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. $Circuit$? [ZoOhms] miny2=140 maxy2=170 divsy2=1 scaley2=1 miny4=140 maxy4=170 divsy4=1 scaley4=1 minx2=100maxx2=100000000 divsx2=6 scalex2=2 minx4=100maxx4=100000000 divsx4=6 scalex4=2[Zo]miny2=121.866696762maxy2=121.866696763 divsy2=2 scaley2=1miny4=121.866696762maxy4=121.866696763 divsy4=2 scaley4=1[AM1]miny1=-1.1E-5 maxy1=1.1E-5 divsy1=1 scaley1=0[All] minx1=3E-6 maxx1=4E-6 divsx1=4 scalex1=0 miny2=-40 maxy2=120 divsy2=8 scaley2=1 miny4=-40 maxy4=120 divsy4=8 scaley4=1 minx2=0.1maxx2=1000000 divsx2=7 scalex2=2 minx4=0.1maxx4=1000000 divsx4=7 scalex4=2 miny1=-1maxy1=1 divsy1=4 scaley1=0 minx7=10maxx7=10000000 divsx7=6 scalex7=2miny7=0 maxy7=180 divsy7=2 scaley7=0[Out] miny2=-40 maxy2=10 divsy2=5 scaley2=1 miny4=-40 maxy4=10 divsy4=5 scaley4=1 miny7=-300 maxy7=100 divsy7=4 scaley7=0 [Inoise]miny12=1.989615138E-15maxy12=1.128258429E-12 divsy12=2 scaley12=0[Vout] miny1=-0.5 maxy1=0.5 divsy1=1 scaley1=0 minx1=25 maxx1=50 divsx1=2 scalex1=0 miny12=0 maxy12=2E-14 divsy12=4 scaley12=0 miny2=-40 maxy2=125 divsy2=4 scaley2=1 miny4=-40 maxy4=125 divsy4=4 scaley4=1 minx2=0.1maxx2=1000000 divsx2=7 scalex2=2 minx4=0.1maxx4=1000000 divsx4=7 scalex4=2[Vfb]minx2=1maxx2=100000000 divsx2=8 scalex2=2minx4=1maxx4=100000000 divsx4=8 scalex4=2 miny2=-60maxy2=0 divsy2=3 scaley2=1 miny4=-60maxy4=0 divsy4=3 scaley4=1[VF1] miny1=-8maxy1=8 divsy1=8 scaley1=0 minx2=0.001maxx2=1000000000 divsx2=6 scalex2=2 minx4=0.001maxx4=1000000000 divsx4=6 scalex4=2[CMRR] miny2=-100 maxy2=200 divsy2=3 scaley2=1 miny4=-100 maxy4=200 divsy4=3 scaley4=1 minx2=100maxx2=100000000 divsx2=6 scalex2=2 minx4=100maxx4=100000000 divsx4=6 scalex4=2[Vo]miny1=0maxy1=5 divsy1=5 scaley1=0[Aol] minx7=10maxx7=10000000 divsx7=6 scalex7=2[PSRRp] minx2=100maxx2=100000000 divsx2=6 scalex2=2 minx4=100maxx4=100000000 divsx4=6 scalex4=2[PSRRn] minx2=100maxx2=100000000 divsx2=6 scalex2=2 minx4=100maxx4=100000000 divsx4=6 scalex4=2[SIN+] minx7=10maxx7=100000000 divsx7=7 scalex7=2[Vout_Charge_Amp] miny1=1.64 maxy1=1.66 divsy1=1 scaley1=0 miny2=-60maxy2=0 divsy2=6 scaley2=1 miny4=-60maxy4=0 divsy4=6 scaley4=1 minx2=0.1maxx2=1000000 divsx2=7 scalex2=2 minx4=0.1maxx4=1000000 divsx4=7 scalex4=2[VG1]miny1=0 maxy1=0.0015 divsy1=1 scaley1=0 [Vsensor]miny1=0 maxy1=0.002 divsy1=1 scaley1=0;(o_?|?