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** Copyright Newbury Technology 2000 All rights reserved ** SIMetrix release 3.1 Model Library ** ** These models are believed to be accurate but Newbury Technology Ltd. ** offers no guarantee as to their fitness for any purpose nor do they ** accept any responsibility for damage caused directly or indirectly ** by their use. ** Library supplied with SIMetrix Intro ** Revised 7.2.2000 added ZTX605 and ZTX705 darlingtons .model HC00D d_nand + rise_delay = 6.5n + fall_delay = 6.5n + out_res = 40 + input_load = 4.5p + family = "HC" .model HC02D d_nor + rise_delay = 6.5n + fall_delay = 6.5n + out_res = 40 + input_load = 4.5p + family = "HC" .model HC03 d_nand + rise_delay = 8.5n + fall_delay = 8.5n + out_res = 40 + input_load = 4.5p + family = "HC" + open_c=true .model HC04D d_inverter + rise_delay = 5.5n + fall_delay = 5.5n + out_res = 40 + input_load = 4.5p + family = "HC" .model HC08D d_and + rise_delay = 6.5n + fall_delay = 6.5n + out_res = 40 + input_load = 4.5p + family = "HC" .model HC10D d_nand + rise_delay = 7.5n + fall_delay = 7.5n + out_res = 40 + input_load = 4.5p + family = "HC" .model HC11D d_and + rise_delay = 7.5n + fall_delay = 7.5n + out_res = 40 + input_load = 4.5p + family = "HC" .model HC14 d_inverter + input_load = 4.5p + out_res = 40 + rise_delay = 10.5n + fall_delay = 10.5n + out_family = "HC" + in_family = "HC_schmitt" .model HC27D d_nor + rise_delay = 6.5n + fall_delay = 6.5n + out_res = 40 + input_load = 4.5p + family = "HC" .model HC32D d_or + rise_delay = 6.5n + fall_delay = 6.5n + out_res = 40 + input_load = 4.5p + family = "HC" .subckt HC74D D CLOCK SET RESET QP QN Ahc74 [D CLOCK SET RESET] [QP QN] Ahc74 .model Ahc74 d_logic_block + file = 74 + out_delay = 4n + user = [5n, 5n, 6n, 7n, 8n] ; [ setup, rs delay, min clock, dtype delay ] + input_load = 4.5p + out_res = 40 + family = "HC" .ends .model HC86D d_xor + rise_delay = 8.5n + fall_delay = 8.5n + out_res = 40 + input_load = 4.5p + family = "HC" .subckt HC139 A0 A1 E Q0 Q1 Q2 Q3 Ahc139 [A0 A1 E] [Q0 Q1 Q2 Q3] Ahc139 .model Ahc139 d_logic_block + out_delay=11.4n + file = 139 + input_load = 4.5p + out_res = 40 + family = "HC" .ends .subckt HC164 CK A1 A2 RST Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7 Ahc164 [CK A1 A2 RST] [Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7] Ahc164 .model Ahc164 d_logic_block + file = 164 + user = [5n, 3n, 5n, 6n, 7n, 11n, 3n] + input_load = 4.5p + out_res = 40 + family = "HC" .ends .subckt HC4520 CPA ENA RSTA QA0 QA1 QA2 QA3 CPB ENB RSTB QB0 QB1 QB2 QB3 Ahc4520A [Clka CPA ENA RSTA] [Clka QA0 QA1 QA2 QA3] Ahc4520 Ahc4520B [Clkb CPB