* Library of diode model parameters * * Copyright 1989-1995 by MicroSim Corporation * Neither this library nor any part may be copied without the express * written consent of MicroSim Corporation * * $Revision: 1.23.1.0 $ * $Author: MSB $ * $Date: 09 Sep 1996 09:00:06 $ *---------------------------------------------------------------------------- * MicroSim Corporation would like to acknowledge Sandia National Laboratories * for the contribution of their measurement-based models included in this * library. *---------------------------------------------------------------------------- * The parameters in this model library were derived from the data sheets for * each part. Most parts were characterized using the Parts option. *---------------------------------------------------------------------------- *$ .model D1N914 D(Is=168.1E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4p M=.3333 + Vj=.75 Fc=.5 Isr=100p Nr=2 Bv=100 Ibv=100u Tt=11.54n) *$ .model D1N914a D(Is=100f N=1 Rs=16 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 Vj=.75 + Fc=.5 Isr=100p Nr=2 Bv=100 Ibv=100f Tt=12n) *$ .model D1N914B D(Is=0.1p Rs=2 CJO=2p Tt=12n Bv=100 Ibv=0.1p) * 85-??-?? Original library *$ * * MEASURED TRR = 302.0NS, SIMULATED TRR = 88.15NS. * RAD: PRERAD * TEMP: -55 .MODEL D1N914/-55C D ( + IS = 2.32292E-15 + RS = 1.525844 + N = 1.071906 + TT = 1.26E-7 + CJO = 3.0177E-12 + VJ = 0.4 + M = 0.2147523 + EG = 1.11 + XTI = 6.260188 + KF = 0 + AF = 1 + FC = 0.764906 + BV = 94 + IBV = 5E-6 + ) *$ * * * MEASURED TRR = 380.0NS, SIMULATED TRR = 105.8NS. * RAD: PRERAD * TEMP: 125 .MODEL D1N914/125C D ( + IS = 2.25833E-15 + RS = 1.799439 + N = 1.067043 + TT = 1.46E-7 + CJO = 3.0177E-12 + VJ = 0.4 + M = 0.2147523 + EG = 1.11 + XTI = 4.799594 + KF = 0 + AF = 1 + FC = 0.764906 + BV = 94 + IBV = 5E-6 + ) *$ * * * MANUFACTURERS PART NO. = 914NGTS * MANUFACTURER = SPRAGUE * TYPE: DIODE * SUBTYPE: RECTIFIER * THE FOLLOWING CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED DEVICES * AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA. **** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * * * MEASURED TRR = 344.0NS, SIMULATED TRR = 96.16NS. * RAD: PRERAD * TEMP: 27 .MODEL D1N914/27C D ( + IS = 1.6436E-15 + RS = 1.581604 + N = 1.057899 + TT = 1.36E-7 + CJO = 3.0177E-12 + VJ = 0.4 + M = 0.2147523 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.764906 + BV = 94 + IBV = 5E-6 + ) *$ * * * MANUFACTURERS PART NO. = 914NGTS * MANUFACTURER = SPRAGUE * TYPE: DIODE * SUBTYPE: RECTIFIER * THIS FILE CONTAINS 1 PARAMETER SET, POST NEUTRON RADIATION OF THE 914NGTS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * * * * MEASURED TRR = 202.0NS, SIMULATED TRR = 82.64NS. * TYPE: NEUTRON * TEMP= 27 .MODEL D1N914/27C/RAD D ( + IS = 1.5331E-13 + RS = 1.38794 + N = 1.274012 + TT = 1.16E-7 + CJO = 3.01491E-12 + VJ = 0.4 + M = 0.2145244 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.85 + BV = 91 + IBV = 1E-5 + ) *$ .model D1N916 D(Is=168.1E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=757.7n Nr=2.091 Bv=100 Ibv=100u Tt=25.95n) *$ .model D1N916A D(Is=0.1p Rs=4 CJO=1p Tt=12n Bv=100 Ibv=0.1p) * 85-??-?? Original library *$ .model D1N916B D(Is=0.1p Rs=4 CJO=1p Tt=12n Bv=100 Ibv=0.1p) * 85-??-?? Original library *$ .model D1N1190 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 D1N3063 D(Is=2.989n N=1.704 Rs=3.886 Ikf=26.84 Xti=3 Eg=1.11 Cjo=2p + M=.3333 Vj=.75 Fc=.5 Isr=100p Nr=2 Bv=75 Ibv=5u Tt=5.771n) *$ .model D1N3064 D(Is=168.1E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=24.54n Nr=2 Bv=100 Ibv=100u Tt=5.771n) *$ .model D1N3491 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=11.02u Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model D1N3492 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=5.651u Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model D1N3493 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=2.888u Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model D1N3494 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=1.949u Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model D1N3495 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=1.474u Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model D1N3501 D(Is=10f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=168.9p M=.1794 + Vj=.3905 Fc=.5 Isr=678.5n Nr=2 Bv=6.444 Ibv=.2898 Tt=7.213u) *$ .model D1N3600 D(Is=8.845E-18 N=.7522 Rs=1.22 Ikf=21.53 Xti=3 Eg=1.11 Cjo=2.5p + M=.3333 Vj=.75 Fc=.5 Isr=2.668u Nr=2 Bv=75 Ibv=100u Tt=8.656n) *$ .model D1N3604 D(Is=980.8E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=12.27n Nr=2 Bv=75 Ibv=5u Tt=5.771n) *$ .model D1N3605 D(Is=1.098n N=1.659 Rs=1.156 Ikf=8.872 Xti=3 Eg=1.11 Cjo=2p + M=.3333 Vj=.75 Fc=.5 Isr=14.18n Nr=2 Bv=40 Ibv=5u Tt=5.771n) *$ .model D1N3606 D(Is=1.098n N=1.659 Rs=1.156 Ikf=8.872 Xti=3 Eg=1.11 Cjo=2p + M=.3333 Vj=.75 Fc=.5 Isr=12n Nr=2 Bv=75 Ibv=5u Tt=5.771n) *$ .model D1N3879 D(Is=1.058E-18 Rs=11.56m Ikf=2.349 N=1 Xti=14 Eg=1.11 Cjo=113.2p + M=.2834 Vj=.75 Fc=.5 Isr=908.6n Nr=2 Tt=369.9n) * Motorola pid=1N3879 case=DO4 * 88-08-25 rmn *$ .model D1N3880 D(Is=1.058E-18 Rs=11.56m Ikf=2.349 N=1 Xti=14 Eg=1.11 Cjo=113.2p + M=.2834 Vj=.75 Fc=.5 Isr=798n Nr=2 Tt=369.9n) * Motorola pid=1N3879 case=DO4 * 88-08-25 rmn *$ .model D1N3881 D(Is=1.058E-18 Rs=11.56m Ikf=2.349 N=1 Xti=14 Eg=1.11 Cjo=113.2p + M=.2834 Vj=.75 Fc=.5 Isr=820.5n Nr=2 Tt=369.9n) * Motorola pid=1N3879 case=DO4 * 88-08-25 rmn *$ .model D1N3882 D(Is=1.058E-18 Rs=11.56m Ikf=2.349 N=1 Xti=14 Eg=1.11 Cjo=113.2p + M=.2834 Vj=.75 Fc=.5 Isr=887.2n Nr=2 Tt=369.9n) * Motorola pid=1N3879 case=DO4 * 88-08-25 rmn *$ .model D1N3883 D(Is=1.058E-18 Rs=11.56m Ikf=2.349 N=1 Xti=14 Eg=1.11 Cjo=113.2p + M=.2834 Vj=.75 Fc=.5 Isr=994.9n Nr=2 Tt=369.9n) * Motorola pid=1N3879 case=DO4 * 88-08-25 rmn *$ .model D1N3889 D(Is=15.03f Rs=9.606m Ikf=.2003 N=1 Xti=3 Eg=1.11 Cjo=117.8p + M=.2976 Vj=.75 Fc=.5 Isr=770.3n Nr=2 Tt=369.9n) * Motorola pid=1N3889 case=DO4 * 88-08-25 rmn *$ .model D1N3890 D(Is=15.03f Rs=9.606m Ikf=.2003 N=1 Xti=3 Eg=1.11 Cjo=117.8p + M=.2976 Vj=.75 Fc=.5 Isr=684.1n Nr=2 Tt=369.9n) * Motorola pid=1N3889 case=DO4 * 88-08-25 rmn *$ .model D1N3891 D(Is=15.03f Rs=9.606m Ikf=.2003 N=1 Xti=3 Eg=1.11 Cjo=117.8p + M=.2976 Vj=.75 Fc=.5 Isr=672.7n Nr=2 Tt=369.9n) * Motorola pid=1N3889 case=DO4 * 88-08-25 rmn *$ .model D1N3892 D(Is=15.03f Rs=9.606m Ikf=.2003 N=1 Xti=3 Eg=1.11 Cjo=117.8p + M=.2976 Vj=.75 Fc=.5 Isr=705.6n Nr=2 Tt=369.9n) * Motorola pid=1N3889 case=DO4 * 88-08-25 rmn *$ .model D1N3893 D(Is=15.03f Rs=9.606m Ikf=.2003 N=1 Xti=3 Eg=1.11 Cjo=117.8p + M=.2976 Vj=.75 Fc=.5 Isr=809.8n Nr=2 Tt=369.9n) * Motorola pid=1N3889 case=DO4 * 88-08-25 rmn *$ .model D1N3899 D(Is=5.62f Rs=6.414m Ikf=9.692 N=1 Xti=2 Eg=1.11 Cjo=144.1p + M=.2272 Vj=.75 Fc=.5 Isr=1.036u Nr=2 Tt=521.4n) * Motorola pid=1N3899 case=DO5 * 88-08-30 rmn *$ .model D1N3900 D(Is=5.62f Rs=6.414m Ikf=9.692 N=1 Xti=2 Eg=1.11 Cjo=144.1p + M=.2272 Vj=.75 Fc=.5 Isr=985.4n Nr=2 Tt=521.4n) * Motorola pid=1N3899 case=DO5 * 88-08-30 rmn *$ .model D1N3901 D(Is=5.62f Rs=6.414m Ikf=9.692 N=1 Xti=2 Eg=1.11 Cjo=144.1p + M=.2272 Vj=.75 Fc=.5 Isr=997n Nr=2 Tt=521.4n) * Motorola pid=1N3899 case=DO5 * 88-08-30 rmn *$ .model D1N3902 D(Is=5.62f Rs=6.414m Ikf=9.692 N=1 Xti=2 Eg=1.11 Cjo=144.1p + M=.2272 Vj=.75 Fc=.5 Isr=1.076u Nr=2 Tt=521.4n) * Motorola pid=1N3899 case=DO5 * 88-08-30 rmn *$ .model D1N3903 D(Is=5.62f Rs=6.414m Ikf=9.692 N=1 Xti=2 Eg=1.11 Cjo=144.1p + M=.2272 Vj=.75 Fc=.5 Isr=1.248u Nr=2 Tt=521.4n) * Motorola pid=1N3899 case=DO5 * 88-08-30 rmn *$ .model D1N3909 D(Is=20.07f Rs=3.842m Ikf=2.963 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=887.6n Nr=2 Tt=369.9n) * Motorola pid=1N3909 case=DO5 * 88-08-30 rmn *$ .model D1N3910 D(Is=20.07f Rs=3.842m Ikf=2.963 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=805.6n Nr=2 Tt=369.9n) * Motorola pid=1N3909 case=DO5 * 88-08-30 rmn *$ .model D1N3911 D(Is=20.07f Rs=3.842m Ikf=2.963 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=825.8n Nr=2 Tt=369.9n) * Motorola pid=1N3909 case=DO5 * 88-08-30 rmn *$ .model D1N3912 D(Is=20.07f Rs=3.842m Ikf=2.963 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=851.1n Nr=2 Tt=369.9n) * Motorola pid=1N3909 case=DO5 * 88-08-30 rmn *$ .model D1N3913 D(Is=20.07f Rs=3.842m Ikf=2.963 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=973.4n Nr=2 Tt=369.9n) * Motorola pid=1N3909 case=DO5 * 88-08-30 rmn *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N3940 * TYPE: DIODE * SUBTYPE: RECTIFIER * * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED FROM * PRODUCT SPECIFICATION LIMITS AND MEASUREMENTS MADE ON ONE DEVICE. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. * .MODEL D1N3940 D( + IS = 4E-10 + RS = .105 + N = 1.48 + TT = 8E-7 + CJO = 1.95E-11 + VJ = .4 + M = .38 + EG = 1.36 + XTI = -8 + KF = 0 + AF = 1 + FC = .9 + BV = 600 + IBV = 1E-4 + ) * *$ .model D1N4001 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=75 Ibv=10u Tt=5.7u) * Motorola * Semiconductor Databook (mid 1970s) * 03 Jun 91 pwt creation *$ .MODEL D1N4002 D (IS=14.11E-9 N=1.984 RS=33.89E-3 IKF=94.81 XTI=3 + EG=1.110 CJO=51.17E-12 M=.2762 VJ=.3905 FC=.5 ISR=100.0E-12 + NR=2 BV=100.1 IBV=10 TT=4.761E-6) *$ .model D1N4003 ako:D1N4001 D(Bv=300) ; use non-rep. peak voltage *$ * * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * MEASURED TRR = 203.5NS, SIMULATED TRR = 208.2NS. * * RAD: PRERAD * TEMP: -55 * * .SUBCKT D1N4003/-55C 99 2 D1 99 2 DFOR C1 2 99 9.36289E-12 .MODEL DFOR D ( + IS = 5.11588E-9 + RS = 0.1 + N = 1.738842 + TT = 3.E-7 + CJO = 4.31731E-12 + VJ = 0.4421822 + M = 1.90735 + EG = 1.11 + XTI = 2.167819 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1E5 + IBV = 1E-3 + ) .ENDS *$ * * BV, IBV, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 203.5NS, SIMULATED TRR = 208.2NS. * * * RAD: PRERAD * TEMP: 125 * * .SUBCKT D1N4003/125C 99 2 D1 99 2 DFOR C1 2 99 9.36289E-12 .MODEL DFOR D ( + IS = 5.5415E-9 + RS = 0.1 + N = 1.732494 + TT = 7.05E-7 + CJO = 4.31731E-12 + VJ = 0.4421822 + M = 1.90735 + EG = 1.11 + XTI = 5.642014 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1E5 + IBV = 1E-3 + ) .ENDS *$ * * MANUFACTURERS PART NO. = THD4003 * MANUFACTURER = SPRAGUE * TYPE: DIODE * SUBTYPE: RECTIFIER * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES OF THE 1N4003 * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 337.6NS, SIMULATED TRR =336.6NS. * * RAD: PRERAD * TEMP: 27 * * .SUBCKT D1N4003/27C 99 2 D1 99 2 DFOR C1 2 99 9.36289E-12 .MODEL DFOR D ( + IS = 6.12912E-9 + RS = 0.1035407 + N = 1.705596 + TT = 4.65E-7 + CJO = 4.31731E-12 + VJ = 0.4421822 + M = 1.90735 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 417 + IBV = 1E-6 + ) .ENDS *$ * * MANUFACTURERS PART NO. = THD4003 * MANUFACTURER = SPRAGUE * TYPE: DIODE * SUBTYPE: RECTIFIER * THE FOLLOWING SECTION CONTAINS 2 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS OF THE 1N4003. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 110.7NS, SIMULATED TRR = 108.9NS. * * RAD: 3.08E13 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N4003/27C/RAD1 D ( + IS = 1.34779E-7 + RS = 0.1 + N = 2.067915 + TT = 1.48E-7 + CJO = 2.17106E-11 + VJ = 0.4 + M = 0.390894 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.809613 + BV = 345 + IBV = 1E-6 +) *$ * * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 12.8NS, SIMULATED TRR = 13NS. * * RAD: 3.07E14 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N4003/27C/RAD2 D ( + IS = 4.30065E-7 + RS = 0.243508 + N = 2.603175 + TT = 1.69E-8 + CJO = 8.55433E-12 + VJ = 0.7143081 + M = 0.2393511 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-3 + ) *$ .model D1N4004 ako:D1N4001 D(Bv=600) ; use non-rep. peak voltage *$ .model D1N4005 ako:D1N4001 D(Bv=900) ; use non-rep. peak voltage *$ .model D1N4006 ako:D1N4001 D(Bv=1200) ; use non-rep. peak voltage *$ .model D1N4007 ako:D1N4001 D(Bv=1500) ; use non-rep. peak voltage *$ .model D1N4009 D(Is=544.7E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4p M=.3333 + Vj=.75 Fc=.5 Isr=30.77n Nr=2 Bv=25 Ibv=100u Tt=2.885n) *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4097 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A PRELIMINARY MODEL FOR THE SIMULATION OF THE DC CHARACTERISTICS * OF THIS DEVICE. THE PARAMETERS WERE EXTRACTED FROM MEASUREMENTS * MADE ON ONE DEVICE. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * .SUBCKT D1N4097 1 4 D1 1 4 DFOR D2 4 2 DBLOCK IC 3 2 22.4 RC 2 3 2.3 TC=1.69E-3,0 VB 3 1 48 RL 4 1 3.25E10 TC=-1.53E-2,1.24E-4 * .MODEL DFOR D( + IS = 1.2E-12 + RS = .1 + N = 1.2 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.09 + XTI = 2.9 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 1.37 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.5 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .ENDS *$ .model D1N4148 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) *$ * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 3.379NS, SIMULATED TRR = 3.062NS. * * RAD: PRERAD * TEMP= -55 .MODEL D1N4148/-55C D ( + IS = 1.26351E-8 + RS = 0.7600063 + N = 1.953465 + TT = 2.424E-9 + CJO = 1.72434E-12 + VJ = 0.3026211 + M = 0.2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.998001 + BV = 1E5 + IBV = 1.0E-10 + ) *$ * * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 10.40NS, SIMULATED TRR = 5.373NS. * * RAD: PRERAD * TEMP= 125 .MODEL D1N4148/125C D ( + IS = 6.42601E-9 + RS = 0.7520202 + N = 1.8485649 + TT = 6.303E-9 + CJO = 1.75198E-12 + VJ = 0.4 + M = 0.2289422 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1E5 + IBV = 1.0E-10 + ) *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4148 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: SWITCHING * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES OF THE 1N4148-1JTXV DIODE. * THIS MODEL CAN BE USED FOR ALL OF THE FOLLOWING DEVICES: * 1N4148 * 1N4148-1 * 1N4148-1JTXV * THE ROOM TEMPERATURE PRE-RAD PARAMETER SET SIMULATES NEARLY * IDENTICALLY TO THE -55 AND THE 125 DEG C WHEN .TEMP IS USED. THIS * PARAMETER SET CAN BE USED AT ALL TEMPERATURES BETWEEN -55 AND 125 DEG * C. * * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 4.681NS, SIMULATED TRR = 6.544NS. * RAD: PRERAD * TEMP= 27 .MODEL D1N4148/27C D ( + IS = 1.27106E-8 + RS = 0.7546332 + N = 1.9215823 + TT = 3.679E-9 + CJO = 1.72434E-12 + VJ = 0.3026211 + M = 0.2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.998001 + BV = 1E5 + IBV = 1.0E-10 + ) *$ * * 1N4148 * GENERIC FUNCTIONAL EQUIVALENT = 1N4148 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: SWITCHING * THIS FILE CONTAINS 3 MODELS AT VARIOUS RADIATION LEVELS OF THE * 1N4148-1JTXV DIODE. * THIS MODEL CAN BE USED FOR ALL OF THE FOLLOWING DEVICES: * 1N4148 * 1N4148-1 * 1N4148-1JTXV * THE ROOM TEMPERATURE PRE-RAD PARAMETER SET SIMULATES NEARLY * IDENTICALLY TO THE -55 AND THE 125 DEG C WHEN .TEMP IS USED. THIS * PARAMETER SET CAN BE USED AT ALL TEMPERATURES BETWEEN -55 AND 125 DEG C. * * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 5.99NS, SIMULATED TRR = 5.79NS. * * * RAD: 5E12 * TYPE: NEUTRON * TEMP: 27 * * .SUBCKT D1N4148/27C/RAD1 99 2 D1 99 2 DFOR C1 2 99 1.2202E-12 .MODEL DFOR D ( + IS = 1.04734E-8 + RS = 0.7505 + N = 1.873917 + TT = 7.2E-9 + CJO = 2.34983E-13 + VJ = 0.4 + M = 2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 165 + IBV = 1E-6 + ) .ENDS *$ * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 5.67NS, SIMULATED TRR = 5.61NS. * * * RAD: 2E13 * TYPE: NEUTRON * TEMP: 27 * * .SUBCKT D1N4148/27C/RAD2 99 2 D1 99 2 DFOR C1 2 99 1.30456E-12 .MODEL DFOR D ( + IS = 6.20257E-9 + RS = 0.7388511 + N = 1.805135 + TT = 7.3E-9 + CJO = 3.05464E-13 + VJ = 0.4 + M = 1.824741 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 163 + IBV = 5E-6 + ) .ENDS *$ * * MEASURED TRR = 3.4NS, SIMULATED TRR = 1.521NS. * * RAD: 2E14 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N4148/27C/RAD3 99 2 D1 99 2 DFOR C1 2 99 1.34841E-12 .MODEL DFOR D ( + IS = 7.51054E-9 + RS = 1.672287 + N = 1.864477 + TT = 1E-9 + CJO = 1.652E-13 + VJ = 0.3619 + M = 1.721 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.85 + BV = 148 + IBV = 2E-6 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4148 * TYPE: DIODE * SUBTYPE: SWITCHING * THIS FILE CONTAINS 1 MODEL THAT CAN BE USED AS A TEMPERATURE TRACKING * MODEL FROM -55 TO 125 DEG C. * THIS MODEL CAN BE USED FOR ALL OF THE FOLLOWING DEVICES: * 1N4148 * 1N4148-1 * 1N4148-1JTXV * THE ROOM TEMPERATURE PRE-RAD PARAMETER SET SIMULATES NEARLY * IDENTICALLY TO THE -55 AND THE 125 DEG C WHEN .TEMP IS USED. THIS * PARAMETER SET CAN BE USED AT ALL TEMPERATURES BETWEEN -55 AND 125 DEG * C. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA. * * MEASURED TRR = 4.681NS, SIMULATED TRR = 6.544NS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * RAD: PRERAD * TEMP= 27 .MODEL D1N4148/TEMP D ( + IS = 1.27106E-8 + RS = 0.7546332 + N = 1.9215823 + TT = 3.679E-9 + CJO = 1.72434E-12 + VJ = 0.3026211 + M = 0.2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.998001 + BV = 1E5 + IBV = 1.0E-10 + ) *$ .model D1N4149 D(Is=2.682n N=1.836 Rs=.5664 Ikf=44.17m Xti=3 Eg=1.11 Cjo=2p + M=.3333 Vj=.5 Fc=.5 Isr=1.565n Nr=2 Bv=100 Ibv=100u Tt=11.54n) *$ .model D1N4150 D(Is=740.5p N=1.65 Rs=.5949 Ikf=8.039 Xti=3 Eg=1.11 Cjo=2.5p + M=.3333 Vj=.75 Fc=.5 Isr=24.36n Nr=2 Bv=75.37 Ibv=100u + Tt=5.771n) *$ .model D1N4151 D(Is=2.2n N=1.768 Rs=.5927 Ikf=8.512m Xti=3 Eg=1.11 Cjo=1.725p + M=88.82m Vj=.5 Fc=.5 Isr=7.832n Nr=2 Bv=75 Ibv=5u Tt=5.771n) *$ .model D1N4152 D(Is=36.16E-18 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=14.5n Nr=2 Bv=40 Ibv=100u Tt=5.581m) *$ .model D1N4153 D(Is=36.16E-18 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=12.27n Nr=2 Bv=100 Ibv=100u Tt=5.771n) *$ .model D1N4154 D(Is=153.4p N=1.487 Rs=.6329 Ikf=3.53m Xti=3 Eg=1.11 Cjo=2.251p + M=.1575 Vj=.5 Fc=.5 Isr=4.763n Nr=2 Bv=35 Ibv=5u Tt=5.771n) *$ .model D1N4305 D(Is=55.48E-18 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=24.54n Nr=2 Bv=75 Ibv=100u Tt=5.771n) *$ .model D1N4444 D(Is=26.66n N=2.062 Rs=.4266 Ikf=22.1 Xti=3 Eg=1.11 Cjo=2p + M=.3333 Vj=.75 Fc=.5 Isr=5.729n Nr=2 Bv=70 Ibv=100u Tt=10.1n) *$ .model D1N4446 D(Is=1.071n N=1.698 Rs=.8383 Ikf=0 Xti=3 Eg=1.11 Cjo=4p M=.3333 + Vj=.75 Fc=.5 Isr=2.441n Nr=2 Bv=100 Ibv=100u Tt=11.54n) *$ .model D1N4447 D(Is=1.071n N=1.698 Rs=.8383 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.5 Fc=.5 Isr=2.149n Nr=2 Bv=100 Ibv=100u Tt=11.54n) *$ .model D1N4448 D(Is=2.681n N=1.835 Rs=.5142 Ikf=34.82m Xti=3 Eg=1.11 Cjo=4p + M=.3333 Vj=.5 Fc=.5 Isr=1.566n Nr=2 Bv=100 Ibv=100u Tt=11.54n) *$ .model D1N4449 D(Is=2.018n N=1.791 Rs=.6887 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.5 Fc=.5 Isr=1.806n Nr=2 Bv=100 Ibv=100u Tt=11.54n) *$ .model D1N4454 D(Is=168.1E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=24.54n Nr=2 Bv=75 Ibv=100u Tt=5.771n) *$ .model D1n4460 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1n M=.3333 Vj=.75 + Fc=.5 Isr=5.516u Nr=2 Bv=6.233 Ibv=.1658 Tt=144.3n) *$ .model D1N4461 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1n M=.3333 Vj=.75 + Fc=.5 Isr=2.688u Nr=2 Bv=6.85 Ibv=.2913 Tt=144.3n) *$ .model D1N4462 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1n M=.3333 Vj=.75 + Fc=.5 Isr=522.8n Nr=2 Bv=7.554 Ibv=.317 Tt=144.3n) *$ .model D1n4463 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1n M=.3333 Vj=.75 + Fc=.5 Isr=254.8n Nr=2 Bv=8.255 Ibv=.2877 Tt=144.3n) *$ .model D1N4464 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1n M=.3333 Vj=.75 + Fc=.5 Isr=148.3n Nr=2 Bv=9.152 Ibv=.2369 Tt=144.3n) *$ .model D1n4465 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=950p M=.3333 + Vj=.75 Fc=.5 Isr=132.3n Nr=2 Bv=10.05 Ibv=.2111 Tt=144.3n) *$ .model D1n4466 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=950p M=.3333 + Vj=.75 Fc=.5 Isr=128.5n Nr=2 Bv=11.05 Ibv=.1906 Tt=144.3n) *$ .model D1n4467 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=930p M=.3333 + Vj=.75 Fc=.5 Isr=83.39n Nr=2 Bv=12.05 Ibv=.1785 Tt=144.3n) *$ .model D1n4468 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=920p M=.3333 + Vj=.75 Fc=.5 Isr=20.34n Nr=2 Bv=13.06 Ibv=.1723 Tt=144.3n) *$ * * RAD: PRE * TEMP= -15 * .SUBCKT D1N4468/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.69 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.309E-11 + RS = 0.1 + N = 78.79 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.438E-12 + RS = 1.031 + N = 0.8781 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.783E-13 + RS = 0.109 + N = 1.153 + TT = 1.3E-7 + CJO = 2.364E-10 + VJ = 0.6215 + M = 0.3444 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= -15 .SUBCKT D1N4468/-15C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.33 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 4.951E-10 + RS = 0.05 + N = 66.16 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.041E-12 + RS = 0.7303 + N = 1.158 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.368E-9 + RS = 0.1322 + N = 1.495 + TT = 5.0E-9 + CJO = 2.455E-10 + VJ = 0.6305 + M = 0.3531 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= -55 .SUBCKT D1N4468/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.11 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.404E-12 + RS = 0.7659 + N = 69.72 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 8.408E-13 + RS = 0.7997 + N = 1.145 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.661E-13 + RS = 0.2267 + N = 1.165 + TT = 1.5E-7 + CJO = 2.300E-10 + VJ = 0.6156 + M = 0.3304 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= -55 .SUBCKT D1N4468/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.24 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.659E-11 + RS = 0.05 + N = 60.52 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.375E-6 + RS = 1.252 + N = 1.050 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.195E-9 + RS = 0.1509 + N = 1.539 + TT = 1.52E-8 + CJO = 2.377E-10 + VJ = 0.600 + M = 0.3280 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= 125 * .SUBCKT D1N4468/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.825 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.743E-8 + RS = 0.1102 + N = 163.