ƚJ$l9l]J$ EMFQ8%xRpMS Sans SerifTI" IP"  P$#H8"iPP"IP" I"M"uz\""M 4Cz MNM 4"z"<+w_ul"^udv%  '%   TT *tAqtA LPT  % RpArial=FQ@" IFp""uy0100000000000000000"Cdv%  % RpArial/``rY0600009999999999872u,"H($l"/`(d/`N` /`N` 9wł" `!2dv%  % %  % %  % %  % %  % %  % %  % %  % %  % % %  %   +i% %   +i% nn&%  6n66666666664464NN6Naa6app6p||6|66666666666''6'//6/66666666cc6c~~6~6666666666))6)8868DD6DNN6NWW6W^^6^ee6eee6e6666666666++6+FF6FYY6Ygg6gss6s}}6}66% nn&%  6n6% nn%  6nLnL6Lnn6nn6% nn%  6nn6% nn&%  6% %  &%    TdG]*tAqtAdGLhFrequency (Hz)   G% %    Txc+B*tAqtAc+L\100.00m  +% nn%  6n'66666666% %    Td+!B*tAqtA+LT1.00  "+% %  6'4464NN6Naa6app6p||6|666% %    Tl+B*tAqtA+LX10.00  +% %  6'666666''6'//6/% %    Tp++gB*tAqtA++LX100.00  h+% 66%  66'cc6c~~6~666666% %    Tl+B*tAqtA+LX1.00k  +% %  6'66))6)8868DD6DNN6NWW6W^^6^% %    TpZ+B*tAqtAZ+LX10.00k  +% ee%  6e'66666666% %    Tx+9B*tAqtA+L\100.00k  9+% %  6'++6+FF6FYY6Ygg6gss6s}}6}66% %    Tx+B*tAqtA+L\1.00MEG   +% %  6'% nn6n% %  %    % Rp Arial!@@v8*Fl" /uo!@Fl" /uo!@"9/uo!@("u)" @v =Po@Fl "2u d"<"xRSvo!@* d"NAI "'C!@* d"B*`'C"#/@"2]@UEMdv%  T?*tAqtA? L`Gain (dB)   [?% ( %  % %    TpW*tAqtALX-30.00  X% \\%  6nj j 6n jj6njj6njj6nff6njj6njj6njj6njj6n% %    TpW*tAqtALX-20.00  X% \\%  6njj6njj6njj6njj6nf~f~6n~jtjt6ntjjjj6njj`j`6n`jVjV6nV% %    Tp@WW*tAqtA@LX-10.00  X@% \L\L%  6nLjBjB6nBj8j86n8j.j.6n.j$j$6n$ff6njj6njj6njj6njj6n% %    Td1W*tAqtA1LT0.00  X% \\%  6njj6njj6njj6njj6nff6njj6njj6njj6njj6n% %    Tl&wW*tAqtA&wLX10.00  Xw% \\%  6njyjy6nyjojo6nojeje6nej[j[6n[fQfQ6nQjGjG6nGj=j=6n=j3j36n3j)j)6n)% %    Tl&W**tAqtA&LX20.00  X% \\%  6n% % nn& %  6yy666666||6nn6``6RR6DD6666((66    66##6--6886CC6MM6XX6bb6mm6xx66yy6qq6jj6dd6__6[[6XX6VV6TT6SS6RR6QQ6 Q Q6PP6"P"P6,P,P67P7P6BPBP6LPLP6WPWP6bPbP6lOlO6wOwO6OO6OO6OO6PP6PP6PP6PP6PP6PP6PP6PP6QQ6QQ6 R R6SS6!T!T6,V,V66X6X6A[A[6K_K_6VdVd6aiai6kpkp6vxvx666666666666  66 ' '6556 C C6+Q+Q65_5_6@m@m6K{K{6UU6``6jj6uu666% % %  % %  % Rp SymbolC`P"zo@N!@z z"CP8"lSvo!@"C"CP8P8C@g"CB*"*"@g"C,C4CP8P8"CSymboldv%  % ( %  % Rp SymbolC`zo@N!@z z"CP8"lSvo!@"C"CP8P8C@g"CB*"*"@g"C,C4CP8P8"CSymboldv%  % ( %  & %  %   +X_y% % ( % %  % Rp SymbolC`P"zo@N!@z z"CP8"lSvo!@"C"CP8P8C@g"CB*"*"@g"C,C4CP8P8"CSymboldv%  % ( %  % Rp SymbolC`zo@N!@z z"CP8"lSvo!@"C"CP8P8C@g"CB*"*"@g"C,C4CP8P8"CSymboldv%  % ( %  %  %   +X_y% %   % ^j%  6j% %   T^t*tAqtA^3L Vout_Charge_Amp A:(10; 12.25) B:(10.11k; 12.25)              ^% Rp SymbolC`rgzo@N!@z z"CP8"lSvo!