* PSpice Model Editor - Version 9.2 *$ * ****************************** * Acquisition d'un signal analogique * par Echantillonnage de celui-ci * a une frequence = fech * (c) LOUTRE Noel mars 1999 * * macro-modele de l'echantillonneur bloqueur * d'ordre Zero * .SUBCKT Echant_HF_faible e Sech PARAMS: fech=352.8k * * Interupteur d'acquisition de e Sechant e s1 c 0 Inter-ech .MODEL Inter-ech VSWITCH (Von=3V Voff=2V Ron=0.1 Roff=10E6) * * signal de commande de l'inter d'acquisition de e Vc c 0 PULSE (0 5 0 {1/(500*fech)} {1/(500*fech)} + {1/(500*fech)} {1/fech}) * * memorisation de la tension acquise dans C1 * R1 elimine parasite transitoire lors de la simulation * 5*R1*C1 < a la fenetre d'acquisition (pw) * R1 s1 s2 {1/(5E-6*fech)} C1 s1 0 1pF * * etage tampon de sortie Gain=1 Eunite Sech 0 VALUE={V(s1)} R2 Sech 0 1k .ENDS Echant_HF_faible *$ * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058-65C 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS=65 ) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS=65 ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS=65 ) .MODEL DLIM D (IS=100U T_ABS=65 ) .ENDS 2SK1058-65C *$ * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058-75C 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS=75 ) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS=75 ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS=75 ) .MODEL DLIM D (IS=100U T_ABS=75 ) .ENDS 2SK1058-75C *$ *************************** .SUBCKT IRFZ46N-75C 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS=75 +VTO=3.82619 LAMBDA=0 KP=36.481 +CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS=75 +IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 +CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS=75 +CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS=75 RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS=75 .ENDS IRFZ46N-75C *$ * * .SUBCKT TIP142-75C 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS=75 + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS=75 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS=75 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-75C *$ * .subckt IRF540-75C 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.56362 lambda=0.00291031 + kp=25.0081 cgso=1.60584e-05 cgdo=4.25919e-07 + T_ABS=75 rs 8 3 0.0317085 d1 3 1 md .model md d is=1.02194e-10 rs=0.00968022 n=1.21527 bv=100 ibv=0.00025 + eg=1.2 xti=3.03885 tt=0.0001 cjo=1.81859e-09 vj=1.1279 m=0.449161 fc=0.5 + T_ABS=75 rds 3 1 4e+06 rd 9 1 0.0135649 rg 2 7 5.11362 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=2.49697e-09 vj=0.5 m=0.9 fc=1e-08 + T_ABS=75 d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.4 rs=3e-06 + T_ABS=75 rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 2.49697e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.4 + T_ABS=75 .ends IRF540-75C *$ * .subckt IRF540-65C 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.56362 lambda=0.00291031 + kp=25.0081 cgso=1.60584e-05 cgdo=4.25919e-07 + T_ABS=65 rs 8 3 0.0317085 d1 3 1 md .model md d is=1.02194e-10 rs=0.00968022 n=1.21527 bv=100 ibv=0.00025 + eg=1.2 xti=3.03885 tt=0.0001 cjo=1.81859e-09 vj=1.1279 m=0.449161 fc=0.5 + T_ABS=65 rds 3 1 4e+06 rd 9 1 0.0135649 rg 2 7 5.11362 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=2.49697e-09 vj=0.5 m=0.9 fc=1e-08 + T_ABS=65 d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.4 rs=3e-06 + T_ABS=65 rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 2.49697e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.4 + T_ABS=65 .ends IRF540-65C *$ * * .SUBCKT TIP142-65C 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS=65 + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS=65 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS=65 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-65C *$ *************************** .SUBCKT IRFZ46N-85C 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS=85 +VTO=3.82619 LAMBDA=0 KP=36.481 +CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS=85 +IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 +CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS=85 +CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS=85 RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS=85 .ENDS IRFZ46N-85C *$ * * .SUBCKT TIP142-85C 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS=85 + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS=85 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS=85 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-85C *$ .model 1N4007-30C D(Is=14.11n N=1.984 Rs=33.89m Ikf=94.81 Xti=3 Eg=1.11 T_ABS=30 + Cjo=25.89p M=.44 Vj=.3245 Fc=.5 Bv=1500 Ibv=10u Tt=5.7u) * Motorola * Semiconductor Databook (mid 1970s) * 03 Jun 91 pwt creation *$ * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058-90C 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS=90 ) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS=90 ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS=90) .MODEL DLIM D (IS=100U T_ABS=90) .ENDS 2SK1058-90C *$ *************************** .SUBCKT IRFZ46N-60C 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS=60 +VTO=3.82619 LAMBDA=0 KP=36.481 +CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS=60 +IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 +CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS=60 +CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS=60 RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS=60 .ENDS IRFZ46N-60C *$ *************************** .SUBCKT IRFZ46N-70C 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS=70 +VTO=3.82619 LAMBDA=0 KP=36.481 +CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS=70 +IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 +CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS=70 +CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS=70 RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS=70 .ENDS IRFZ46N-70C *$ *************************** .SUBCKT IRFZ46N-80C 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS=80 +VTO=3.82619 LAMBDA=0 KP=36.481 +CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS=80 +IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 +CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS=80 +CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS=80 RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS=80 .ENDS IRFZ46N-80C *$ * * .SUBCKT TIP142-70C 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS=70 + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS=70 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS=70 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-70C *$ * .subckt IRF540-60C 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.56362 lambda=0.00291031 + kp=25.0081 cgso=1.60584e-05 cgdo=4.25919e-07 + T_ABS=60 rs 8 3 0.0317085 d1 3 1 md .model md d is=1.02194e-10 rs=0.00968022 n=1.21527 bv=100 ibv=0.00025 + eg=1.2 xti=3.03885 tt=0.0001 cjo=1.81859e-09 vj=1.1279 m=0.449161 fc=0.5 + T_ABS=60 rds 3 1 4e+06 rd 9 1 0.0135649 rg 2 7 5.11362 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=2.49697e-09 vj=0.5 m=0.9 fc=1e-08 + T_ABS=60 d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.4 rs=3e-06 + T_ABS=60 rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 2.49697e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.4 + T_ABS=60 .ends IRF540-60C *$ * .subckt IRF540-90C 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.56362 lambda=0.00291031 + kp=25.0081 cgso=1.60584e-05 cgdo=4.25919e-07 + T_ABS=90 rs 8 3 0.0317085 d1 3 1 md .model md d is=1.02194e-10 rs=0.00968022 n=1.21527 bv=100 ibv=0.00025 + eg=1.2 xti=3.03885 tt=0.0001 cjo=1.81859e-09 vj=1.1279 m=0.449161 fc=0.5 + T_ABS=70 rds 3 1 4e+06 rd 9 1 0.0135649 rg 2 7 5.11362 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=2.49697e-09 vj=0.5 m=0.9 fc=1e-08 + T_ABS=90 d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.4 rs=3e-06 + T_ABS=90 rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 2.49697e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.4 + T_ABS=90 .ends IRF540-90C *$ * .subckt IRF540-70C 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.56362 lambda=0.00291031 + kp=25.0081 cgso=1.60584e-05 cgdo=4.25919e-07 + T_ABS=70 rs 8 3 0.0317085 d1 3 1 md .model md d is=1.02194e-10 rs=0.00968022 n=1.21527 bv=100 ibv=0.00025 + eg=1.2 xti=3.03885 tt=0.0001 cjo=1.81859e-09 vj=1.1279 m=0.449161 fc=0.5 + T_ABS=70 rds 3 1 4e+06 rd 9 1 0.0135649 rg 2 7 5.11362 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=2.49697e-09 vj=0.5 m=0.9 fc=1e-08 + T_ABS=70 d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.4 rs=3e-06 + T_ABS=70 rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 2.49697e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.4 + T_ABS=70 .ends IRF540-70C *$ * * .SUBCKT TIP142-60C 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS=60 + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS=60 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS=60 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-60C *$ .SUBCKT IRFZ46N-MODPEX 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS={temp_abs} +VTO=3.82619 LAMBDA=0 KP=36.481 +CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS={temp_abs} +IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 +CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS={temp_abs} +CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS={temp_abs} RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS={temp_abs} .ENDS IRFZ46N-MODPEX *$ .SUBCKT IRFZ46N 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS={temp_abs} + VTO=3.82619 LAMBDA=0 KP=36.481 + CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS={temp_abs} + IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 + CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS={temp_abs} + CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS={temp_abs} RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS={temp_abs} .ENDS IRFZ46N *$ * ********************************************* * .SUBCKT IRF540-MODPEX 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS={temp_abs} + VTO=3.56362 LAMBDA=0.00291031 KP=25.0081 + CGSO=1.60584e-05 CGDO=4.25919e-07 RS 8 3 0.0317085 D1 3 1 MD .MODEL MD D IS=1.02194e-10 RS=0.00968022 N=1.21527 BV=100 + T_ABS={temp_abs} + IBV=0.00025 EG=1.2 XTI=3.03885 TT=1e-07 + CJO=1.81859e-09 VJ=1.1279 M=0.449161 FC=0.5 RDS 3 1 4e+06 RD 9 1 0.0135649 RG 2 7 5.11362 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 T_ABS={temp_abs} +CJO=2.49697e-09 VJ=0.5 M=0.9 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS={temp_abs} RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 2.49697e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 T_ABS={temp_abs} .ENDS IRF540 *$ * *************************** * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS={temp_abs}) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS={temp_abs} ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS={temp_abs}) .MODEL DLIM D (IS=100U T_ABS={temp_abs}) .ENDS 2SK1058 *$ *************************** * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058-ICAP 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS={temp_abs}) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS={temp_abs} ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS={temp_abs}) .MODEL DLIM D (IS=100U T_ABS={temp_abs}) .ENDS 2SK1058-ICAP *$ * ********************************** * qlq modif pour compatibilite avec PSPICE v8 * modelisation de R avec TC1 et TC2 * (c) Loutre Noel juin 2001 * MOSFETs N /Harris RFP50N06 * 0,022 Ohms : .SUBCKT RFP50N06-HARRIS 2 1 3 Ca 12 8 3.68e-9 Cb 15 14 3.625e-9 Cin 6 8 1.98e-9 Dbody 7 5 DBDMOD Dbreak 5 11 DBKMOD Dplcap 10 5 DPLCAPMOD Ebreak 11 7 17 18 64.59 Eds 14 8 5 8 1 Egs 13 8 6 8 1 Esg 6 10 6 8 1 Evto 20 6 18 8 1 It 8 17 1 Ldrain 2 5 1e-9 Lgate 1 9 5.65e-9 Lsource 3 7 4.13e-9 Mos1 16 6 8 8 MOSMOD L=.99U W=.99U ; M=0.99 Mos2 16 21 8 8 MOSMOD L=.01U W=.01U ; M=0.01 * Rbreak 17 18 RBKMOD 1 Rbreak 17 18 1 TC=1.23e-3,-2.34e-6 * Rdrain 5 16 RDSMOD 1.00e-4 Rdrain 5 16 1.00e-4 TC=5.01e-3,1.49e-5 Rgate 9 20 0.690 Rin 6 8 1e9 * Rsource 8 7 RDSMOD 12.0e-3 Rsource 8 7 12.0e-3 TC=5.01e-3,1.49e-5 * Rvto 18 19 RVTOMOD 1 Rvto 18 19 1 TC=-5.03e-3,-5.16e-6 S1a 6 12 13 8 S1AMOD S1b 13 12 13 8 S1BMOD S2a 6 15 14 13 S2AMOD S2b 13 15 14 13 S2BMOD Vbat 8 19 DC 1 Vto 21 6 0.678 .MODEL DBDMOD D (IS=9.851e-13 RS=4.91e-3 T_ABS={temp_abs} + CJO=2.05e-9 TT=4.33e-8) ; TRS1=2.07e-3 TRS2=2.51e-7) .MODEL DBKMOD D (RS=1.98e-1 T_ABS={temp_abs}) ; TRS1=-2.35e-3 TRS2=-3.83e-6 .MODEL DPLCAPMOD D (CJO=1.42e-9 IS=1e-30 N=10 T_ABS={temp_abs}) .MODEL MOSMOD NMOS (VTO=3.65 KP=35 IS=1e-30 TOX=1 T_ABS={temp_abs}) *.MODEL RBKMOD R (TC1=1.23e-3 TC2=-2.34e-6) *.MODEL RDSMOD R (TC1=5.01e-3 TC2=1.49e-5) *.MODEL RVTOMOD R (TC1=-5.03e-3 TC2=-5.16e-6) .MODEL S1AMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=-6.75 VOFF=-2.50) .MODEL S1BMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=-2.50 VOFF=-6.75) .MODEL S2AMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=-2.7 VOFF=2.3) .MODEL S2BMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=2.3 VOFF=-2.7) .ENDS RFP50N06-HARRIS *$ ********************************** * qlq modif pour compatibilite avec PSPICE v8 * modelisation de R avec TC1 et TC2 * (c) Loutre Noel juin 2001 * MOSFETs N /Harris RFP50N06 * 0,022 Ohms : .SUBCKT RFP50N06 2 1 3 Ca 12 8 3.68e-9 Cb 15 14 3.625e-9 Cin 6 8 1.98e-9 Dbody 7 5 DBDMOD Dbreak 5 11 DBKMOD Dplcap 10 5 DPLCAPMOD Ebreak 11 7 17 18 64.59 Eds 14 8 5 8 1 Egs 13 8 6 8 1 Esg 6 10 6 8 1 Evto 20 6 18 8 1 It 8 17 1 Ldrain 2 5 1e-9 Lgate 1 9 5.65e-9 Lsource 3 7 4.13e-9 Mos1 16 6 8 8 MOSMOD L=.99U W=.99U ; M=0.99 Mos2 16 21 8 8 MOSMOD L=.01U W=.01U ; M=0.01 * Rbreak 17 18 RBKMOD 1 Rbreak 17 18 1 TC=1.23e-3,-2.34e-6 * Rdrain 5 16 RDSMOD 1.00e-4 Rdrain 5 16 1.00e-4 TC=5.01e-3,1.49e-5 Rgate 9 20 0.690 Rin 6 8 1e9 * Rsource 8 7 RDSMOD 12.0e-3 Rsource 8 7 12.0e-3 TC=5.01e-3,1.49e-5 * Rvto 18 19 RVTOMOD 1 Rvto 18 19 1 TC=-5.03e-3,-5.16e-6 S1a 6 12 13 8 S1AMOD S1b 13 12 13 8 S1BMOD S2a 6 15 14 13 S2AMOD S2b 13 15 14 13 S2BMOD Vbat 8 19 DC 1 Vto 21 6 0.678 .MODEL DBDMOD D (IS=9.851e-13 RS=4.91e-3 T_ABS={temp_abs} + CJO=2.05e-9 TT=4.33e-8) ; TRS1=2.07e-3 TRS2=2.51e-7) .MODEL DBKMOD D (RS=1.98e-1 T_ABS={temp_abs}) ; TRS1=-2.35e-3 TRS2=-3.83e-6 .MODEL DPLCAPMOD D (CJO=1.42e-9 IS=1e-30 N=10 T_ABS={temp_abs}) .MODEL MOSMOD NMOS (VTO=3.65 KP=35 IS=1e-30 TOX=1 T_ABS={temp_abs}) *.MODEL RBKMOD R (TC1=1.23e-3 TC2=-2.34e-6) *.MODEL RDSMOD R (TC1=5.01e-3 TC2=1.49e-5) *.MODEL RVTOMOD R (TC1=-5.03e-3 TC2=-5.16e-6) .MODEL S1AMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=-6.75 VOFF=-2.50) .MODEL S1BMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=-2.50 VOFF=-6.75) .MODEL S2AMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=-2.7 VOFF=2.3) .MODEL S2BMOD VSWITCH(RON=1e-5 ROFF=0.1 VON=2.3 VOFF=-2.7) .ENDS RFP50N06 *$ * .model 1N4148 D(Is=2.682n N=1.836 Rs=.5664 Ikf=44.17m Xti=3 Eg=1.11 Cjo=4p + M=.3333 Vj=.5 Fc=.5 Isr=1.565n Nr=2 Bv=100 Ibv=100u Tt=11.54n) * ******************* *$ .model 1N4007 D(Is=14.11n N=1.984 Rs=33.89m Ikf=94.81 Xti=3 Eg=1.11 + Cjo=25.89p M=.44 Vj=.3245 Fc=.5 Bv=1500 Ibv=10u Tt=5.7u) * Motorola * Semiconductor Databook (mid 1970s) * 03 Jun 91 pwt creation *$ .model 1N4007-40C D(Is=14.11n N=1.984 Rs=33.89m Ikf=94.81 Xti=3 Eg=1.11 T_ABS=40 + Cjo=25.89p M=.44 Vj=.3245 Fc=.5 Bv=1500 Ibv=10u Tt=5.7u) * Motorola * Semiconductor Databook (mid 1970s) * 03 Jun 91 pwt creation ********************************************* * *$ .MODEL 1N1184 D (IS=23.4N RS=1.75M N=1.61 BV=133.3 IBV=4M + CJO=4.4N VJ=.75 M=.333 TT=144U ) * Motorola 100 Volt 20 Amp 100 us Si Diode 11-23-1990 * ***************** *$ .model 1N1190 D(Is=1.331u N=2.108 Rs=1.029m + Ikf=11.73 Xti=3 Eg=1.11 Cjo=1p M=.5 Vj=.7 Fc=.5 + Isr=40.74u Nr=2 Bv=400 Ibv=100u Tt=5n ) * *$ .model 1N1190-50C D(Is=1.331u N=2.108 Rs=1.029m + Ikf=11.73 Xti=3 Eg=1.11 Cjo=1p M=.5 Vj=.7 Fc=.5 + Isr=40.74u Nr=2 Bv=400 Ibv=100u Tt=5n + T_ABS=50) * *************************************** * macro-modele TIP 141 Darlington NPN *(ICmax=10A:Pmax=125W:BETAmin=500:VCEomax=80V) *$ .SUBCKT TIP141 1 2 3 * connections: C B E Q1 1 2 4 QTIP141 0.1 Q2 1 4 3 QTIP141 R1 2 4 8K R2 4 3 40 D1 3 1 DTIP141 .MODEL QTIP141 NPN (IS=12P NF=1 BF=99.9 VAF=161 IKF=8 ISE=981P NE=2 + BR=4 NR=1 VAR=20 IKR=12 RE=40M RB=.16 RC=16M XTB=1.5 T_ABS={temp_abs} + CJE=1.34N VJE=.74 MJE=.45 CJC=193P VJC=1.1 MJC=.24 TF=98.5N TR=4.25U) .MODEL DTIP141 D (IS=12P N=1 RS=40M BV=80 IBV=.001 CJO=193P TT=4.25U T_ABS={temp_abs}) .ENDS TIP141 * * macro-modele TIP 141 Darlington NPN *(ICmax=10A:Pmax=125W:BETAmin=500:VCEomax=80V) *$ .SUBCKT TIP141-ICAP 1 2 3 * connections: C B E Q1 1 2 4 QTIP141 0.1 Q2 1 4 3 QTIP141 R1 2 4 8K R2 4 3 40 D1 3 1 DTIP141 .MODEL QTIP141 NPN (IS=12P NF=1 BF=99.9 VAF=161 IKF=8 ISE=981P NE=2 + BR=4 NR=1 VAR=20 IKR=12 RE=40M RB=.16 RC=16M XTB=1.5 T_ABS={temp_abs} + CJE=1.34N VJE=.74 MJE=.45 CJC=193P VJC=1.1 MJC=.24 TF=98.5N TR=4.25U) .MODEL DTIP141 D (IS=12P N=1 RS=40M BV=80 IBV=.001 CJO=193P TT=4.25U T_ABS={temp_abs}) .ENDS TIP141-ICAP *$ ************************ *TIP142;BJTs NPN;Darlington;100V 10A * .SUBCKT TIP142 1 2 3 * TERMINALS: C B E * 100 Volt 10 Amp NPN Darlington Transistor 08-04-1995 Q1 1 2 4 QPWR .1 Q2 1 4 3 QPWR R1 2 4 8K R2 4 3 40 D1 3 1 DSUB .MODEL QPWR NPN (IS=12P NF=1 BF=150 VAF=180 IKF=4.64 ISE=494P NE=2 + BR=4 NR=1 VAR=20 IKR=6.96 RE=.115 RB=.46 RC=46M XTB=1.5 T_ABS={temp_abs} + CJE=1.34N VJE=.74 MJE=.45 CJC=193P VJC=1.1 MJC=.24 TF=110N TR=4.75U) .MODEL DSUB D (IS=12P N=1 RS=.115 BV=100 IBV=.001 CJO=193P TT=4.75U T_ABS={temp_abs}) .ENDS TIP142 *$ * * OPA627E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * "E" IS ENHANCED MODEL * CREATED USING PARTS RELEASE 4.03 ON 10/04/90 AT 09:30 * * REV.B 5/22/91 TK * REV.C 3/21/92 BCB: added input bias current correction and * current and voltage noise * * ------------------------------------------------------------------------ * | NOTICE: THE INFORMATION PROVIDED HEREIN IS BELIEVED TO BE RELIABLE; | * | HOWEVER; BURR-BROWN ASSUMES NO RESPONSIBILITY FOR INACCURACIES OR | * | OMISSIONS. BURR-BROWN ASSUMES NO RESPONSIBILITY FOR THE USE OF THIS | * | INFORMATION, AND ALL USE OF SUCH INFORMATION SHALL BE ENTIRELY AT | * | THE USER'S OWN RISK. NO PATENT RIGHTS OR LICENSES TO ANY OF THE | * | CIRCUITS DESCRIBED HEREIN ARE IMPLIED OR GRANTED TO ANY THIRD PARTY. | * | BURR-BROWN DOES NOT AUTHORIZE OR WARRANT ANY BURR-BROWN PRODUCT FOR | * | USE IN LIFE-SUPPORT DEVICES AND/OR SYSTEMS. | * ------------------------------------------------------------------------ * * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OPA627 