OBSSCircuit DescriptionV1.1010/02/94 20:07 CET.Component & analysis parameters of a circuit.TINA 9.3.200.353 SF-TIB(c) Copyright 1993,94,95,96 DesignSoft Inc. All rights reserved. $Circuit$??[All] minx1=-5 maxx1=30 divsx1=7 scalex1=0 miny1=-0.5 maxy1=5.5 divsy1=12 scaley1=0 minx2=10maxx2=1000000 divsx2=5 scalex2=2 minx4=10maxx4=1000000 divsx4=5 scalex4=2 miny2=0.1 maxy2=1000 divsy2=4 scaley2=2 miny4=0.1 maxy4=1000 divsy4=4 scaley4=2 [I_VREFA]miny1=-9.99999999999999E-5 maxy1=0.0005 divsy1=1 scaley1=0[VOUT] miny2=0.1 maxy2=1000 divsy2=4 scaley2=2 miny4=0.1 maxy4=1000 divsy4=4 scaley4=2miny1=0 maxy1=2.5 divsy1=5 scaley1=0 miny14=1E-12 maxy14=0.001 divsy14=1 scaley14=2minx1=0 maxx1=0.06 divsx1=12 scalex1=0 minx2=10maxx2=10000000 divsx2=6 scalex2=2 minx4=10maxx4=10000000 divsx4=6 scalex4=2 miny13=1E-8 maxy13=1E-6 divsy13=2 scaley13=2 minx13=10maxx13=10000000 divsx13=6 scalex13=2[PSRR]minx2=1maxx2=1000000 divsx2=6 scalex2=2minx4=1maxx4=1000000 divsx4=6 scalex4=2 miny2=40 maxy2=110 divsy2=7 scaley2=1 miny4=40 maxy4=110 divsy4=7 scaley4=1[RON]miny1=5 maxy1=75 divsy1=7 scaley1=0 minx1=1E-6 maxx1=1.2 divsx1=6 scalex1=0[Gain]minx2=1000000maxx2=1000000000 divsx2=3 scalex2=2minx4=1000000maxx4=1000000000 divsx4=3 scalex4=2 miny2=-14maxy2=0 divsy2=7 scaley2=1 miny4=-14maxy4=0 divsy4=7 scaley4=1 [OFF_ISO] miny2=-90 maxy2=-10 divsy2=8 scaley2=1 miny4=-90 maxy4=-10 divsy4=8 scaley4=1[IQ]miny1=0.00015 maxy1=0.0004 divsy1=5 scaley1=0[IIBP] miny1=-2E-5maxy1=0.00012 divsy1=7 scaley1=0[IIBN] miny1=-2E-5maxy1=0.00012 divsy1=7 scaley1=0[VOUT1] miny1=-1maxy1=2 divsy1=3 scaley1=0[VOUT2] miny1=-1maxy1=2 divsy1=3 scaley1=0[VOS] miny1=-7E-5 maxy1=5E-6 divsy1=5 scaley1=0[CMRR] miny2=50 maxy2=125 divsy2=3 scaley2=1 miny4=50 maxy4=125 divsy4=3 scaley4=1minx2=1maxx2=10000000 divsx2=7 scalex2=2minx4=1maxx4=10000000 divsx4=7 scalex4=2[VF1] miny2=-30 maxy2=120 divsy2=5 scaley2=1 miny4=-30 maxy4=120 divsy4=5 scaley4=1 miny7=-400 maxy7=200 divsy7=12 scaley7=0 minx7=1000maxx7=10000000000 divsx7=7 scalex7=2[VD] miny1=-0.5 maxy1=0.5 divsy1=1 scaley1=0PFt??