@"C"CP8P8C@g"CB*"*"@g"C,C4CP8P8"CSymboldv%  % ( %  % Rp SymbolC`zo@N!@z z"CP8"lSvo!@"C"CP8P8C@g"CB*"*"@g"C,C4CP8P8"CSymboldv%  % ( %   % & %  6)om6Zmnm6m6% % Rp Arial*}^@d".@*L"]@*}^@"L"#/@d"8:Iy;K"@gP8"I "Co!@o!@P88bd% !@X" u o!@zz"> u% zz,Co@ z@"uz(""C`dv%  % ( Rp Arial ccIFU " u% zzFlo@ z@"uz(""C`"dv%  % ( Rp Arial"Aa"bw "UX@}-XuYdJX"z@(`Ga8"Ϗwz@"鏎wX"P"JJDywGaU  "A"bwR fUGadEdv%  % Rp Arial@v=o@!@"94u"S4u@v"f4uJ"o!@o!@8bd% !@g" u o!@zz"> u% zzFlo@ z@"uz(""C`"dv%  % ( Rp Arial.E`1EIFU " u% zzFlo@ z@"uz(""C`"dv%  % ( Rp ArialTJF.E/EIFU " u% zzFlo@ z@"uz(""C`"dv%  % ( %  % Rp Arial@v=o@!@"94u"S4u@v"f4ul]"o!@o!@8bd% !@D" u o!@zz"> u% zzFlo@ z@"uz(""C`"dv%  % ( Rp Arial.E1E8JFU " u% zzFlo@ z@"uz(""C`"dv%  % ( Rp Arial.E 1E8JFU ">6??6AA6DD6KK6QQ6TT6ZZ6^^6ee6pp6zz666666666666}}6||6{{6yy6xx6ww6 v v6tt6ss6(r(r62q2q6<p<p6EoEo6OnOn6XmXm6blbl6hehe6hdhd6hchc6hbhb6haha6h`h`6h_h_6h^h^6h\h\6hYhY6hShS6hQhQ6hMhM6iJiJ6iEiE6i=i=6i3i36j'j'6kk6ll6ll6mm6nn6oo6qq6uu6zz666  6!!6""6$$6%%6&&6((6))6**6++6,,6--6//6006116$2$26'7'76'8'86'9'96':':6(;(;6(<(<6(=(=6(>(>6(?(?6(B(B6(G(G6(P(P6(T(T6)Z)Z6)^)^6)e)e6)o)o6*z*z6++6,,6,,6--6..6//6226666;;6AA6HH6R~R~6[|[|6e{e{6ozoz6xxxx6ww6vv6uu6ss6rr6qq6pp6oo6nn6mm6ll6ee6dd6cc6bb6aa6``6__6]]6YY6SS6PP6KK6GG6AA6776,,6""66666666666  6  6 " "6)#)#63$3$6<&<&6F'F'6O(O(6Y)Y)6c+c+6l,l,6v-v-6..6//60061162262263% & %  666666666666666666666666666666666$$6--6776AA6JJ6TT6]]6gg6qq6zz6666666666666666666666666666666666666666666  666((6226<<6EE6OO6XX6bb6hh6hh6hh6hh6hh6hh6hh6hh6hh6hh6hh6hh6hh6hh6hh6hh6ii6ii6ii6ii6jj6kk6ll6mm6nn6oo6qq6uu6zz666666666666666666$$6''6''6''6''6''6''6((6((6((6((6((6((6((6((6((6))6))6))6))6**6++6,,6--6..6//6226666;;6AA6HH6RR6[[6ee6oo6xx666666666666666666666666666666666666666666  66  6))6336<<6FF6OO6YY6cc6ll6vv6666666% xx& %  6ww6vv6uu6tt6ss6rr6pp6nn6ii6dd6bb6]]6YY6RR6HH6<<6226,,6**6**6**6**6++6++6++6,,6,,6--6..6$.$.6-/-/670706A0A06J1J16T2T26]2]26g3g36q4q46z4z46556556666666==6>>6??6@@6AA6BB6CC6DD6FF6JJ6PP6VV6YY6__6cc6jj6uu6666666666666666666  666((6226<<6EE6O~O~6X~X~6b}b}6hwhw6hvhv6huhu6hshs6hrhr6hqhq6hphp6hnhn6hkhk6hehe6hchc6h_h_6i\i\6iWiW6iOiO6iDiD6j8j86k0k06l,l,6l+l+6m*m*6n+n+6o+o+6q+q+6u,u,6z,z,6--6--6..6//6//6006116116226226336446446556556666776$7$76'<'<6'='=6'>'>6'?'