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 9.599E-20 + RS = 0.8671 + N = 0.8097 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.781E-14 + RS = 0.0868 + N = 1.115 + TT = 5.50E-8 + CJO = 2.835E-10 + VJ = 0.2676 + M = 0.3041 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N4468/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 13.01 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1E-6 + RS = 3.851E-3 + N = 99.81 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.119E-12 + RS = 1.454 + N = 0.8624 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.181E-10 + RS = 0.0661 + N = 1.445 + TT = 0 + CJO = 2.940E-10 + VJ = 0.2689 + M = 0.3078 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4468 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * * PARAMETER SETS EXTRACTED FROM MEASURED DATA. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM * THIS TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * RAD: PRE * TEMP= 27 .SUBCKT D1N4468/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.17 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.504E-10 + RS = 0.8833 + N = 87.06 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.763E-12 + RS = 0.9004 + N = 0.8829 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.432E-13 + RS = 0.1 + N = 1.149 + TT = 1.1E-7 + CJO = 2.457E-10 + VJ = 0.616 + M = 0.3608 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4468 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 8 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. PARAMETER SETS EXTRACTED FROM MEASURED * DATA. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * RAD: 5.78E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4468/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.16 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.419E-10 + RS = 0.1 + N = 88.24 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.789E-12 + RS = 0.924 + N = 0.8315 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 9.644E-13 + RS = 0.0600 + N = 1.210 + TT = 7.24E-8 + CJO = 2.528E-10 + VJ = 0.6036 + M = 0.3617 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 2.15E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4468/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.09 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 6.397E-9 + RS = 0.1 + N = 84.34 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.677E-12 + RS = 0.8757 + N = 0.8812 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.950E-10 + RS = 0.0868 + N = 1.422 + TT = 6.0E-9 + CJO = 2.752E-10 + VJ = 0.6077 + M = 0.3637 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4468/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.89 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.222E-8 + RS = 0.05 + N = 76.26 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.809E-12 + RS = 0.7467 + N = 1.030 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.320E-9 + RS = 0.1169 + N = 1.503 + TT = 0 + CJO = 2.584E-10 + VJ = 0.4127758 + M = 0.3120 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 1.06E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4468/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.22 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.551E-8 + RS = 0.0408 + N = 78.60 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.131E-11 + RS = 1.086 + N = 1.158 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.229E-8 + RS = 0.0898 + N = 1.656 + TT = 0 + CJO = 2.984E-10 + VJ = 0.4100 + M = 0.3089 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= 75 * .SUBCKT D1N4468/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.77 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 4.668E-9 + RS = 2.471 + N = 160.7 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 5.990E-13 + RS = 0.9807 + N = 0.7313 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 6.136E-14 + RS = 0.0935 + N = 1.115 + TT = 1.0E-7 + CJO = 2.601E-10 + VJ = 0.3815 + M = 0.3142 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 75 .SUBCKT D1N4468/75C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.45 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.140E-7 + RS = 0.05 + N = 91.28 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.763E-12 + RS = 0.8301 + N = 0.9394 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 6.535E-10 + RS = 0.1241 + N = 1.441 + TT = 0 + CJO = 2.712E-10 + VJ = 0.3377 + M = 0.3070 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4468 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL. THE MODEL IS INTENDED FOR * USE FROM -55 C TO 125 C. NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS * USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL DEVICES AND * SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT SPECIFICATION. * * ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N4468/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 7.91 RC 2 1 1.533 TC = 5.76E-4, -4.63E-8 * .MODEL DBLOCK D( + IS = 1.0E-12 + RS = 0 + N = .889 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.5E-10 + RS = 0 + N = 87.1 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 4.79893362 + XTI = 826 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 * + ) .MODEL DFOR D( + IS = 1.432E-13 + RS = 0.1 + N = 1.149 + TT = 1.1E-7 + CJO = 2.457E-10 + VJ = 0.616 + M = 0.3608 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ .model D1n4469 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=920p M=.3333 + Vj=.75 Fc=.5 Isr=19.45n Nr=2 Bv=15.06 Ibv=.1709 Tt=144.3n) *$ .model D1n4470 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=920p M=.3333 + Vj=.75 Fc=.5 Isr=19.06n Nr=2 Bv=16.06 Ibv=.1686 Tt=144.3n) *$ .model D1N4471 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=910p M=.3333 + Vj=.75 Fc=.5 Isr=18.36n Nr=2 Bv=18.06 Ibv=.1695 Tt=144.3n) *$ .model D1n4472 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=900p M=.3333 + Vj=.75 Fc=.5 Isr=17.76n Nr=2 Bv=20.07 Ibv=.1739 Tt=144.3n) *$ .model D1n4473 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=880p M=.3333 + Vj=.75 Fc=.5 Isr=17.22n Nr=2 Bv=22.07 Ibv=.1618 Tt=144.3n) *$ .model D1n4474 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=880p M=.3333 + Vj=.75 Fc=.5 Isr=16.75n Nr=2 Bv=24.07 Ibv=.1549 Tt=144.3n) *$ .model D1n4475 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=880p M=.3333 + Vj=.75 Fc=.5 Isr=16.13n Nr=2 Bv=27.07 Ibv=.1521 Tt=144.3n) *$ .model D1n4476 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=850p M=.3333 + Vj=.75 Fc=.5 Isr=15.59n Nr=2 Bv=30.07 Ibv=.1529 Tt=144.3n) *$ .model D1n4477 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=840p M=.3333 + Vj=.75 Fc=.5 Isr=15.12n Nr=2 Bv=33.07 Ibv=.1385 Tt=144.3n) *$ .model D1n4478 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=820p M=.3333 + Vj=.75 Fc=.5 Isr=14.7n Nr=2 Bv=36.08 Ibv=.1374 Tt=144.3n) *$ .model D1n4479 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=810p M=.3333 + Vj=.75 Fc=.5 Isr=14.32n Nr=2 Bv=39.08 Ibv=.1331 Tt=144.3n) *$ .model D1n4480 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=790p M=.3333 + Vj=.75 Fc=.5 Isr=13.87n Nr=2 Bv=43.07 Ibv=.108 Tt=144.3n) *$ .model D1n4481 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=770p M=.3333 + Vj=.75 Fc=.5 Isr=13.48n Nr=2 Bv=47.07 Ibv=94.24m Tt=144.3n) *$ .model D1n4482 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=750p M=.3333 + Vj=.75 Fc=.5 Isr=13.12n Nr=2 Bv=51.07 Ibv=86.36m Tt=144.3n) *$ .model D1n4483 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=720p M=.3333 + Vj=.75 Fc=.5 Isr=63.61n Nr=2 Bv=56.07 Ibv=82.23m Tt=144.3n) *$ .model D1n4484 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=690p M=.3333 + Vj=.75 Fc=.5 Isr=61.52n Nr=2 Bv=62.08 Ibv=80.93m Tt=144.3n) *$ .model D1n4485 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=660p M=.3333 + Vj=.75 Fc=.5 Isr=59.68n Nr=2 Bv=68.08 Ibv=69.97m Tt=144.3n) *$ .model D1n4486 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=630p M=.3333 + Vj=.75 Fc=.5 Isr=57.66n Nr=2 Bv=75.07 Ibv=60.34m Tt=144.3n) *$ .model D1n4487 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=600p M=.3333 + Vj=.75 Fc=.5 Isr=56.11n Nr=2 Bv=82.07 Ibv=53.92m Tt=144.3n) *$ .model D1N4488 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=600p M=.3333 + Vj=.75 Fc=.5 Isr=54.22n Nr=2 Bv=91.07 Ibv=46.21m Tt=144.3n) *$ .model D1N4489 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=560p M=.3333 + Vj=.75 Fc=.5 Isr=52.56n Nr=2 Bv=100.1 Ibv=41.4m Tt=144.3n) *$ .model D1N4490 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=500p M=.3333 + Vj=.75 Fc=.5 Isr=50.93n Nr=2 Bv=110.1 Ibv=43.12m Tt=144.3n) *$ .model D1N4491 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=440p M=.3333 + Vj=.75 Fc=.5 Isr=49.49n Nr=2 Bv=120.1 Ibv=32.34m Tt=144.3n) *$ .model D1N4492 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=380p M=.3333 + Vj=.75 Fc=.5 Isr=48.19n Nr=2 Bv=130.1 Ibv=27.23m Tt=144.3n) *$ .model D1N4493 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=300p M=.3333 + Vj=.75 Fc=.5 Isr=45.96n Nr=2 Bv=150.1 Ibv=21.74m Tt=144.3n) *$ .model D1N4494 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=240p M=.3333 + Vj=.75 Fc=.5 Isr=44.99n Nr=2 Bv=160.1 Ibv=16.17m Tt=144.3n) *$ .model D1N4495 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=200p M=.3333 + Vj=.75 Fc=.5 Isr=43.27n Nr=2 Bv=180.1 Ibv=14.21m Tt=144.3n) *$ .model D1N4496 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=125p M=.3333 + Vj=.75 Fc=.5 Isr=41.78n Nr=2 Bv=200.1 Ibv=14.37m Tt=144.3n) *$ .model D1N4531 D(Is=168.1E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4p M=.3333 + Vj=.75 Fc=.5 Isr=8.267n Nr=2 Bv=75 Ibv=5u Tt=25.95n) *$ .model D1N4532 D(Is=168.1E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=24.54n Nr=2 Bv=75 Ibv=5u Tt=5.771n) *$ .model D1N4533 D(Is=0.1p Rs=6 CJO=1p Tt=3n Bv=70 Ibv=0.1p) * 85-??-?? Original library *$ .model D1N4534 D(Is=260.5E-18 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2p M=.3333 + Vj=.75 Fc=.5 Isr=12.27n Nr=2 Bv=50 Ibv=100u Tt=2.885n) *$ .model D1N4536 D(Is=544.7E-21 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4p M=.3333 + Vj=.75 Fc=.5 Isr=33.07n Nr=2 Bv=35 Ibv=5u Tt=2.885n) *$ * * MEASURED TRR = 135.50NS, SIMULATED TRR = 108.20NS. * * RAD: PRERAD * TEMP= -15 * .SUBCKT D1N4883/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.92 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.33696E-10 + RS = 0.0549465 + N = 89.138441 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.97215E-10 + RS = 0.4588389 + N = 0.6912608 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.17294E-13 + RS = 0.0817365 + N = 1.1769107 + TT = 1.0257E-7 + CJO = 2.60542E-10 + VJ = 0.6407164 + M = 0.3543371 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ *$ * * MEASURED TRR = 162.25NS, SIMULATED TRR = 125.40NS. * * RAD: PRERAD * TEMP= -55 * .SUBCKT D1N4883/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.40 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.0216E-10 + RS = 0.0549465 + N = 97.8836591 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 9.94255E-11 + RS = 0.3848094 + N = 0.931313 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.34034E-13 + RS = 0.0991687 + N = 1.2020537 + TT = 1.2980E-7 + CJO = 2.53073E-10 + VJ = 0.600082 + M = 0.3291898 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 66.75NS, SIMULATED TRR = 61.13NS. * * RAD: 5.29E14 * TYPE: NEUTRON * TEMP= -55 * * .SUBCKT D1N4883/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.57 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.16379E-11 + RS = 0.0603696 + N = 62.5591437 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.16615E-8 + RS = 0.2390426 + N = 1.325631 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.22493E-8 + RS = 0.1047875 + N = 1.6206031 + TT = 2.163E-8 + CJO = 3.2621E-10 + VJ = 0.6146646 + M = 0.3423415 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 99.33NS, SIMULATED TRR = 108.6NS. * * RAD: PRERAD * TEMP= 125 * .SUBCKT D1N4883/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.99 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.50217E-8 + RS = 0.0549465 + N = 82.9979788 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.00004E-19 + RS = 0.6020582 + N = 0.6093854 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.32236E-13 + RS = 0.05779 + N = 1.1372725 + TT = 6.623E-8 + CJO = 3.11054E-10 + VJ = 0.35 + M = 0.3398407 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * * MEASURED TRR = 57.25NS, SIMULATED TRR = 55.43NS. * * RAD: 5.29E14 * TYPE: NEUTRON * TEMP= 125 * * .SUBCKT D1N4883/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.92 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5E-7 + RS = 0.0604 + N = 70 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.97573E-14 + RS = 0.2083187 + N = 1.0470646 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.11603E-10 + RS = 0.063207 + N = 1.3274135 + TT = 3.000E-9 + CJO = 3.90783E-10 + VJ = 0.4 + M = 0.3541483 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4883 * TYPE: DIODE * SUBTYPE:VOLTAGE_REG_GP * THIS FILE CONTAINS 5 PARAMETER SETS OF NON-IRRADIATED DEVICES AT VARIOUS * TEMPERATURES. PARAMETER MODELS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * * MEASURED TRR = 120.50NS, SIMULATED TRR = 100.40NS. * * RAD: PRERAD * TEMP= 27 * .SUBCKT D1N4883/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.32 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.95053E-10 + RS = 0.0549465 + N = 80.8460628 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.96847E-10 + RS = 0.3137005 + N = 0.8662591 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.81314E-13 + RS = 0.0710592 + N = 1.1825864 + TT = 8.757E-8 + CJO = 2.70231E-10 + VJ = 0.6002737 + M = 0.3600673 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 47.46NS, SIMULATED TRR = 49.00NS. * * RAD: 2.18E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N4883/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.28 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.89126E-9 + RS = 0.0848337 + N = 64.5571271 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-9 + RS = 0.3789758 + N = 0.9545003 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.981019E-10 + RS = 0.0936874 + N = 1.4583612 + TT = 2.000E-8 + CJO = 2.501814E-10 + VJ = 0.4048599 + M = 0.3201048 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4883 * TYPE: DIODE * SUBTYPE:VOLTAGE_REG_GP * THE FOLLOWING SECTION CONTAINS 6 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM * THIS TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 81.00NS, SIMULATED TRR = 91.47NS. * * RAD: 2.2E13 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N4883/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.35 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.43E-9 + RS = 0.0798355 + N = 71.965 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.494114E-11 + RS = 0.3526769 + N = 0.7517583 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.106257E-11 + RS = 0.083692 + N = 1.3108789 + TT = 6.2E-8 + CJO = 3.353895E-10 + VJ = 0.4044767 + M = 0.323948 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * * MEASURED TRR = 59.25NS, SIMULATED TRR = 55.72NS. * * RAD: 1.06E15 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N4883/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.28 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.06782E-8 + RS = 0.0497895 + N = 67.9921178 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5.25602E-12 + RS = 0.4153329 + N = 0.7682543 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.64483E-9 + RS = 0.0627487 + N = 1.5161172 + TT = 3.000E-9 + CJO = 3.77259E-10 + VJ = 0.4 + M = 0.3193536 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 58.25NS, SIMULATED TRR = 54.39NS. * * RAD: 5.29E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N4883/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.6587E-8 + RS = 0.0603696 + N = 68.6321719 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.2332E-9 + RS = 0.2784525 + N = 1.0219232 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.62585E-9 + RS = 0.0803513 + N = 1.4765392 + TT = 5.000E-9 + CJO = 3.52304E-10 + VJ = 0.4 + M = 0.311707 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 107.75NS, SIMULATED TRR = 95.67NS. * * RAD: PRERAD * TEMP= 75 * .SUBCKT D1N4883/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.51 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.41776E-9 + RS = 0.0549465 + N = 80.9250573 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.26968E-19 + RS = 0.4610873 + N = 0.6263676 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.5652E-13 + RS = 0.0633942 + N = 1.1404541 + TT = 7.475E-8 + CJO = 2.86614E-10 + VJ = 0.3559094 + M = 0.3095685 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS A TEMPERATURE TRACKING MODEL. THE MODEL IS INTENDED FOR USE * FROM -55 C TO 125 C. NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. *** CAUTION: THE SIMULATED TRR RANGES FROM 70 TO 110% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N4883/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 137.4335 RC 2 1 .0768286 TC = 4.086352E-04 , -1.73474E-07 * .MODEL DBLOCK D( + IS = 9.041354E-13 + RS = 0 + N = 1.843196 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .2095625 + XTI = -2.285844 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 8.779967E-10 + RS = 0 + N = 76.49002 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = 815.6081 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 3.81314E-13 + RS = .0710592 + N = 1.1825864 + TT = 8.757E-8 + CJO = 2.70231E-100 + VJ = .60027375 + M = .3600673 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * RAD: PRE * TEMP= -15 .SUBCKT D1N4884/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 18.12 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 4.963E-15 + RS = 1.073E-4 + N = 58.81 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.106E-12 + RS = 1.455 + N = 1.237 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.258E-13 + RS = 0.2467 + N = 1.197 + TT = 1.09E-7 + CJO = 1.433E-10 + VJ = 0.6271 + M = 0.3437 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= -15 .SUBCKT D1N4884/-15C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 18.51 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 7.787E-11 + RS = 0.1 + N = 100.5 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.276E-12 + RS = 1.695 + N = 1.444 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 9.365E-10 + RS = 0.2158 + N = 1.466 + TT = 7.0E-9 + CJO = 1.378E-10 + VJ = 0.6061 + M = 0.3335 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= -55 .SUBCKT D1N4884/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 17.41 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.376E-16 + RS = 0.0197 + N = 66.36 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.244E-12 + RS = 1.794 + N = 1.207 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.069E-13 + RS = 0.3320 + N = 1.182 + TT = 9.8E-8 + CJO = 1.385E-10 + VJ = 0.6323 + M = 0.3296 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= -55 .SUBCKT D1N4884/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 17.81 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.523E-12 + RS = 0.1 + N = 92.53 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 6.526E-12 + RS = 1.628 + N = 1.517 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.232E-9 + RS = 0.2271 + N = 1.494 + TT = 1.0E-8 + CJO = 1.330E-10 + VJ = 0.6343 + M = 0.3244 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= 125 .SUBCKT D1N4884/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 20.61 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.724E-8 + RS = 4.392 + N = 159.9 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.445E-12 + RS = 2.223 + N = 1.072 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.997E-13 + RS = 0.2168 + N = 1.158 + TT = 1.65E-7 + CJO = 1.775E-10 + VJ = 0.3500 + M = 0.3506 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N4884/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 20.98 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 3.338E-7 + RS = 1.562 + N = 127.7 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.795E-12 + RS = 1.814 + N = 1.276 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 7.014E-10 + RS = 0.2148 + N = 1.455 + TT = 0.0 + CJO = 1.711E-10 + VJ = 0.350 + M = 0.3431 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4884 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING FILE CONTAINS 5 MODELS AT VARIOUS TEMPERATURES. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * * RAD: PRE * TEMP= 27 * .SUBCKT D1N4884/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 18.88 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.869E-10 + RS = 0.1 + N = 278.7 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1E-12 + RS = 1.725 + N = 1.138 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.015E-13 + RS = 0.2370 + N = 1.189 + TT = 1.1520E-7 + CJO = 1.500E-10 + VJ = 0.6005 + M = 0.3582 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4884 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING FILE CONTAINS 8 MODELS AT VARIOUS RADIATION LEVELS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * * * RAD: 5.78E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4884/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 19.11 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 3.450E-11 + RS = 0.2453 + N = 105.2 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.399E-12 + RS = 2.077 + N = 0.9187 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.685E-12 + RS = 0.2221 + N = 1.221 + TT = 5.680E-8 + CJO = 1.921E-10 + VJ = 0.6122 + M = 0.3559 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 1.06E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4884/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 19.12 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.081E-9 + RS = 0 + N = 86.70 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.956E-12 + RS = 1.660 + N = 1.766 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.416E-10 + RS = 0.2834 + N = 1.356 + TT = 2.8E-9 + CJO = 1.453E-10 + VJ = 0.4172 + M = 0.3097 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 2.15E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4884/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 18.88 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.004E-9 + RS = 0.1 + N = 106.5 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.933E-12 + RS = 1.618 + N = 1.511 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 3.201E-10 + RS = 0.2556 + N = 1.4257 + TT = 2.4E-9 + CJO = 1.641E-10 + VJ = 0.6113 + M = 0.3578 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N4884/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 19.28 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.117E-9 + RS = 0.1011 + N = 95.33 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.342E-12 + RS = 2.293 + N = 1.363 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.529E-10 + RS = 0.2342 + N = 1.411 + TT = 2.8E-9 + CJO = 1.442E-10 + VJ = 0.6043 + M = 0.3539 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= 75 .SUBCKT D1N4884/75C 99 2 D1 2 88499 DLEAK R1 2 99 1E12 V2 5 99 19.66 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 5.498E-10 + RS = 0.2537 + N = 119.3 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 6.422E-13 + RS = 1.800 + N = 1.181 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.867E-13 + RS = 0.2293 + N = 1.154 + TT = 1.39E-7 + CJO = 1.606E-10 + VJ = 0.3500 + M = 0.3102 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 75 .SUBCKT D1N4884/75C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 20.16 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 5.779E-8 + RS = 0.1 + N = 126.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.047E-12 + RS = 2.290 + N = 1.268 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.588E-10 + RS = 0.2384 + N = 1.428 + TT = 5.0E-9 + CJO = 1.551E-10 + VJ = 0.3290 + M = 0.3015 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4884 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N4884 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 6.37 RC 2 1 3 TC = 7.03E-04 , -2.87E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 1.167 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 6.950E-12 + RS = 0 + N = 100 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 3.49811005 + XTI = 2145 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.015E-13 + RS = 0.2370 + N = 1.189 + TT = 1.1520E-7 + CJO = 1.500E-10 + VJ = 0.6005 + M = 0.3582 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MANUFACTURER PART NO. = 1N4901A * THE FOLLOWING MODEL WAS EXTRACTED FROM MEASURED DATA AND IS * INTENDED TO SIMULATE THE DC REVERSE BIASED OPERATION OF THE * TEMPERATURE COMPENSATED ZENER DIODE FROM -55 C TO 125 C. .SUBCKT D1N4901 4 1 DC 1 2 DCOMP EC 2 4 POLY(1) 3 4 9.519 1 G1 4 3 POLY(1) 1 2 1.05 -.325 R1 3 4 1 TC=7E-3,-2.53E-5 D2 1 4 DLEAK .MODEL DCOMP D( + IS = 1E-12 + RS = 1 + N = 6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 3 + XTI = 8 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DLEAK D ( + IS = 7.3E-14 + RS = 20 + N = 24.8 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 10.67 + XTI = 106 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ .model D1N4933 D(Is=7.303f Rs=39.41m Ikf=8.427m N=1 Xti=3 Eg=1.11 Cjo=28.09p + M=.4422 Vj=.75 Fc=.5 Isr=77.55n Nr=2 Tt=53.73n) * Motorola pid=1N4933 case=59-04 * 88-09-01 rmn * 90-01-09 pwt update Tt: Trr=120ns, If=10A, Ir=1.2A, Rl=4 *$ .model D1N4934 D(Is=7.303f Rs=39.41m Ikf=8.427m N=1 Xti=3 Eg=1.11 Cjo=28.09p + M=.4422 Vj=.75 Fc=.5 Isr=59.55n Nr=2 Tt=53.73n) * Motorola pid=1N4933 case=59-04 * 88-09-01 rmn * 90-01-09 pwt update Tt: Trr=120ns, If=10A, Ir=1.2A, Rl=4 *$ .model D1N4935 D(Is=7.303f Rs=39.41m Ikf=8.427m N=1 Xti=3 Eg=1.11 Cjo=28.09p + M=.4422 Vj=.75 Fc=.5 Isr=50.66n Nr=2 Tt=53.73n) * Motorola pid=1N4933 case=59-04 * 88-09-01 rmn * 90-01-09 pwt update Tt: Trr=120ns, If=10A, Ir=1.2A, Rl=4 *$ .model D1N4936 D(Is=7.303f Rs=39.41m Ikf=8.427m N=1 Xti=3 Eg=1.11 Cjo=28.09p + M=.4422 Vj=.75 Fc=.5 Isr=47.26n Nr=2 Tt=53.73n) * Motorola pid=1N4933 case=59-04 * 88-09-01 rmn * 90-01-09 pwt update Tt: Trr=120ns, If=10A, Ir=1.2A, Rl=4 *$ .model D1N4937 D(Is=7.303f Rs=39.41m Ikf=8.427m N=1 Xti=3 Eg=1.11 Cjo=28.09p + M=.4422 Vj=.75 Fc=.5 Isr=49.4n Nr=2 Tt=53.73n) * Motorola pid=1N4933 case=59-04 * 88-09-01 rmn * 90-01-09 pwt update Tt: Trr=120ns, If=10A, Ir=1.2A, Rl=4 *$ .model D1N4938 D(Is=2.38E-18 N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1p M=.3333 + Vj=.75 Fc=.5 Isr=100p Nr=2 Bv=200 Ibv=100u Tt=72.13n) *$ .model D1n4954 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4n M=.3333 Vj=.75 + Fc=.5 Isr=75.21u Nr=2 Bv=6.781 Ibv=.1642 Tt=144.3n) *$ .model D1n4955 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4n M=.3333 Vj=.75 + Fc=.5 Isr=48.81u Nr=2 Bv=7.469 Ibv=.1056 Tt=144.3n) *$ .model D1n4956 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4n M=.3333 Vj=.75 + Fc=.5 Isr=23.81u Nr=2 Bv=8.18 Ibv=.1232 Tt=144.3n) *$ .model D1n4957 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4n M=.3333 Vj=.75 + Fc=.5 Isr=11.53u Nr=2 Bv=9.072 Ibv=90.75m Tt=144.3n) *$ .model D1n4958 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=4n M=.3333 Vj=.75 + Fc=.5 Isr=11.2u Nr=2 Bv=9.984 Ibv=.1089 Tt=144.3n) *$ .model D1n4959 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.9n M=.3333 + Vj=.75 Fc=.5 Isr=4.344u Nr=2 Bv=10.98 Ibv=86.21m Tt=144.3n) *$ .model D1N4960 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.88p M=.3333 + Vj=.75 Fc=.5 Isr=4.239u Nr=2 Bv=11.99 Ibv=.1078 Tt=144.3n) *$ .model D1n4961 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.9n M=.3333 + Vj=.75 Fc=.5 Isr=4.13u Nr=2 Bv=12.99 Ibv=89.19m Tt=144.3n) *$ .model D1n4962 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.9n M=.3333 + Vj=.75 Fc=.5 Isr=1.976u Nr=2 Bv=15 Ibv=.1014 Tt=144.3n) *$ .model D1n4963 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.9n M=.3333 + Vj=.75 Fc=.5 Isr=1.935u Nr=2 Bv=16 Ibv=.1014 Tt=144.3n) *$ .model D1n4964 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.9n M=.3333 + Vj=.75 Fc=.5 Isr=1.865u Nr=2 Bv=18.01 Ibv=.102 Tt=144.3n) *$ .model D1n4965 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.87n M=.3333 + Vj=.75 Fc=.5 Isr=721.9n Nr=2 Bv=20 Ibv=90.43m Tt=144.3n) *$ .model D1n4966 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.85n M=.3333 + Vj=.75 Fc=.5 Isr=700.6n Nr=2 Bv=22.01 Ibv=.1056 Tt=144.3n) *$ .model D1n4967 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.83n M=.3333 + Vj=.75 Fc=.5 Isr=681.6n Nr=2 Bv=24.01 Ibv=.1056 Tt=144.3n) *$ .model D1n4968 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.8n M=.3333 + Vj=.75 Fc=.5 Isr=655.1n Nr=2 Bv=27.01 Ibv=87.68m Tt=144.3n) *$ .model D1n4969 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.77n M=.3333 + Vj=.75 Fc=.5 Isr=634n Nr=2 Bv=30.01 Ibv=81.85m Tt=144.3n) *$ .model D1n4970 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.73n M=.3333 + Vj=.75 Fc=.5 Isr=614.6n Nr=2 Bv=33.01 Ibv=65.31m Tt=144.3n) *$ .model D1n4971 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.7n M=.3333 + Vj=.75 Fc=.5 Isr=597.4n Nr=2 Bv=36.02 Ibv=79.1m Tt=144.3n) *$ .model D1n4972 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.67n M=.3333 + Vj=.75 Fc=.5 Isr=582n Nr=2 Bv=39.02 Ibv=62.02m Tt=144.3n) *$ * * RAD: PRE * TEMP= -55 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 178.5NS, SIMULATED TRR = 165.8NS. .SUBCKT D1N4972/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 34.31 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.68585E-12 + RS = 0.1052471 + N = 206.7897924 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.39815E-9 + RS = 0.8577728 + N = 0.8726256 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.66701E-12 + RS = 0.1284924 + N = 1.1904098 + TT = 1.395E-7 + CJO = 4.63966E-10 + VJ = 0.7010351 + M = 0.3297838 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP: 125 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 474.0NS, SIMULATED TRR = 279.3NS. .SUBCKT D1N4972/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 40.61 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.3E-8 + RS = 1E-3 + N = 219.1106048 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.55622E-19 + RS = 1.707823 + N = 0.467603 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.22297E-13 + RS = 0.116133 + N = 1.1148095 + TT = 2.500E-7 + CJO = 6.34833E-10 + VJ = 0.35 + M = 0.3655184 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4972 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 3 PRE-RAD MODELS AT VARIOUS TEMPS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE * MEASURED TRR = 291.5NS, SIMULATED TRR = 228.3NS. * RAD: PRE * TEMP= 27 .SUBCKT D1N4972/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 37.41 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.35655E-12 + RS = 0.1052471 + N = 117.7055553 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.92618E-9 + RS = 0.6487153 + N = 0.8104903 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.47399E-12 + RS = 0.106974 + N = 1.1801483 + TT = 2.264E-7 + CJO = 5.05295E-10 + VJ = 0.6335948 + M = 0.3538478 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRERAD * TEMP= -55 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE * MEASURED TRR = 663.0NS, SIMULATED TRR = 391.6NS. .SUBCKT D1N4977/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 57.96 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.709085E-11 + RS = 0.0609964 + N = 900.6294617 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 14.0681415 + N = 1.1046144 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.365348E-12 + RS = 0.0281412 + N = 1.183285 + TT = 4.91E-7 + CJO = 2.997109E-10 + VJ = 0.6740052 + M = 0.3281168 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRERAD * TEMP= 125 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 3.00US, SIMULATED TRR = 1.375US. .SUBCKT D1N4977/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 67.89 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.371464E-9 + RS = 0.0385922 + N = 424.2901273 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.301195E-19 + RS = 16.3129139 + N = 0.9164559 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.360472E-13 + RS = 0.0336061 + N = 1.1050701 + TT = 1.414E-6 + CJO = 4.165236E-10 + VJ = 0.35 + M = 0.3763707 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4977 * MANUFACTURERS PART NO. = 1N4977JTXV * TYPE: DIODE * SUBTYPE: VOLTAGE-REG-GP * THIS FILE CONTAINS 4 PRE-RAD MODELS OF THE 1N4977JTXV DIODE. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * RAD: PRE * TEMP= 27 * MEASURED TRR = 1.826US, SIMULATED TRR = 562.7NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. .SUBCKT D1N4977/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 62.97 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-10 + RS = 0.0298521 + N = 463.3167133 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.27954E-12 + RS = 23.4102394 + N = 0.6633787 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.92128E-13 + RS = 0.0277338 + N = 1.1245472 + TT = 7.49E-7 + CJO = 3.30209E-10 + VJ = 0.6073145 + M = 0.3574466 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * RAD: PRERAD * TEMP= 75 *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE * MEASURED TRR = 2.47US, SIMULATED TRR = 1.012US. .SUBCKT D1N4977/75C 99 2 D1 2 99 DLEAK R1 2 99 3E9 V2 5 99 64.971 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-12 + RS = 1E-3 + N = 178 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-17 + RS = 5.2295291 + N = 1.3803991 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.435045E-13 + RS = 0.0281772 + N = 1.1201273 + TT = 1.35E-6 + CJO = 3.56832E-10 + VJ = 0.3944424 + M = 0.3248864 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N4997 * MANUFACTURERS PART NO. = IN4977JTXV * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS A TEMPERATURE TRACKING MODEL OF THE 1N4977 WHICH WAS * CONSTRUCTED FROM MEASURED DATA. THE MODEL IS INTENDED * FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. .SUBCKT D1N4977/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 4.705296 RC 2 1 13.35362 TC = 8.173053E-04 , -7.195472E-07 * .MODEL DBLOCK D( + IS = 8.703424E-13 + N = .9313751 + RS = .147365 + EG = .103192 + XTI = -1.858972 + CJO = 0 + BV = 1E5 ) * .MODEL DLEAK D( + IS = 2.861522E-11 + N = 398.0562 + RS = 1.532324E-02 + EG = .1018647 + XTI = 8017.72 + CJO = 0 + BV = 1E5 +) * .MODEL DFOR D( + IS = 5.92128E-13 + N = 1.1245472 + RS = .0277338 + EG = 1.11 + XTI = 3 + CJO = 3.30209E-10 + VJ = .6073145 + M = .3574466 + FC = .5 + TT = 7.49E-7 + BV = 1E5 + ) * .ENDS *$ .model D1n4973 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.63n M=.3333 + Vj=.75 Fc=.5 Isr=564n Nr=2 Bv=43.01 Ibv=43.32m Tt=144.3n) *$ .model D1n4974 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.6n M=.3333 + Vj=.75 Fc=.5 Isr=547.6n Nr=2 Bv=47.01 Ibv=41.55m Tt=144.3n) *$ .model D1n4975 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.56n M=.3333 + Vj=.75 Fc=.5 Isr=533.4n Nr=2 Bv=51.01 Ibv=38.46m Tt=144.3n) *$ .model D1n4976 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.51n M=.3333 + Vj=.75 Fc=.5 Isr=517.3n Nr=2 Bv=56.01 Ibv=37.05m Tt=144.3n) *$ .model D1n4977 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.45n M=.3333 + Vj=.75 Fc=.5 Isr=500.6n Nr=2 Bv=62.01 Ibv=30.86m Tt=144.3n) *$ .model D1n4978 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.35n M=.3333 + Vj=.75 Fc=.5 Isr=485.5n Nr=2 Bv=68 Ibv=25.92m Tt=144.3n) *$ .model D1n4979 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.28n M=.3333 + Vj=.75 Fc=.5 Isr=472.9n Nr=2 Bv=75 Ibv=23.56m Tt=144.3n) *$ .model D1n4980 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.21n M=.3333 + Vj=.75 Fc=.5 Isr=456.9n Nr=2 Bv=82.01 Ibv=21.58m Tt=144.3n) *$ .model D1n4981 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3.12n M=.3333 + Vj=.75 Fc=.5 Isr=441.1n Nr=2 Bv=91 Ibv=19.18m Tt=144.3n) *$ .model D1n4982 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=3n M=.3333 Vj=.75 + Fc=.5 Isr=427.7n Nr=2 Bv=100 Ibv=19.61m Tt=144.3n) *$ .model D1n4983 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2.9n M=.3333 + Vj=.75 Fc=.5 Isr=414.4n Nr=2 Bv=110 Ibv=17.26m Tt=144.3n) *$ .model D1n4984 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2.8n M=.3333 + Vj=.75 Fc=.5 Isr=402.7n Nr=2 Bv=120 Ibv=15.22m Tt=144.3n) *$ .model D1n4985 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2.7n M=.3333 + Vj=.75 Fc=.5 Isr=392.1n Nr=2 Bv=130 Ibv=13.62m Tt=144.3n) *$ .model D1n4986 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2.5n M=.3333 + Vj=.75 Fc=.5 Isr=374n Nr=2 Bv=150 Ibv=9.8m Tt=144.3n) *$ .model D1n4987 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2.4n M=.3333 + Vj=.75 Fc=.5 Isr=366.1n Nr=2 Bv=160 Ibv=9.24m Tt=144.3n) *$ .model D1n4988 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2.2n M=.3333 + Vj=.75 Fc=.5 Isr=352.1n Nr=2 Bv=180 Ibv=11.5m Tt=144.3n) *$ .model D1n4989 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=2n M=.3333 Vj=.75 + Fc=.5 Isr=340n Nr=2 Bv=200 Ibv=10.35m Tt=144.3n) *$ .model D1n4990 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1.8n M=.3333 + Vj=.75 Fc=.5 Isr=329.5n Nr=2 Bv=220 Ibv=9.407m Tt=144.3n) *$ .model D1n4991 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1.6n M=.3333 + Vj=.75 Fc=.5 Isr=320.3n Nr=2 Bv=240 Ibv=7.959m Tt=144.3n) *$ .model D1n4992 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1.3n M=.3333 + Vj=.75 Fc=.5 Isr=307.4n Nr=2 Bv=270 Ibv=6.467m Tt=144.3n) *$ .model D1n4993 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1n M=.3333 Vj=.75 + Fc=.5 Isr=297.2n Nr=2 Bv=300 Ibv=6.807m Tt=144.3n) *$ .model D1n4994 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=700p M=.3333 + Vj=.75 Fc=.5 Isr=287.8n Nr=2 Bv=330 Ibv=5.503m Tt=144.3n) *$ .model D1n4995 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=450p M=.3333 + Vj=.75 Fc=.5 Isr=279.6n Nr=2 Bv=360 Ibv=6.159m Tt=144.3n) *$ .model D1n4996 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=100p M=.3333 + Vj=.75 Fc=.5 Isr=272.2n Nr=2 Bv=390 Ibv=4.79m Tt=144.3n) *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5063 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATIONS. * *** CAUTION: THE SIMULATED TRR RANGES FROM 80 TO 110% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5063 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 123.461 RC 2 1 5.026215E-02 TC = 7.156879E-05 , -2.934908E-07 * .MODEL DBLOCK D( + IS = 1.001055E-12 + RS = 5.568735E-05 + N = 1.221526 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1048899 + XTI = -.9011511 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.800594E-08 + RS = .1102465 + N = 30.96348 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .5636078 + XTI = 296.788 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.247426E-10 + RS = 0.0407272 + N = 1.4229591 + TT = 2E-9 + CJO = 4.487785E-10 + VJ = 0.625406 + M = 0.3148121 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * MEASURED TRR = 78.167NS, SIMULATED TRR = 63.37NS. * * RAD: PRERAD * TEMP= -55 * .SUBCKT D1N5063/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.98 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-9 + RS = 0.0437 + N = 30 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.412722E-10 + RS = 0.1541585 + N = 1.2506135 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.908714E-8 + RS = 0.0212704 + N = 1.9541573 + TT = 2E-9 + CJO = 4.289823E-10 + VJ = 0.7196854 + M = 0.3154472 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 78.0NS, SIMULATED TRR = 87.62NS * * RAD: PRERAD * TEMP= 125 * .SUBCKT D1N5063/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.62 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.147954E-8 + RS = 0.0395399 + N = 25.2853376 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-19 + RS = 0.3043699 + N = 0.7138701 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.921463E-13 + RS = 0.0516232 + N = 1.1780895 + TT = 2E-9 + CJO = 4.798589E-10 + VJ = 0.6043555 + M = 0.3379108 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5063 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 3 PARAMETER SETS OF NON-IRRADIATED DEVICES AT VARIOUS * TEMPERATURES. