 1 2)**************************************** * Parameters.PARAM FLW=10$.PARAM GLF={PWR(FLW,0.25)*NLF/1164}.PARAM NLF=64.13 .PARAM NVR=4.PARAM RNV={1.184*PWR(NVR,2)})**************************************** * Models1.MODEL DVN D (KF={PWR(FLW,0.5)/1E11} IS=1.0E-16))**************************************** * Components D1 7 0 DVN D2 8 0 DVN E1 3 6 7 8 {GLF}E2 6 4 5 0 10 E3 1 2 3 4 1 I1 0 7 10E-3 I2 0 8 10E-3 R1 3 0 1E9 R2 3 0 1E9 R3 3 6 1E9 R4 5 0 {RNV} R5 5 0 {RNV} R6 3 4 1E9 R7 4 0 1E9 .ENDS VNSE_0_TLV916xy************************************************************************************************************************12345Bf(T_03C646B020200812152745 NOPCB (GND)BfhT_03C640D020200812152745 NOPCB (GND)Bfh@T_03C63AF020200812152745 NOPCB (GND)BfhT_03C69ED020200812152745 NOPCB (GND)BfT_03C6931020200812152745 NOPCB (GND)BfT_03C68D3020200812152745 NOPCB (GND)8?= ]@"MbP??ư>'dd?Y@[dddd??.AחA.AeAMbP?@@?~jth?ư> $ 4@D@ =B?& .>??ư>ư>ư>ư>ư>ư>?I@?I@?I@& .>#;@& .>-q=ư>MbP?-q=MbP?vIh%<=@@D@& .>?MbP?4@?{Gz?ꌠ9Y>)F @?+= _BKH9$@Y@& .>ư>?.AMbP??????I@?Xd I@nMbP?{Gz?{Gz?MbP????|=Hz>}Ô%ITNoname