ƚaFpl aF EMFHP Qr RpArialPuQpwвk X` вk Arial"pw` n ` 8"pw` 8"8pwuw|"Gpw|"P"CD ,C4ChO% CArialAridv%  % RpArial* @B"TV9'0273Arial096"pw` "8pwuw(" GpwM(" GpwM@" Q@$" I"7uL@G"ͩ|=u-3\"MbP?l"dv%  % %  % %  % %  % %  % %  % %  % %  % %  % MM&%  '%   6M6666666666YY6Y~~6~66666666((6(LL6Lff6fzz6z6666% MM&%  6M6% M{M{%  6{M?M?6?MM6MM6MM6MOMO6O% MM%  6MM6% MM&%  6% % %  &%  %     TU0 B BULhFrequency (Hz)    % % %  %     TdDq0 B BDLT1MEG  r% ( MM%  6M66666666% % &%  %     TlH0 B BLX10MEG_U  I% ( %  6YY6Y~~6~666666% % &%  %     Tp 0 B BLX100MEG  !% ( %  6((6(LL6Lff6fzz6z6666% % &%  %     TX0 B BLP1G % ( %  6% MM6M% % %  &%  %     Td$0 B BLTGain %% % % ( %  &%  %     T`%;0 B B%LT-1475 <% ( ??%  6MFF6MFF6MFF6M% % &%  %     T`%q;0 B B%qLT-12Vo <q% ( ?{?{%  6M{FlFl6MlF]F]6M]FNFN6MN% % &%  %     T`%5;G0 B B%5LT-10)} <5% ( ????%  6M?F0F06M0F!F!6M!FF6M% % &%  %     TX.; 0 B B.LP-8 <% ( ??%  6MFF6MFF6MFF6M% % &%  %     TX.;0 B B.LP-6 <% ( ??%  6MFF6MFF6MFF6M% % &%  %     TX.;0 B B.LP-4 <% ( ??%  6MF|F|6M|FmFm6MmF^F^6M^% % &%  %     TX.E;W0 B B.ELP-2 <E% ( ?O?O%  6MOF@F@6M@F1F16M1F"F"6M"% % &%  %     TT3 ;0 B B3 LP0D < % ( ??%  6M% % MgMg&%  6OO6QQ6SS6UU6WW6YY6[[6^^6``6bb6dd6ff6hh6jj6ll6nn6pp6rr6tt6vv6xx6zz6||66666666666666666666666666666666666666666666666666666666666666666666  6  6  6666666666""6$$6&&6((6**6,,6..6006226446666886::6<<6>>6@@6CC6EE6GG6II6KK6MM6OO6QQ6SS6UU6WW6YY6[[6]]6__6aa6dd6ff6hh6jj6ll6nn6pp6rr6tt6vv6xx6zz6||6~~6666666666666666666666666666666666666666666666666  6  6  6!!6!!6""6##6##6$$6%%6%%6&&6''6((6))6**6++6--6 . .6 / /6 1 16336446666886::6<<6??6AA6DD6!F!F6#I#I6&L&L6(O(O6*R*R6,V,V6.Y.Y60]0]62`2`64d4d66h6h68l8l6:p:p6<u<u6>y>y6@}@}6BB6DD6GG6II6KK6MM6OO6QQ6SS6UU6WW6YY6[[6]]6__6aa6cc6ee6hh6jj6ll6nn6pp6rr6tt6vv6x x 6zz6||6~~6$$6**6//6556;;6@@6FF6LL6QQ6WW6]]6bb6hh6mm6ss6yy6~~66666666666RpMS Sans Serif+t! " MS Sans Serif4"w"t""wɺw "P""f" IP"ffPd!\"" """ dv%  % % % KCVER=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,77,18,3BF0=TMUX1119: 5-V, Low-Leakage-Current, 2:1 Precision MultiplexerF3=SCDS401 - DECEMBER 2018F5=March 26, 2019F6=1F7=1sL@sL ArialTMUX1119 Reference CircuitSymbol????333333??;8888T_086AEF5020190211155341?P`PP`T_086AF6D020190211155341;PPPPT_086AFA9020190211155341;((((T_086B2B5020190211155341;PPPPT_086B459020190211155341;`P`PT_086B495020190211155341?T_086B4D1020190211155341;T_086B50D020190211155341?T_086B549020190211155341;PPPPPPT_086B585020190211155341;xxT_086B5C1020190211155341?HPHHPT_086B5FD020190211155341;HHHHT_086B639020190211155341;HHxHHxT_086B675020190211155341?8HP8H8HPT_086B6B1020190211155341;  T_086B7A1020190211155341;`x`xT_086B7DD020190211155341;8(8(T_086B819020190211155341;88T_17E91E5020190326135257;8888T_17E9221020190326135257?phphhT_0E90E57020190326135555;T_17E2E53020190326135557DB8 V1T_0827ECA020180726103604Battery_9V_V (V)@BHP VG1T_08281BA020180726103738 Sgen (VG)?