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * * MEASURED TRR = 78.25NS, SIMULATED TRR = 70.29NS. * * RAD: PRERAD * TEMP= 27 * .SUBCKT D1N5063/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.46 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.831033E-8 + RS = 0.0312785 + N = 29.5259778 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 0.2711952 + N = 0.8000272 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.247426E-10 + RS = 0.0407272 + N = 1.4229591 + TT = 2E-9 + CJO = 4.487785E-10 + VJ = 0.625406 + M = 0.3148121 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5065 * * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMTS OF THE * PRODUCT SPECIFICATION. * * *** CAUTION: THE SIMULATED TRR RANGES FROM 87 TO 115% OF THE MEASURED * TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * * .SUBCKT D1N5065 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 7.51 RC 2 1 1 TC = 2.70E-04 , -7.29E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.954 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 2.130E-09 + RS = 0 + N = 46.8 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 0.81585 + XTI = 513 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.37221E-12 + RS = 0.0374341 + N = 1.2547221 + TT = 3.696E-8 + CJO = 3.71683E-10 + VJ = 0.6021066 + M = 0.3313482 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 81.875NS, SIMULATED TRR = 94.53NS. * * RAD: PRERAD * TEMP= 125 * * .SUBCKT D1N5065/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 8.32 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.92328E-8 + RS = 0.0394666 + N = 45.6229636 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.90123E-19 + RS = 0.6100315 + N = 0.6311677 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.0299E-14 + RS = 0.0447147 + N = 1.1034666 + TT = 3.0645E-8 + CJO = 4.09849E-10 + VJ = 0.360532 + M = 0.3020305 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5065 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THE FOLLOWING SECTION CONTAINS 2 PARAMETER SETS AT POST NEUTRON * RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 63.75NS, SIMULATED TRR = 59.95NS. * * RAD: 2.73E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5065/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.26 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.423315E-9 + RS = 0.0609964 + N = 39.9947653 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.241378E-12 + RS = 0.1 + N = 1.9407469 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.876261E-10 + RS = 0.0619188 + N = 1.4132682 + TT = 5.0E-9 + CJO = 3.783271E-10 + VJ = 0.6042629 + M = 0.3319749 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 79.20NS, SIMULATED TRR = 78.58NS. * * RAD: 2.219E13 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5065/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.93 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.284463E-9 + RS = 0.0377498 + N = 41.1948431 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.234085E-9 + RS = 0.1439738 + N = 1.1673616 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.971577E-12 + RS = 0.0609009 + N = 1.2498016 + TT = 3.5E-8 + CJO = 3.658288E-10 + VJ = 0.6001265 + M = 0.3315063 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5067 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO * RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT * THE REPONSES OF NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE * LIMITS OF THE PRODUCT SPECIFICATION. * *** CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD PORTENTIALLY LEAD TO ERRORS IN CKT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5067 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 16.49639 RC 2 1 .599842 TC = 4.499518E-04 , 9.397534E-08 * .MODEL DBLOCK D( + IS = 1.268273E-12 + RS = .0088527 + N = 1.371141 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1007347 + XTI = -.387482 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.870527E-10 + RS = .1262351 + N = 55.66678 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1007539 + XTI = 652.1613 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 2.299E-13 + RS = 0.0839 + N = 1.158 + TT = 1.45E-7 + CJO = 3.061E-10 + VJ = 0.4021 + M = 0.3139 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * RAD: PRE * TEMP= -15 * * .SUBCKT D1N5067/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.86 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 4.630E-11 + RS = 0.1 + N = 62.28 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.511E-10 + RS = 0.5681 + N = 0.9161 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.898E-13 + RS = 0.0850 + N = 1.201 + TT = 2.00E-7 + CJO = 2.918E-10 + VJ = 0.6052 + M = 0.3537 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= -15 * * .SUBCKT D1N5067/-15C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.34 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 9.670E-10 + RS = 1E-6 + N = 54.08 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.081E-22 + RS = 0.3496 + N = 1.032 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.048E-9 + RS = 0.0868 + N = 1.501 + TT = 1.0E-8 + CJO = 3.137E-10 + VJ = 0.6690 + M = 0.3656 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= -55 * * .SUBCKT D1N5067/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.37 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 9.698E-12 + RS = 0.1785 + N = 62.70 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.721E-12 + RS = 0.4276 + N = 0.9947 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.769E-13 + RS = 0.3524 + N = 1.167 + TT = 2.43E-7 + CJO = 2.833E-10 + VJ = 0.6184 + M = 0.3437 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= -55 * * .SUBCKT D1N5067/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.50 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 9.431E-11 + RS = 0.1 + N = 56.35 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.168E-12 + RS = 0.377 + N = 1.079 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 5.277E-9 + RS = 0.4379 + N = 1.554 + TT = 2.30E-8 + CJO = 3.0628E-10 + VJ = 0.6085 + M = 0.3357 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ *$ * * RAD: PRE * TEMP= 125 * * .SUBCKT D1N5067/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.03 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.396E-8 + RS = 0.1 + N = 86.69 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 6.859E-23 + RS = 0.2092 + N = 1.047 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.718E-14 + RS = 0.06 + N = 1.079 + TT = 7.5E-8 + CJO = 3.48E-10 + VJ = 0.3500 + M = 0.3462 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 125 * * .SUBCKT D1N5067/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.60 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 8.161E-7 + RS = 0 + N = 71.10 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 5.733E-18 + RS = 0.2459 + N = 1.088 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.329E-10 + RS = 0.0554 + N = 1.382 + TT = 0.0 + CJO = 3.750E-10 + VJ = 0.35 + M = 0.3432 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5067 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * RAD: PRE * TEMP= 27 * * .SUBCKT D1N5067/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.22 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.642E-10 + RS = 0.1 + N = 65.59 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.246E-12 + RS = 0.4573 + N = 0.8144 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.299E-13 + RS = 0.0839 + N = 1.158 + TT = 1.45E-7 + CJO = 3.061E-10 + VJ = 0.4021 + M = 0.3139 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5067 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 8 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * RAD: 5.78E12 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5067/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.96 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.028E-10 + RS = 1E-6 + N = 52.40 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.470E-12 + RS = 0.4195 + N = 0.9795 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.016E-12 + RS = 0.0759 + N = 1.252 + TT = 1.05E-7 + CJO = 2.810E-10 + VJ = 0.4109 + M = 0.3145 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 1.06E15 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5067/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.05 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.876E-8 + RS = 1E-6 + N = 57.10 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.382E-12 + RS = 0.3866 + N = 0.9719 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 6.065E-9 + RS = 0.0914 + N = 1.569 + TT = 0.0 + CJO = 2.878E-10 + VJ = 0.4008 + M = 0.3115 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 2.15E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5067/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.09 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 5.526E-9 + RS = 1E-6 + N = 57.78 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.757E-12 + RS = 0.6231 + N = 0.9897 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.851E-10 + RS = 0.1842 + N = 1.468 + TT = 1.2E-8 + CJO = 2.674E-10 + VJ = 0.4118 + M = 0.3139 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5067/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.33 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.966E-8 + RS = 0.1 + N = 68.49 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.718E-12 + RS = 0.4152 + N = 0.9191 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.495E-9 + RS = 0.0670 + N = 1.475 + TT = 2.05E-9 + CJO = 3.308E-10 + VJ = 0.4085 + M = 0.3112 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= 75 * * .SUBCKT D1N5067/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.67 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 6.079E-9 + RS = 0.1228 + N = 107.4 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.380E-12 + RS = 0.4683 + N = 0.8084 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 8.562E-14 + RS = 0.0667 + N = 1.119 + TT = 1.25E-7 + CJO = 3.208E-10 + VJ = 0.3281 + M = 0.3081 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.39E14 * TYPE: NEUTRON * TEMP= 75 * * .SUBCKT D1N5067/75C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.82 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.692E-7 + RS = 1E-6 + N = 74.38 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 5.742E-12 + RS = 0.3906 + N = 0.8895 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 7.347E-10 + RS = 0.0670 + N = 1.434 + TT = 0.0 + CJO = 3.480E-10 + VJ = 0.35 + M = 0.3147 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5069 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. * *** CAUTION: THE SIMULATED TRR RANGES FROM 78 TO 105% OF THE MEASURED * TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5069 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 8.33 RC 2 1 1.5 TC = 7.12E-04 , -4.40E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.686 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.00E-11 + RS = 0 + N = 61.1 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.38440741 + XTI = 845 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 3.63662E-13 + RS = 0.0997065 + N = 1.185342 + TT = 8.593E-8 + CJO = 2.5575E-10 + VJ = 0.60251 + M = 0.3631192 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 139.5NS, SIMULATED TRR = 108.8NS. * * RAD: PRE * TEMP= -55 * * .SUBCKT D1N5069/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 11.15 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.33357E-13 + RS = 0.0557478 + N = 63.1268991 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.54124E-18 + RS = 0.9019952 + N = 0.8277087 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.39221E-12 + RS = 0.2078357 + N = 1.236703 + TT = 1.1041E-7 + CJO = 2.38996E-10 + VJ = 0.6003687 + M = 0.327572 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 109.875NS, SIMULATED TRR = 114.8NS. * * RAD: PRE * TEMP= 125 * * .SUBCKT D1N5069/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 13.08 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.13511E-9 + RS = 0.0557478 + N = 70.89482 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.02224E-19 + RS = 0.7602634 + N = 0.6748929 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.49264E-14 + RS = 0.0765052 + N = 1.1302636 + TT = 7.7775E-8 + CJO = 2.951E-10 + VJ = 0.35 + M = 0.3433 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5069 * TYPE: DIODE * SUBTYPE:VOLTAGE_REG_GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 115.1NS, SIMULATED TRR = 96.25NS. * * TEMP= 27 * .SUBCKT D1N5069/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.22 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.52989E-12 + RS = 0.0557478 + N = 49.2792219 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-18 + RS = 0.9488272 + N = 0.5560082 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.63662E-13 + RS = 0.0997065 + N = 1.185342 + TT = 8.593E-8 + CJO = 2.5575E-10 + VJ = 0.60251 + M = 0.3631192 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5069 * TYPE: DIODE * SUBTYPE:VOLTAGE_REG_GP * THE FOLLOWING SECTION CONTAINS 2 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 71.10NS, SIMULATED TRR = 80.80NS. * * RAD: 2.2E13 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5069/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.3 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.794381E-10 + RS = 0.1117427 + N = 74.5262923 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.98173E-12 + RS = 0.6375239 + N = 0.8908809 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.0702E-11 + RS = 0.1114862 + N = 1.3063926 + TT = 5.00E-8 + CJO = 3.185167E-10 + VJ = 0.3905495 + M = 0.3266494 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 41.13NS, SIMULATED TRR = 42.18NS. * RAD: 2.18E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5069/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 12.28 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.797407E-9 + RS = 0.1217409 + N = 76.652346 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.757201E-11 + RS = 0.5844222 + N = 1.1184054 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.517125E-10 + RS = 0.1319986 + N = 1.4391953 + TT = 1.000E-8 + CJO = 2.491193E-10 + VJ = 0.435664 + M = 0.3219004 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 104.5NS, SIMULATED TRR = 85.36NS. * * RAD: PRE * TEMP= -15 * .SUBCKT D1N5071/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 14.05 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.49887E-10 + RS = 0.1333832 + N = 109.8492994 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.07199E-9 + RS = 1.1180287 + N = 0.494611 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.46784E-13 + RS = 0.1625959 + N = 1.1662649 + TT = 8.285E-8 + CJO = 1.81221E-10 + VJ = 0.6160646 + M = 0.3431752 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 117.33NS, SIMULATED TRR = 93.69NS. * * RAD: PRE * TEMP= -55 * .SUBCKT D1N5071/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 13.472 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.62267E-10 + RS = 0.1333832 + N = 122.4627448 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.61254E-9 + RS = 1.2830017 + N = 0.5691162 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.86634E-13 + RS = 1.2985598 + N = 1.1939664 + TT = 9.574E-8 + CJO = 1.75949E-10 + VJ = 0.6116184 + M = 0.3286622 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 101.25NS, SIMULATED TRR = 101.2NS. * * RAD: PRE * TEMP= 125 * .SUBCKT D1N5071/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 15.51 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.77539E-8 + RS = 0.1333832 + N = 89.1975458 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.49506E-19 + RS = 1.2610363 + N = 0.5894411 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.32163E-14 + RS = 0.1373973 + N = 1.1151662 + TT = 7.752E-8 + CJO = 2.19186E-10 + VJ = 0.35 + M = 0.3419438 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5071 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTEDH FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 100.0NS, SIMULATED TRR = 82.41NS. * * RAD: PRE * TEMP= 27 .SUBCKT D1N5071/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 14.52 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.394E-9 + RS = 0.1334 + N = 100.5 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.22126E-12 + RS = 0.9520378 + N = 0.5904894 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.56551E-13 + RS = 0.1297082 + N = 1.1509043 + TT = 7.755E-8 + CJO = 1.88433E-10 + VJ = 0.603388 + M = 0.358129 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 100.0NS, SIMULATED TRR = 85.11NS. * * RAD: PRE * TEMP= 75 .SUBCKT D1N5071/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 14.92 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.81487E-9 + RS = 0.1333832 + N = 94.0700725 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.80663E-19 + RS = 1.1560834 + N = 0.5536913 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.49828E-14 + RS = 0.1398204 + N = 1.1279831 + TT = 7.648E-8 + CJO = 2.00778E-10 + VJ = 0.3582397 + M = 0.3098927 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5073 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED FROM * PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. THE * MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS ARE * INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPEICIFICATION. * *** CAUTION: THE SIMULATED TRR RANGES FROM 100 TO 115% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5073 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 8.66 RC 2 1 2 TC = 7.34E-04 , -3.19E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.763 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 2.500E-11 + RS = 0 + N = 103 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 12.2815406 + XTI = 920 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.24503E-13 + RS = 0.1663096 + N = 1.1340381 + TT = 1.740E-7 + CJO = 1.90504E-10 + VJ = 0.3916497 + M = 0.3131873 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 152.64NS, SIMULATED TRR = 156.4NS. * * RAD: PRERAD * TEMP= -55 * .SUBCKT D1N5073/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 16.13 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.32192E-13 + RS = 0.1522097 + N = 118.5819516 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.04128E-12 + RS = 1.7118756 + N = 0.7272662 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.97247E-12 + RS = 0.1618843 + N = 1.2533152 + TT = 1.900E-7 + CJO = 1.7508E-10 + VJ = 0.6183594 + M = 0.342852 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 145.5NS, SIMULATED TRR = 151.2NS. * * RAD: PRERAD * TEMP= 125 * * .SUBCKT D1N5073/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 18.59 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.87596E-10 + RS = 0.1522097 + N = 106.0898101 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.58685E-16 + RS = 1.0335875 + N = 0.9177874 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.6714E-14 + RS = 0.1873928 + N = 1.0708417 + TT = 1.500E-7 + CJO = 2.24861E-10 + VJ = 0.35 + M = 0.3660208 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5073 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 139.4NS, SIMULATED TRR = 148.7NS. * * RAD: PRERAD * TEMP= 27 * .SUBCKT D1N5073/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 17.54 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.37854E-12 + RS = 0.1522097 + N = 83.71221289 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.42243E-11 + RS = 1.8848835 + N = 0.6442021 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.24503E-13 + RS = 0.1663096 + N = 1.1340381 + TT = 1.740E-7 + CJO = 1.90504E-10 + VJ = 0.3916497 + M = 0.3131873 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5073 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 2 MODELS AT VARIOUS RADIATION LEVELS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * * RAD: 2.09E13 * TYPE: NEUTRON * TEMP= 27 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 50.25NS, SIMULATED TRR = 57.94NS. .SUBCKT D1N5073/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 17.