?6(@(@6(A(A6(B(B6(C(C6(D(D6(G(G6(L(L6(U(U6(Y(Y6)_)_6)c)c6)j)j6)t)t6**6++6,,6,,6--6..6//6226666;;6AA6HH6RR6[[6ee6oo6xx6666666666~~6}}6ww6vv6uu6tt6ss6rr6qq6pp6nn6kk6ee6bb6]]6YY6SS6II6>>6446..6++6++6++6,,6,,6,,6,,6--6 . .6..6 / /6)0)0630306<1<16F2F26O2O26Y3Y36c4c46l4l46v5v565566666667767768% & %  66666hh6hh6''6''6''6666%  % % % 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,77,18,3F0=Charge Amplifier Circuit F3=SBOA287F4=A F5=9/30/2021F6=1F7=1?`x``xT_1091060020211001111637Gh`XhxHxHX`XT_109109C020211001111637;T_10910D8020211001111637;0000T_1091114020211001111637;0000T_1091150020211001111637;HHHHT_109118C020211001111637;x`xpx`xpT_10911C8020211001111637Cx0xx0T_1091204020211001111637;T_1091240020211001111637;xxpxxpT_109127C020211001111637;`888`888T_10912B8020211001111637;8888T_1091330020211001111637?8xH8x8xHT_10913A8020211001111637?X8X88T_10913E4020211001111637;888888T_1091420020211001111637;X8X8T_109145C020211001111637;888888T_1091498020211001111637?T_1091510020211001111637;HHT_109154C020211001111637;T_1091588020211001111637;HHHHT_10915C4020211001111637;H8HH8HT_1091600020211001111637;xxT_109163C020211001111637;T_1091678020211001111637;T_10916B4020211001111637?Xh8HXh8h8HT_10916F0020211001111637C8HP8H8H8PT_109172C020211001111637;T_1091768020211001111637;hhhhT_10917A4020211001111637;hhT_10917E0020211001111637;hhhhT_109181C020211001111637;T_1091858020211001111637;ppT_1091894020211001111637C(@(  @T_10918D0020211001111637?hhT_109190C020211001111637;T_1091948020211001111637?HHHT_1091984020211001111637;T_10919FC020211001111637;XHXXHXT_1091A38020211001111637;XxXXxXT_1091A74020211001111637CHXHXHXHT_1091AB0020211001111637;xXHXxXHXT_1091AEC020211001111637;XXXXT_1091B28020211001111637;T_1091B64020211001111637;XXXXT_05C3730020211001111637?XhXXhT_05DB9E4020211001111637;hhhhT_05FDBFA020211001112241?hhhhhT_05FDC36020211001112241B}H+Vout_Charge_AmpT_121DB06020180305135637 NOPCB (VF)DB V2T_0D0CBA1020210929153416Battery_9V_V (V)ffffff @ B8CsensorT_0D0CDD5020210929154219CP_CYL300_D700_L1400 (C) =@eAY@? BCfT_0D0CE33020210929154353CP_CYL300_D700_L1400 (C) @=@eAY@? BRfT_0D0CE91020210929154401R_AX600_W200 (R)8A@?Y@DB0 V1T_0D0CFAB020210929170859Battery_9V_V (V)ffffff?BxHVsensorT_03B3249020210929171407 L9802 (VG)_LE?_LE?Y@& .> B8RinT_04FBA7E020210929174701R_AX600_W200 (R)$@@?Y@ BPR1T_04FBA20020210929185016R_AX600_W200 (R)L@@?Y@ BR2T_04FB9C2020210929185024R_AX600_W200 (R)L@@?Y@ BC1T_04FB964020210929185028CP_CYL300_D700_L1400 (C) & .>@eAY@? BXhC2T_04FB906020210929185034CP_CYL300_D700_L1400 (C) & .