@@V B8R1T_0828218020180726103746R_AX600_W200 (R)I@@?Y@ BH R2T_0828332020180726103830R_AX600_W200 (R)I@@?Y@ B` #R3T_082844C020180726103939R_AX600_W200 (R)I@@?Y@ B`C1T_08284AA020180726103956CP_CYL300_D700_L1400 (C) dy=@eAY@?BqPVD:T_0828856020180726104314 NOPCB (VF)Bq VS1T_0841513020190326135249 NOPCB (VF)DBp V2T_0A944EC020190326135551Battery_9V_V (V):B7 PU2T_06B7457020190326143755  TMUX1119 TMUX1119TC:\Users\a0867324\AppData\Local\Temp\DesignSoft\{Tina9-TI-12212018-112309}\TMUX1119SCK# TMUX1119Label33))pd*S1D @d*S2DN2)*0.003UVA @d*DELN2)UT GND VA 0 @d*SEL M  @d*VDDD5   @d*GND 0 @f)(g#TMUX1119Arial۶m۶m?}j =@}j =@P * TMUX1119N*****************************************************************************v* (C) Copyright 2018 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 customerN******************************************************************************D* This model is subject to change without notice. Texas Instruments;* Incorporated is not responsible for updating this model.*N******************************************************************************'** Released by: Texas Instruments Inc.* Part: TMUX1119* Date: 2/15/19* Model Type: ALL-IN-ONE* Simulator: PSPICE!* Simulator Version: 16.2.0.p001* EVM Order Number: * EVM Users Guide: * Datasheet: SCDS401* Topologies Supported: ** Model Version: Preliminary*N****************************************************************************** * Updates:*&* Updated model to support more specs* *N******************************************************************************* Model Usage Notes:* ?* 1. The following limited specs/feature set have been modeledC* This model reflects RON versus VS or VD for 1.2V < VDD < 5.0V?* This model reflects the published specs for 5V operation:* a. CS_ON, CS_OFF* b. CD_ON* c. Bandwidth'* d. Isolation at 1MHZ and 10MHz#* e. Break-Before-Make Time.+* f. Switching Time Between Channels,* g. Source and Drain leakage G* 3. This model may not reflect other published specs and/or features.