ENB RSTB] [Clkb QB0 QB1 QB2 QB3] Ahc4520 .model Ahc4520 d_logic_block + file = 4520 + user = [3n, 10n, 8n, 7n, 1n] + input_load=4.5p + out_res=40 + family="HC" .ends .model HC_dac dac_bridge + out_high=5 ; Logic high voltage + input_load=-31p ; Compensates for added rise and fall time + t_rise=2n ; Output rise time + t_fall=2n ; Output fall time + g_pullup=0.024 ; 1/(logic high output resistance) + g_pulldown=0.034 ; 1/(logic low output resistance) + g_hiz=1e-9 ; 1/(high impedance output res) + knee_low = 2.0 ; voltage at resistive/constant current knee logic low + knee_high =2.75 ; voltage at resistive/constant current knee logic high + v_smooth = 0.5 ; Knee smoothing band + in_family="HC" .model HC_adc adc_bridge + in_low=2.1 + in_high=2.2 + rise_delay=1e-12 + fall_delay=1e-12 + out_family = "HC" + out_low = 0 + out_high = 5 + clamp_bias=0.5 + clamp_res=10 .model HC_schmitt_adc adc_schmitt + in_low = 2.0 + in_high = 2.9 + rise_delay = 1e-12 + fall_delay = 1e-12 + out_family = "HC" + out_low = 0 + out_high = 5 + clamp_bias=0.5 + clamp_res=10 .model FORCE5_dac dac_bridge + out_high=5 + g_pullup=10 ; 0.1 Ohm + g_pulldown=10 ; 0.1 Ohm + g_resistive=0.001 ; 1K when in resistive strength i.e. for pull-up/down + g_hiz=1e-9 + knee_low = 5.0 + knee_high = 0.0 + v_smooth = 0.5 .model UNIV_dac dac_bridge + out_high=5 ; Logic high voltage + input_load=-31p ; Compensates for added rise and fall time + t_rise=2n ; Output rise time + t_fall=2n ; Output fall time + g_pullup=0.024 ; 1/(logic high output resistance) + g_pulldown=0.034 ; 1/(logic low output resistance) + g_hiz=1e-9 ; 1/(high impedance output res) + knee_low = 2.0 ; voltage at resistive/constant current knee logic low + knee_high =2.75 ; voltage at resistive/constant current knee logic high + v_smooth = 0.5 ; Knee smoothing band + in_family="UNIV" .model UNIV_adc adc_bridge + in_low=2.1 + in_high=2.2 + rise_delay=1e-12 + fall_delay=1e-12 + out_family = "UNIV" + out_low = 0 + out_high = 5 + clamp_bias=0.5 + clamp_res=10 .model BC546B npn ( IS=7.59E-15 VAF=73.4 BF=480 IKF=0.0962 NE=1.2665 + ISE=3.278E-15 IKR=0.03 ISC=2.00E-13 NC=1.2 NR=1 BR=5 RC=0.25 CJC=6.33E-12 + FC=0.5 MJC=0.33 VJC=0.65 CJE=1.25E-11 MJE=0.55 VJE=0.65 TF=4.26E-10 + ITF=0.6 VTF=3 XTF=20 RB=100 IRB=0.0001 RBM=10 RE=0.5 TR=1.50E-07) .model BC556B pnp ( IS=3.50E-15 VAF=80.5 BF=330 IKF=0.1018 NE=1.3140 + ISE=3.816E-16 IKR=0.03 ISC=5.00E-13 NC=1.6 NR=1 BR=5 RC=0.35 CJC=8.80E-12 + FC=0.5 MJC=0.28 VJC=1 CJE=1.00E-11 MJE=0.38 VJE=0.4 TF=7.00E-10 + ITF=0.6 VTF=3 XTF=11.5 RB=100 IRB=0.0001 RBM=10 RE=0.75 TR=2.00E-07) .model BC337 npn ( IS=8.52E-15 VAF=120.7 BF=280 IKF=1.1412 NE=1.3647 + ISE=3.562E-14 IKR=0.1 