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.654451E-10 + RS = 0.2060952 + N = 116.0185845 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5.587243E-13 + RS = 3.4293286 + N = 0.773331 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.156683E-11 + RS = 0.2061735 + N = 1.3173892 + TT = 5.100E-8 + CJO = 1.462817E-10 + VJ = 0.6001817 + M = 0.3601692 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 2.12E14 * TYPE: NEUTRON * TEMP= 27 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 31.20NS, SIMULATED TRR = 31.14NS. .SUBCKT D1N5073/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 17.24 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.270214E-9 + RS = 0.1356057 + N = 115.0386781 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.148856E-11 + RS = 2.5051159 + N = 1.3125771 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.65194E-10 + RS = 0.1439861 + N = 1.4592964 + TT = 9.0E-9 + CJO = 1.752684E-10 + VJ = 0.3896546 + M = 0.3115474 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5073 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 2 MODELS AT VARIOUS RADIATION LEVELS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * * RAD: 2.09E13 * TYPE: NEUTRON * TEMP= 27 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 50.25NS, SIMULATED TRR = 57.94NS. .SUBCKT D1N5073/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 17.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.654451E-10 + RS = 0.2060952 + N = 116.0185845 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5.587243E-13 + RS = 3.4293286 + N = 0.773331 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.156683E-11 + RS = 0.2061735 + N = 1.3173892 + TT = 5.100E-8 + CJO = 1.462817E-10 + VJ = 0.6001817 + M = 0.3601692 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5074 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125C. * NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL * REPRESENT THE RESPONSES OF NOMINAL DEVICES AND SIMULATIONS ARE * ACCURATE WITHIN THE LIMITS OF THE PRODUCT SPECIFICATION. * * *** CAUTION: THE MEASURED TRR RANGES FROM 97 TO 99% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5074 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 10.19899 RC 2 1 2.064405 TC = 7.090279E-04 , -1.64995E-07 * .MODEL DBLOCK D( + IS = 9.841674E-13 + RS = 2.490113E-03 + N = .9486288 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1007624 + XTI = -.3931155 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 5.253941E-11 + RS = .6047307 + N = 205.4172 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1013472 + XTI = 2597.48 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.468651E-13 + RS = .2932612 + N = 1.1404336 + TT = 1.35E-7 + CJO = 1.525455E-10 + VJ = 0.6021379 + M = 0.360357 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * MEASURED TRR = 113.0NS, SIMULATED TRR = 110.6NS. * * RAD: PRERAD * TEMP= -55 * .SUBCKT D1N5074/-55C 99 2 D1 2 99 DLEAK R1 2 99 6E11 V2 5 99 19.53 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-14 + RS = 1.0442306 + N = 110 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.729036E-10 + RS = 1.4691715 + N = 1.0195893 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.3E-12 + RS = 0.2938868 + N = 1.32 + TT = 1.30E-7 + CJO = 1.415135E-10 + VJ = 0.6016659 + M = 0.3269842 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 139.0NS, SIMULATED TRR = 137.70NS. * * RAD: PRERAD * TEMP= 125 * .SUBCKT D1N5074/125C 99 2 D1 2 99 DLEAK R1 2 99 1.5E9 V2 5 99 22.80 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-12 + RS = 0.2875744 + N = 56 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.137972E-21 + RS = 5.4263979 + N = 0.4739324 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.239824E-14 + RS = 0.2923741 + N = 1.0489394 + TT = 1.45E-7 + CJO = 1.79E-10 + VJ = 0.35 + M = 0.3472 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5074 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 3 PARAMETER SETS AT VARIOUS TEMPS. * PARAMETERS EXTRACTED FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 118.1NS, SIMULATED TRR = 116.2NS. * * RAD: PRERAD * TEMP= 27 * .SUBCKT D1N5074/27C 99 2 D1 2 99 DLEAK R1 2 99 3.5E10 V2 5 99 21.28 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5E-14 + RS = 0.2810658 + N = 75 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.232463E-16 + RS = 5.559041 + N = 0.311378 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.468651E-13 + RS = 0.2932612 + N = 1.1404336 + TT = 1.35E-7 + CJO = 1.525455E-10 + VJ = 0.6021379 + M = 0.360357 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5077 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C . NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. * *** CAUTION: THE SIMULATED TRR RANGES FROM 35 TO 65% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5077 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 14.72 RC 2 1 2 TC = 8.59E-04 , -1.87E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.808 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 8.000E-09 + RS = 0 + N = 1000 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 219.019822 + XTI = 23925 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 8.25991E-13 + RS = 0.428689 + N = 1.21978 + TT = 1.277E-7 + CJO = 0.977E-10 + VJ = 0.6880 + M = 0.3650 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 104.75NS, SIMULATED TRR = 66.86NS. * * RAD: PRE * TEMP= -55 * * .SUBCKT D1N5077/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 26.60 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.39089E-13 + RS = 0.0532339 + N = 885.9476724 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.09381E-13 + RS = 2.9277552 + N = 1.0258924 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.93673E-13 + RS = 0.4482566 + N = 1.2636264 + TT = 7.748E-8 + CJO = 0.911E-10 + VJ = 0.6645 + M = 0.3256 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 399.6NS, SIMULATED TRR = 141.8NS. * * RAD: PRE * TEMP= 125 * * .SUBCKT D1N5077/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 31.58 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.06852E-4 + RS = 1.001E-6 + N = 1.8062E5 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.233E-21 + RS = 4.4163784 + N = 0.6017373 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.21588E-12 + RS = 0.4457898 + N = 1.2005383 + TT = 1.728E-7 + CJO = 1.145E-10 + VJ = 0.35 + M = 0.3337 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5077 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 233.6NS, SIMULATED TRR = 95.67NS. * * RAD: PRE * TEMP= 27 * * .SUBCKT D1N5077/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 29.03 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.00193E-8 + RS = 0.05 + N = 5.902E3 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.75611E-13 + RS = 3.6630852 + N = 0.7970774 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.25991E-13 + RS = 0.428689 + N = 1.21978 + TT = 1.277E-7 + CJO = 0.977E-10 + VJ = 0.6880 + M = 0.3650 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5077 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THE FOLLOWING SECTION CONTAINS 2 PARAMETER SETS AT POST NEUTRON * RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 58.50NS, SIMULATED TRR = 66.05NS. * * RAD: 5.78E12 * TYPE: NEUTRON * TEMP: 27 * * .SUBCKT D1N5077/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 29.07 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.48364E-9 + RS = 1E-6 + N = 949.1723658 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.94451E-13 + RS = 4.6687586 + N = 0.8082552 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.87998E-12 + RS = 0.4473763 + N = 1.3070188 + TT = 7.09E-8 + CJO = 1.24752E-10 + VJ = 0.4158752 + M = 0.3094078 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 16.36NS, SIMULATED TRR = 20.49NS. * * RAD: 2.15E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5077/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 29.11 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.36805E-9 + RS = 1E-6 + N = 267.0705798 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.76862E-12 + RS = 4.1541163 + N = 1.0277536 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.5429E-9 + RS = 0.3932201 + N = 1.5876557 + TT = 0.000000 + CJO = 1.27816E-10 + VJ = 0.6426254 + M = 0.3516804 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5079 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE * FROM -55 C TO 125 C. NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS * USING THIS MODEL REPRESENT THE REPONSES OF NOMINAL DEVICES AND * SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR RANGES FROM 30 TO 50% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * IN HIGH SPEED SWITCHING APPLICATIONS. ***ATTENTION: THE CURRENT AT -55 DEG C. IS BELOW THE RESOLUTION OF THE * SOURCE USED TO MAKE THE MEASUREMENTS. THEREFORE THE REAL * CURRENT IS BELOW THE VALUE SHOWN. .SUBCKT D1N5079 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 34.29 RC 2 1 1 TC = 8.06E-4 , -2.72E-7 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 1.15 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.82 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.38E-9 + RS = 0 + N = 816 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 515 + XTI = -4980 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.07646E-12 + RS = 0.305822 + N = 1.2259131 + TT = 1.660E-7 + CJO = 1.05312E-10 + VJ = 0.35 + M = 0.3227551 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 173.5NS, SIMULATED TRR = 85.32NS. * * RAD: PRERAD * TEMP= -15 .SUBCKT D1N5079/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 33.77 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.332E-9 + RS = 0.3723163 + N = 999 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.82697E-11 + RS = 4.5989519 + N = 0.6290187 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.6999E-13 + RS = 0.406099 + N = 1.1898009 + TT = 9.853E-8 + CJO = 8.81243E-11 + VJ = 0.6302105 + M = 0.3261414 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 91.33NS, SIMULATED TRR = 62.33NS. * * RAD: PRERAD * TEMP= -55 .SUBCKT D1N5079/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 32.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.11697E-9 + RS = 0.3723163 + N = 999 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.94E-12 + RS = 4.44 + N = 0.4919 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.42388E-13 + RS = 0.4118467 + N = 1.1904054 + TT = 6.795E-8 + CJO = 8.49487E-11 + VJ = 0.6990247 + M = 0.3257591 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 15.80NS, SIMULATED TRR = 15.31NS. * * RAD: 5.21E14 * TYPE: NEUTRON * TEMP= -55 .SUBCKT D1N5079/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 33.03 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.94372E-12 + RS = 0.6431317 + N = 203.31222 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.5993E-12 + RS = 5.2205858 + N = 1.1663284 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.13145E-9 + RS = 0.5123136 + N = 1.4673684 + TT = 5.822E-9 + CJO = 8.24909E-11 + VJ = 0.6000953 + M = 0.3014575 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 16.00NS, SIMULATED TRR = 19.57NS. * * RAD: 5.21E14 * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N5079/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 37.13 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-6 + RS = 0.4181538 + N = 185.4187564 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.81743E-17 + RS = 4.3751858 + N = 1.8750072 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.22931E-10 + RS = 0.852367 + N = 1.348401 + TT = 5.7E-9 + CJO = 1.0851E-10 + VJ = 0.35 + M = 0.3417375 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5079 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 250.6NS, SIMULATED TRR = 95.7NS. * * RAD: PRERAD * TEMP= 27 .SUBCKT D1N5079/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 35.28 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.889E-9 + RS = 0.4188 + N = 995.4555399 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5.82469E-13 + RS = 5.3271547 + N = 0.4283178 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.18496E-13 + RS = 0.4351743 + N = 1.1832904 + TT = 1.296E-7 + CJO = 9.25253E-11 + VJ = 0.6016536 + M = 0.3397914 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5079 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 6 PARAMETER SETS AT VARIOUS RADIATION LEVELS * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 16.00NS, SIMULATED TRR = 16.13NS. * * RAD: 5.21E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5079/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 35.49 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.55784E-9 + RS = 0.6431317 + N = 272.7016834 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.07554E-12 + RS = 5.9138005 + N = 1.191928 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.14005E-10 + RS = 0.6464092 + N = 1.4115037 + TT = 5.56E-9 + CJO = 9.03117E-11 + VJ = 0.6021072 + M = 0.3440819 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5079 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THE FOLLOWING SECTION CONTAINS 2 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. PARAMETER SETS EXTRACTED FROM MEASURED * DATA. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIAITON FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 29.67NS, SIMULATED TRR = 32.80NS. * * RAD: 2.2E13 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5079/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 34.213 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.96776E-10 + RS = 0.4826744 + N = 304.2482825 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.968386E-18 + RS = 7.7440222 + N = 0.8 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.1233E-11 + RS = 0.4939114 + N = 1.3352885 + TT = 2.192E-8 + CJO = 1.226843E-10 + VJ = 0.3710708 + M = 0.3187057 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 60.20NS, SIMULATED TRR = 44.89NS. * * RAD: 6.67E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5079/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1.129E9 V2 5 99 34.87 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3E-13 + RS = 0.6074 + N = 105 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.62418E-8 + RS = 4.4302665 + N = 0.849888 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.75794E-12 + RS = 0.6373441 + N = 1.2319344 + TT = 4.409E-8 + CJO = 9.2792E-11 + VJ = 0.603319 + M = 0.3415964 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 16.40NS, SIMULATED TRR = 17.33NS. * * RAD: 2.18E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5079/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 34.37 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.354989E-9 + RS = 0.5943862 + N = 251.2515361 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.428452E-14 + RS = 5.9368313 + N = 1.4913243 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.813378E-10 + RS = 0.6527923 + N = 1.404278 + TT = 5.00E-9 + CJO = 9.782417E-11 + VJ = 0.35 + M = 0.3222494 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 16.42NS, SIMULATED TRR = 14.04NS. * * RAD: 2.11E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5079/27C/RAD5 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 35.05 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.33986E-17 + RS = 0.6895596 + N = 54.7649967 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.04929E-12 + RS = 5.2827798 + N = 0.9349847 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.61719E-10 + RS = 0.7022799 + N = 1.3400938 + TT = 1.50E-9 + CJO = 8.45812E-11 + VJ = 0.60822 + M = 0.3394286 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 14.10NS, SIMULATED TRR = 13.40NS. * * RAD: 1.02E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5079/27C/RAD6 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 36.17 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.8257E-14 + RS = 0.6588532 + N = 71.426966 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.91905E-12 + RS = 6.3433871 + N = 1.6958885 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.02974E-9 + RS = 0.7260003 + N = 1.4559062 + TT = 2.00E-9 + CJO = 7.89243E-11 + VJ = 0.6014668 + M = 0.3341418 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 383.67NS, SIMULATED TRR = 155.2NS. * * RAD: PRERAD * TEMP= 75 .SUBCKT D1N5079/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 36.50 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.22267E-9 + RS = 0.3723163 + N = 572.1654421 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.53608E-26 + RS = 8.4198836 + N = 0.4132447 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.95851E-13 + RS = 0.4231143 + N = 1.1964022 + TT = 1.9567E-7 + CJO = 9.9683E-11 + VJ = 0.3734362 + M = 0.3065205 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 509.5NS, SIMULATED TRR = 184.3NS. * * RAD: PRERAD * TEMP= 125 .SUBCKT D1N5079/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 37.92 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.8E-7 + RS = 0.3723163 + N = 860.2149924 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.88506E-26 + RS = 6.0886727 + N = 0.4805477 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.03301E-13 + RS = 0.4517748 + N = 1.1978507 + TT = 2.311E-7 + CJO = 1.12184E-10 + VJ = 0.35 + M = 0.3468825 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5081 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE * FROM -55 C TO 125 C. NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING * THIS MODEL REPRESENT THE RESPONSES OF NOMINAL DEVICES AND SIMULATIONS * ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT SPECIFICATION. *** CAUTION: THE SIMULATED TRR RANGES FROM 40 TO 60% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * IN HIGH SPEED SWITCHING APPLICATIONS. ***ATTENTION: THE CURRENT AT -55 DEG C. IS BELOW THE RESOLUTION OF THE * SOURCE USED TO MAKE THE MEASUREMENTS. THEREFORE THE REAL * CURRENT IS BELOW THE VALUE SHOWN. .SUBCKT D1N5081 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 3.81 RC 2 1 10.3 TC = 8.43E-4 , -8.35E-7 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = .729 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.82 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 4.86E-10 + RS = .1934682 + N = 884 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 419 + XTI = 4424 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 5.62239E-12 + RS = .354156 + N = 1.321912 + TT = 2.605E-7 + CJO = 7.63768E-11 + VJ = .3509401 + M = .2855811 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * MEASURED TRR = 168.6NS, SIMULATED TRR = 100.7NS. * * RAD: PRE * TEMP= -55 * .SUBCKT D1N5081/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 36.11 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.64354E-11 + RS = 0.3723163 + N = 390.8517265 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.40423E-15 + RS = 6.2102748 + N = 0.676934 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.35439E-12 + RS = 0.3607796 + N = 1.3298919 + TT = 1.300E-7 + CJO = 7.0282E-11 + VJ = 0.3996793 + M = 0.2703798 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 715.00NS, SIMULATED TRR = 291.7NS. * * RAD: PRE * TEMP= 125 * .SUBCKT D1N5081/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 42.31 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.569E-8 + RS = 0.3723163 + N = 377.9608252 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.71113E-20 + RS = 8.4129189 + N = 0.6171964 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.45915E-12 + RS = 0.3817542 + N = 1.296354 + TT = 3.990E-7 + CJO = 9.42896E-11 + VJ = 0.35 + M = 0.372311 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5081 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 3 PARAMETER SETS AT VARIOUS TEMPS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 402.0NS, SIMULATED TRR = 188.6NS. * * RAD: PRE * TEMP= 27 * .SUBCKT D1N5081/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 39.36 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.28367E-10 + RS = 0.4007134 + N = 431.1147175 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.7989E-12 + RS = 8.2593833 + N = 0.4287865 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.62239E-12 + RS = 0.354156 + N = 1.321912 + TT = 2.605E-7 + CJO = 7.63768E-11 + VJ = 0.3509401 + M = 0.2855811 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5083 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL DO NOT REPRESENT THE ACTUAL * RESPONSES OF ANY PARTICULAR DEVICE. *** CAUTION: THE SIMULATED TRR RANGES FROM 28 TO 100% OF THE MEASURED * TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * IN HIGH SPEED SWITCHING APPLICATIONS. * MEASURED TRR = 1.328US, SIMULATED TRR = 351.0NS. * RAD: PRERAD * * CAUTION: IN SPICE USE GMIN = 1E-16 .SUBCKT D1N5083 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 3.079206 RC 2 1 14.18405 TC = 8.514852E-04 , -8.509787E-07 * .MODEL DBLOCK D( + IS = 9.126569E-13 + N = 1.592791 + RS = 4.011134E-03 + EG = .1000536 + XTI = -.4150062 + CJO = 0 + BV = 1E5 +) * .MODEL DLEAK D( + IS = 1.228692E-11 + N = 330.0013 + RS = 1.830718 + EG = .319647 + XTI = 6277.638 + CJO = 0 + BV = 1E5 ) .MODEL DFOR D( + IS = 1.19623E-13 + N = 1.1313329 + RS = 0.0546673 + EG = 1.11 + XTI = 3 + CJO = 1.3077E-10 + VJ = 0.35 + M = 0.3070167 + FC = .5 + TT = 4.906E-7 + BV = 1E5 +) * .ENDS *$ * * MEASURED TRR = 518.0NS, SIMULATED TRR = 213.1NS. * * RAD: PRERAD * TEMP= -55 * * .SUBCKT D1N5083/-55C 99 2 D1 2 99 DLEAK R1 2 99 7E10 V2 5 99 40.42 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2E-23 + RS = 80 + N = 66 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.313E-10 + RS = 5.7 + N = 1.552 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.25874E-13 + RS = 0.0574409 + N = 1.1825519 + TT = 2.871E-7 + CJO = 1.15325E-10 + VJ = 0.6008827 + M = 0.3220457 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 2.270US, SIMULATED TRR = 628.7NS. * * RAD: PRERAD * TEMP= 125 * * .SUBCKT D1N5083/125C 99 2 D1 2 99 DLEAK R1 2 99 1E9 V2 5 99 47.27 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5E-14 + RS = 35 + N = 89 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.26522E-19 + RS = 13.7018743 + N = 0.9693046 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.25858E-14 + RS = 0.0470031 + N = 1.1145083 + TT = 6.820E-7 + CJO = 1.53596E-10 + VJ = 0.35 + M = 0.3683771 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5083 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 4 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 1.328US, SIMULATED TRR = 351.0NS. * * RAD: PRERAD * TEMP= 27 * * .SUBCKT D1N5083/27C 99 2 D1 2 99 DLEAK R1 2 99 3.42584E10 V2 5 99 43.69 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-22 + RS = 2.6576691 + N = 53 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.59069E-12 + RS = 6.9072376 + N = 1.4318406 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.19623E-13 + RS = 0.0546673 + N = 1.1313329 + TT = 4.906E-7 + CJO = 1.3077E-10 + VJ = 0.35 + M = 0.3070167 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5083 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 2 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. PARAMETER SETS EXTRACTED FROM MEASURED * DATA. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 41.3NS, SIMULATED TRR = 43.12NS. * * RAD: 2.219E13 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5083/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 44.16 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.638487E-12 + RS = 0.0816191 + N = 165.1414569 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.277953E-12 + RS = 14.3155728 + N = 0.7846711 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.83484E-10 + RS = 0.0917222 + N = 1.4112423 + TT = 4.000E-8 + CJO = 1.101328E-10 + VJ = 0.4054357 + M = 0.312645 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 17.6NS, SIMULATED TRR = 17.82NS. * * RAD: 2.73E14 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5083/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 43.97 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.217231E-9 + RS = 0.0994119 + N = 240.90298 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 124.7862837 + N = 1.3181783 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.082243E-9 + RS = 0.1096388 + N = 1.4946829 + TT = 5.0E-9 + CJO = 1.01209E-10 + VJ = 0.4157725 + M = 0.3116009 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 1.805US, SIMULATED TRR = 655.8NS. * * RAD: PRERAD * TEMP= 75 * * .SUBCKT D1N5083/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 44.88 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.157363E-10 + RS = 0.3550123 + N = 314.4746141 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.398447E-19 + RS = 5.209105 + N = 1.4228832 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.089959E-13 + RS = 0.0451316 + N = 1.1179846 + TT = 9.05E-7 + CJO = 1.365393E-10 + VJ = 0.4 + M = 0.3329029 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.6048652 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = UZ746 * TYPE : DIODE * SUBTYPE : VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL * REPRESENT THE RESPONSES OF NOMINAL DEVICES AND SIMULATIONS ARE * ACCURATE WITHIN THE LIMITS OF THE PRODUCT SPECIFICATION. .SUBCKT D1N5085 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 5.810833 RC 2 1 8.018217 TC = 8.649727E-04 , -5.029992E-07 * .MODEL DBLOCK D( + IS = 9.386733E-13 + N = .431079 + RS = 6.399395E-02 + EG = .100972 + XTI = -4.382382 + CJO = 0 + BV = 1E5 + ) * .MODEL DLEAK D( + IS = 5.107612E-10 + N = 4478.348 + RS = 0 + EG = .1066272 + XTI = 83231.46 + CJO = 0 + BV = 1E5 ) .MODEL DFOR D( + IS = 4.4433E-14 + N = 1.0923964 + RS = .1425629 + EG = 1.11 + XTI = 3 + CJO = 1.126622E-10 + VJ = .6165069 + M = .3428894 + FC = .5 + TT = 1.1E-6 + BV = 1E5 +) * .ENDS *$ * * MEASURED TRR = 789.0NS, SIMULATED TRR = 526.1NS. * RAD: PRERAD * TEMP= -55 * * .SUBCKT D1N5085/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 43.05 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-16 + RS = 0.1341918 + N = 464.2302495 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.060478E-12 + RS = 42.3146168 + N = 1.4705497 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.345615E-14 + RS = 0.1644552 + N = 1.0870948 + TT = 7.6E-7 + CJO = 1.035537E-10 + VJ = 0.7219453 + M = 0.3292478 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 1.7325US, SIMULATED TRR = 1.336US. * RAD: PRERAD * TEMP= 125 * * .SUBCKT D1N5085/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 50.33 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.396769E-10 + RS = 0.1341918 + N = 478.5027407 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.129053E-21 + RS = 58.945228 + N = 0.8289641 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.677579E-14 + RS = 0.1350839 + N = 1.0772816 + TT = 1.7E-6 + CJO = 1.342664E-10 + VJ = 0.35 + M = 0.3371819 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = UZ746 * TYPE: DIODE * SUBTYPE: VOLTAGE-REG-GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 1.228US, SIMULATED TRR = 768.5NS. * * RAD: PRERAD * TEMP= 27 * * .SUBCKT D1N5085/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 46.9 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.183078E-12 + RS = 0.1341918 + N = 725.4621153 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.072047E-12 + RS = 62.2074622 + N = 0.7525365 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.443347E-14 + RS = 0.1425629 + N = 1.0923964 + TT = 1.1E-6 + CJO = 1.126622E-10 + VJ = 0.6165069 + M = 0.3428894 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5085 * TYPE: DIODE * SUBTYPE: VOLTAGE-REG-GP * THE FOLLOWING SECTION CONTAINS 1 POST NEUTRON RADIATED PARAMETER SET * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 288.75NS, SIMULATED TRR = 162.1NS. * * RAD: 2.21E12 * TEMP= 27 * .SUBCKT D1N5085/27C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 43.9 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.949807E-12 + RS = 0.1584963 + N = 182.2175821 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.163271E-22 + RS = 82.5263666 + N = 2.968494 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.355993E-12 + RS = 0.1536245 + N = 1.2788865 + TT = 2.10E-7 + CJO = 1.108605E-10 + VJ = 0.6005515 + M = 0.3395862 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5106 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL DO NOT * REPRESENT THE ACTUAL RESPONSES OF ANY PARTICULAR DEVICE. * CAUTION: IN SPICE USE GMIN = 1E-16 .SUBCKT D1N5106 1 3 D1 1 3 DFOR D2 3 4 DBLOCK D3 3 1 DLEAK IC 1 2 226.7 RC 2 1 1 TC = 9.24E-4 , -1.53E-6 RSE 4 2 6.41 TC = 6.41E-3, 2.02E-5 * .MODEL DBLOCK D( + IS = 1E-12 + N = 14.9 + RS = 0 + EG = .1 + XTI = -3.82 + CJO = 0 + BV = 1E5 + ) * .MODEL DLEAK D( + IS = 4.02e-10 + N = 6097 + RS = 1K + EG = 3500 + XTI = 1731 + CJO = 0 + BV = 1E5) .MODEL DFOR D( + IS = 8.468E-12 + N = 1.3048 + RS = .1 + EG = 1.11 + XTI = 5 + CJO = 3.215e-11 + VJ = 0.35 + M = 0.3598 + FC = 0.5 + TT = 1.52e-6 + BV = 1E5 +) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5115 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THIS IS A PRE-RAD MODEL AT 27 C OF THE 1N5115 * PARAMETER MODEL EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE. * * MEASURED TRR = 3.00US, SIMULATED TRR = 1.491US. * RAD: PRERAD * TEMP= 27 * .MODEL D1N5115/27C D ( + IS = 4.26043E-12 + RS = 1.8062982 + N = 1.2993515 + TT = 2.06E-6 + CJO = 2.04122E-11 + VJ = 0.3624538 + M = 0.4085035 + EG = 1.11 + XTI = 3.0458416 + KF = 0 + AF = 1 + FC = 0.5 + BV = 390.50 + IBV = 1E-5 + ) *$ * * MEASURED TRR = 128.75NS, SIMULATED TRR = 119.7NS. * * RAD: PRERAD * TEMP= -55 * .SUBCKT D1N5229/-55C 99 2 D1 3 99 DLEAK1 D2 2 3 DLEAK2 R1 2 99 1E12 V2 6 99 3.36 D3 2 6 DBLOCK D4 99 2 DFOR .MODEL DLEAK1 D ( + IS = 4E-11 + RS = 0 + N = 5.75 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DLEAK2 D ( + IS = 3E-6 + RS = 1 + N = 10.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.025325E-9 + RS = 0.4098618 + N = 2.1458533 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.359807E-15 + RS = 0.2672441 + N = 1.1033822 + TT = 1.25E-7 + CJO = 2.149831E-10 + VJ = 0.6324107 + M = 0.3274862 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 100.75NS, SIMULATED TRR = 128.0NS. * * RAD: PRERAD * TEMP= 125 * .SUBCKT D1N5229/125C 99 2 D1 3 99 DLEAK1 D2 2 3 DLEAK2 R1 2 99 1E12 V2 6 99 3.21 D3 2 6 DBLOCK D4 99 2 DFOR .MODEL DLEAK1 D ( + IS = 1E-5 + RS = 0.4517 + N = 5 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DLEAK2 D ( + IS = 1E-10 + RS = 0 + N = 5.95 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.614309E-12 + RS = 0.6859443 + N = 1.9861139 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.416734E-15 + RS = 0.4421635 + N = 1.0688534 + TT = 4.3E-8 + CJO = 2.454832E-10 + VJ = 0.4060664 + M = 0.3153625 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5229 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 101.167NS, SIMULATED TRR = 96.50NS. * RAD: PRERAD * TEMP= 27 * .SUBCKT D1N5229/27C 99 2 D1 3 99 DLEAK1 D2 2 3 DLEAK2 R1 2 99 1E12 V2 6 99 3.47 D3 2 6 DBLOCK D4 99 2 DFOR .MODEL DLEAK1 D ( + IS = 1E-12 + RS = 5.329865E5 + N = 2.9598505 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DLEAK2 D ( + IS = 5.551104E-8 + RS = 0.3500008 + N = 13.914903 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 0.6932695 + N = 1.4482836 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.413484E-15 + RS = 0.3531021 + N = 1.0465094 + TT = 8.9E-8 + CJO = 2.265626E-10 + VJ = 0.6096922 + M = 0.3477396 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5229 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 1 POST NEUTRON RADIATION PARAMETER SET * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 92.00NS, SIMULATED TRR = 92.70NS. * * RAD: 1.93E12 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5229/27C/RAD 99 2 D1 3 99 DLEAK1 D2 2 3 DLEAK2 R1 2 99 1E12 V2 6 99 3.4 D3 2 6 DBLOCK D4 99 2 DFOR .MODEL DLEAK1 D ( + IS = 6.696856E-8 + RS = 0.281478 + N = 13.9559494 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DLEAK2 D ( + IS = 1E-12 + RS = 32.4293916 + N = 6.4313428 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 0.6237072 + N = 1.5530404 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.967124E-14 + RS = 0.3050667 + N = 1.1284245 + TT = 8.3E-8 + CJO = 2.33818E-10 + VJ = 0.4857722 + M = 0.3246798 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5049123 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5229 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. ** CAUTION: THE SIMULATED TRR RANGES FROM 93 TO 127% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5229/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 10 RC 2 1 .22 TC = -3.27E-03 , 3.55E-07 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 3.51 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 2.34E-8 + RS = 5 + N = 12.7 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 4.11 + XTI = 8.37 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.413484E-15 + RS = 0.3531021 + N = 1.0465094 + TT = 8.9E-8 + CJO = 2.265626E-10 + VJ = 0.6096922 + M = 0.3477396 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 181.25NS, SIMULATED TRR = 147.7NS. * * RAD: PRE * TEMP= -55 * * .SUBCKT D1N5231/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.36 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.08831E-10 + RS = 2.3536E-3 + N = 14.9779907 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.36856E-9 + RS = 0.1701631 + N = 0.7255028 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.17857E-12 + RS = 0.062503 + N = 1.2381769 + TT = 1.300E-7 + CJO = 4.00572E-10 + VJ = 0.6006554 + M = 0.3123968 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 108.25NS, SIMULATED TRR = 121.2NS. * * RAD: PRE * TEMP= 125 * * .SUBCKT D1N5231/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.3 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.67848E-10 + RS = 1E-3 + N = 9.5283273 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.22827E-15 + RS = 0.1 + N = 1.2110633 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.40918E-14 + RS = 0.1613899 + N = 1.0745304 + TT = 4.2E-8 + CJO = 4.80809E-10 + VJ = 0.35 + M = 0.3202091 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5231 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 4 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 135.57NS, SIMULATED TRR = 133.70NS. * * RAD: PRE * TEMP= 27 * .SUBCKT D1N5231/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.67 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.12619E-12 + RS = 0.087907 + N = 9.3065501 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.24441E-11 + RS = 0.2201748 + N = 0.6137238 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.31727E-13 + RS = 0.1230492 + N = 1.1305717 + TT = 1.000E-7 + CJO = 4.25529E-10 + VJ = 0.6059945 + M = 0.3469741 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5231 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 1 POST NEUTRON RADIATION PARAMETER SET * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 125.875NS, SIMULATED TRR = 118.8NS. * * RAD: 2.19E12 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5231/27C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.96 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.270344E-12 + RS = 1E-3 + N = 9.2669084 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.258347E-18 + RS = 0.1048536 + N = 1.1388563 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.553168E-13 + RS = 0.1161947 + N = 1.15707 + TT = 7.9E-8 + CJO = 4.258622E-10 + VJ = 0.6006861 + M = 0.3450801 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 117.50NS, SIMULATED TRR = 136.7NS. * * RAD: PRERAD * TEMP= 75 * * .SUBCKT D1N5231/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.66 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2E-10 + RS = 1E-3 + N = 10 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5E-19 + RS = 0.2488261 + N = 0.5111977 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.469741E-14 + RS = 0.1519273 + N = 1.0779823 + TT = 6.7E-8 + CJO = 4.404695E-10 + VJ = 0.4046611 + M = 0.2978173 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5231 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR RANGES FROM 81 TO 116% OF THE MEASURED * TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. SIMULATIONS IF * USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5231/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 4.73 RC 2 1 1 TC = 6.77E-05 , -1.17E-07 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.613 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 3.0E-12 + RS = 0 + N = 9.31 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 5.16 + XTI = 5 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.31727E-13 + RS = 0.1230492 + N = 1.1305717 + TT = 1.000E-7 + CJO = 4.25529E-10 + VJ = 0.6059945 + M = 0.3469741 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * GENERIC FUNCTIONAL EQUIVALENT = 1N5240 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5240/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 0.48 RC 2 1 20 TC = 6.58E-04 , -5.73E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = .6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 2.000E-12 + RS = 0 + N = 34 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 5.04 + XTI = 314 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-14 + RS = .5 + N = 1 + TT = 2E-7 + CJO = 2.5E-10 + VJ = .6 + M = .34 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5242 * TYPE : DIODE * SUBTYPE : VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5242/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 0.46 RC 2 1 25 TC = 6.95E-04 , -4.74E-08 * .MODEL DBLOCK D( + IS = 2E-12 + RS = 0 + N = .6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.000E-12 + RS = 0 + N = 37 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 4.40 + XTI = 428 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-14 + RS = .5 + N = 1 + TT = 2.25E-7 + CJO = 2E-10 + VJ = .6 + M = .34 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5244 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5244/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 1.36 RC 2 1 10 TC = 7.58E-04 , -4.05E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 4.000E-13 + RS = 0 + N = 40 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 2.13 + XTI = 620 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-14 + RS = .5 + N = 1 + TT = 2.5E-7 + CJO = 1.5E-10 + VJ = .6 + M = .34 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 239.5NS, SIMULATED TRR = 230.2NS. * * RAD: PRERAD * TEMP= -55 * * .SUBCKT D1N5245/-55C 99 2 D1 2 99 DLEAK R1 2 99 3.5E10 V2 5 99 13.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.203348E-12 + RS = 0.2875819 + N = 579.3348397 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-16 + RS = 2.4998512 + N = 0.6167564 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.668072E-15 + RS = 0.305206 + N = 1.0914505 + TT = 3.02E-7 + CJO = 1.352016E-10 + VJ = 0.609346 + M = 0.3398645 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 268.0NS, SIMULATED TRR = 197.3NS. * * RAD: PRERAD * TEMP= 125 * * .SUBCKT D1N5245/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 15.52 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.544353E-10 + RS = 0.4820622 + N = 88.5901584 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-19 + RS = 2.720824 + N = 0.6056711 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.486694E-15 + RS = 0.4797574 + N = 1.0156673 + TT = 2.27E-7 + CJO = 1.704462E-10 + VJ = 0.35 + M = 0.3561306 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5245 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 255.0NS, SIMULATED TRR = 199.7NS. * * RAD: PRERAD * TEMP= 27 * .SUBCKT D1N5245/27C 99 2 D1 2 99 DLEAK R1 2 99 3E11 V2 5 99 14.45 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5E-15 + RS = 0.405 + N = 43 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-15 + RS = 2.5 + N = 0.