+* 4. Temperature effects are not modeled. M* 5. If convergece errors are encountered, try making simulation paramaters:* ITL1 = 500 & ITL2 = 200**N*****************************************************************************%.SUBCKT TMUX1119 S1 S2 D SEL VDD GND#R_R5 0 CNTRL5 1e6 TC=0,0 CX_U1_S1 CNTRL1_DELAY GND S1 U1_N00735 SCH_PORT1_U1_S1_TMUX1119 0R_U1_R2 U1_N00735 U1_N08799 23 TC=0,0 #C_U1_C6 GND D 4p TC=0,0 BX_U1_S2 CNTRL1_DELAY GND U1_N00768 D SCH_PORT1_U1_S2_TMUX1119 *R_U1_R1 GND U1_NISO 10e6 TC=0,0 0R_U1_R3 U1_N06532 U1_N00768 23 TC=0,0 AX_U1_U2 U1_N08799 U1_N06532 VDD GND RON_VCC_VD_TMUX1119 'C_U1_C1 GND S1 2.75p TC=0,0 /L_U1_L1 U1_N00735 U1_N08799 14.25nH +C_U1_C2 GND U1_N00735 2p TC=0,0 +C_U1_C7 GND U1_N08799 2f TC=0,0 /C_U1_C5 U1_N13923 U1_NISO 7p TC=0,0 CX_U1_S3 CNTRL1_DELAY GND S1 U1_N12958 SCH_PORT1_U1_S3_TMUX1119 +C_U1_C3 GND U1_N00768 2p TC=0,0 /C_U1_C4 U1_NISO U1_N12958 7p TC=0,0 /L_U1_L2 U1_N06532 U1_N00768 14.25nH BX_U1_S4 CNTRL1_DELAY GND D U1_N13923 SCH_PORT1_U1_S4_TMUX1119 +C_U1_C8 GND U1_N06532 2f TC=0,0 2R_U10_R5 U10_N349504 U10_RC_IN 1 TC=0,0 0D_U10_D3 U10_RC_OUT U10_N349504 Dideal -C_U10_C3 GND U10_RC_OUT 9n TC=0,0 -E_U10_E2 U10_RC_IN GND CNTRL1 GND 102R_U10_R4 U10_RC_IN U10_N345841 2 TC=0,0 &V_U10_V1 U10_N345775 GND 5Vdc0D_U10_D2 U10_N345841 U10_RC_OUT Dideal NX_U10_U9 U10_RC_OUT U10_N345775 CNTRL1_DELAY GND COMPARATOR_TMUX1119 1X_U20 S2 GND VCC_MON ILEAK_OFF_TMUX1119 CX_U2_S1 CNTRL2_DELAY GND S2 U2_N00735 SCH_PORT1_U2_S1_TMUX1119 0R_U2_R2 U2_N00735 U2_N08799 23 TC=0,0 #C_U2_C6 GND D 4p TC=0,0 BX_U2_S2 CNTRL2_DELAY GND U2_N00768 D SCH_PORT1_U2_S2_TMUX1119 *R_U2_R1 GND U2_NISO 10e6 TC=0,0 0R_U2_R3 U2_N06532 U2_N00768 23 TC=0,0 AX_U2_U2 U2_N08799 U2_N06532 VDD GND RON_VCC_VD_TMUX1119 'C_U2_C1 GND S2 2.75p TC=0,0 /L_U2_L1 U2_N00735 U2_N08799 14.25nH +C_U2_C2 GND U2_N00735 2p TC=0,0 +C_U2_C7 GND U2_N08799 2f TC=0,0 /C_U2_C5 U2_N13923 U2_NISO 7p TC=0,0 CX_U2_S3 CNTRL2_DELAY GND S2 U2_N12958 SCH_PORT1_U2_S3_TMUX1119 +C_U2_C3 GND U2_N00768 2p TC=0,0 /C_U2_C4 U2_NISO U2_N12958 7p TC=0,0 /L_U2_L2 U2_N06532 U2_N00768 14.25nH BX_U2_S4 CNTRL2_DELAY GND D U2_N13923 SCH_PORT1_U2_S4_TMUX1119 +C_U2_C8 GND U2_N06532 2f TC=0,0 #R_R4 0 CNTRL6 1e6 TC=0,0 #R_R7 0 CNTRL3 1e6 TC=0,0 2R_U11_R5 U11_N349504 U11_RC_IN 1 TC=0,0 0D_U11_D3 U11_RC_OUT U11_N349504 Dideal -C_U11_C3 GND U11_RC_OUT 9n TC=0,0 -E_U11_E2 U11_RC_IN GND