>@eAY@? BhC3T_04FB8A8020210929185038CP_CYL300_D700_L1400 (C) & .>@eAY@? BR3T_04FB84A020210929185049R_AX600_W200 (R) @@?Y@ BxR4T_04FB616020210929185352R_AX600_W200 (R)[@@?Y@ BR5T_04FB5B8020210929185357R_AX600_W200 (R)|@@?Y@B|xX6Vout_PrefilterT_04FB4FC020210929192719 NOPCB (VF) BXC4T_0382897020210929192752CP_CYL300_D700_L1400 (C) Hz>@eAY@? BhR6T_0382953020210929192758R_AX600_W200 (R)IA@?Y@BrXVoutT_0382A0F020210929192837 NOPCB (VF):B6HU1T_0FC3413020211001150337 TLV6742TLV6742SC:\Users\a0227579\AppData\Local\Temp\DesignSoft\{Tina9-TI-09052019-154922}\TLV6742SCK#TLV6742Label#PP(d*IN+  @d*IN-pJ@; @d*OUT,  @d*VCCptJEz,  @d*VEE8  @h 00g"- Courier New?g"+ Courier New ?g"+ Courier New?g@g@* TLV6742 - Rev. A)* Created by Bala Ravi; January 08, 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)(* 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 TLV6742 IN+ IN- VCC VEE OUT7******************************************************* MODEL DEFINITIONS:9.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)9.model OR_SW VSWITCH(Ron=10e-3 Roff=1e9 Von=1e-3 Voff=0)&.model R_NOISELESS RES(T_ABS=-273.15)7******************************************************I_OS ESDn MID 2.5PI_B 21 MID 3PV_GRp 50 MID 20V_GRn 51 MID -20V_ISCp 44 MID 68V_ISCn 45 MID -68V_ORn 29 VCLP -900MV11 49 28 0V_ORp 27 VCLP 900MV12 48 26 0V4 37 OUT 0VCM_MIN 72 VEE_B 0VCM_MAX 73 VCC_B -1.2I_Q VCC VEE 990UV_OS 80 21 146.46U-SW11 ESDp ESDn ESDp ESDn S_VSWITCH_1-SW10 ESDn ESDp ESDn ESDp S_VSWITCH_2+S5 VEE ESDp VEE ESDp S_VSWITCH_3+S4 VEE ESDn VEE ESDn S_VSWITCH_4+S2 ESDn VCC ESDn VCC S_VSWITCH_5+S3 ESDp VCC ESDp VCC S_VSWITCH_6C28 22 MID 1P #R77 23 22 R_NOISELESS 100 C27 24 MID 1P #R76 25 24 R_NOISELESS 100 "R75 MID 26 R_NOISELESS 1 GVCCS8 26 MID 27 MID -1"R74 28 MID R_NOISELESS 1 GVCCS7 28 MID 29 MID -1"R73 30 MID R_NOISELESS 1 )XVCCS_LIM_ZO 31 MID MID 30 VCCS_LIM_ZO_0Xi_nn ESDn MID FEMT_0Xi_np MID 21 FEMT_0Xe_n ESDp 21 VNSE_0C25 32 MID 7.96F %R69 MID 32 R_NOISELESS 1MEG #GVCCS6 32 MID VSENSE MID -1UC20 CLAMP MID 144.7N (R68 MID CLAMP R_NOISELESS 1MEG *XVCCS_LIM_2 33 MID MID CLAMP VCCS_LIM_2_0%R44 MID 33 R_NOISELESS 1MEG &XVCCS_LIM_1 34 35 MID 33 VCCS_LIM_1_0C21 36 31 636.6F $R51 31 MID R_NOISELESS 2.5 #R50 31 36 R_NOISELESS 10K &Rdummy MID 37 R_NOISELESS 1.65K %Rx 37 30 R_NOISELESS 16.5K "Rdc 36 MID R_NOISELESS 1 $G_Aol_Zo 36 MID CL_CLAMP 37 -90&R61 MID 38 R_NOISELESS 812.5 C16 38 39 