1 2 3 4 5 * C1 11 12 3.182E-12 C2 6 7 23.00E-12 CSS 10 99 40.45E-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 0 419.4E6 -40E6 40E6 40E6 -40E6 GA 6 0 11 12 2.432E-3 GCM 0 6 10 99 3.779E-9 ISS 3 10 DC 1.840E-3 HLIM 90 0 VLIM 1K J1 11 2 10 JX J2 12 64 10 JX G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 1.6E-6 G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 1.6E-6 R2 6 9 100.0E3 RD1 4 11 419.4 RD2 4 12 419.4 RO1 8 5 54 RO2 7 99 1 * RP 3 4 4.286E3 RSS 10 99 108.7E3 VB 9 0 DC 0 VC 3 53 DC 2.700 VE 54 4 DC 2.700 VLIM 7 8 DC 0 VLP 91 0 DC 55 VLN 0 92 DC 55 **************************** * OPA627 "E" - ENHANCEMENTS **************************** * OUTPUT SUPPLY MIRROR FQ3 0 20 POLY(1) VLIM 0 1 DQ1 20 21 DX DQ2 22 20 DX VQ1 21 0 0 VQ2 22 0 0 FQ1 3 0 POLY(1) VQ1 4.76E-3 1 FQ2 0 4 POLY(1) VQ2 4.76E-3 -1 * QUIESCIENT CURRENT RQ 3 4 7.5E4 * DIFF INPUT CAPACITANCE CDIF 1 2 8.0E-12 * COMMON MODE INPUT CAPACITANCE C1CM 1 99 7.0E-12 C2CM 2 99 7.0E-12 * INPUT VOLTAGE NOISE VN1 61 0 0.6 VN2 0 62 0.6 DN1 61 63 DY DN2 63 62 DY EN 64 1 63 0 1 * INPUT CURRENT NOISE RN1 0 65 60.3865 RN2 65 66 60.3865 RN3 66 0 120.773 RN4 0 67 60.3865 RN5 67 68 60.3865 RN6 68 0 120.773 ****************** .MODEL DY D(IS=1E-12 AF=1 KF=71.89E-15) .MODEL DX D(IS=800.0E-18) .MODEL JX PJF(IS=500.0E-15 BETA=1.545E-3 VTO=-1) .ENDS OPA627 *$ **************************************** * ****** TL071 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT ********** * * CREATED USING PARTS RELEASE 4.01 ON 06/16/89 AT 13:08 * (REV N/A) SUPPLY VOLTAGE: +/-15V * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT TL07x 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 TL07x *$ * * OPA627E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * "E" IS ENHANCED MODEL * CREATED USING PARTS RELEASE 4.03 ON 10/04/90 AT 09:30 * * REV.B 5/22/91 TK * REV.C 3/21/92 BCB: added input bias current correction and * current and voltage noise * * ------------------------------------------------------------------------ * | NOTICE: THE INFORMATION PROVIDED HEREIN IS BELIEVED TO BE RELIABLE; | * | HOWEVER; BURR-BROWN ASSUMES NO RESPONSIBILITY FOR INACCURACIES OR | * | OMISSIONS. BURR-BROWN ASSUMES NO RESPONSIBILITY FOR THE USE OF THIS | * | INFORMATION, AND ALL USE OF SUCH INFORMATION SHALL BE ENTIRELY AT | * | THE USER'S OWN RISK. NO PATENT RIGHTS OR LICENSES TO ANY OF THE | * | CIRCUITS DESCRIBED HEREIN ARE IMPLIED OR GRANTED TO ANY THIRD PARTY. | * | BURR-BROWN DOES NOT AUTHORIZE OR WARRANT ANY BURR-BROWN PRODUCT FOR | * | USE IN LIFE-SUPPORT DEVICES AND/OR SYSTEMS. | * ------------------------------------------------------------------------ * * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OPA627E-BB 1 2 3 4 5 * C1 11 12 3.182E-12 C2 6 7 23.00E-12 CSS 10 99 40.45E-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 0 419.4E6 -40E6 40E6 40E6 -40E6 GA 6 0 11 12 2.432E-3 GCM 0 6 10 99 3.779E-9 ISS 3 10 DC 1.840E-3 HLIM 90 0 VLIM 1K J1 11 2 10 JX J2 12 64 10 JX G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 1.6E-6 G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 1.6E-6 R2 6 9 100.0E3 RD1 4 11 419.4 RD2 4 12 419.4 RO1 8 5 54 RO2 7 99 1 * RP 3 4 4.286E3 RSS 10 99 108.7E3 VB 9 0 DC 0 VC 3 53 DC 2.700 VE 54 4 DC 2.700 VLIM 7 8 DC 0 VLP 91 0 DC 55 VLN 0 92 DC 55 **************************** * OPA627 "E" - ENHANCEMENTS **************************** * OUTPUT SUPPLY MIRROR FQ3 0 20 POLY(1) VLIM 0 1 DQ1 20 21 DX DQ2 22 20 DX VQ1 21 0 0 VQ2 22 0 0 FQ1 3 0 POLY(1) VQ1 4.76E-3 1 FQ2 0 4 POLY(1) VQ2 4.76E-3 -1 * QUIESCIENT CURRENT RQ 3 4 7.5E4 * DIFF INPUT CAPACITANCE CDIF 1 2 8.0E-12 * COMMON MODE INPUT CAPACITANCE C1CM 1 99 7.0E-12 C2CM 2 99 7.0E-12 * INPUT VOLTAGE NOISE VN1 61 0 0.6 VN2 0 62 0.6 DN1 61 63 DY DN2 63 62 DY EN 64 1 63 0 1 * INPUT CURRENT NOISE RN1 0 65 60.3865 RN2 65 66 60.3865 RN3 66 0 120.773 RN4 0 67 60.3865 RN5 67 68 60.3865 RN6 68 0 120.773 ****************** .MODEL DY D(IS=1E-12 AF=1 KF=71.89E-15) .MODEL DX D(IS=800.0E-18) .MODEL JX PJF(IS=500.0E-15 BETA=1.545E-3 VTO=-1) .ENDS OPA627E-BB *$ * ****** TL071 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT ********** * * CREATED USING PARTS RELEASE 4.01 ON 06/16/89 AT 13:08 * (REV N/A) SUPPLY VOLTAGE: +/-15V * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT TL07x-TEXAS 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 TL07x-TEXAS *$ * ************************* * OP-27G OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * CREATED USING PARTS RELEASE 4.01 ON 06/26/89 AT 12:59 * REV (N/A) * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OP27 1 2 3 4 5 * C1 11 12 2.730E-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 22.86E6 -20E6 20E6 20E6 -20E6 GA 6 0 11 12 852.1E-6 GCM 0 6 10 99 754.1E-12 IEE 10 4 DC 42.03E-6 HLIM 90 0 VLIM 1K Q1 11 2 13 QX Q2 12 1 14 QX R2 6 9 100.0E3 RC1 3 11 1.326E3 RC2 3 12 1.326E3 RE1 13 10 94.44 RE2 14 10 94.44 REE 10 99 4.759E6 RO1 8 5 88 RO2 7 99 87 RP 3 4 10.14E3 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 40 VLN 0 92 DC 40 .MODEL DX D(IS=800.0E-18) .MODEL QX NPN(IS=800.0E-18 BF=1.400E3) .ENDS OP27 *$ ************************* * OP-27G OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * CREATED USING PARTS RELEASE 4.01 ON 06/26/89 AT 12:59 * REV (N/A) * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OP27-AD 1 2 3 4 5 * C1 11 12 2.730E-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 22.86E6 -20E6 20E6 20E6 -20E6 GA 6 0 11 12 852.1E-6 GCM 0 6 10 99 754.1E-12 IEE 10 4 DC 42.03E-6 HLIM 90 0 VLIM 1K Q1 11 2 13 QX Q2 12 1 14 QX R2 6 9 100.0E3 RC1 3 11 1.326E3 RC2 3 12 1.326E3 RE1 13 10 94.44 RE2 14 10 94.44 REE 10 99 4.759E6 RO1 8 5 88 RO2 7 99 87 RP 3 4 10.14E3 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 40 VLN 0 92 DC 40 .MODEL DX D(IS=800.0E-18) .MODEL QX NPN(IS=800.0E-18 BF=1.400E3) .ENDS OP27-AD *$ * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | open collector output * | | | | | .SUBCKT LM339 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=2.000E3) .model qmi NPN(Is=800.0E-18 Bf=1002) .model qmo NPN(Is=800.0E-18 Bf=1000 Cjc=1E-15 Tr=475.4E-9) e1 10 4 9 4 1 v1 10 11 dc 0 q5 5 11 4 qoc .model qoc NPN(Is=800.0E-18 Bf=20.69E3 Cjc=1E-15 Tf=3.540E-9 Tr=472.8E-9) dp 4 3 dx rp 3 4 37.50E3 .model dx D(Is=800.0E-18 Rs=1) * .ENDS LM339 *$ ********************************** * ADG406 SPICE Macro-model 10/95, Rev. D * WF / ADSC * * Revision History: NONE * * NOTE: This model was setup with typical leakage currents * at +25C for ADG406 * * Copyright 1995 by Analog Devices, Inc. * * Refer to "README.DOC" file for License Statement. Use of this * model indicates your acceptance with the terms and provisions * in the License Statement. * * Node assignments * 19 - S1, 20 - S2, 21 - S3, 22 - S4, 23 - S5, 24 - S6, 25 - S7 * 26 - S8, 11 - S9,10 - S10, 9 - S11, 8 - S12, 7 - S13, 6 - S14 * 5 - S15, 4 - S16, 14 - A3, 15 - A2, 16 - A1, 17 - A0, 18 - EN * 28 - D, 1 - VDD, 12 - GND, 27 - VSS * .SUBCKT ADG406 19 20 21 22 23 24 25 26 11 10 9 8 7 6 5 4 14 15 16 17 18 28 1 12 27 * * DEMUX SWITCHES (S1-16 ---> D) * * First Section is for control line A0 * All nodes in this section are in the 30's unless * they are I/O nodes * E_A0_2 200 12 17 12 1 E_A0_1 30 40 201 40 -1 R_A0_1 200 201 1000 C_A0_X2 201 12 100E-12 V_AX_1 40 12 1.6 S_A0_16 4 31 201 12 Sdemux S_A0_15 5 31 30 12 Sdemux S_A0_14 6 32 201 12 Sdemux S_A0_13 7 32 30 12 Sdemux S_A0_12 8 33 201 12 Sdemux S_A0_11 9 33 30 12 Sdemux S_A0_10 10 34 201 12 Sdemux S_A0_9 11 34 30 12 Sdemux S_A0_8 26 35 201 12 Sdemux S_A0_7 25 35 30 12 Sdemux S_A0_6 24 36 201 12 Sdemux S_A0_5 23 36 30 12 Sdemux S_A0_4 22 37 201 12 Sdemux S_A0_3 21 37 30 12 Sdemux S_A0_2 20 38 201 12 Sdemux S_A0_1 19 38 30 12 Sdemux C_A0_X1 17 12 4E-12 C_A0_D 17 39 4E-12 * Input capacitances C_A0_1 19 12 8E-12 C_A0_2 20 12 8E-12 C_A0_3 21 12 8E-12 C_A0_4 22 12 8E-12 C_A0_5 23 12 8E-12 C_A0_6 24 12 8E-12 C_A0_7 25 12 8E-12 C_A0_8 26 12 8E-12 C_A0_9 11 12 8E-12 C_A0_10 10 12 8E-12 C_A0_11 9 12 8E-12 C_A0_12 8 12 8E-12 C_A0_13 7 12 8E-12 C_A0_14 6 12 8E-12 C_A0_15 5 12 8E-12 C_A0_16 4 12 8E-12 C_D_1 28 12 80E-12 * * Leakage Current (SX and D ON only) * R_ON_S1 19 500 1.5E12 R_ON_S2 20 500 1.5E12 R_ON_S3 21 500 1.5E12 R_ON_S4 22 500 1.5E12 R_ON_S5 23 500 1.5E12 R_ON_S6 24 500 1.5E12 R_ON_S7 25 500 1.5E12 R_ON_S8 26 500 1.5E12 R_ON_S9 11 500 1.5E12 R_ON_S10 10 500 1.5E12 R_ON_S11 9 500 1.5E12 R_ON_S12 8 500 1.5E12 R_ON_S13 7 500 1.5E12 R_ON_S14 6 500 1.5E12 R_ON_S15 5 500 1.5E12 R_ON_S16 4 500 1.5E12 SLEAK_ON_D 28 500 28 500 SLEAK ILEAK_ON_D 28 500 -10E-12 * Leakage Current (SX OFF only) * * Leakage Current (D OFF only) * S_OFF_D 28 58 80 12 Sdemux R_OFF_D 58 12 1E12 G_OFF_D 28 12 58 12 0.75E-12 *C_OFF_D 58 12 0E-12 * * Second Section is for control line A1 * E_A1_2 170 12 16 12 1 E_A1_1 41 40 171 40 -1 R_A1_1 170 171 1000 C_A1_X2 171 12 100E-12 S_A1_1 31 42 171 12 Sdemux S_A1_2 32 42 41 12 Sdemux S_A1_3 33 43 171 12 Sdemux S_A1_4 34 43 41 12 Sdemux S_A1_5 35 44 171 12 Sdemux S_A1_6 36 44 41 12 Sdemux S_A1_7 37 45 171 12 Sdemux S_A1_8 38 45 41 12 Sdemux C_A1_X 16 12 4E-12 C_A1_D 16 39 4E-12 * * Third Section is for control line A2 * E_A2_2 160 12 15 12 1 E_A2_1 46 40 161 40 -1 R_A2_1 160 161 1000 C_A2_X2 161 12 100E-12 S_A2_1 42 47 161 12 Sdemux S_A2_2 43 47 46 12 Sdemux S_A2_3 44 48 161 12 Sdemux S_A2_4 45 48 46 12 