ISC=1.00E-12 NC=1.4 NR=1 BR=10 RC=0.05 CJC=1.20E-11 + FC=0.5 MJC=0.28 VJC=0.4 CJE=3.10E-11 MJE=0.38 VJE=0.9 TF=4.10E-10 + ITF=1.5 VTF=3 XTF=25 RE=0.2 TR=1.10E-07) .model Q2N2222 npn ( IS=2.48E-13 VAF=73.9 BF=400 IKF=0.1962 NE=1.2069 + ISE=3.696E-14 IKR=0.02 ISC=5.00E-09 NC=2 NR=1 BR=5 RC=0.3 CJC=7.00E-12 + FC=0.5 MJC=0.5 VJC=0.5 CJE=1.80E-11 MJE=0.5 VJE=1 TF=4.00E-10 + ITF=2 VTF=10 XTF=10 RE=0.4 TR=4.00E-08) .model Q2N2904 pnp ( IS=3.58E-14 VAF=26.4 BF=120 IKF=0.3416 NE=1.2861 + ISE=9.574E-14 IKR=0.03 ISC=2.00E-12 NC=1.2 NR=1 BR=5 RC=0.4 CJC=1.80E-11 + FC=0.5 MJC=0.45 VJC=0.8 CJE=2.65E-11 MJE=0.33 VJE=0.75 TF=4.10E-10 + ITF=0.54 VTF=3 XTF=20 RE=1.4 TR=8.00E-08) .model BC327 pnp ( IS=2.48E-13 VAF=99.6 BF=170 IKF=0.9648 NE=1.7746 + ISE=3.464E-12 IKR=0.1 ISC=1.00E-12 NC=1.4 NR=1 BR=10 RC=0.05 CJC=2.00E-11 + FC=0.5 MJC=0.37 VJC=0.6 CJE=4.70E-11 MJE=0.44 VJE=0.6 TF=9.70E-10 + ITF=1.9 VTF=3 XTF=25 RE=0.2 TR=9.00E-08) .alias BC547 BC546B npn .alias BC557 BC556B pnp .model J2N3819 NJF BETA=1.57m LAMBDA=4m VTO=-1.954 + CGD=1.5p M=.3821 PB=1 FC=.5 CGS=1.5p IS=173.3f N=1 XTI=3 KF=37.24E-18 AF=1 .model J175 PJF BETA=1.57m LAMBDA=30m VTO=-4 + CGD=6.5p M=.3224 PB=1 FC=.5 CGS=6.5p IS=1.023p N=1 XTI=3 KF=247.5E-18 AF=1 .model U404 NJF BETA=1.518m BETATCE=-.5 RD=1 Rs=1 LAMBDA=7.5m VTO=-1.968 + CGD=5.5p M=.4586 PB=1 Fc=.5 CGS=4.5p IS=36.51f N=1 XTI=3 KF=14.9E-18 AF=1 .model BAR42 D( + IS=1.13853e-08 ISR=3.26235e-08 RS=0.99517 + CJO=9.26191e-12 VJ=1.6 M=0.411631 BV=33 EG=0.7 ) .alias BAR43A BAR42 D .alias BAR43C BAR42 D .alias BAR43S BAR42 D .alias BAR43 BAR42 D .model D1N4148 D(IS=1.6f RS=1.0 IKF=22m CJO=3p M=0.3 VJ=0.75 ISR=2.6n + BV=70 TT=20n) .model mur105 D(IS=9p RS=23m IKF=11m CJO=40p M=0.37 VJ=0.75 ISR=820p + BV=50 IBV=100u tt=62n) .subckt RFD14N05L D G S .model mosfet NMOS( LEVEL=7 VTO=1.959 RS=0.01243 KP=18.025 RD=0.0557 TC1RD=0.0114 RG=74.831 IS=1e-36 + CGDMAX=6.00E-10 CGDMIN=4.00E-11 XG2CGD=0.5 XG1CGD=0.1 CBD=1.76E-10 VTCGD=0) .model diode D( IS=2.31e-11 RS=0.015 TT=1.000e-07) M1 D G S S mosfet D1 S D Diode Cgs G S 6.16E-10 .ends .subckt IRF530 D G S .model mosfet NMOS( LEVEL=7 VTO=3.705 RS=0.05585 KP=4.543 RD=0.0492 TC1RD=0.031 RG=7.5 IS=1e-36 + CGDMAX=1.70E-09 CGDMIN=3.00E-11 XG2CGD=0.5 XG1CGD=0.1 CBD=2.61E-10 VTCGD=0.9) .model diode D( IS=1.62e-12 RS=0.0147 TT=1.929e-07) M1 D G S S mosfet D1 S D Diode Cgs G S 6.17E-10 .ends .subckt RFD15P05 D G S .model mosfet PMOS( LEVEL=7 VTO=-3.849 RS=0.05502 KP=8.885 RD=0.0367 TC1RD=0.0204 RG=20.81 IS=1e-36 + CGDMAX=6.50E-10 CGDMIN=5.00E-11 XG2CGD=0.5 XG1CGD=0.1 CBD=3.22E-10 VTCGD=0) .model diode D( IS=2.47e-11 RS=0.022 TT=9.866e-08) M1 D G S S mosfet D1 D S Diode Cgs G S 