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.649357E-15 + RS = 0.405147 + N = 1.027365 + TT = 2.54E-7 + CJO = 1.478778E-10 + VJ = 0.4204929 + M = 0.3186104 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5245 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 1 POST NEUTRON RADIATION PARAMETER SET * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 139.5NS, SIMULATED TRR = 135.97NS. * * RAD: 1.84E12 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5245/27C/RAD 99 2 D1 2 99 DLEAK R1 2 99 3.5E10 V2 5 99 14.45 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.259837E-12 + RS = 0.3753919 + N = 72.8318287 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 1.8735614 + N = 0.7362917 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.235407E-13 + RS = 0.372709 + N = 1.1763128 + TT = 1.60E-7 + CJO = 1.480374E-10 + VJ = 0.4299006 + M = 0.3235248 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5245 * MANUFACTURER = SPRAGUE * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL CONSTRUCTED FROM MEASUREMENTS * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. *** CAUTION: THE SIMULATED TRR RANGES FROM 73 TO 96% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. SIMULATIONS IF * USED IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5245/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 1.46 RC 2 1 10 TC = 7.62E-04 , -3.77E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 5.000E-15 + RS = 0 + N = 43 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 10.1202914 + XTI = 654 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.649357E-15 + RS = 0.405147 + N = 1.027365 + TT = 2.54E-7 + CJO = 1.478778E-10 + VJ = 0.4204929 + M = 0.3186104 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 459.6NS, SIMULATED TRR = 173.0NS. * * RAD: PRE * TEMP= -55 * * .SUBCKT D1N5248/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 16.06 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-19 + RS = 0.05 + N = 95 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.27286E-13 + RS = 6.053895 + N = 0.8764825 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.31179E-15 + RS = 0.2373164 + N = 1.0166037 + TT = 2.305E-7 + CJO = 1.05941E-10 + VJ = 0.6613288 + M = 0.323898 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 819.00NS, SIMULATED TRR = 249.8NS. * * RAD: PRE * TEMP= 125 * * .SUBCKT D1N5248/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 18.69 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.42145E-11 + RS = 0.2199163 + N = 110.4800389 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-19 + RS = 7.2183041 + N = 0.6796894 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.78777E-15 + RS = 0.3283029 + N = 1.0177223 + TT = 3.000E-7 + CJO = 1.32679E-10 + VJ = 0.35 + M = 0.3288266 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5248 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 4 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 673.33NS, SIMULATED TRR = 214.70NS. * * TEMP= 27 * * .SUBCKT D1N5248/27C 99 2 D1 2 99 DLEAK R1 2 99 8.67589E10 V2 5 99 17.19 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-23 + RS = 0.1650112 + N = 103.1622777 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.727E-18 + RS = 6.8212179 + N = 0.7682746 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.68868E-15 + RS = 0.2636432 + N = 1.0213594 + TT = 2.9023E-7 + CJO = 1.13597E-10 + VJ = 0.6016557 + M = 0.3406627 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * GENERIC FUNCTIONAL EQUIVALENT = 1N5248 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 1 POST NEUTRON RADIATION PARAMETER SET. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 152.00NS, SIMULATED TRR = 107.1NS. * * RAD: 1.39E12 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5248/27C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 17.56 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.258937E-11 + RS = 0.2968556 + N = 112.799042 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.91346E-15 + RS = 23.3540156 + N = 0.3480359 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.704725E-14 + RS = 0.2536879 + N = 1.1365884 + TT = 1.30E-7 + CJO = 1.135672E-10 + VJ = 0.6034316 + M = 0.339968 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 772.50NS, SIMULATED TRR = 214.1NS. * * RAD: PRERAD * TEMP= 75 * * .SUBCKT D1N5248/75C 99 2 D1 2 99 DLEAK R1 2 99 5E10 V2 5 99 18.07 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8E-15 + RS = 0.2873 + N = 48 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5.5509E-17 + RS = 5 + N = 0.7201119 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.381419E-15 + RS = 0.2837502 + N = 1.0278062 + TT = 2.8E-7 + CJO = 1.225952E-10 + VJ = 0.4570504 + M = 0.3349657 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.3898892 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5248 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. * *** CAUTION: THE SIMULATED TRR RANGES FROM 28 TO 38% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. SIMULATIONS IF * USED IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5248/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 1.76 RC 2 1 10 TC = 7.93E-04 , -3.14E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.716 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.000E-12 + RS = 0 + N = 103 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 34.3 + XTI = 309 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.68868E-15 + RS = 0.2636432 + N = 1.0213594 + TT = 2.9023E-7 + CJO = 1.13597E-10 + VJ = 0.6016557 + M = 0.3406627 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5250 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. * ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5250/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 0.98 RC 2 1 20 TC = 8.18E-04 , -2.81E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.000E-10 + RS = 0 + N = 120 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 17.8281822 + XTI = 711 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-14 + RS = .5 + N = 1 + TT = 3.5E-7 + CJO = 1E-10 + VJ = .6 + M = .34 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5251 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. .SUBCKT D1N5251/TEMP 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 0.72 RC 2 1 30 TC = 8.32E-04 , -2.55E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.000E-10 + RS = 0 + N = 140 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 20.6145459 + XTI = 830 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-14 + RS = .5 + N = 1 + TT = 3.5E-7 + CJO = 9E-11 + VJ = .6 + M = .34 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * GENERIC FUNCTIONAL EQUIVALENT = 1N5256 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION * EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE * RESPONSES OF NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE * LIMITS OF THE PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5256 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 0.74 RC 2 1 40 TC = 8.70E-04 , -2.05E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.2500E-10 + RS = 0 + N = 195 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 28.1 + XTI = 1150 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-14 + RS = .5 + N = 1 + TT = 4.3E-7 + CJO = 8E-11 + VJ = .6 + M = .34 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5258 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY EXTRACTED MODELS. * THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS * ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF * NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE * PRODUCT SPECIFICATION. ***CAUTION: THE SIMULATED TRR FOR THIS FAMILY OF DEVICES ARE OFTEN OFF BY * A FACTOR OF 2. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. * SIMULATIONS IF USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5258 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 0.71 RC 2 1 50 TC = 9.08E-04 , -1.55E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 0.6 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.500E-10 + RS = 0 + N = 250 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 35.9395462 + XTI = 1479 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-14 + RS = .5 + N = 1 + TT = 5E-7 + CJO = 7E-11 + VJ = .6 + M = .34 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5262 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS * CONSTRUCTED FROM PRODUCT SPECIFICATION LIMITS AND PREVIOUSLY * EXTRACTED MODELS. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO * RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT * THE RESPONSES OF NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN * THE LIMITS OF THE PRODUCT SPECIFICATION. * * ***CAUTION: THE SIMULATED TRR RANGES FRO 19 T0 21% OF THE MEASURED TRR. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. SIMULATIONS IF * USED IN HIGH SPEED SWITCHING APPLICATIONS. * .SUBCKT D1N5262 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 0.50 RC 2 1 100 TC = 9.30E-04 , -1.10E-08 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 1.19 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.86 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 5E-12 + RS = 0 + N = 446 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 55.2 + XTI = 4625 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) * .MODEL DFOR D( + IS = 1E-12 + RS = 1 + 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 = .001 + ) .ENDS *$ * * MEASURED TRR = 1.817US, SIMULATED TRR = 348.10NS. * * RAD: PRERAD * TEMP= -55 * .SUBCKT D1N5262/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 45.42 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.47E-11 + RS = 0.6746 + N = 1.065353E4 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.15011E-18 + RS = 53.5216147 + N = 0.9405492 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.076936E-14 + RS = 0.3232554 + N = 1.1227059 + TT = 4.8E-7 + CJO = 4.179716E-11 + VJ = 0.7375992 + M = 0.3230735 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 3.262US, SIMULATED TRR = 671.10NS. * RAD: PRERAD * TEMP= 125 * .SUBCKT D1N5262/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 53.9 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.7E-12 + RS = 0.5928123 + N = 163.28 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.405036E-20 + RS = 70.4403805 + N = 0.9660176 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.95797E-13 + RS = 0.7295271 + N = 1.1483622 + TT = 8.8E-7 + CJO = 5.764482E-11 + VJ = 0.35 + M = 0.3577085 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5262 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 3 PRE-RAD MODELS AT VARIOUS TEMPS * PARAMETER MODELS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * * * MEASURED TRR = 2.645US, SIMULATED TRR = 549.10NS. * * RAD: PRERAD * TEMP= 27 * .SUBCKT D1N5262/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 49.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.564659E-12 + RS = 0.5928123 + N = 446.567585 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.443881E-15 + RS = 55.7502581 + N = 1.5275378 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.26317E-14 + RS = 0.6329284 + N = 1.1134204 + TT = 8.000E-7 + CJO = 4.593312E-11 + VJ = 0.6040744 + M = 0.3364323 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ .model D1N5391 D(Is=127.2f Rs=41.78m Ikf=4.315m N=1 Xti=3 Eg=1.11 Cjo=47.97p + M=.4547 Vj=.75 Fc=.5 Isr=36.79u Nr=2 Tt=5.049u) * Motorola pid=1N5391 case=59-04/DO15 * 88-09-07 rmn *$ .model D1N5392 D(Is=127.2f Rs=41.78m Ikf=4.315m N=1 Xti=3 Eg=1.11 Cjo=47.97p + M=.4547 Vj=.75 Fc=.5 Isr=26.93u Nr=2 Tt=5.049u) * Motorola pid=1N5391 case=59-04/DO15 * 88-09-07 rmn *$ .model D1N5393 D(Is=127.2f Rs=41.78m Ikf=4.315m N=1 Xti=3 Eg=1.11 Cjo=47.97p + M=.4547 Vj=.75 Fc=.5 Isr=19.69u Nr=2 Tt=5.049u) * Motorola pid=1N5391 case=59-04/DO15 * 88-09-07 rmn *$ .model D1N5395 D(Is=127.2f Rs=41.78m Ikf=4.315m N=1 Xti=3 Eg=1.11 Cjo=47.97p + M=.4547 Vj=.75 Fc=.5 Isr=14.38u Nr=2 Tt=5.049u) * Motorola pid=1N5391 case=59-04/DO15 * 88-09-07 rmn *$ .model D1N5397 D(Is=127.2f Rs=41.78m Ikf=4.315m N=1 Xti=3 Eg=1.11 Cjo=47.97p + M=.4547 Vj=.75 Fc=.5 Isr=11.96u Nr=2 Tt=5.049u) * Motorola pid=1N5391 case=59-04/DO15 * 88-09-07 rmn *$ .model D1N5398 D(Is=127.2f Rs=41.78m Ikf=4.315m N=1 Xti=3 Eg=1.11 Cjo=34.79p + M=.4399 Vj=.75 Fc=.5 Isr=10.49u Nr=2 Tt=7.213u) * Motorola pid=1N5391 case=59-04/DO15 * 88-09-12 rmn *$ .model D1N5399 D(Is=127.2f Rs=41.78m Ikf=4.315m N=1 Xti=3 Eg=1.11 Cjo=34.79p + M=.4399 Vj=.75 Fc=.5 Isr=10.55u Nr=2 Tt=7.213u) * Motorola pid=1N5391 case=59-04/DO15 * 88-09-12 rmn *$ .model D1N5400 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=130.4p + M=.3758 Vj=.75 Fc=.5 Isr=102.6u Nr=2) * Motorola pid=1N5400 case=267-01 * 88-09-12 rmn *$ .model D1N5401 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=130.4p + M=.3758 Vj=.75 Fc=.5 Isr=79.29u Nr=2) * Motorola pid=1N5400 case=267-01 * 88-09-12 rmn *$ .model D1N5402 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=130.4p + M=.3758 Vj=.75 Fc=.5 Isr=61.19u Nr=2) * Motorola pid=1N5400 case=267-01 * 88-09-12 rmn *$ .model D1N5404 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=130.4p + M=.3758 Vj=.75 Fc=.5 Isr=47.19u Nr=2) * Motorola pid=1N5400 case=267-01 * 88-09-12 rmn *$ .model D1N5406 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=130.4p + M=.3758 Vj=.75 Fc=.5 Isr=40.53u Nr=2) * Motorola pid=1N5400 case=267-01 * 88-09-12 rmn *$ * * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. ***CAUTION: THE MEASURED TRR AND THE SIMULATED TRR ARE DIFFERENT. THIS * COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS. .SUBCKT D1N5521 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 23.01 RC 2 1 6.562E-2 TC = -7.06E-3 , -4.53E-7 * .MODEL DBLOCK D( + IS = 1E-10 + RS = 0 + N = 5.9 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.82 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 3.362218E-08 + RS = 1000 + N = 13.44642 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.852449 + XTI = 55.67418 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.07E-14 + RS = .1504 + N = 1.09 + TT = 3.662E-8 + CJO = 2.298E-10 + VJ = .657 + M = .3099 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * MEASURED TRR = 80.13NS, SIMULATED TRR = 70.64NS. * * RAD: PRE * TEMP: -15 * * .SUBCKT D1N5521/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.24 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.12367E-8 + RS = 1E-3 + N = 14.4334569 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 9.26697E-17 + RS = 0.1 + N = 4.3184212 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.95587E-15 + RS = 0.1576556 + N = 1.0765525 + TT = 4.765E-8 + CJO = 2.28218E-10 + VJ = 0.482582 + M = 0.2698506 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 63.50NS, SIMULATED TRR = 56.47NS. * * RAD: PRE * TEMP: -55 * * .SUBCKT D1N5521/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.4 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.0575E-8 + RS = 1E-3 + N = 16.6465487 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 9.04268E-17 + RS = 0.1 + N = 4.5799438 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.67166E-15 + RS = 0.1689143 + N = 1.0773729 + TT = 3.068E-8 + CJO = 2.23987E-10 + VJ = 0.5051959 + M = 0.2687559 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 33.45NS, SIMULATED TRR = 36.10NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * TYPE: NEUTRON * TEMP= -55 * .SUBCKT D1N5521/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.72027E-7 + RS = 1E-3 + N = 19.0142929 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.34971E-13 + RS = 0.1 + N = 5.9492706 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.46034E-11 + RS = 0.0870913 + N = 1.4241991 + TT = 1.265E-8 + CJO = 2.37147E-10 + VJ = 0.508438 + M = 0.2681223 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 48.75NS, SIMULATED TRR = 85.82NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * RAD: PRE * TEMP: 125 * * .SUBCKT D1N5521/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.46 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.29086E-8 + RS = 1E-3 + N = 9.9619292 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.63426E-18 + RS = 0.1 + N = 2.7830413 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.51328E-15 + RS = 0.1675414 + N = 1.0441045 + TT = 3.181E-8 + CJO = 2.49079E-10 + VJ = 0.4313516 + M = 0.2883027 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 33.7NS, SIMULATED TRR = 41.62NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * TYPE: NEUTRON * TEMP= 125 * .SUBCKT D1N5521/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.21 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.54172E-8 + RS = 1E-3 + N = 10.8329367 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.286E-14 + RS = 0.1 + N = 4.1327399 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.00529E-13 + RS = 0.126763 + N = 1.1862724 + TT = 1.175E-8 + CJO = 2.61134E-10 + VJ = 0.4221585 + M = 0.2791173 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5521 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * * MEASURED TRR = 72.31NS, SIMULATED TRR = 66.79NS. * * RAD: PRE * TEMP: 27 * * * .SUBCKT D1N5521/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 2.10 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.74992E-8 + RS = 1E-3 + N = 12.8432837 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.02042E-13 + RS = 0.1 + N = 3.9789916 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.07148E-14 + RS = 0.1504462 + N = 1.0932217 + TT = 3.662E-8 + CJO = 2.29791E-10 + VJ = 0.6570289 + M = 0.3099216 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 6 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. *** CAUTION: USE ONLY AT SPECIFIED TEMPERATURE. ANY DEVIATION FROM THIS * WILL PRODUCE INCORRECT RESULTS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * * * MEASURED TRR = 33.15NS, SIMULATED TRR = 38.30NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * RAD: 5.36E14 * TYPE: NEUTRON * TEMP: 27 * .SUBCKT D1N5521/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.42 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.74022E-7 + RS = 0.0897077 + N = 14.4711166 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5.18665E-13 + RS = 0.1 + N = 5 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.97556E-12 + RS = 0.1462045 + N = 1.2348553 + TT = 1.165E-8 + CJO = 2.46294E-10 + VJ = 0.4603751 + M = 0.2688606 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 49.00NS, SIMULATED TRR = 43.72NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * RAD: 5.79E12 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5521/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.42 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.6585E-8 + RS = 1E-3 + N = 13.0050101 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.65456E-19 + RS = 0.1093582 + N = 3.1271589 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.03946E-14 + RS = 0.150795 + N = 1.0787119 + TT = 2.000E-9 + CJO = 2.41831E-10 + VJ = 0.4516706 + M = 0.2663687 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 33.36NS, SIMULATED TRR = 32.13NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * RAD: 2.22E14 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5521/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.48 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.58136E-8 + RS = 1E-3 + N = 13.1696161 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.18818E-18 + RS = 0.154555 + N = 3.1938658 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.7714E-13 + RS = 0.1411484 + N = 1.2206534 + TT = 2.000E-9 + CJO = 2.48518E-10 + VJ = 0.458027 + M = 0.2658461 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 32.80NS, SIMULATED TRR = 31.51NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * RAD: 1.08E15 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5521/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.54 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.60272E-7 + RS = 1E-3 + N = 15.0866452 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.46891E-14 + RS = 0.1001 + N = 4.4900781 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.32041E-11 + RS = 0.1349023 + N = 1.3450362 + TT = 2.500E-9 + CJO = 2.4214E-10 + VJ = 0.4550857 + M = 0.2665805 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 47.33NS, SIMULATED TRR = 52.15NS. * * NOTE: TRR MEASUREMENT WAS MADE AT 20% OF REPEAT CURRENT BECAUSE OF * THE EXCESSIVE LEAKAGE CURRENT. * * RAD: PRE * TEMP: 75 * * .SUBCKT D1N5521/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 1.64 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.83469E-8 + RS = 1E-3 + N = 11.2093009 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.59974E-16 + RS = 0.1 + N = 3.3717825 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.21386E-15 + RS = 0.1554061 + N = 1.0593211 + TT = 3.099E-8 + CJO = 2.41047E-10 + VJ = 0.4104132 + M = 0.2704933 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. ***CAUTION: THIS MEASURED TRR AND