Sdemux C_A2_X 15 12 4E-12 C_A2_D 15 39 4E-12 * * Forth Section is for control line A3 * E_A3_2 140 12 14 12 1 E_A3_1 49 40 141 40 -1 R_A3_1 140 141 1000 C_A3_X2 141 12 100E-12 S_A3_1 47 39 141 12 Sdemux S_A3_2 48 39 49 12 Sdemux C_A3_X 14 12 4E-12 C_A3_D 14 39 4E-12 * * Main Series Switch combination * * V_1_A 419 12 15 V_1_B 420 12 -15 V_1_C 421 500 -0.5 ;sets pos main offset V_1_D 422 27 2.5 ;sets neg main offset R_1_C 39 0 1E13 S_1_A 425 39 420 73 SNCM R_1_A 412 425 24 ;sets neg at max d S_1_B 426 39 419 73 SPCM R_1_B 73 426 30 ;sets pos at max d S_1_C 73 412 611 12 SMAINP S_1_D 412 411 12 612 SMAINN E_1_E 611 12 VALUE = {(10*V(73,421))/(0.5*V(1,500)+0.005)} E_1_F 612 12 VALUE = {(10*V(73,500))/(PWR(V(500,422),1)+0.005)} S_1_G 411 39 1 27 SBASE I_XX_1 99 0 0 ;add a 'do-nothing' component I_XX_2 421 0 0 ; at nodes 99, 421 I_XX_3 422 0 0 ; and 422 to keep SPICE happy * * Voltage Clamp * D_1_POS 39 1 DClamp G_1_POS 39 1 39 1 -1E-12 D_2_NEG 27 39 DClamp G_2_NEG 27 39 27 39 1E-12 * Enable Switch section * S_EN_1 73 28 18 12 Sdemux C_EN_1 18 28 4.2E-12 ; SETS CHARGE INJECTION * Invert Enable Switch section E_EN0_1 18 81 80 12 -2 V_EN0_1 82 12 2.5 R_EN0_1 82 81 1 R_EN0_2 80 12 1E12 * * Power Supply Current Correction * I_PS_1 1 12 80E-6 I_PS_2 12 27 0.0001E-6 E_PS_1 99 12 1 12 1 E_PS_2 500 27 1 27 .5 * * Crosstalk * RXT_1 19 52 1E13 RXT_2 20 52 1E13 RXT_3 21 52 1E13 RXT_4 22 52 1E13 RXT_5 23 52 1E13 RXT_6 24 52 1E13 RXT_7 25 52 1E13 RXT_8 26 52 1E13 RXT_9 11 52 1E13 RXT_10 10 52 1E13 RXT_11 9 52 1E13 RXT_12 8 52 1E13 RXT_13 7 52 1E13 RXT_14 6 52 1E13 RXT_15 5 52 1E13 RXT_16 4 52 1E13 CXT_1 19 52 1E-12 CXT_2 20 52 1E-12 CXT_3 21 52 1E-12 CXT_4 22 52 1E-12 CXT_5 23 52 1E-12 CXT_6 24 52 1E-12 CXT_7 25 52 1E-12 CXT_8 26 52 1E-12 CXT_9 11 52 1E-12 CXT_10 10 52 1E-12 CXT_11 9 52 1E-12 CXT_12 8 52 1E-12 CXT_13 7 52 1E-12 CXT_14 6 52 1E-12 CXT_15 5 52 1E-12 CXT_16 4 52 1E-12 * * OFF Isolation * COI_1 19 28 1E-13 COI_2 20 28 1E-13 COI_3 21 28 1E-13 COI_4 22 28 1E-13 COI_5 23 28 1E-13 COI_6 24 28 1E-13 COI_7 25 28 1E-13 COI_8 26 28 1E-13 COI_9 11 28 1E-13 COI_10 10 28 1E-13 COI_11 9 28 1E-13 COI_12 8 28 1E-13 COI_13 7 28 1E-13 COI_14 6 28 1E-13 COI_15 5 28 1E-13 COI_16 4 28 1E-13 ROI_1 19 1901 1.6E9 COI_1A 1901 28 10E-12 ROI_2 20 1902 1.6E9 COI_2A 1902 28 10E-12 ROI_3 21 1903 1.6E9 COI_3A 1903 28 10E-12 ROI_4 22 1904 1.6E9 COI_4A 1904 28 10E-12 ROI_5 23 1905 1.6E9 COI_5A 1905 28 10E-12 ROI_6 24 1906 1.6E9 COI_6A 1906 28 10E-12 ROI_7 25 1907 1.6E9 COI_7A 1907 28 10E-12 ROI_8 26 1908 1.6E9 COI_8A 1908 28 10E-12 ROI_9 11 1909 1.6E9 COI_9A 1909 28 10E-12 ROI_10 10 1910 1.6E9 COI_10A 1910 28 10E-12 ROI_11 9 1911 1.6E9 COI_11A 1911 28 10E-12 ROI_12 8 1912 1.6E9 COI_12A 1912 28 10E-12 ROI_13 7 1913 1.6E9 COI_13A 1913 28 10E-12 ROI_14 6 1914 1.6E9 COI_14A 1914 28 10E-12 ROI_15 5 1915 1.6E9 COI_15A 1915 28 10E-12 ROI_16 4 1916 1.6E9 COI_16A 1916 28 10E-12 * * MODELS USED * .MODEL SNCM VSWITCH (RON=1 ROFF=500001 VON=9 VOFF=-44) .MODEL SPCM VSWITCH (RON=450000 ROFF=1 VON=41 VOFF=-6.5) .MODEL SBASE VSWITCH (RON=11 ROFF=3500 VON=28 VOFF=-10) .MODEL SMAINP VSWITCH (RON=650001 ROFF=19 VON=32 VOFF=0) .MODEL SMAINN VSWITCH (RON=700001 ROFF=7 VON=28.5 VOFF=0) .MODEL Sdemux VSWITCH (RON=1 ROFF=1E12 VON=2.0 VOFF=1.4) .MODEL DClamp D(IS=1E-15 IBV=1E-13) .MODEL SLEAK VSWITCH (RON=750E9 ROFF=150E9 VON=-15 VOFF=15) .ENDS ADG406 *$ * ****************************** * Acquisition d'un signal analogique * par Echantillonnage de celui-ci * a une frequence = fech * (c) LOUTRE Noel mars 1999 * * macro-modele de l'echantillonneur bloqueur * d'ordre Zero * .SUBCKT Echant e Sech PARAMS: fech=352.8k * * Interupteur d'acquisition de e Sechant e s1 c 0 Inter-ech .MODEL Inter-ech VSWITCH (Von=3V Voff=2V Ron=0.1 Roff=10E6) * * signal de commande de l'inter d'acquisition de e Vc c 0 PULSE (0 5 0 {1/(500*fech)} {1/(500*fech)} + {1/(500*fech)} {1/fech}) * * memorisation de la tension acquise dans C1 * R1 elimine parasite transitoire lors de la simulation * 5*R1*C1 < a la fenetre d'acquisition (pw) R1 s1 s2 {1/(5E-6*fech)} C1 s2 0 1nF * * etage tampon de sortie Gain=1 Eunite Sech 0 VALUE={V(s2)} R2 Sech 0 1k .ENDS echant *$ * ***************************** * * Standard Linear ICs Macromodels, 1993 * Timer * 1 NEGATIVE POWER SUPPLY * 2 TRIGGER * 3 OUTPUT * 4 RESET * 5 CONTROL VOLTAGE * 6 THRESHOLD * 7 DISCHARGE * 8 POSITIVE POWER SUPPLY * 9 ADJUST & INITIALIZATION *10 ADJUST * .SUBCKT ICM7555 1 2 3 4 5 6 7 8 9 10 * data sheet SGS THOMSON / STMicroelectronics TS555 .MODEL MPJR PMOS VTO=0.0 TOX=3000E-09 KP=2.0E-02 LEVEL=3 .MODEL MNJR NMOS VTO=0.0 TOX=3000E-09 KP=2.0E-02 LEVEL=3 .MODEL MNDIS NMOS VTO=1.0 TOX=80E-09 KP=2.0E-02 LEVEL=3 .MODEL MDTH D N=0.7 IS=1E-08 * RAA 8 5 1E+5 RBB 5 27 1E+5 RCC 27 1 1E+5 IALIM 8 1 94E-06 EALIM 24 1 8 1 1 * COMPA 1 * E1H 24 41 24 4 1 D1H 32 41 MDTH D1B 1 32 MDTH I1 6 1 10P G1 1 32 5 6 6E-07 * COMPA 2 * E2H 24 42 24 4 1 D2H 22 42 MDTH D2B 1 22 MDTH I2 2 1 10P G2 1 22 27 2 6E-07 * R S * MPH 31 32 24 24 MPJR W=50U L=6U MNB 31 22 1 1 MNJR W=100U L=6U MP1 9 31 24 24 MPJR W=42U L=6U MN1 9 31 1 1 MNJR W=26U L=6U MP2 31 9 24 24 MPJR W=10U L=37U MN2 31 9 1 1 MNJR W=9U L=40U * RESET * RRST 4 1 1E+12 * OUTPUT STAGE * EOUT 15 1 9 1 1 ROUT 15 3 100 RCHOUT 3 1 1E+12 EMI 10 1 24 1 0.5 EGRILLE 11 1 24 9 1 MDIS 13 11 1 1 MNDIS W=4500U L=6U RDIS 13 7 20 RCHDIS 7 1 1E+12 .ENDS ICM7555 *$ * ********************************** * * Librairie des modeles utilises pour l'ampli Medium a tube * kit VERDIER modele 210 * --------------------------------------------------------- * .SUBCKT ECC83 A G K H1 H2 TRIODE * .SUBCKT ECC81 A G K H1 H2 TRIODE * .SUBCKT EL84 A S G K * .SUBCKT Transfo_EL84 1 2 3 4 5 6 * .SUBCKT Transfo_220 1 2 3 4 5 6 7 * ********************************************************************** * Duncan Amplfication Generic Triode Model (PSpice Implementation) * Copyright (C)1997-1998 Duncan Amplfication * Unauthorised Commercial use prohibited * Please refer to documentation at http://www.duncanamps.simplenet.com * * $MODEL_VERSION$ 3.1 * $AUTOGENERATED$ 15/08/98 11:35:13 ********************************************************************** * CURRENT MODEL SET AND VERSIONS: * * 12AT7 / ECC81 [3.0, 30/12/97 ] * 12AX7 / ECC83 [3.0, 30/12/97 ] ********************************************************************** * CORE MODEL VERSION HISTORY: * * 1.0 23/09/97 Initial model * 1.1 19/11/97 Model altered for 1 gig resistors between each node and ground * 2.0 18/12/97 Two new parameters, ERP and ERI added * 3.0 30/12/97 New parameter added, RAS * 3.1 05/01/98 ERI parameter removed * 3.2 06/01/98 Fix errors in Pspice model * 3.3 13/01/98 Fixed errors with CDO parameter * 3.4 25/01/98 Errors with heater versions using ERI fixed ********************************************************************** .SUBCKT TRIODE A G K H1 H2 +PARAMS: RCO=1.6 RHO=10.5 HTV=6.3 HWU=10.5 + LIP=1 LIF=3.7E-3 RAF=18E-3 RAS=1 CDO=0 RAP=4E-3 + ERP=1.5 + MU0=17.3 MUR=19E-3 EMC=9.6E-6 GCO=0 GCF=213E-6 + CGA=3.9p CGK=2.4p CAK=0.7p ************************************************************************ * * Heater model * * Can be operated from AC or DC power sources. * NB: When operating from DC power sources, "Skip initial transient * solution" must be checked, to make use of this model. * * PARAMETERS * * RCO Heater resistance cold (ohms) * RHO Heater resistance hot (ohms) * HTV Normal heater voltage (V) * HWU Heater time to warm up to 90% of emission (seconds) * ************************************************************************ Rcool H1 HA {RCO} Rload HA HB 1M Esens HD 0 VALUE={V(HA,HB)*1000} Epwr HE 0 VALUE={V(H1,H2)*V(HD)/(PWR({HTV},2)/{RHO})} RH1 HE HF 91k CH1 HF 0 {HWU/1E6} EH2 HG 0 VALUE={V(HF)} RH2 HG HH 270k CH2 HH 0 {HWU/1E6} EH3 HJ 0 VALUE={LIMIT{V(HH)-0.75,0,1E6}*4} RH3 HJ HK 91k CH3 HK 0 {HWU/1E6} Ghot HB H2 VALUE={(1/(V(HG)+0.001))/({RHO}-{RCO})*V(HB,H2)} ************************************************************************ * * Anode/grid model * * Models reduction in mu at large negative grid voltages * Models change in Ra with negative grid voltages * Models limit in Ia with high +Vg and low Va * * PARAMETERS * * LIP Conduction limit exponent * LIF Conduction limit factor * CDO Conduction offset * RAF Anode resistance factor for neg grid voltages * RAP Anode resistance factor for positive grid voltages * ERP Emission power * MU0 Mu between grid and anode at Vg=0 * MUR Mu reduction factor for large negative grid voltages * EMC Emission coefficient * GCO Grid current offset in volts * GCF Grid current scale factor * ************************************************************************ Elim LI 0 VALUE={PWR(LIMIT{V(A,K),0,1E6},{LIP})*{LIF}} Egg GG 0 VALUE={V(G,K)-{CDO}} Erpf RP 0 VALUE={1-PWR(LIMIT{-V(GG)*{RAF},0,0.999},{RAS})+LIMIT{V(GG),0,1E6}*{RAP}} Egr GR 0 VALUE={LIMIT{V(GG),0,1E6}+LIMIT{(V(GG))*(1+V(GG)*{MUR}),0,-1E6}} Eem EM 0 VALUE={LIMIT{V(A,K)+V(GR)*{MU0},0,1E6}} Eep EP 0 VALUE={PWR(V(EM),ERP)*{EMC}*V(RP)} Eel EL 0 VALUE={LIMIT{V(EP),0,V(LI)}} Eld LD 0 VALUE={LIMIT{V(EP)-V(LI),0,1E6}} Ga A K VALUE={V(HK)*V(EL)} ************************************************************************ * * Grid current model * * Models grid current, along with rise in grid current at low Va * ************************************************************************ Egf GF 0 VALUE={PWR(LIMIT{V(G,K)-{GCO},0,1E6},1.5)*{GCF}} Gg