24.49P &R58 39 38 R_NOISELESS 100MEG &GVCCS2 39 MID VEE_B MID -87.13M"R57 MID 39 R_NOISELESS 1 &R56 MID 40 R_NOISELESS 1.14K C15 40 41 19.89P &R55 41 40 R_NOISELESS 100MEG &GVCCS1 41 MID VCC_B MID -61.95M"R54 MID 41 R_NOISELESS 1 &R49 MID 42 R_NOISELESS 8.33K C14 42 43 3.18P &R48 43 42 R_NOISELESS 100MEG %G_adjust 43 MID ESDp MID -37.95M"Rsrc MID 43 R_NOISELESS 1 .XIQPos VIMON MID MID VCC VCCS_LIMIT_IQ_0.XIQNeg MID VIMON VEE MID VCCS_LIMIT_IQ_0C_DIFF ESDp ESDn 6P 1XCL_AMP 44 45 VIMON MID 46 47 CLAMP_AMP_LO_0+SOR_SWp CLAMP 48 CLAMP 48 S_VSWITCH_7+SOR_SWn 49 CLAMP 49 CLAMP S_VSWITCH_8.XGR_AMP 50 51 52 MID 53 54 CLAMP_AMP_HI_0#R39 50 MID R_NOISELESS 1T #R37 51 MID R_NOISELESS 1T &R42 VSENSE 52 R_NOISELESS 1M C19 52 MID 1F "R38 53 MID R_NOISELESS 1 "R36 MID 54 R_NOISELESS 1 "R40 53 55 R_NOISELESS 1M "R41 54 56 R_NOISELESS 1M C17 55 MID 1F C18 MID 56 1F *XGR_SRC 55 56 CLAMP MID VCCS_LIM_GR_0"R21 46 MID R_NOISELESS 1 "R20 MID 47 R_NOISELESS 1 "R29 46 57 R_NOISELESS 1M "R30 47 58 R_NOISELESS 1M C9 57 MID 1F C8 MID 58 1F ,XCL_SRC 57 58 CL_CLAMP MID VCCS_LIM_4_0#R22 44 MID R_NOISELESS 1T #R19 MID 45 R_NOISELESS 1T 0XCLAWp VIMON MID 59 VCC_B VCCS_LIM_CLAW+_00XCLAWn MID VIMON VEE_B 60 VCCS_LIM_CLAW-_0%R12 59 VCC_B R_NOISELESS 1K "R16 59 61 R_NOISELESS 1M %R13 VEE_B 60 R_NOISELESS 1K "R17 62 60 R_NOISELESS 1M C6 62 MID 1F C5 MID 61 1F $G2 VCC_CLP MID 61 MID -1M(R15 VCC_CLP MID R_NOISELESS 1K $G3 VEE_CLP MID 62 MID -1M(R14 MID VEE_CLP R_NOISELESS 1K V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}OGVO- COM VO- VALUE = {IF(V(VIN,COM)V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}OGVO- COM VO- VALUE = {IF(V(VIN,COM)10E-3 | V(OLP,COM)>10E-3),1,0)}.ENDS*6.SUBCKT VCCS_EXT_LIM_0 VIN+ VIN- IOUT- IOUT+ VP+ VP-.PARAM GAIN = 1IG1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VIN+,VIN-),V(VP-,VIN-), V(VP+,VIN-))}.ENDS*IN+IN-VCCVEEOUT:B6XU2T_0FC3471020211001150341 TLV6742TLV6742SC:\Users\a0227579\AppData\Local\Temp\DesignSoft\{Tina9-TI-09052019-154922}\TLV6742SCK#TLV6742Label#PP(d*IN+  @d*IN-pJ@; @d*OUT,  @d*VCCptJEz,  @d*VEE8  @h 00g"- Courier New?g"+ Courier New ?g"+ Courier New?g@g@* TLV6742 - Rev. A)* Created by Bala Ravi; January 08, 2020B* Created with Green-Williams-Lis Op Amp Macro-model Architecture2* Copyright 2020 by Texas Instruments Corporation7******************************************************$* 