CNTRL2 GND 102R_U11_R4 U11_RC_IN U11_N345841 2 TC=0,0 &V_U11_V1 U11_N345775 GND 5Vdc0D_U11_D2 U11_N345841 U11_RC_OUT Dideal NX_U11_U9 U11_RC_OUT U11_N345775 CNTRL2_DELAY GND COMPARATOR_TMUX1119 #R_R2 0 CNTRL8 1e6 TC=0,0 #R_R1 0 EN_INT 1e6 TC=0,0 #R_R3 0 CNTRL7 1e6 TC=0,0 1X_U19 S1 GND VCC_MON ILEAK_OFF_TMUX1119 #R_R6 0 CNTRL4 1e6 TC=0,0 JX_U29 GND GND SEL VDD VDD GND EN_INT VCC_MON CNTRL1 CNTRL2 CNTRL38+ CNTRL4 CNTRL5 CNTRL6 CNTRL7 CNTRL8 DIGITAL_TMUX1119 .MODEL Dideal D.ENDS*************** ***************+.subckt SCH_PORT1_U1_S1_TMUX1119 1 2 3 4 S_U1_S1 3 4 1 2 _U1_S1RS_U1_S1 1 2 1GC.MODEL _U1_S1 VSWITCH Roff=5e9 Ron=1m Voff=0.25V Von=0.75V.ends SCH_PORT1_U1_S1_TMUX1119*************** ***************+.subckt SCH_PORT1_U1_S2_TMUX1119 1 2 3 4 S_U1_S2 3 4 1 2 _U1_S2RS_U1_S2 1 2 1GC.MODEL _U1_S2 VSWITCH Roff=5e9 Ron=1m Voff=0.25V Von=0.75V.ends SCH_PORT1_U1_S2_TMUX1119*************** ***************+.subckt SCH_PORT1_U1_S3_TMUX1119 1 2 3 4 S_U1_S3 3 4 1 2 _U1_S3RS_U1_S3 1 2 1GD.MODEL _U1_S3 VSWITCH Roff=10e6 Ron=1m Voff=0.75V Von=0.25V.ends SCH_PORT1_U1_S3_TMUX1119*************** ***************+.subckt SCH_PORT1_U1_S4_TMUX1119 1 2 3 4 S_U1_S4 3 4 1 2 _U1_S4RS_U1_S4 1 2 1GD.MODEL _U1_S4 VSWITCH Roff=10e6 Ron=1m Voff=0.75V Von=0.25V.ends SCH_PORT1_U1_S4_TMUX1119*************** ***************+.subckt SCH_PORT1_U2_S1_TMUX1119 1 2 3 4 S_U2_S1 3 4 1 2 _U2_S1RS_U2_S1 1 2 1GC.MODEL _U2_S1 VSWITCH Roff=5e9 Ron=1m Voff=0.25V Von=0.75V.ends SCH_PORT1_U2_S1_TMUX1119*************** ***************+.subckt SCH_PORT1_U2_S2_TMUX1119 1 2 3 4 S_U2_S2 3 4 1 2 _U2_S2RS_U2_S2 1 2 1GC.MODEL _U2_S2 VSWITCH Roff=5e9 Ron=1m Voff=0.25V Von=0.75V.ends SCH_PORT1_U2_S2_TMUX1119*************** ***************+.subckt SCH_PORT1_U2_S3_TMUX1119 1 2 3 4 S_U2_S3 3 4 1 2 _U2_S3RS_U2_S3 1 2 1GD.MODEL _U2_S3 VSWITCH Roff=10e6 Ron=1m Voff=0.75V Von=0.25V.ends SCH_PORT1_U2_S3_TMUX1119*************** ***************+.subckt SCH_PORT1_U2_S4_TMUX1119 1 2 3 4 S_U2_S4 3 4 1 2 _U2_S4RS_U2_S4 1 2 1GD.MODEL _U2_S4 VSWITCH Roff=10e6 Ron=1m Voff=0.75V Von=0.25V.ends SCH_PORT1_U2_S4_TMUX1119*************** ***************(.SUBCKT RON_VCC_VD_TMUX1119 1 2 VCC GND5* Functions below are valid only for 0V <= VCC <= 5VEV NVCC 0 VALUE = {V(VCC,GND)}*EIN NIN 0 VALUE = {V(1,GND)}!