G K VALUE={(V(GF)+V(LD))*V(HK)} * * Capacitances and anti-float resistors * CM1 G K {CGK} CM2 A G {CGA} CM3 A K {CAK} RF1 A 0 1000MEG RF2 G 0 1000MEG RF3 K 0 1000MEG * .ENDS TRIODE *$ * * ********************************************************************** * GENERIC: 12AT7 / ECC81 * MODEL: 12AT7 * NOTES: Heater model for one half of heater (6.3V) ********************************************************************** .SUBCKT ECC81 A G K H1 H2 XV1 A G K H1 H2 TRIODE +PARAMS: RCO= 6.2 RHO= 42 HTV= 6.3 HWU= 10.5 + LIP= 1 LIF= 0.0037 RAF= 0.09869 RAS= 1 CDO=-0.5 + RAP= 0.1 ERP= 1.4 + MU0= 45.093 MUR= 0.012937 EMC= 0.00000863 + GCO=-0.5 GCF= 0.00012 + CGA=1.60E-12 CGK=2.30E-12 CAK=4.00E-13 .ENDS ECC81 *$ * * ********************************************************************** * GENERIC: 12AX7 / ECC83 * MODEL: 12AX7 * NOTES: Heater model for one half of heater (6.3V) ********************************************************************** .SUBCKT ECC83 A G K H1 H2 XV1 A G K H1 H2 TRIODE +PARAMS: RCO= 6.2 RHO= 42 HTV= 6.3 HWU= 10.5 + LIP= 1.5 LIF= 0.000016 RAF= 0.076498 RAS= 1 CDO=-0.53056 + RAP= 0.18 ERP= 1.5 + MU0= 87.302 MUR=-0.013621 EMC= 0.00000111 + GCO=-0.2 GCF= 0.00001 + CGA=3.90E-12 CGK=2.40E-12 CAK=7.00E-13 .ENDS ECC83 *$ * * ************************************************ * Filename: 6bq5.inc 12/10/97 V3 * Simulator: PSpice * Device type: Power pentode * Device model: 6BQ5/EL84 * * Author: Duncan Munro * Date: 12/5/97 * Copyright: (C)1997 DDS * * * V3 [12/10/97]: Screen current limited to prevent screen current * draw at Vs = 0. * * The following parameters are not modelled: * * (1) Heater * (2) Grid current is an approximation * * Please note that this model is provided "as is" and * no warranty is provided in respect of its suitability * for any application. * * This model is provided for educational and non-profit use. * * Email queries to duncan@muffy.demon.co.uk * * Pins A Anode * S Screen * G Grid * K Cathode * * .SUBCKT EL84 A S G K * * Calculate contribution to cathode current * Eat at 0 VALUE={0.636*ATAN(V(A,K)/15)} Egs gs 0 VALUE={LIMIT{V(S,K)/19+V(G,K)+V(A,K)/1400,0,1E6}} Egs2 gs2 0 VALUE={PWRS(V(gs),1.5)} Ecath cc 0 VALUE={V(gs2)*V(at)} * * Calculate anode current * Ga A K VALUE={3.2E-3*V(cc)} * * Calculate screen current * Escrn sc 0 VALUE={V(gs2)*(1.1-V(at))} Gs S K VALUE={2.0E-3*V(sc)*LIMIT{V(S,K),0,10}/10} * * Grid current (approximation - does not model low va/vs) * Gg G K VALUE={PWR(LIMIT{V(G,K)+1,0,1E6},1.5)*50E-6} * * Capacitances * Cg1 G K 10.8p Cak A K 6.5p Cg1a G A 0.5p * .ENDS EL84 *$ * ******************************************************* * Transformateur d'alimentation secteur 220V * * Subcircuit for Parmeko mains transformer model 6000/71 * * Primary 230/240V AC * * Secondary 318V AC @ 300mA DC * 6.3V AC @ 5A * * D.Munro - 10/4/97 * * 10/04/97 Initial model * * 02/05/97 Model changed to take out leaked inductance/capacitance etc. * Also "leak" resistors put in to stop error messages when windings * were left unconnected. * * * Pin 1 Mains neutral * 2 Mains 230V tap * 3 Mains 240V tap * * 4,5 318V AC * 6,7 6.3V AC * * || .--- [4] * [1] Neutre--. || ( * ) || ( 318V * ) || ( * ) || .--- [5] * [2] 230V----. || ( * ) || .--- [6] * ) || ( * ) || ( 6,3V * [3] 240V----. || ( * || .--- [7] * .SUBCKT Transfo_220 1 2 3 4 5 6 7 * * Primary * Rpri1 1 10 5.7 Lpri1 10 2 5.1H Rpri2 2 11 0.5 Lpri2 11 3 10mH Rleak1 0 1 1000MEG Rleak2 0 2 1000MEG Rleak3 0 3 1000MEG * * HV Secondary * Rsec1 4 20 18 Lsec1 20 21 4.8H Rsec2 21 22 7.5 Lsec2 22 5 1.17H Rleak4 0 4 1000MEG Rleak5 0 5 1000MEG * * Heater secondary * Rsec3 6 30 0.025 Lsec3 30 31 1.09mH Rsec4 31 32 0.025 Lsec4 32 7 1.09mH Rleak6 0 6 1000MEG Rleak7 0 7 1000MEG * * Coupling * K1 Lpri1 Lpri2 Lsec1 Lsec2 Lsec3 Lsec4 0.997 * .ENDS Transfo_220 *$ * **************************************************************** * * Trace Elliot 15W output transformer, 8k primary, 16/8 ohm sec. * Part no. 73 TRAN 15W OP * * [1] Red ---. || * ) || .--- Green (16 ohm) [4] * ) || ( * ) || ( * [2] White ---. || .--- Yellow (8 ohm) [5] * ) || ( * ) || ( * ) || .--- Brown [6] * [3] Blue ---. || * .SUBCKT Transfo_EL84 1 2 3 4 5 6 * * Primary * Lleak1 1 20 2mH Lpri1 20 21 150H Rpri1 21 2 186 Cpri1 1 2 120p Lleak2 2 22 2mH Lpri2 22 23 150H Rpri2 23 3 201 Cpri2 2 3 120p * * Secondary * Lleak3 5 24 10uH Lsec1 24 25 0.6H Rsec1 25 6 0.8 Lleak4 4 27 10uH Lsec2 27 28 0.3H Rsec2 28 5 0.4 * Kcoup Lpri1 LPri2 Lsec1 Lsec2 1.0 * .ENDS Transfo_EL84 *$ * * -------------------------------- * fin de la librairie Ampli a TUBE * -------------------------------- * .SUBCKT 4011B 3 5 8 9 *Connections e1 e2 s Vcc M2 1 3 0 0 CD4011BN M15 6 5 9 9 CD4011BP M5 6 5 0 0 CD4011BN M16 8 11 9 9 CD4011BP M7 8 11 0 0 CD4011BN M17 11 6 4 9 CD4011BP M9 11 6 0 0 CD4011BN M14 1 3 9 9 CD4011BP M12 11 1 0 0 CD4011BN M13 4 1 9 9 CD4011BP * .MODEL CD4011BN NMOS (LEVEL=1 VTO=3.5 KP=2.9M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) .MODEL CD4011BP PMOS (LEVEL=1 VTO=-3.0 KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 + CBD=15.9P CBS=19P CGSO=23.4N CGDO=19.5N CGBO=32.1N) .ENDS 4011B *$ * ************************ .MODEL NMOS_4xxx NMOS (LEVEL=1 VTO=3.5 KP=2.9M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) *$ .MODEL PMOS_4xxx PMOS (LEVEL=1 VTO=-3.0 KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 + CBD=15.9P CBS=19P CGSO=23.4N CGDO=19.5N CGBO=32.1N) * ********************************* * * (c) Loutre Noel mai 2001 * *$ .SUBCKT 4023B e1 e2 e3 s Vcc * * S = /e1 + /e2 + /e3 * M_M5 Vcc e3 3 Vcc PMOS_4xxx M_M10 6 1 0 0 NMOS_4xxx M_M11 6 2 0 0 NMOS_4xxx M_M12 6 3 0 0 NMOS_4xxx M_M7 Vcc 1 4 Vcc PMOS_4xxx M_M9 5 3 6 Vcc PMOS_4xxx M_M8 4 2 5 Vcc PMOS_4xxx M_M13 s 6 0 0 NMOS_4xxx M_M14 Vcc 6 s Vcc PMOS_4xxx M_M3 Vcc e2 2 Vcc PMOS_4xxx M_M1 Vcc e1 1 Vcc PMOS_4xxx M_M2 1 e1 0 0 NMOS_4xxx M_M4 2 e2 0 0 NMOS_4xxx M_M6 3 e3 0 0 NMOS_4xxx * .MODEL NMOS_4xxx NMOS (LEVEL=1 VTO=3.5 KP=2.9M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) .MODEL PMOS_4xxx PMOS (LEVEL=1 VTO=-3.0 KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 + CBD=15.9P CBS=19P CGSO=23.4N CGDO=19.5N CGBO=32.1N) .ENDS 4023B *$ * ******************************* * * (c) Loutre Noel mai 2001 * .SUBCKT 4012B e1 e2 e3 e4 s Vcc * * S = /e1 + /e2 + /e3 /e4 * M_M7 Vcc 1 5 Vcc PMOS_4xxx M_M8 5 2 6 Vcc PMOS_4xxx M_M2 1 e1 0 0 NMOS_4xxx M_M1 Vcc e1 1 Vcc PMOS_4xxx M_M3 Vcc e2 2 Vcc PMOS_4xxx M_M4 2 e2 0 0 NMOS_4xxx M_M9 6 3 7 Vcc PMOS_4xxx M_M6 3 e3 0 0 NMOS_4xxx M_M5 Vcc e3 3 Vcc PMOS_4xxx M_M17 4 e4 0 0 NMOS_4xxx M_M18 Vcc e4 4 Vcc PMOS_4xxx M_M11 8 2 0 0 NMOS_4xxx M_M10 8 1 0 0 NMOS_4xxx M_M13 s 8 0 0 NMOS_4xxx M_M14 Vcc 8 s Vcc PMOS_4xxx M_M16 7 4 8 Vcc PMOS_4xxx M_M12 8 3 0 0 NMOS_4xxx M_M15 8 4 0 0 NMOS_4xxx .ENDS 4012B *$ * ***************** * * .SUBCKT 4001B 6 4 9 5 *Connections e1 e2 s Vcc *CMOS Nor Gate 2 input * M11 1 6 5 5 CD4001BP M3 2 4 0 0 CD4001BN M12 2 4 5 5 CD4001BP M5 3 1 8 8 CD4001BN M13 3 2 5 5 CD4001BP M7 9 3 0 0 CD4001BN M14 9 3 5 5 CD4001BP M15 3 1 5 5 CD4001BP M10 8 2 0 0 CD4001BN M1 1 6 0 0 CD4001BN .MODEL CD4001BN NMOS (LEVEL=1 VTO=3.5 KP=2.9M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) .MODEL CD4001BP PMOS (LEVEL=1 VTO=-3.0 KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) .ENDS 4001B *$ * *********************** * .SUBCKT 4016B 1 2 3 4 * Specifications from SGS and Harris data books * 1 ANALOG INPUT * 2 ANALOG OUTPUT * 3 CONTROL * 4 Vcc (POSITIVE SUPPLY) * 0 GND (NEGATIVE SUPPLY) * RINP 3 11 1500 D1 11 4 D1 D2 5 11 D1 * M1 12 11 4 4 MP4016A L=8U W=48U AD=500P AS=500P PD=110U PS=110U M2 12 11 0 0 MN4016A L=8U W=16U AD=160P AS=160P PD=48U PS=48U * M1A 13 12 4 4 MP4016A L=8U W=96U AD=500P AS=500P PD=110U PS=110U M2A 13 12 0 0 MN4016A L=8U W=32U AD=160P AS=160P PD=48U PS=48U * M3 1 12 2 4 MP4016A L=8U W=360U AD=3600P AS=3600P PD=900U PS=900U M4 2 13 1 0 MN4016A L=8U W=120U AD=1080P AS=1080P PD=286U PS=286U * .MODEL MN4016A NMOS LEVEL=2 VTO=1.45 TOX=1000E-10 NSUB=4.7E16 +XJ=3U LD=2U UO=625 UCRIT=1E5 UEXP=0.45 UTRA=0.25 RSH=15 +NEFF=2.5 VMAX=1E6 CGBO=3E-10 CGDO=10E-10 CGSO=10E-10 CJSW=2F +NFS=4E12 GAMMA=2.2 LAMBDA=0.02 * .MODEL MP4016A PMOS LEVEL=2 VTO=-1.5 TOX=1000E-10 NSUB=7.6E15 +XJ=3U LD=1.5U UO=225 UCRIT=3E5 UEXP=.5 UTRA=0.25 RSH=15 +NEFF=2.5 VMAX=1E5 CGBO=3E-10 CGDO=10E-10 CGSO=10E-10 CJSW=1F +NFS=1E12 GAMMA=1.8 LAMBDA=0.02 * .MODEL D1 D IS=923.17E-18 RS=10 CJO=1.0000E-12 M=.3333 VJ=.75 + ISR=100.00E-12 BV=35.357 IBV=10U TT=5.0000E-9 .ENDS 4016B *$ * ************************************************* .SUBCKT 4050B 1 2 3 *Hex Buffer e s Vcc M1 4 1 3 3 CD4069BP M2 4 1 0 0 CD4069BN M3 2 4 3 3 CD4069BP M4 2 4 0 0 CD4069BN .MODEL CD4069BN NMOS (LEVEL=1 VTO=2.1 KP=2.9M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=47.6P CBS=57.2P CGSO=70.2N CGDO=58.5N CGBO=96.3N) .MODEL CD4069BP PMOS (LEVEL=1 VTO=-2.9 KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 + CBD=47.6P CBS=57.2P CGSO=70.2N CGDO=58.5N CGBO=96.3N) ***** .MODEL CD4049P PMOS (LEVEL=1 VTO=-2.9 KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=45.2 IS=31.2F PB=.8 MJ=.46 + CBD=148P CBS=177P CGSO=218N CGDO=182N CGBO=299N) .MODEL CD4049N NMOS (LEVEL=1 VTO=2.1 KP=5M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=4.2 RS=4.2 IS=31.2F PB=.8 MJ=.46 + CBD=105P CBS=127P CGSO=156N CGDO=130N CGBO=214N) .ENDS 4050B *$ ********* .SUBCKT 4069UB 6 1 4 *Connections