1.09E-09 .ends .alias IRF130 IRF530 subckt .subckt BZX79-2V7 1 2 D1 1 2 D1 D2 2 3 D2 I1 1 3 0.64353 R1 1 3 3 TC1=-1.0359m .model D1 D IS=9.19e-16 CJO=450p RS=0.57061 ISR=3.30e-07 .model D2 D IS=1.00e-15 .ends .subckt BZX79-4V7 1 2 D1 1 2 D1 D2 2 3 D2 I1 1 3 0.9814 R1 1 3 4 TC1=-0.3566m .model D1 D IS=9.19e-16 CJO=300p RS=0.57061 ISR=4.05e-08 .model D2 D IS=1.00e-15 .ends .subckt BZX79-10 1 2 D1 1 2 D1 D2 2 3 D2 I1 1 3 2.3064 R1 1 3 4 TC1=0.6937m .model D1 D IS=9.19e-16 CJO=90p RS=0.57061 ISR=1.65e-09 .model D2 D IS=1.00e-15 .ends .subckt BZX79-15 1 2 D1 1 2 D1 D2 2 3 D2 I1 1 3 2.84412 R1 1 3 5 TC1=0.8017m .model D1 D IS=9.19e-16 CJO=75p RS=0.57061 ISR=3.44e-10 .model D2 D IS=1.00e-15 .ends .SUBCKT TL071 1 2 3 4 5 * C1 11 12 3.498E-12 C2 6 7 15.00E-12 DC 5 53 DX DE 54 5 DX DLP 90 91 DX DLN 92 90 DX DP 4 3 DX EGND 99 0 POLY(2) (3,0) (4,0) 0 .5 .5 FB 7 99 POLY(5) VB VC VE VLP VLN 0 4.715E6 -5E6 5E6 5E6 -5E6 GA 6 0 11 12 282.8E-6 GCM 0 6 10 99 8.942E-9 ISS 3 10 DC 195.0E-6 HLIM 90 0 VLIM 1K J1 11 2 10 JX J2 12 1 10 JX R2 6 9 100.0E3 RD1 4 11 3.536E3 RD2 4 12 3.536E3 RO1 8 5 150 RO2 7 99 150 RP 3 4 2.143E3 RSS 10 99 1.026E6 VB 9 0 DC 0 VC 3 53 DC 2.200 VE 54 4 DC 2.200 VLIM 7 8 DC 0 VLP 91 0 DC 25 VLN 0 92 DC 25 .MODEL DX D(IS=800.0E-18) .MODEL JX PJF(IS=15.00E-12 BETA=270.1E-6 VTO=-1) .ENDS .alias TL072 TL071 SUBCKT .alias TL074 TL071 SUBCKT .SUBCKT LP339 1 2 3 4 5 * F1 9 3 V1 1 IEE 3 7 DC 100.0E-6 VI1 21 1 DC .75 VI2 22 2 DC .75 Q1 9 21 7 QIN Q2 8 22 7 QIN Q3 9 8 4 QMO Q4 8 8 4 QMI .MODEL QIN PNP(IS=800.0E-18 BF=20.00E3) .MODEL QMI NPN(IS=800.0E-18 BF=1002) .MODEL QMO NPN(IS=800.0E-18 BF=1000 CJC=1E-15 TR=4.968E-6) E1 10 4 9 4 1 V1 10 11 DC 0 Q5 5 11 4 QOC .MODEL QOC NPN(IS=800.0E-18 BF=16.84E3 CJC=1E-15 TF=2.826E-9 TR=3.350E-6) DP 4 3 DX RP 3 4 -77E3 .MODEL DX D(IS=800.0E-18) * .ENDS .SUBCKT LM324/NS 1 2 99 50 28 * *Features: *Eliminates need for dual supplies *Large DC voltage gain = 100dB *High bandwidth = 1MHz *Low input offset voltage = 2mV *Wide supply range = +-1.5V to +-16V * *NOTE: Model is for single device only and simulated * supply current is 1/4 of total device current. * Output crossover distortion with dual supplies * is not modeled. * ****************INPUT STAGE************** * IOS 2 1 5N *^Input offset current R1 1 3 500K R2 3 2 500K I1 99 4 100U R3 5 50 517 R4 6 50 517 Q1 5 2 4 QX Q2 6 7 4 QX *Fp2=1.2 MHz C4 5 6 128.27P * ***********COMMON MODE EFFECT*********** * I2 99 50 75U *^Quiescent supply current EOS 7 1 POLY(1) 16 49 2E-3 1 *Input offset voltage.