********************************#E1_1 NA2_1 0 TABLE {V(VCC,GND)} = + (1.2, 42.3005397390134)+ (1.8, 57.8002033895847)+ (2.5, 8.496635954912536)+ (3.3, 1.21890185523962)+ (5.0, 0.0982697628988714)***#E2_1 NA1_1 0 TABLE {V(VCC,GND)} = + (1.2, 45.7002025290512)+ (1.8, -22.9619444990021)+ (2.5, -2.709280360118320)+ (3.3, 0.366538369751295)+ (5.0, 0.334075012262873)***#E3_1 NA0_1 0 TABLE {V(VCC,GND)} = + (1.2, 6.05538463555096)+ (1.8, 7.55014634577868)+ (2.5, 3.258145248231845)+ (3.3, 2.2258522266275)+ (5.0, 1.59270630931255)"*********************************#E1_2 NA2_2 0 TABLE {V(VCC,GND)} = + (1.2, 0) + (1.8, 0) + (2.5, 0)+ (3.3, 1.01001434656275)+ (5.0, 0.313515990674095)***#E2_2 NA1_2 0 TABLE {V(VCC,GND)} = + (1.2, 0) + (1.8, 0) + (2.5, 0)+ (3.3, -3.01061852785705)+ (5.0, -1.33603519270412)***#E3_2 NA0_2 0 TABLE {V(VCC,GND)} = + (1.2, 71.8) + (1.8, 40)+ (2.5, 11.44)+ (3.3, 6.71137851675848)+ (5.0, 3.52701455285872)$***********************************#E1_3 NA2_3 0 TABLE {V(VCC,GND)} = + (1.2, 1814.33338866619)+ (1.8, 140.185865720934)+ (2.5, 8.090241639781409)+ (3.3, 1.08257115897377)+ (5.0, 0.131198754759804)***#E2_3 NA1_3 0 TABLE {V(VCC,GND)} = + (1.2, -4047.3787914191)+ (1.8, -435.501145398796)+ (2.5, -36.97051245497705)+ (3.3, -7.39874940186072)+ (5.0, -1.56761016639175)***#E3_3 NA0_3 0 TABLE {V(VCC,GND)} = + (1.2, 2263.40418487475)+ (1.8, 340.692213160212)+ (2.5, 45.36917654029237)+ (3.3, 15.0821060821423)+ (5.0, 6.4754818417246)$***********************************,* Max values for RON as functions of supply(ERONMAX NRONMAX 0 TABLE {V(VCC,GND)} = + (1.2, 71.8)+ (1.8, 41.7)+ (2.5, 11.44)+ (3.3, 11.44)+ (5.0, 11.44),* Min values for RON as functions of supply(ERONMIN NRONMIN 0 TABLE {V(VCC,GND)} = + (1.2, 8.22) + (1.8, 4.2) + (2.5, 2.9) + (3.3, 2.2) + (5.0, 1.6)**KE11 N1 0 VALUE = {V(NA2_1)*PWR(V(1,GND),2) + V(NA1_1)*V(1,GND) + V(NA0_1)}KE22 N2 0 VALUE = {V(NA2_2)*PWR(V(1,GND),2) + V(NA1_2)*V(1,GND) + V(NA0_2)}KE33 N3 0 VALUE = {V(NA2_3)*PWR(V(1,GND),2) + V(NA1_3)*V(1,GND) + V(NA0_3)}:E44 N44 0 VALUE = {ABS(MIN(MIN(V(N1),V(N2)),V(N3))) + 1u}9E4 N4 0 VALUE = {MAX(MIN(V(N44),V(NRONMAX)),V(NRONMIN))}G1 1 2 VALUE = {V(1,2)/V(N4)}.ENDS*************** ***************-.SUBCKT COMPARATOR_TMUX1119 INP INN OUT GND.PARAM VHI = 1.PARAM VLOW = 0QEOUT OUT GND VALUE = {VHI*0.5*(1+ (SGN(V(INP,INN)) - ABS(SGN(V(INP,INN))) + 