e s Vcc M2 1 6 0 0 CD4069BN M3 1 6 4 4 CD4069BP .MODEL CD4069BN NMOS (LEVEL=1 VTO=2.1 KP=2.9M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=47.6P CBS=57.2P CGSO=70.2N CGDO=58.5N CGBO=96.3N) .MODEL CD4069BP PMOS (LEVEL=1 VTO=-2.9 KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 + CBD=47.6P CBS=57.2P CGSO=70.2N CGDO=58.5N CGBO=96.3N) .ENDS 4069UB *$ * ************* .SUBCKT 4049UB 1 2 3 *Hex Buffer e s Vcc M1 2 1 3 3 CD4049P M2 2 1 0 0 CD4049N .MODEL CD4049P PMOS (LEVEL=1 VTO={VTO_PMOS} KP=2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=45.2 IS=31.2F PB=.8 MJ=.46 + CBD=148P CBS=177P CGSO=218N CGDO=182N CGBO=299N) .MODEL CD4049N NMOS (LEVEL=1 VTO={VTO_NMOS} KP=5M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=4.2 RS=4.2 IS=31.2F PB=.8 MJ=.46 + CBD=105P CBS=127P CGSO=156N CGDO=130N CGBO=214N) .ENDS 4049UB *$ * ************************************* .SUBCKT 4069B e s Vcc * X1 1 s Vcc 4050B X2 e 1 Vcc 4069UB * .ENDS 4069B *$ * * * .SUBCKT 4093B 3 2 13 9 *Connections e1 e2 S Vcc X1 15 1 9 0 INV4093 X2 1 17 9 0 INV4093 X3 1 13 9 0 INV4093 M12 7 11 0 0 CD4093N L=.6U W=2U M13 15 12 7 0 CD4093N L=.6U W=2U M16 5 11 17 0 CD4093N L=.4U W=.7U M17 15 12 5 0 CD4093N L=.4U W=.7U M18 15 11 9 9 CD4093P L=.4U W=.8U M19 15 12 9 9 CD4093P L=.4U W=.8U M20 15 12 17 9 CD4093P L=1.4U W=1.4U M21 15 11 17 9 CD4093P L=1.4U W=1.4U R1 3 12 .1 R2 2 11 .1 .MODEL CD4093N NMOS (LEVEL=1 VTO=2.1 KP=3M GAMMA=3.97U + PHI=.75 LAMBDA=1.97M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=15.9P CBS=19P CGSO=23.4N CGDO=19.5N CGBO=32.1N) .MODEL CD4093P PMOS (LEVEL=1 VTO=-1.9 KP=2.2M GAMMA=3.97U + PHI=.75 LAMBDA=1.97M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 + CBD=15.9P CBS=19P CGSO=23.4N CGDO=19.5N CGBO=32.1N) * .ENDS 4093B *$ * .SUBCKT INV4093 6 1 4 0 *Connections e S Vcc GND M2 1 6 0 0 CD469BN M3 1 6 4 4 CD469BP .MODEL CD469BN NMOS (LEVEL=1 VTO=2.1 KP=3M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 * CBD=15.9P CBS=19P CGSO=23.4N CGDO=19.5N CGBO=32.1N) + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) .MODEL CD469BP PMOS (LEVEL=1 VTO=-1.9 KP=2.2M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=28.2 RS=145.2 IS=31.2F PB=.8 MJ=.46 * CBD=15.9P CBS=19P CGSO=23.4N CGDO=19.5N CGBO=32.1N) + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) .ENDS INV4093 *$ * *************** * .MODEL NMOS_vco_in NMOS (LEVEL=1 VTO=1.5 KP=2.9M GAMMA=3.97U + PHI=.75 LAMBDA=1.87M RD=20.2 RS=184.1 IS=31.2F PB=.8 MJ=.46 + CBD=21.2P CBS=25.4P CGSO=31.2N CGDO=26N CGBO=42.8N) * ****************************** *** N-Channel 160V 7a *$ .MODEL 2SK1058-MICROCAP NMOS (VTO=-767.135M KP=20U L=2U W=20.8177M GAMMA=0 PHI=600M + LAMBDA=862.511U CBD=915.478P IS=10F CGSO=1.65276N CGDO=1.65276N TOX=0 NSUB=0 + TPG=1 UO=600 RG=10 RDS=1MEG GDSNOI=0 + T_ABS={temp_abs}) *$ .subckt TIP142-B2SPICE 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * tip142 n darlington * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on jul 29, 97 * darlington macro model * external node designations * node 1 -> collect * node 2 -> base * node 3 -> emitter q1 1 2 4 qmodel q2 1 4 3 q1model 10.3581 d1 3 1 dmodel r1 2 4 10000 r2 4 3 1000 * default values used in dmodel * eg=1.11 tt=0 bv=infinite .model dmodel d is=1e-12 rs=0 n=0.880238 xti=2.88024 cjo=0 vj=0.75 m=0.33 fc=0.5 + T_ABS={temp_abs} .model qmodel npn is=1e-17 bf=197.5 nf=1.08793 vaf=30 ikf=0.472185 ise=9.13306e-10 + ne=2.93252 br=1.52768 nr=1.25371 var=10.5731 ikr=0.0973502 isc=1.15204e-16 nc=1 + rb=15.2272 irb=0.1 rbm=15.2272 re=0.000100054 rc=3.88667 xtb=0 xti=4 eg=1.206 cje=1e-11 + vje=0.75 mje=0.33 tf=1e-09 xtf=1 vtf=10 itf=0.01 cjc=1e-11 vjc=0.75 mjc=0.33 xcjc=0.9 fc=0.5 + tr=1e-07 ptf=0 kf=0 af=1 + T_ABS={temp_abs} .model q1model npn is=1e-17 bf=197.5 nf=1.08793 vaf=30 ikf=0.472185 ise=9.13306e-10 + ne=2.93252 br=1.52768 nr=1.25371 var=10.5731 ikr=0.0973502 isc=1.15204e-16 nc=1 + rb=15.2272 irb=0.1 rbm=15.2272 re=0.000100054 rc=3.88667 xtb=0 xti=4 eg=1.206 + cje=1e-11 vje=0.75 mje=0.33 tf=1e-09 xtf=1 vtf=10 itf=0.01 cjc=0 vjc=0.75 mjc=0.33 + xcjc=0.9 fc=0.5 tr=1e-07 ptf=0 kf=0 af=1 + T_ABS={temp_abs} .ends tip142-B2SPICE *$ ************************************************* * Intusoft ICAP *SRC=TIP142;TIP142;BJTs NPN;Darlington;100V 10A *SYM=DARBJTN .SUBCKT TIP142-ICAP 1 2 3 * TERMINALS: C B E * 100 Volt 10 Amp NPN Darlington Transistor 08-04-1995 Q1 1 2 4 QPWR .1 Q2 1 4 3 QPWR R1 2 4 8K R2 4 3 40 D1 3 1 DSUB * VAF=180 d'origine .MODEL QPWR NPN (IS=12P NF=1 BF=150 VAF=180 IKF=4.64 ISE=494P NE=2 + BR=4 NR=1 VAR=20 IKR=12 RE=40m RB=.16 RC=16M XTB=1.5 T_ABS={temp_abs} + CJE=1.34N VJE=.74 MJE=.45 CJC=193P VJC=1.1 MJC=.24 TF=110N TR=4.75U) * BV=100 d'origine .MODEL DSUB D (IS=12P N=1 RS=.115 BV=100 IBV=.001 CJO=193P TT=4.75U T_ABS={temp_abs} ) .ENDS TIP142-ICAP *$ * TIP142, MOTOROLA BIPOLAR POWER TRANSISITOR DATA BOOK, 1992. ********************************* * Motorola 100 Volt 10 Amp Darlington Transistor 07/20/98 * * connections: Collector * | Base * | | Emitter * | | | .SUBCKT TIP142-PSPICE 1 2 3 * Q1 1 2 4 Q1model Q2 1 4 3 Q2model .6286 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 40 .MODEL Dmodel D + T_ABS={temp_abs} + IS=4.3887E-12 + N=3.4748 + RS=1.0000E-3 + CJO=1.0000E-12 + M=.3333 + VJ=.75 + ISR=100.00E-12 + BV=120 + IBV=1.00E-6 + TT=5.0000E-9 .MODEL Q1model NPN + T_ABS={temp_abs} + IS=1.605E-12 BF=745.1 NF=1 VAF=100 + IKF=.3592 ISE=3.554E-9 NE=1.998 BR=.1018 + NR=1 VAR=100 IKR=2.814 ISC=3.257E-12 + NC=2.370 RB=0.159612 NK=.4489 + RE=0 RC=0.106336 EG=1.110 + CJE=2.000E-12 VJE=.75 MJE=.33 TF=23.00E-9 + XTF=1 VTF=10 ITF=10.00E-3 CJC=2.000E-12 + VJC=.75 MJC=.33 XCJC=.9 FC=.5 + TR=1.50E-6 .MODEL Q2model NPN + T_ABS={temp_abs} + IS=1.605E-12 BF=745.1 NF=1 VAF=100 + IKF=.3592 ISE=3.554E-9 NE=1.998 BR=.1018 + NR=1 VAR=100 IKR=2.814 ISC=3.257E-12 + NC=2.370 RB=0.159612 NK=.4489 + RE=0 RC=0.106336 EG=1.110 + CJE=2.000E-12 VJE=.75 MJE=.33 TF=23.00E-9 + XTF=1 VTF=10 ITF=10.00E-3 CJC=0 + VJC=.75 MJC=.33 XCJC=.9 FC=.5 + TR=1.50E-6 .ENDS TIP142-PSPICE *$ *************************************** .SUBCKT TIP142-MICROCAP 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS={temp_abs} + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS={temp_abs} + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS={temp_abs} + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-MICROCAP *$ * +++++++++++++++++++++++++++ .subckt IRF540-B2SPICE 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.56362 lambda=0.00291031 + kp=25.0081 cgso=1.60584e-05 cgdo=4.25919e-07 + T_ABS={temp_abs} rs 8 3 0.0317085 d1 3 1 md .model md d is=1.02194e-10 rs=0.00968022 n=1.21527 bv=100 ibv=0.00025 + eg=1.2 xti=3.03885 tt=0.0001 cjo=1.81859e-09 vj=1.1279 m=0.449161 fc=0.5 + T_ABS={temp_abs} rds 3 1 4e+06 rd 9 1 0.0135649 rg 2 7 5.11362 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=2.49697e-09 vj=0.5 m=0.9 fc=1e-08 + T_ABS={temp_abs} d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.4 rs=3e-06 + T_ABS={temp_abs} rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 2.49697e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.4 + T_ABS={temp_abs} .ends IRF540-B2SPICE *$ ****************************** .subckt IRF540n-B2SPICE 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.55958 lambda=0.000888191 + kp=28.379 cgso=1.23576e-05 cgdo=1.77276e-08 + T_ABS={temp_abs} rs 8 3 0.0251193 d1 3 1 md .model md d is=1.13149e-09 rs=0.0078863 n=1.32265 bv=100 ibv=0.00025 + eg=1.17475 xti=3.00167 tt=0 cjo=7.95433e-10 vj=0.5 m=0.374991 fc=0.5 + T_ABS={temp_abs} rds 3 1 4e+06 rd 9 1 0.00623556 rg 2 7 4.10175 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=1.75616e-09 vj=0.513551 m=0.614054 fc=1e-08 + T_ABS={temp_abs} d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.40002 rs=3e-06 + T_ABS={temp_abs} rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 3.86673e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.40002 .ends IRF540N-B2SPICE *$ ********************** .subckt IRF540NS-B2SPICE 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.55958 lambda=0.000888191 + kp=28.379 cgso=1.23576e-05 cgdo=1.77276e-08 + T_ABS={temp_abs} rs 8 3 0.0251193 d1 3 1 md .model md d is=1.13149e-09 rs=0.0078863 n=1.32265 bv=100 ibv=0.00025 + eg=1.17475 xti=3.00167 tt=0 cjo=7.95433e-10 vj=0.5 m=0.374991 fc=0.5 + T_ABS={temp_abs} rds 3 1 4e+06 rd 9 1 0.00623556 rg 2 7 4.10175 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=1.75616e-09 vj=0.513551 m=0.614054 fc=1e-08 + T_ABS={temp_abs} d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.40002 rs=3e-06 + T_ABS={temp_abs} rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 3.86673e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.40002 + T_ABS={temp_abs} .ends IRF540NS-B2SPICE *$ ***************************************** .model IRF540-PSPICE NMOS(Level=3 Gamma=0 Delta=0 Eta=0 Theta=0 Kappa=0.2 Vmax=0 Xj=0 + Tox=100n Uo=600 Phi=.6 Rs=21.34m Kp=20.71u W=.94 L=2u Vto=3.136 + Rd=22.52m Rds=444.4K Cbd=2.408n Pb=.8 Mj=.5 Fc=.5 Cgso=1.153n + Cgdo=445.7p Rg=5.557 Is=2.859p N=1 Tt=142n + T_ABS={temp_abs}) * Int'l Rectifier pid=IRFC140 case=TO220 * 88-08-25 bam creation **************************************************** *SRC=IRF540M;IRF540M;MOSFETs N;Power <=100V;100V 28A .077ohm IR *SYM=POWMOSN *$ .SUBCKT IRF540N-ICAP 1 2 3 * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + VTO=3.56362 LAMBDA=0.00291031 