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)$* COMMON-MODE INPUT IMPEDANCE (Zic)0* OPEN-LOOP OUTPUT IMPEDANCE VS. FREQUENCY (Zo)+* OUTPUT CURRENT THROUGH THE SUPPLY (Iout)1* INPUT VOLTAGE NOISE DENSITY VS. FREQUENCY (en)1* INPUT CURRENT NOISE DENSITY VS. FREQUENCY (in)/* OUTPUT VOLTAGE SWING vs. OUTPUT CURRENT (Vo)%* SHORT-CIRCUIT OUTPUT CURRENT (Isc)* QUIESCENT CURRENT (Iq))* SETTLING TIME VS. CAPACITIVE LOAD (ts)* SLEW RATE (SR)-* SMALL SIGNAL OVERSHOOT VS. CAPACITIVE LOAD* LARGE SIGNAL RESPONSE* OVERLOAD RECOVERY TIME (tor)* INPUT BIAS CURRENT (Ib)* INPUT OFFSET CURRENT (Ios)* INPUT OFFSET VOLTAGE (Vos)(* INPUT COMMON-MODE VOLTAGE RANGE (Vcm)C* INPUT OFFSET VOLTAGE VS. INPUT COMMON-MODE VOLTAGE (Vos vs. Vcm))* INPUT/OUTPUT ESD CELLS (ESDin, ESDout)7******************************************************$.subckt TLV6742 IN+ IN- VCC VEE OUT7******************************************************* MODEL DEFINITIONS:9.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)9.model OR_SW VSWITCH(Ron=10e-3 Roff=1e9 Von=1e-3 Voff=0)&.model R_NOISELESS RES(T_ABS=-273.15)7******************************************************I_OS ESDn MID 2.5PI_B 21 MID 3PV_GRp 50 MID 20V_GRn 51 MID -20V_ISCp 44 MID 68V_ISCn 45 MID -68V_ORn 29 VCLP -900MV11 49 28 0V_ORp 27 VCLP 900MV12 48 26 0V4 37 OUT 0VCM_MIN 72 VEE_B 0VCM_MAX 73 VCC_B -1.2I_Q VCC VEE 990UV_OS 80 21 146.46U-SW11 ESDp ESDn ESDp ESDn S_VSWITCH_1-SW10 ESDn ESDp ESDn ESDp S_VSWITCH_2+S5 VEE ESDp VEE ESDp S_VSWITCH_3+S4 VEE ESDn VEE ESDn S_VSWITCH_4+S2 ESDn VCC ESDn VCC S_VSWITCH_5+S3 ESDp VCC ESDp VCC S_VSWITCH_6C28 22 MID 1P #R77 23 22 R_NOISELESS 100 C27 24 MID 1P #R76 25 24 R_NOISELESS 100 "R75 MID 26 R_NOISELESS 1 GVCCS8 26 MID 27 MID -1"R74 28 MID R_NOISELESS 1 GVCCS7 28 MID 29 MID -1"R73 30 MID R_NOISELESS 1 )XVCCS_LIM_ZO 31 MID MID 30 VCCS_LIM_ZO_0Xi_nn ESDn MID FEMT_0Xi_np MID 21 FEMT_0Xe_n ESDp 21 VNSE_0C25 32 MID 7.96F %R69 MID 32 R_NOISELESS 1MEG #GVCCS6 32 MID VSENSE MID -1UC20 CLAMP MID 144.7N (R68 MID CLAMP R_NOISELESS 1MEG *XVCCS_LIM_2 33 MID MID CLAMP VCCS_LIM_2_0%R44 MID 33 R_NOISELESS 1MEG &XVCCS_LIM_1 34 35 MID 33 VCCS_LIM_1_0C21 36 31 636.6F $R51 31 MID R_NOISELESS 2.5 #R50 31 36 R_NOISELESS 10K &Rdummy MID 37 R_NOISELESS 1.65K %Rx 37 30 R_NOISELESS 16.5K "Rdc 36 MID R_NOISELESS 1 $G_Aol_Zo 36 MID CL_CLAMP 37 -90&R61 MID 38 R_NOISELESS 812.5 C16 38 39 24.49P &R58 39 38 R_NOISELESS 