1))}.ENDS*************** ***************&.SUBCKT ILEAK_OFF_TMUX1119 OUT GND EN.PARAM I_LEAK_OFF = 0.01n1*G1 OUT GND VALUE = {(1 - V(EN,GND))*I_LEAK_OFF}*G1 OUT GND VALUE = {V(EN,GND)*I_LEAK_OFF}.ENDS*************** ***************t.SUBCKT DIGITAL_TMUX1119 A2 A1 A0 EN VCC GND EN_INT VCC_MON CNTRL1 CNTRL2 CNTRL3 CNTRL4 CNTRL5 CNTRL6 CNTRL7 CNTRL8** Digital Threshold.PARAM VTHR = 0.85.PARAM VCC_MAX = 5.6.PARAM VCC_MIN = 0.9** ** Convert EN pin to '1' or '0'IEEN NEN 0 VALUE = {0.5*(SGN(V(EN,GND)-VTHR) + ABS(SGN(V(EN,GND)-VTHR)))}**'** Test for Min and Max power suppliesRE1 N1 0 VALUE = {0.5*(SGN(VCC_MAX - V(VCC,GND))+ ABS(SGN(VCC_MAX - V(VCC,GND))))}RE2 N2 0 VALUE = {0.5*(SGN(V(VCC,GND) - VCC_MIN)+ ABS(SGN(V(VCC,GND) - VCC_MIN)))}***1** Convert digital input voltages to '1' and '0'IEA0 NA0 0 VALUE = {0.5*(SGN(V(A0,GND)-VTHR) + ABS(SGN(V(A0,GND)-VTHR)))}IEA1 NA1 0 VALUE = {0.5*(SGN(V(A1,GND)-VTHR) + ABS(SGN(V(A1,GND)-VTHR)))}IEA2 NA2 0 VALUE = {0.5*(SGN(V(A2,GND)-VTHR) + ABS(SGN(V(A2,GND)-VTHR)))}**MES1 CNTRL1 GND VALUE = {V(N1)*V(N2)*V(NEN)*(1-V(NA2))*(1-V(NA1))*(1-V(NA0))}KES2 CNTRL2 GND VALUE = {V(N1)*V(N2)*V(NEN)*(1-V(NA2))*(1-V(NA1))*(V(NA0))}KES3 CNTRL3 GND VALUE = {V(N1)*V(N2)*V(NEN)*(1-V(NA2))*(V(NA1))*(1-V(NA0))}IES4 CNTRL4 GND VALUE = {V(N1)*V(N2)*V(NEN)*(1-V(NA2))*(V(NA1))*(V(NA0))}KES5 CNTRL5 GND VALUE = {V(N1)*V(N2)*V(NEN)*(V(NA2))*(1-V(NA1))*(1-V(NA0))}IES6 CNTRL6 GND VALUE = {V(N1)*V(N2)*V(NEN)*(V(NA2))*(1-V(NA1))*(V(NA0))}IES7 CNTRL7 GND VALUE = {V(N1)*V(N2)*V(NEN)*(V(NA2))*(V(NA1))*(1-V(NA0))}GES8 CNTRL8 GND VALUE = {V(N1)*V(N2)*V(NEN)*(V(NA2))*(V(NA1))*(V(NA0))}**** Current Drain at 5V*GVCC VCC GND VALUE = {V(N1)*V(N2)*0.003u}**$EEN_INT EN_INT GND VALUE = {V(NEN)}**$** TRUE if VCC__MIN < VCC < VCC_MAX0*EENOUT EN_OUT GND VALUE = {V(N1)*V(N2)*V(NEN)}*EVCCMON VCC_MON GND VALUE = {V(N1)*V(N2)}.ENDSS1S2DSELVDDGNDDBP V3T_0A89450020190326143836Battery_9V_V (V)Bn( VCCT_0827F86020180726103614 NOPCB (J)Bn VCCT_0827FE4020180726103633 NOPCB (J)BfxT_0827F28020180726103610 NOPCB (GND)BfHT_0828276020180726103758 NOPCB (GND)BfT_08283EE020180726103905 NOPCB (GND)BfT_0828508020180726104033 NOPCB (GND)Bf(T_082879A020180726104156 NOPCB (GND)BfT_08414B5020190326134425 NOPCB (GND)8?H ]@H"MbP??ư>'dd?Y@[,ddd.A?.AeA.AeAMbP?@@?{Gz?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%IT*Gain VD(s)/VS1(s)Noname