^ R8 99 49 60K R9 49 50 60K * *********OUTPUT VOLTAGE LIMITING******** V2 99 8 1.63 D1 9 8 DX D2 10 9 DX V3 10 50 .635 * **************SECOND STAGE************** * EH 99 98 99 49 1 G1 98 9 POLY(1) 5 6 0 9.8772E-4 0 .3459 *Fp1=7.86 Hz R5 98 9 101.2433MEG C3 98 9 200P * ***************POLE STAGE*************** * *Fp=2 MHz G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.9577E-14 * *********COMMON-MODE ZERO STAGE********* * *Fpcm=10 KHz G4 98 16 3 49 5.6234E-8 L2 98 17 15.9M R13 17 16 1K * **************OUTPUT STAGE************** * F6 50 99 POLY(1) V6 300U 1 E1 99 23 99 15 1 R16 24 23 17.5 D5 26 24 DX V6 26 22 .63V R17 23 25 17.5 D6 25 27 DX V7 22 27 .63V V5 22 21 0.27V D4 21 15 DX V4 20 22 0.27V D3 15 20 DX L3 22 28 500P RL3 22 28 100K * ***************MODELS USED************** * .MODEL DX D(IS=1E-15) .MODEL QX PNP(BF=1.111E3) * .ENDS *////////////////////////////////////////////////////////// *LF353 Wide Bandwidth Dual JFET-Input OP-AMP MACRO-MODEL *////////////////////////////////////////////////////////// * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF353/NS 1 2 99 50 28 * *Features: *Low supply current = 1.8mA *Wide bandwidth = 4MHz *High slew rate = 13V/uS *Low offset voltage = 10mV * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * ****************INPUT STAGE************** * IOS 2 1 25P *^Input offset current R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX J2 6 7 4 JX R3 5 50 20K R4 6 50 20K *Fp2=12 MHz C4 5 6 3.31573E-13 * ***********COMMON MODE EFFECT*********** * I2 99 50 1.7MA *^Quiescent supply current EOS 7 1 POLY(1) 16 49 5E-3 1 *Input offset voltage.^ R8 99 49 50K R9 49 50 50K * *********OUTPUT VOLTAGE LIMITING******** V2 99 8 2.13 D1 9 8 DX D2 10 9 DX V3 10 50 2.13 * **************SECOND STAGE************** * EH 99 98 99 49 1 F1 9 98 POLY(1) VA3 0 0 0 1.0985E7 G1 98 9 5 6 1E-3 R5 98 9 100MEG VA3 9 11 0 *Fp1=40.3 HZ C3 98 11 39.493P * ***************POLE STAGE*************** * *Fp3=42 MHz G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 3.7894E-15 * *********COMMON-MODE ZERO STAGE********* * G4 98 16 3 49 1E-8 L2 98 17 31.831M R13 17 16 1K * **************OUTPUT STAGE************** * F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX VA7 99 21 0 D6 23 99 DX E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 35 V5 28 25 0.1V D4 25 15 DX V4 24 28 0.1V D3 15 24 DX * ***************MODELS USED************** * .MODEL DX D(IS=1E-15) .MODEL JX PJF(BETA=1.25E-5 VTO=-2.00 IS=50E-12) * .ENDS *$ *////////////////////////////////////////////////////////// *LM6218 Fast Settling Dual OP-AMP MACRO-MODEL *////////////////////////////////////////////////////////// * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6218/NS 1 2 99 50 28 * *Features: *Low offset voltage = .2mV *High bandwidth = 17MHz *Slew rate (Av=-1) = 140V/uS * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * ****************INPUT STAGE************** * IOS 2 1 20N *^Input offset current CI1 1 0 2.5P CI2 2 0 2.5P R1 1 3 3.125G R2 3 2 3.125G I1 99 4 40U R43 45 4 1.25K R44 46 4 1.25K Q1 5 2 45 QX Q2 6 7 46 QX R3 50 5 2.54K R4 50 6 2.54K *Fp2=30 MHz C4 5 6 1.0433P * ***********COMMON MODE EFFECT*********** * I2 99 50 2.71M *^Quiescent supply current EOS 7 1 POLY(1) 16 49 .2E-3 1 *Input offset voltage.^ R8 99 49 71.4K R9 49 50 71.4K * *********OUTPUT VOLTAGE LIMITING******** V2 99 8 2.63 D1 9 8 DX D2 10 9 DX V3 10 50 2.63 * **************SECOND STAGE************** * EH 99 98 99 49 1 G1 98 9 POLY(1) 5 6 0 5E-3 0 5.056 *Fp1=38.24 Hz R5 98 9 100MEG C3 98 9 41.62P * ***************POLE STAGE*************** * *Fp=110 MHz G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1.4469E-15 * *********COMMON-MODE ZERO STAGE********* * *Fpcm=6 KHz G4 98 16 3 49 1E-8 L2 98 17 26.526M R13 17 16 1K * **************OUTPUT STAGE************** * F6 50 99 POLY(1) V6 200U 1 E1 99 23 99 15 1 R16 24 23 10 D5 26 24 DY V6 26 22 .63V R17 23 25 10 D6 25 27 DY C9 23 22 .001U V7 22 27 .63V V5 22 21 .63V D4 21 15 DX V4 20 22 .63V D3 15 20 DX L3 22 28 100P RL3 22 28 100K * ***************MODELS USED************** * .MODEL DX D(IS=1E-15) .MODEL DY D(IS=1E-25) .MODEL QX PNP(BF=100) * .ENDS *$ *////////////////////////////////////////////////////////////////////// * (C) National Semiconductor, Inc. * Models developed and under copyright by: * National Semiconductor, Inc. *///////////////////////////////////////////////////////////////////// * Legal Notice: This material is intended for free software support. * The file may be copied, and distributed; however, reselling the * material is illegal. *//////////////////////////////////////////////////////////////////// * For ordering or technical information on these models, contact: * National Semiconductor's Customer Response Center * 7:00 A.M.--7:00 P.M. U.S. Central Time * (800) 272-9959 * For Applications support, contact the Internet address: * amps-apps@galaxy.nsc.com *////////////////////////////////////////////////////////// *LMC6681A CMOS Single OP-AMP MACRO-MODEL *////////////////////////////////////////////////////////// * * Connections: Non-inverting input * | Inverting input * | | Positive power supply * | | | Negative power supply * | | | | Output * | | | | | Shutdown * | | | | | | .SUBCKT LMC6681A/NS 1 2 99 50 28 33 * CAUTION: SET .OPTIONS GMIN=1E-16 TO CORRECTLY MODEL INPUT BIAS CURRENT. * Features: * Operates from single supply * Rail-to-rail output swing * Low offset voltage (max) = 1mV@5V * Slew rate = 1.2V/uS * Gain-bandwidth