100MEG &GVCCS2 39 MID VEE_B MID -87.13M"R57 MID 39 R_NOISELESS 1 &R56 MID 40 R_NOISELESS 1.14K C15 40 41 19.89P &R55 41 40 R_NOISELESS 100MEG &GVCCS1 41 MID VCC_B MID -61.95M"R54 MID 41 R_NOISELESS 1 &R49 MID 42 R_NOISELESS 8.33K C14 42 43 3.18P &R48 43 42 R_NOISELESS 100MEG %G_adjust 43 MID ESDp MID -37.95M"Rsrc MID 43 R_NOISELESS 1 .XIQPos VIMON MID MID VCC VCCS_LIMIT_IQ_0.XIQNeg MID VIMON VEE MID VCCS_LIMIT_IQ_0C_DIFF ESDp ESDn 6P 1XCL_AMP 44 45 VIMON MID 46 47 CLAMP_AMP_LO_0+SOR_SWp CLAMP 48 CLAMP 48 S_VSWITCH_7+SOR_SWn 49 CLAMP 49 CLAMP S_VSWITCH_8.XGR_AMP 50 51 52 MID 53 54 CLAMP_AMP_HI_0#R39 50 MID R_NOISELESS 1T #R37 51 MID R_NOISELESS 1T &R42 VSENSE 52 R_NOISELESS 1M C19 52 MID 1F "R38 53 MID R_NOISELESS 1 "R36 MID 54 R_NOISELESS 1 "R40 53 55 R_NOISELESS 1M "R41 54 56 R_NOISELESS 1M C17 55 MID 1F C18 MID 56 1F *XGR_SRC 55 56 CLAMP MID VCCS_LIM_GR_0"R21 46 MID R_NOISELESS 1 "R20 MID 47 R_NOISELESS 1 "R29 46 57 R_NOISELESS 1M "R30 47 58 R_NOISELESS 1M C9 57 MID 1F C8 MID 58 1F ,XCL_SRC 57 58 CL_CLAMP MID VCCS_LIM_4_0#R22 44 MID R_NOISELESS 1T #R19 MID 45 R_NOISELESS 1T 0XCLAWp VIMON MID 59 VCC_B VCCS_LIM_CLAW+_00XCLAWn MID VIMON VEE_B 60 VCCS_LIM_CLAW-_0%R12 59 VCC_B R_NOISELESS 1K "R16 59 61 R_NOISELESS 1M %R13 VEE_B 60 R_NOISELESS 1K "R17 62 60 R_NOISELESS 1M C6 62 MID 1F C5 MID 61 1F $G2 VCC_CLP MID 61 MID -1M(R15 VCC_CLP MID R_NOISELESS 1K $G3 VEE_CLP MID 62 MID -1M(R14 MID VEE_CLP R_NOISELESS 1K V(VC+,COM),((V(VIN,COM)-V(VC+,COM))*G),0)}OGVO- 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(OLP,COM)>10E-3),1,0)}.ENDS*6.SUBCKT VCCS_EXT_LIM_0 VIN+ VIN- IOUT- IOUT+ VP+ VP-.PARAM GAIN = 1IG1 IOUT+ IOUT- VALUE={LIMIT(GAIN*V(VIN+,VIN-),V(VP-,VIN-), V(VP+,VIN-))}.ENDS*IN+IN-VCCVEEOUTBn VCCT_0D0CC5D020210929153430 NOPCB (J)Bnxp VCCT_0D0CD77020210929153714 NOPCB (J)Bo0 VREFT_04E12B6020210929170905 NOPCB (J)Boh VREFT_0428DC4020210929172416 NOPCB (J)Bn VCCT_04FB6D2020210929185239 NOPCB (J)Bo` VREFT_04FB55A020210929185422 NOPCB (J)BfT_0D0CBFF020210929153419 NOPCB (GND)Bf0T_04E1314020210929170915 NOPCB (GND)BfxT_0428EDE020210929172730 NOPCB (GND)BfT_04FB7EC020210929185120 NOPCB (GND)BfT_04FB78E020210929185145 NOPCB (GND)BfT_03829B1020210929192809 NOPCB (GND)BfT_116B93C020210930091353 NOPCB (GND)Bf(T_0C40C2D020210930091356 NOPCB (GND)8? ]@p"MbP??ư>'dd?Y@[dddd??.A.A.AeAMbP?@@???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