KP=25.0081 + CGSO=1.60584e-05 CGDO=4.25919e-07 + T_ABS={temp_abs} RS 8 3 0.0317085 D1 3 1 MD .MODEL MD D IS=1.02194e-10 RS=0.00968022 N=1.21527 BV=100 + IBV=0.00025 EG=1.2 XTI=3.03885 TT=0.0001 + CJO=1.81859e-09 VJ=1.1279 M=0.449161 FC=0.5 + T_ABS={temp_abs} RDS 3 1 4e+06 RD 9 1 0.0135649 RG 2 7 5.11362 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + CJO=2.49697e-09 VJ=0.5 M=0.9 FC=1e-08 + T_ABS={temp_abs} D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS={temp_abs} RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 2.49697e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS={temp_abs} .ENDS IRF540N-ICAP *$ *************************** .SUBCKT IRFZ46N-90C 1 2 3 ************************************** * Model Generated by MODPEX * *Copyright(c) Symmetry Design Systems* * All Rights Reserved * * UNPUBLISHED LICENSED SOFTWARE * * Contains Proprietary Information * * Which is The Property of * * SYMMETRY OR ITS LICENSORS * *Commercial Use or Resale Restricted * * by Symmetry License Agreement * ************************************** * Model generated on Apr 24, 96 * Model format: SPICE3 * Symmetry POWER MOS Model (Version 1.0) * External Node Designations * Node 1 -> Drain * Node 2 -> Gate * Node 3 -> Source M1 9 7 8 8 MM L=100u W=100u * Default values used in MM: * The voltage-dependent capacitances are * not included. Other default values are: * RS=0 RD=0 LD=0 CBD=0 CBS=0 CGBO=0 .MODEL MM NMOS LEVEL=1 IS=1e-32 + T_ABS=90 +VTO=3.82619 LAMBDA=0 KP=36.481 +CGSO=1.3939e-05 CGDO=5.05896e-07 RS 8 3 0.013932 D1 3 1 MD .MODEL MD D IS=8.99141e-09 RS=0.00661401 N=1.46353 BV=55 + T_ABS=90 +IBV=0.00025 EG=1 XTI=3.00311 TT=0.0001 +CJO=1.41544e-09 VJ=1.09154 M=0.508083 FC=0.5 RDS 3 1 2.2e+06 RD 9 1 0.0001 RG 2 7 3.53852 D2 4 5 MD1 * Default values used in MD1: * RS=0 EG=1.11 XTI=3.0 TT=0 * BV=infinite IBV=1mA .MODEL MD1 D IS=1e-32 N=50 + T_ABS=90 +CJO=1.4611e-09 VJ=0.5 M=0.675133 FC=1e-08 D3 0 5 MD2 * Default values used in MD2: * EG=1.11 XTI=3.0 TT=0 CJO=0 * BV=infinite IBV=1mA .MODEL MD2 D IS=1e-10 N=0.4 RS=3e-06 + T_ABS=90 RL 5 10 1 FI2 7 9 VFI2 -1 VFI2 4 0 0 EV16 10 0 9 7 1 CAP 11 10 1.83136e-09 FI1 7 9 VFI1 -1 VFI1 11 6 0 RCAP 6 10 1 D4 0 6 MD3 * Default values used in MD3: * EG=1.11 XTI=3.0 TT=0 CJO=0 * RS=0 BV=infinite IBV=1mA .MODEL MD3 D IS=1e-10 N=0.4 + T_ABS=90 .ENDS IRFZ46N-90C *$ * .subckt IRF540-80C 1 2 3 ************************************** * model generated by modpex * *copyright(c) symmetry design systems* * all rights reserved * * unpublished licensed software * * contains proprietary information * * which is the property of * * symmetry or its licensors * *commercial use or resale restricted * * by symmetry license agreement * ************************************** * model generated on apr 24, 96 * model format: spice3 * symmetry power mos model (version 1.0) * external node designations * node 1 -> drain * node 2 -> gate * node 3 -> source m1 9 7 8 8 mm l=100u w=100u * default values used in mm: * the voltage-dependent capacitances are * not included. other default values are: * rs=0 rd=0 ld=0 cbd=0 cbs=0 cgbo=0 .model mm nmos level=1 is=1e-32 vto=3.56362 lambda=0.00291031 + kp=25.0081 cgso=1.60584e-05 cgdo=4.25919e-07 + T_ABS=80 rs 8 3 0.0317085 d1 3 1 md .model md d is=1.02194e-10 rs=0.00968022 n=1.21527 bv=100 ibv=0.00025 + eg=1.2 xti=3.03885 tt=0.0001 cjo=1.81859e-09 vj=1.1279 m=0.449161 fc=0.5 + T_ABS=80 rds 3 1 4e+06 rd 9 1 0.0135649 rg 2 7 5.11362 d2 4 5 md1 * default values used in md1: * rs=0 eg=1.11 xti=3.0 tt=0 * bv=infinite ibv=1ma .model md1 d is=1e-32 n=50 cjo=2.49697e-09 vj=0.5 m=0.9 fc=1e-08 + T_ABS=80 d3 0 5 md2 * default values used in md2: * eg=1.11 xti=3.0 tt=0 cjo=0 * bv=infinite ibv=1ma .model md2 d is=1e-10 n=0.4 rs=3e-06 + T_ABS=80 rl 5 10 1 fi2 7 9 vfi2 -1 vfi2 4 0 0 ev16 10 0 9 7 1 cap 11 10 2.49697e-09 fi1 7 9 vfi1 -1 vfi1 11 6 0 rcap 6 10 1 d4 0 6 md3 * default values used in md3: * eg=1.11 xti=3.0 tt=0 cjo=0 * rs=0 bv=infinite ibv=1ma .model md3 d is=1e-10 n=0.4 + T_ABS=80 .ends IRF540-80C *$ * * .SUBCKT TIP142-80C 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS=80 + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS=80 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS=80 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-80C *$ * * .SUBCKT TIP142-90C 1 2 3 Q1 1 2 4 Q1model Q2 1 4 3 Q2model 5.888 D1 3 1 Dmodel R1 2 4 8.000E3 R2 4 3 120 .MODEL Dmodel D + T_ABS=90 + IS=4.721E-12 RS=1.083E-6 N=1.068 + CJO=4.822E-10 VJ=0.5 M=0.34 + FC=0.5 .MODEL Q1model NPN + T_ABS=90 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .MODEL Q2model NPN + T_ABS=90 + IS=8.075E-14 BF=7.827E3 NF=1 + VAF=100 IKF=1.094 ISE=4.463E-13 + NE=1.297 BR=0.1001 NR=1 + VAR=100 IKR=0.4891 ISC=2.302E-13 + NC=3.197 RB=2.222 NK=0.5471 + RE=0.001 RC=0.990 EG=1.110 + CJE=4.389E-10 VJE=0.77 MJE=0.3101 + CJC=4.852E-10 VJC=0.4855 MJC=0.3379 + XCJC=0.469 FC=0.5 .ENDS TIP142-90C *$ * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058-80C 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS=80 ) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS=80 ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS=80) .MODEL DLIM D (IS=100U T_ABS=80) .ENDS 2SK1058-80C *$ * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058-70C 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS=70 ) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS=70 ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS=70) .MODEL DLIM D (IS=100U T_ABS=70) .ENDS 2SK1058-70C *$ * lib de ICAP 1.8.6 (1998) * Hitachi 160 Volt 7 Amp .171 ohm N-Channel Power MOSFET 08-06-1993 .SUBCKT 2SK1058-60C 10 20 40 * TERMINALS: D G S M1 1 2 3 3 DMOS L=1U W=1U RD 100 1 80.4M RS 30 3 5.28M RG 20 2 21.4 CGS 2 3 410P EGD 12 0 2 1 1 VFB 14 0 0 FFB 2 1 VFB 1 CGD 13 14 128P R1 13 0 1 D1 12 13 DLIM DDG 15 14 DCGD R2 12 15 1 D2 15 0 DLIM DSD 3 100 DSUB LS 30 40 7.5N LD 10 100 4N .MODEL DMOS NMOS (LEVEL=3 THETA=85M VMAX=163K ETA=2.2M VTO=.2 KP=.999 T_ABS=60 ) .MODEL DCGD D (CJO=128P VJ=.6 M=.68 T_ABS=60 ) .MODEL DSUB D (IS=29N N=1.5 RS=61.4M BV=160 CJO=802P VJ=.8 M=.42 TT=252N T_ABS=60) .MODEL DLIM D (IS=100U T_ABS=60) .ENDS 2SK1058-60C *$ * OPA2604E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * "E" IS ENHANCED MODEL * CREATED USING PARTS RELEASE 4.03 ON 09/28/90 AT 16:46 * REV.B 3/21/92 BCB: added input bias current correction and * current and voltage noise * * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OPA604 1 2 3 4 5 * C1 11 12 22.85E-12 C2 6 7 32.00E-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 0 418.4E3 -40E3 40E3 40E3 -40E3 GA 6 0 11 12 2.011E-3 GCM 0 6 10 99 20.11E-9 ISS 3 10 DC 800.0E-6 HLIM 90 0 VLIM 1K J1 11 2 10 JX J2 12 64 10 JX G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 6E-6 G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 6E-6 R2 6 9 100.0E3 RD1 4 11 497.4 RD2 4 12 497.4 RO1 8 5 25 RO2 7 99 75 * RP 3 4 6.294E3 RSS 10 99 250.0E3 VB 9 0 DC 0 VC 3 53 DC 3 VE 54 4 DC 3 VLIM 7 8 DC 0 VLP 91 0 DC 50 VLN 0 92 DC 50 **************************** * OPA2604 "E" - ENHANCEMENTS **************************** * OUTPUT SUPPLY MIRROR FQ3 0 20 POLY(1) VLIM 0 1 DQ1 20 21 DX DQ2 22 20 DX VQ1 21 0 0 VQ2 22 0 0 FQ1 3 0 POLY(1) VQ1 3.45E-3 1 FQ2 0 4 POLY(1) VQ2 3.45E-3 -1 * QUIESCIENT CURRENT RQ 3 4 6.0E4 * DIFF INPUT CAPACITANCE CDIF 1 2 8.0E-12 * COMMON MODE INPUT CAPACITANCE C1CM 1 99 5.0E-12 C2CM 2 99 5.0E-12 * INPUT VOLTAGE NOISE VN1 61 0 0.6 VN2 0 62 0.6 DN1 61 63 DY DN2 63 62 DY EN 64 1 63 0 1 * INPUT CURRENT NOISE RN1 0 65 60.3865 RN2 65 66 60.3865 RN3 66 0 120.773 RN4 0 67 60.3865 RN5 67 68 60.3865 RN6 68 0 120.773 * .MODEL DY D(IS=133.62E-18 AF=1 KF=11.726E-18) .MODEL DX D(IS=800.0E-18) .MODEL JX PJF(IS=12.50E-12 BETA=2.528E-3 VTO=-1) .ENDS OPA604 *$ * MANUFACTURERS PART NO.= SG137A (SILICON GENERAL) * SUBTYPE: REGULATOR * THIS FILE CONTAINS A PRE-RAD TEMPERATURE DEPENDENT MACROMODEL OF THE * SG137A. * * PLEASE NOTE THE FOLLOWING: * * THIS MODEL CAN BE USED FROM -55 C TO 125 C WITH THE .TEMP * STATEMENT. IT INCLUDES POWER-UP AND POWER-DOWN EFFECTS. IT IS * NECESSARY TO SET ITL1=300 ITL2=300 WITH THE .OPTIONS COMMAND FOR 100% * CONVERGENCE. THESE SETTINGS DETERMINE THE NUMBER OF ITERATIONS * ALLOW FOR THE CALCULATION OF THE DC AND BIAS PT VALUES WHEN THE * STARTING POINT IS CONSIDERED "BLIND" OR AN "EDUCATED GUESS". * OTHER SETTINGS MAY WORK, BUT HAVE NOT BEEN TESTED YET. * * RIPPLE REJECTION, OUTPUT IMPEDANCE, QUIESCENT CURRENT, LINE * TRANSIENT, DROPOUT, AND LOAD TRANSIENT RESPONSE ARE MODELED BASED * ON LABORATORY MEASUREMENTS. THE CORRELATION IS QUITE GOOD. * CURRENT LIMITING AND ADJUSTMENT CURRENT BASED ON DATA SHEET * INFORMATION ARE MODELED ACCURATELY. * * *------------------------------------------------------------------ * * * .SUBCKT LM337 1 2 3 100 * | | | | * ADJ | | | * OUT | | * IN | * GND(REFERNCE) *** VOLTAGE REFERENCE SECTION *** LR 1 4 IND1 0.2709 .MODEL IND1 IND( + L = 1 + IL1 = 0 + IL2 = 0 + TC1 = 7.8864E-4 + TC2 = -2.8391E-5 + ) RR 4 5 98.2994 TC=-0.0063, 6.2251E-5 CR 1 6 3P RCR 6 7 150K DZR 7 5 DZR .MODEL DZR D ( + IS = 1E-14 + RS = 0 + N = 1 + TT = 0 + CJO = 0.1P + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1.25 + IBV = 1E-10 + ISR = 0 + NR = 2 + IKF = 9.9999E+13 + NBV = 0.0001 + IBVL = 0 + NBVL = 1 + TIKF = 0 + TBV1 = 2.2444E-6 + TBV2 = 6.5556E-8 + TRS1 = 0 + TRS2 = 0 + ) RZR 7 5 1MEG DZ1 8 7 DZ1 .MODEL DZ1 D( + IS = 1E-14 + RS = 1 + N = 1 + TT = 0 + CJO = 1P + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1 + IBV = 1E-10 + ISR = 0 + NR = 2 + IKF = 9.9999E+13 + NBV = 0.0001 + IBVL = 0 + NBVL = 1 + TIKF = 0 + TBV1 = -0.002847 + TBV2 = 3.4722E-6 + TRS1 = 0 + TRS2 = 0 + ) RQ 8 3 1.7546MEG TC=4.5212E-4,5.6515E-6 *** QUIESCENT CURRENT SECTION *** FQ 1 3 VQ1 0.0625M EQ1 24 100 1 7 1 VQ1 24 25 DC 0 RQ1 25 100 1 TC=-3.9528E-4,-1.1597E-5 *** ERROR AMPLIFIER *** RIN 7 23 100K E1 11 3 23 7 600 ROE1 9 11 10 D+ 9 13 DC V+ 14 3 -1 E+ 13 14 1 3 1 .MODEL DC D( + IS = 1E-14 + RS = 0 + N = 1 + TT = 0 + CJO = 10P + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = 1E-10 + ISR = 0 + NR = 2 + IKF = 9.9999E+13 + NBV = 1 + IBVL = 0 + NBVL = 1 + TIKF = 0 + TBV1 = 0 + TBV2 = 0 + TRS1 = 0 + TRS2 = 0 + ) D- 12 9 DC V- 12 3 DC 1 RP 9 10 151 CP 10 3 0.01U E2 15 3 10 3 1 *** RB1 15 16 50 RB2 16 19 500 TC=-1.9327E-4,3.3434E-6 *** SHORT CIRCUIT AND FOLDBACK CURRENT SECTION *** DSC 16 17 DMOD ESC 17 3 POLY(1),(2,3) 2.447 -0.01 DFB 16 18 DMOD EFB 18 3 POLY(1),(2,3) 12.5955 -1.2275 0.0457 -5.9169E-4 *** QP 20 19 3 QMOD .MODEL QMOD NPN( + IS = 1E-14 + BF = 500 + NF = 1 + VAF = 9.9999E+13 + IKF = 9.9999E+13 + ISE = 0 + NE = 1.5 + BR = 1 + NR = 1 + VAR = 9.9999E+13 + IKR = 9.9999E+13 + ISC = 0 + NC = 2 + RB = 0 + IRB = 9.9999E+13 + RBM = 0 + RE = 0 + RC = 0 + CJE = 0 + VJE = .75 + MJE = .33 + TF = 0 + XTF = 0 + VTF = 9.9999E+13 + ITF = 0 + PTF = 0 + CJC = 0 + VJC = .75 + MJC = .33 + XCJC = 1 + TR = 0 + CJS = 0 + VJS = .75 + MJS = 0 + XTB = 0 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + NK = .5 + ISS = 0 + NS = 1 + QCO = 0 + RCO = 0 + VO = 10 + GAMMA = 1E-11 + TRE1 = 0 + TRE2 = 0 + TRB1 = 0 + TRB2 = 0 + TRM1 = 0 + TRM2 = 0 + TRC1 = 0 + TRC2 = 0 + ) *** DROPOUT VOLTAGE SECTION *** RDO 23 22 0.1 DDO1 22 21 DDO DDO2 21 20 DDO .MODEL DDO D( + IS = 1E-14 + RS = 0 + N = 0.9687 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = 1E-10 + ISR = 0 + NR = 2 + IKF = 9.9999E+13 + NBV = 1 + IBVL = 0 + NBVL = 1 + TIKF = 0 + TBV1 = 0 + TBV2 = 0 + TRS1 = 0 + TRS2 = 0 + ) *** RO 23 2 0.0017 TC=-0.07894, 0.001136 DDIS 3 23 DDIS .MODEL DDIS D( + IS = 1E-14 + RS = 0 + N = 1 + TT = 0 + CJO = 1PF + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = 1E-10 + ISR = 0 + NR = 2 + IKF = 9.9999E+13 + NBV = 1 + IBVL = 0 + NBVL = 1 + TIKF = 0 + TBV1 = 0 + TBV2 = 0 + TRS1 = 0 + TRS2 = 0 + ) .MODEL DMOD D( + IS = 1E-14 + RS = 0 + N = 1 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = 1E-10 + ISR = 0 + NR = 2 + IKF = 9.9999E+13 + NBV = 1 + IBVL = 0 + NBVL = 1 + TIKF = 0 + TBV1 = 0 + TBV2 = 0 + TRS1 = 0 + TRS2 = 0 + ) .ENDS LM337 *$ * * * * *** Voltage regulators (positive/adjustable) * * LM117 voltage regulator "macromodel" subcircuit * created using Parts release 5.3 on 04/08/93 at 11:33 * * connections: input * | adjustment pin * | | output * | | | .SUBCKT LM317 IN ADJ OUT * * POSITIVE ADJUSTABLE VOLTAGE REGULATOR * JADJ IN ADJ ADJ JADJMOD ;ADJUSTMENT PIN CURRENT VREF 4 ADJ 1.25 DBK IN 13 DMOD * * ZERO OF RIPPLE REJECTION * CBC 13 15 8e-010 RBC 15 5 1000 * QPASS 13 5 OUT QPASSMOD RB1 7 6 1 RB2 6 5 128.3 * * CURRENT LIMITING * DSC 6 11 DMOD ESC 11 OUT VALUE {5.646-0.1125*V(6,5)*V(13,5)} * * FOLDBACK CURRENT * DFB 6 12 DMOD EFB 12 OUT VALUE {7.886-0.3727*V(13,5)+0.005097*V(13,5)*V(13,5) + -0.02*V(13,5)*V(6,5)} * EB 7 OUT 8 OUT 7.691 * * ZERO OF OUTPUT IMPEDANCE * RP 9 8 100 CPZ 10 OUT 3.979e-006 * DPU 10 OUT DMOD ;POWER-UP CLAMPLING DIODE RZ 8 10 0.1 EP 9 OUT 4 OUT 100 RI OUT 4 100MEG * .MODEL QPASSMOD NPN (IS=30F BF=50 VAF=8.891 NF=2.612) .MODEL JADJMOD NJF (BETA=5e-005 VTO=-1) .MODEL DMOD D (IS=30F N=2.612) .ENDS LM317 * * ************************************************************************** * OPA604 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * CREATED USING PARTS RELEASE 4.03 6/10/92 * REV.A * * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OPA604/BB 1 2 3 4 5 * C1 11 12 22.85E-12 C2 6 7 32.00E-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 0 418.4E3 -40E3 40E3 40E3 -40E3 GA 6 0 11 12 2.011E-3 GCM 0 6 10 99 20.11E-9 ISS 3 10 DC 800.0E-6 HLIM 90 0 VLIM 1K J1 11 2 10 JX J2 12 1 10 JX R2 6 9 100.0E3 RD1 4 11 497.4 RD2 4 12 497.4 RO1 8 5 25 RO2 7 99 75 RP 3 4 6.294E3 RSS 10 99 250.0E3 VB 9 0 DC 0 VC 3 53 DC 3 VE 54 4 DC 3 VLIM 7 8 DC 0 VLP 91 0 DC 50 VLN 0 92 DC 50 * .MODEL DX D(IS=800.0E-18) .MODEL JX PJF(IS=12.50E-12 BETA=2.528E-3 VTO=-1) .ENDS * ************************************************************************** * OPA604E OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * "E" IS ENHANCED MODEL * CREATED USING PARTS RELEASE 4.03 6/10/92 * REV.A * * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OPA604E/BB 1 2 3 4 5 * C1 11 12 22.85E-12 C2 6 7 32.00E-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 0 418.4E3 -40E3 40E3 40E3 -40E3 GA 6 0 11 12 2.011E-3 GCM 0 6 10 99 20.11E-9 ISS 3 10 DC 800.0E-6 HLIM 90 0 VLIM 1K J1 11 2 10 JX J2 12 64 10 JX G11 2 4 POLY(4) (10,2) (11,2) (4,2) (66,0) 0 1E-12 1E-12 1E-12 6E-6 G21 1 4 POLY(4) (10,1) (12,1) (4,1) (68,0) 0 1E-12 1E-12 1E-12 6E-6 R2 6 9 100.0E3 RD1 4 11 497.4 RD2 4 12 497.4 RO1 8 5 25 RO2 7 99 75 * RP 3 4 6.294E3 RSS 10 99 250.0E3 VB 9 0 DC 0 VC 3 53 DC 3 VE 54 4 DC 3 VLIM 7 8 DC 0 VLP 91 0 DC 50 VLN 0 92 DC 50 **************************** * OPA2604 "E" - ENHANCEMENTS **************************** * OUTPUT SUPPLY MIRROR FQ3 0 20 POLY(1) VLIM 0 1 DQ1 20 21 DX DQ2 22 20 DX VQ1 21 0 0 VQ2 22 0 0 FQ1 3 0 POLY(1) VQ1 3.45E-3 1 FQ2 0 4 POLY(1) VQ2 3.45E-3 -1 * QUIESCIENT CURRENT RQ 3 4 6.0E4 * DIFF INPUT CAPACITANCE CDIF 1 2 8.0E-12 * COMMON MODE INPUT CAPACITANCE C1CM 1 99 5.0E-12 C2CM 2 99 5.0E-12 * INPUT VOLTAGE NOISE VN1 61 0 0.6 VN2 0 62 0.6 DN1 61 63 DY DN2 63 62 DY EN 64 1 63 0 1 * INPUT CURRENT NOISE RN1 0 65 60.3865 RN2 65 66 60.3865 RN3 66 0 120.773 RN4 0 67 60.3865 RN5 67 68 60.3865 RN6 68 0 120.773 * .MODEL DY D(IS=133.62E-18 AF=1 KF=11.726E-18) .MODEL DX D(IS=800.0E-18) .MODEL JX PJF(IS=12.50E-12 BETA=2.528E-3 VTO=-1) .ENDS * * ************************************************************************** * OPA604M OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * "M" IS MULTIPLE POLE/ZERO TOPOLOGY * CREATED 7/8/92 BCB * REV.A * * ------------------------------------------------------------- * | This macro model is being supplied as an aid to | * | circuit designs. While it reflects reasonably close | * | similarity to the actual device in terms of performance, | * | it is not suggested as a replacement for breadboarding. | * | Simulation should be used as a forerunner or a supplement | * | to traditional lab testing. | * | | * | Neither this library nor any part may be copied without | * | the express written consent of Burr-Brown Corporation. | * | | * | The users should carefully note the following factors | * | regarding this model. | * ------------------------------------------------------------- * * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OPA604M/BB 3 2 7 4 6 * * INPUT STAGE (pole=1.6MHz) J1 13 2 12 PJ J2 14 11 12 PJ G51 2 4 POLY(2) (13,2) (12,2) 0 1E-12 1E-12 G52 11 4 POLY(2) (14,11) (12,11) 0 1E-12 1E-12 R3 4 13 198.94 R4 4 14 198.94 C1 13 14 250E-12 IEE 7 12 1.8E-3 EOS 11 3 POLY(1) (33,10) 3E-3 1 R1 2 15 5E11 R2 3 15 5E11 CIN 2 3 8E-12 IOS 2 3 4E-12 * GAIN STAGE (gain=100dB, pole=200Hz) V21 7 21 3.236 D21 23 21 DX V22 22 4 3.236 D22 22 23 DX G21 7 23 POLY(1) (13,14) 2.9238E-3 5.0265E-3 G22 4 23 POLY(1) (13,14) -2.9238E-3 5.0265E-3 R27 7 23 19.89E6 R28 4 23 19.89E6 C22 7 23 40E-12 C23 4 23 40E-12 * ZERO / POLE STAGE (zero=1.6MHz, pole=10MHz) R46 41 43 1E6 R47 42 43 1E6 R45 7 41 5.25E6 R48 4 42 5.25E6 L41 7 41 83.6E-3 L42 4 42 83.6E-3 G45 7 43 23 10 1E-6 G46 4 43 23 10 1E-6 * POLE / ZERO STAGE (pole=0.4MHz, zero=1.6MHz) R81 7 83 1E6 R84 4 83 1E6 R82 81 83 0.25E6 R83 82 83 0.25E6 C84 81 7 397.9E-15 C85 82 4 397.9E-15 G81 7 83 43 10 1E-6 G82 4 83 43 10 1E-6 * COMMON-MODE REJECTION STAGE (zero at 2kHz) R31 31 33 1E6 R32 32 33 1E6 G31 7 33 15 10 1E-11 G32 4 33 15 10 1E-11 L31 31 7 79.577 L32 32 4 79.577 * OUTPUT STAGE D3 83 71 DX D4 72 83 DX D5 7 73 DX D6 7 74 DX D7 4 73 DZ D8 4 74 DZ G14 73 4 6 83 20E-3 G13 74 4 83 6 20E-3 V3 71 6 0.38686 V4 6 72 0.38686 G11 6 7 7 83 20E-3 G12 4 6 83 4 20E-3 R23 7 6 50 R24 4 6 50 * CENTER OF SUPPLIES R9 7 10 31.304E3 R10 4 10 31.304E3 * .MODEL DX D(IS=1E-15) .MODEL PJ PJF(BETA=12.63285E-3 VTO=-2 IS=50E-12) .MODEL DZ D(IS=1E-15 BV=50) .ENDS * * ************************************************************************** * OPA627 OPERATIONAL AMPLIFIER "MACROMODEL" SUBCIRCUIT * CREATED USING PARTS RELEASE 4.03 ON 10/12/90 AT 07:59 * REV.B 5/22/91 TK * * CONNECTIONS: NON-INVERTING INPUT * | INVERTING INPUT * | | POSITIVE POWER SUPPLY * | | | NEGATIVE POWER SUPPLY * | | | | OUTPUT * | | | | | .SUBCKT OPA627/BB 1 2 3 4 5 * C1 11 12 3.182E-12 C2 6 7 23.00E-12 CSS 10 99 40.45E-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 0 419.4E6 -40E6 40E6 40E6 -40E6 GA 6 0 11 12 2.432E-3 GCM 0 6 10 99 3.779E-9 ISS 3 10 DC 1.840E-3 HLIM 90 0 VLIM 1K J1 11 2 10 JX J2 12 1 10 JX R2 6 9 100.0E3 RD1 4 11 419.4 RD2 4 12 419.4 RO1 8 5 54 RO2 7 99 1 RP 3 4 4.286E3 RSS 10 99 108.7E3 VB 9 0 DC 0 VC 3 53 DC 2.700 VE 54 4 DC 2.700 VLIM 7 8 DC 0 VLP 91 0 DC 55 VLN 0 92 DC 55 * .MODEL DX D(IS=800.0E-18) .MODEL JX PJF(IS=500.0E-15 BETA=1.545E-3 VTO=-1) .ENDS