product = 1.2 MHz * Amplifier shut-down * * NOTE: - Model is for single device only and simulated. * - Noise is not modeled. * - Asymmetrical gain is not modeled. * CI1 1 50 2P CI2 2 50 2P * 1.4 Hz pole capacitor C3 98 9 5.85N * 2.95 MHz pole capacitor C4 6 5 4.93P * Drain-substrate capacitor C6 50 4 10P * 35 MHz pole capacitor C7 98 11 4.54F COUT 28 0 10P CSD1 41 40 100P DP1 1 99 DA DP2 50 1 DX DP3 2 99 DB DP4 50 2 DX D1 9 8 DX D2 10 9 DX D3 29 22 DX D4 22 30 DX D5 22 26 DX D6 27 22 DX D7 22 99 DX D8 50 22 DX D9 0 14 DX D10 12 0 DX D11 31 32 DX EH 97 98 99 49 1.0 EN 0 96 0 50 1.0 * Input offset voltage -| EOS 7 1 POLY(1) 16 49 1M 1 EP 97 0 99 0 1.0 E1 97 23 99 15 1.0 E2 18 7 32 97 1E-3 * Sourcing load +Vs current F1 99 0 VA2 1 * Sinking load -Vs current F2 0 50 VA3 1 F3 13 0 VA1 1 G1 98 9 5 6 0.1 G2 98 11 9 49 1U G3 98 15 11 49 1U * DC CMRR G4 98 16 POLY(2) 1 49 2 49 0 3.54E-8 3.54E-8 G5 99 4 39 45 11.5U G6 99 50 39 45 340U * Load dependent pole L1 19 28 40.4U * CMR lead L2 16 17 7.95M M1 5 2 4 99 MPX M2 6 18 4 99 MPX M3 41 33 40 40 MN1 M4 45 41 39 39 MP2 M5 45 41 40 40 MN3 R3 5 50 3.60K R4 6 50 3.60K R5 98 9 1E7 R8 42 44 25K R9 44 50 25K R12 98 11 1E6 R13 98 17 1K * -Rout R16 23 24 55 * +Rout R17 23 25 55 * +Isc slope control R18 15 20 1MEG * -Isc slope control R19 21 15 400K R21 98 15 1E6 R22 19 28 900 R23 32 97 100K R24 99 49 10MEG R25 49 50 10MEG R26 33 50 20MEG R27 39 41 250K S1 99 42 41 49 SX S2 22 36 41 49 SX VA1 36 19 0V VA2 14 13 0V VA3 13 12 0V V2 97 8 0.66V V3 10 96 0.66V V4 20 29 0.13V V5 30 21 0.13V V6 24 26 0.63V V7 27 25 0.63V V8 31 96 3.6V V9 39 49 1 V10 49 40 1 * .MODEL DA D (IS=250E-15) .MODEL DB D (IS=175E-15) .MODEL DX D (IS=100E-15) .MODEL MPX PMOS (VTO=-.6 KP=7.0547E-4 GAMMA=1.1) .MODEL MN1 NMOS (VTO=.6 KP=7.0547E-4 GAMMA=1.1) .MODEL MP2 PMOS (VTO=0, KP=7.0547E-4) .MODEL MN3 NMOS (VTO=0, KP=7.0547E-4) .MODEL SX VSWITCH (RON=1, ROFF=1E+8, VON=0.01, VOFF=-0.01) .ENDS * *ZETEX ZTX605 Darlington Spice Subcircuit Last revision 24/6/93 * .SUBCKT ZTX605 1 2 3 * C B E Q1 1 2 4 SUB605 Q2 1 4 3 SUB605 3.46 * .MODEL SUB605 NPN IS=4.8E-14 BF=170 VAF=542 NF=1.0039 IKF=0.2 ISE=1.5E-14 +NE=1.55 BR=12 VAR=20 NR=1.007 IKR=0.35 ISC=7.486E-14 NC=1.0984 RB=0.17 RE=0.3 +RC=0.14 CJE=81E-12 CJC=10.8E-12 VJC=0.58 MJC=0.41 TF=1.024E-9 TR=700E-9 .ENDS ZTX605 *ZETEX ZTX705 Darlington Spice Subcircuit Last revision 9/8/90 * .SUBCKT ZTX705 1 2 3 * C B E Q1 1 2 4 SUB704 Q2 1 4 3 SUB704 4 * .MODEL SUB704 PNP IS =3.35584E-14 BF =85 VAF=212 NF =1.002 IKF=.817 +ISE=3.6E-13 NE =4.1 BR =24 VAR=6 NR =.999 IKR=.114 ISC=1.406E-13 NC =1.13 +RB =1.1 RE =.4 RC =.0339 CJE=100E-12 CJC=37E-12 VJC=1.045 MJC=.595 .ENDS ZTX705