THE MEASURED TRR ARE DIFFERENT. THIS * COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS. * .SUBCKT D1N5522 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 17.14 RC 2 1 .217 TC = -7.05E-4 , 4.253E-8 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 1.62 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1005099 + XTI = -3.86007 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 4.213125E-09 + RS = 2.816979E-02 + N = 13.52193 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 2.815535 + XTI = 57.03966 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 7.82E-15 + RS = 0.1275 + N = 1.07 + TT = 1.3E-8 + CJO = 2.284E-10 + VJ = 0.6439 + M = 0.3249 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRERAD * TEMP: -15 * .SUBCKT D1N5522/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.62 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.235E-10 + RS = 1E-6 + N = 11.87 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.358E-13 + RS = 1E-6 + N = 1.651 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 3.640E-13 + RS = 0.0917 + N = 1.240 + TT = 2.05E-8 + CJO = 2.230E-10 + VJ = 0.6920 + M = 0.3257 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= -15 .SUBCKT D1N5522/-15C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.0 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.080E-8 + RS = 0.0969 + N = 17.22 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.483E-13 + RS = 2.107 + N = 1.102 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.689E-11 + RS = 0.1263 + N = 1.352 + TT = 6.500E-9 + CJO = 2.200E-10 + VJ = 0.6928 + M = 0.3259 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRERAD * TEMP: -55 .SUBCKT D1N5522/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.61 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.048E-10 + RS = 1E-6 + N = 13.53 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.299E-12 + RS = 1.549E-4 + N = 1.670 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 8.197E-15 + RS = 0.1342 + N = 1.073 + TT = 1.852E-8 + CJO = 2.186E-10 + VJ = 0.7342 + M = 0.3262 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP: -55 .SUBCKT D1N5522/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.82 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.023E-8 + RS = 0.1098 + N = 20.00 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.848E-13 + RS = 2.025 + N = 1.301 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.680E-11 + RS = 0.3688 + N = 1.374 + TT = 8.2E-9 + CJO = 2.156E-10 + VJ = 0.7350 + M = 0.3266 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRERAD * TEMP: 125 .SUBCKT D1N5522/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.0 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.499E-9 + RS = 0.9831 + N = 9.852 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.680E-12 + RS = 1E-3 + N = 1.485 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.519E-15 + RS = 0.1274 + N = 1.043 + TT = 1.328E-8 + CJO = 2.453E-10 + VJ = 0.6298 + M = 0.3599 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N5522/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.91 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.899E-8 + RS = 1E-3 + N = 12.38 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.642E-14 + RS = 1.252 + N = 1.454 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.840E-12 + RS = 0.1184 + N = 1.249 + TT = 0.0 + CJO = 2.431E-10 + VJ = 0.6283 + M = 0.3588 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5522 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * * PARAMETER SETS EXTRACTED FROM MEASURED DATA * PRERAD * TEMP: 27 * * .SUBCKT D1N5522/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.67 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.292E-10 + RS = 1E-6 + N = 10.48 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 8.917E-19 + RS = 0.4251 + N = 1.072 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 7.820E-15 + RS = 0.1275 + N = 1.069 + TT = 1.3E-8 + CJO = 2.284E-10 + VJ = 0.6439 + M = 0.3249 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * ** GENERIC FUNCTIONAL EQUIVALENT = 1N5522 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 6 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5522/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.84 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 4.682E-9 + RS = 1.0343164 + N = 13.52 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.727E-12 + RS = 1.151 + N = 1.514 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 3.153E-14 + RS = 0.1325 + N = 1.111 + TT = 7.1E-9 + CJO = 2.387E-10 + VJ = 0.6460 + M = 0.3239 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5522/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.94 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 3.544E-8 + RS = 0.0459 + N = 16.56 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.874E-12 + RS = 1.028 + N = 1.458 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 3.07E-11 + RS = 0.1003 + N = 1.350 + TT = 0.0 + CJO = 2.306E-10 + VJ = 0.634 + M = 0.3248 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5522/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.87 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 7.367E-9 + RS = 0.3827 + N = 14.66 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.536E-12 + RS = 0.5142 + N = 1.561 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 3.355E-12 + RS = 0.1419 + N = 1.290 + TT = 0.0 + CJO = 2.335E-10 + VJ = 0.6477 + M = 0.3254 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5522/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.09 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.097E-8 + RS = 0.0643 + N = 15.05 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.892E-12 + RS = 1.567 + N = 1.211 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.369E-11 + RS = 0.1258 + N = 1.336 + TT = 0.0 + CJO = 2.255E-10 + VJ = 0.6427 + M = 0.3249 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRERAD * TEMP: 75 .SUBCKT D1N5522/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.96 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.252E-9 + RS = 1E-6 + N = 11.40 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 5.388E-13 + RS = 0.3018 + N = 1.337 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.255E-15 + RS = 0.1261 + N = 1.043 + TT = 1.31E-8 + CJO = 2.347E-10 + VJ = 0.6001 + M = 0.3264 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP: 75 .SUBCKT D1N5522/75C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.04 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 2.228E-8 + RS = 0.0666 + N = 14.08 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.334E-13 + RS = 1.066 + N = 1.340 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.969E-12 + RS = 0.1313 + N = 1.272 + TT = 0.0 + CJO = 2.324E-10 + VJ = 0.6006 + M = 0.3238 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5523 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. *** CAUTION: THE SIMULATED TRR AND THE MEASURED TRR ARE DIFFERENT. THIS * COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS. .SUBCKT D1N5523 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 2.30 RC 2 1 1.728 TC = -7.17E-4 , 5.24E-8 * .MODEL DBLOCK D( + IS = 1E-12 + RS = 0 + N = 1.91 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = -3.82 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.26E-10 + RS = 100 + N = 12.3 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 3.39 + XTI = 60.3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.793E-14 + RS = 0.1508 + N = 1.103 + TT = 3.2E-8 + CJO = 1.684E-10 + VJ = 0.6296 + M = 0.3243 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * RAD: PRE * TEMP= -15 .SUBCKT D1N5523/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.4 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 7.42E-12 + RS = 0.1276 + N = 12.16 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.972E-26 + RS = 0.7982 + N = 0.4072 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.139E-14 + RS = 0.1501 + N = 1.083 + TT = 3.55E-8 + CJO = 1.643E-10 + VJ = 0.6817 + M = 0.3269 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= -15 .SUBCKT D1N5523/-15C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.58 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 3.363E-10 + RS = 1.619E-3 + N = 15.07 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 7.727E-14 + RS = 0.7557 + N = 0.5259 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 7.207E-12 + RS = 0.1296 + N = 1.298 + TT = 0.0 + CJO = 1.637E-10 + VJ = 0.6847 + M = 0.3281 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= -55 .SUBCKT D1N5523/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.41 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 9.380E-12 + RS = 0.1275 + N = 14.81 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.699E-16 + RS = 0.8317 + N = 0.4855 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.526E-14 + RS = 0.1665 + N = 1.098 + TT = 3.45E-8 + CJO = 1.608E-10 + VJ = 0.7254 + M = 0.3273 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE NEUTRON * TEMP= -55 .SUBCKT D1N5523/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.45 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 8.285E-10 + RS = 0.1143 + N = 20.42 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.435E-12 + RS = 0.8721 + N = 0.5393 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.447E-11 + RS = 0.1000 + N = 1.393 + TT = 0.0 + CJO = 1.601E-10 + VJ = 0.7326 + M = 0.3292 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= 125 .SUBCKT D1N5523/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.91 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 3.266E-12 + RS = 1E-3 + N = 8.3090 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.008E-21 + RS = 0.6933 + N = 0.4681 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.361E-15 + RS = 0.1540 + N = 1.023 + TT = 4.83E-8 + CJO = 1.800E-10 + VJ = 0.6591 + M = 0.3642 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N5523/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.03 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 4.402E-10 + RS = 1.403E-3 + N = 10.88 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 5.014E-13 + RS = 0.5993 + N = 0.6890 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 2.798E-12 + RS = 0.1141 + N = 1.256 + TT = 0.0 + CJO = 1.814E-10 + VJ = 0.6035 + M = 0.3544 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5523 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING FILE CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * RAD: PRE * TEMP= 27 .SUBCKT D1N5523/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.63 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 6.228E-12 + RS = 0.1577 + N = 10.77 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 6.520E-21 + RS = 0.7056 + N = 0.4434 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.793E-14 + RS = 0.1508 + N = 1.103 + TT = 3.2E-8 + CJO = 1.684E-10 + VJ = 0.6296 + M = 0.3243 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5523/27C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.793 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 9.986E-10 + RS = 2.344E-3 + N = 14.93 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 4.470E-12 + RS = 0.8591 + N = 0.7196 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 6.795E-11 + RS = 0.1337 + N = 1.397 + TT = 0.0 + CJO = 1.686E-10 + VJ = 0.6332 + M = 0.3240 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5523 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING FILE CONTAINS 7 PARAMETER SETS AT VARIOUS RADIATION * LEVELS AND TEMPERATURES. EACH MODELS TEMP., RAD-DOSE, AND RAD * TYPE ARE NOTED. * PARAMETER M0DELS EXTRACTED FROM MEASURED DATA * * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5523/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.79 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.799E-10 + RS = 1E-3 + N = 13.22 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.654E-12 + RS = 0.7074 + N = 0.5925 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 1.759E-12 + RS = 0.2512 + N = 1.252 + TT = 7.5E-9 + CJO = 1.704E-10 + VJ = 0.6397 + M = 0.3279 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5523/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.59 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 3.77E-16 + RS = 1E-3 + N = 6.836 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 1.609E-25 + RS = 1.130 + N = 0.3647 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 9.363E-12 + RS = 0.1228 + N = 1.310 + TT = 0.0 + CJO = 1.681E-10 + VJ = 0.6352 + M = 0.3275 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: PRE * TEMP= 75 .SUBCKT D1N5523/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.61 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.431E-14 + RS = 1.008E-3 + N = 7.230 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 3.025E-20 + RS = 0.0998 + N = 0.6254 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 6.395E-15 + RS = 0.1568 + N = 1.061 + TT = 4.56E-8 + CJO = 1.742E-10 + VJ = 0.6110 + M = 0.3356 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 75 .SUBCKT D1N5523/75C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.71 D2 2 5 DBLOCK D3 99 2 DFOR * .MODEL DLEAK D ( + IS = 1.330E-10 + RS = 2.221E-3 + N = 11.28 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DBLOCK D ( + IS = 2.009E-14 + RS = 0.271 + N = 0.7803 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DFOR D ( + IS = 4.330E-12 + RS = 0.1141 + N = 1.270 + TT = 0.0 + CJO = 1.738E-10 + VJ = 0.6110 + M = 0.3366 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5524 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL * REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. .SUBCKT D1N5524 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 2.925336 RC 2 1 1.862181 TC = 2.909941E-04 , -8.97477E-09 * .MODEL DBLOCK D( + IS = 1.004051E-12 + RS = 3.779846E-03 + N = .2001502 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1012446 + XTI = -.3951724 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 4.733728E-13 + RS = .1301952 + N = 15.12397 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 4.628336 + XTI = 47.34695 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 7.587E-15 + RS = 0.2470116 + N = 1.0741594 + TT = 1.76E-8 + CJO = 1.29835E-10 + VJ = 0.6455345 + M = 0.3315823 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 53.10NS, SIMULATED TRR = 52.59NS. * TEMP= -15 * .SUBCKT D1N5524/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.84 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.98576E-14 + RS = 0.3723163 + N = 15.2428099 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 9.88132E-13 + RS = 1.6600495 + N = 1.0090976 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.16409E-15 + RS = 0.1841928 + N = 1.0480326 + TT = 4.27E-8 + CJO = 1.53749E-10 + VJ = 0.6732948 + M = 0.319394 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 53.10NS, SIMULATED TRR = 52.25NS. * TEMP= -55 * .SUBCKT D1N5524/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.59 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.583E-14 + RS = 0.3723 + N = 16.832 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.69372E-13 + RS = 1.5642083 + N = 1.2457064 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 9.75228E-15 + RS = 0.1796876 + N = 1.0889534 + TT = 4.36E-8 + CJO = 1.50338E-10 + VJ = 0.7161692 + M = 0.3196357 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 31.828NS, SIMULATED TRR = 28.26NS. * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= -55 * .SUBCKT D1N5524/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.51 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.87269E-11 + RS = 0.3723163 + N = 26.3484521 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-18 + RS = 2.1877111 + N = 0.9289646 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.21269E-11 + RS = 0.1561988 + N = 1.3282293 + TT = 7.78E-9 + CJO = 1.49481E-10 + VJ = 0.717399 + M = 0.3191346 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 61.10NS, SIMULATED TRR = 59.52NS. * * TEMP= 125 * .SUBCKT D1N5524/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.16 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.77729E-12 + RS = 0.3723 + N = 14.737 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2E-30 + RS = 1.965 + N = 0.454 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.10842E-15 + RS = 0.1672503 + N = 1.0434614 + TT = 4.94E-8 + CJO = 1.6956E-10 + VJ = 0.6058029 + M = 0.3441553 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 23.333NS, SIMULATED TRR = 29.59NS. * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 125 * .SUBCKT D1N5524/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.47 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.44825E-8 + RS = 0.3723163 + N = 25.4042778 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-20 + RS = 2.7369727 + N = 0.4872158 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.7493E-12 + RS = 0.1515552 + N = 1.2213294 + TT = 6.90E-9 + CJO = 1.69343E-10 + VJ = 0.6022763 + M = 0.344287 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5524 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 54.10NS, SIMULATED TRR = 54.25NS. * TEMP= 27 * .SUBCKT D1N5524/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.02 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.128E-12 + RS = 0.3723163 + N = 17.076 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.008E-12 + RS = 1.586 + N = 0.9527 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.23889E-15 + RS = 0.1961263 + N = 1.0482169 + TT = 4.400E-8 + CJO = 1.57343E-10 + VJ = 0.6315497 + M = 0.3191276 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5524 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 6 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 23.625NS, SIMULATED TRR = 28.91NS. * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5524/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.14 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.07551E-9 + RS = 0.1322042 + N = 24.0855196 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.69108E-14 + RS = 2.2795813 + N = 0.6873642 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.2772E-12 + RS = 0.1413325 + N = 1.3070617 + TT = 7.20E-9 + CJO = 1.56567E-10 + VJ = 0.6295194 + M = 0.3180148 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 34.90NS, SIMULATED TRR = 33.72NS. * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5524/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.32 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.34351E-12 + RS = 0.1616448 + N = 18.1151704 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.00002E-15 + RS = 7.7454887 + N = 0.3371205 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.17089E-14 + RS = 0.1878692 + N = 1.1200462 + TT = 1.232E-8 + CJO = 1.55854E-10 + VJ = 0.6272345 + M = 0.322278 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 23.53NS, SIMULATED TRR = 28.29NS. * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5524/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.35 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.49311E-10 + RS = 0.0992619 + N = 22.9864155 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.74596E-14 + RS = 2.3804162 + N = 0.3615159 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.15326E-12 + RS = 0.1453544 + N = 1.2249581 + TT = 6.46E-9 + CJO = 1.54087E-10 + VJ = 0.6338551 + M = 0.3266928 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 23.00NS, SIMULATED TRR = 28.45NS. * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5524/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.33 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.36893E-9 + RS = 0.1720455 + N = 25.8589446 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.63883E-26 + RS = 5.7171002 + N = 0.1839413 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.54884E-11 + RS = 0.1938886 + N = 1.3795484 + TT = 6.44E-9 + CJO = 1.57128E-10 + VJ = 0.624868 + M = 0.3196039 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 57.30NS, SIMULATED TRR = 55.55NS. * * TEMP= 75 * .SUBCKT D1N5524/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.35 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.77729E-12 + RS = 0.3723163 + N = 14.7374199 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.7772E-13 + RS = 1.7933373 + N = 0.7227879 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.26066E-15 + RS = 0.1641518 + N = 1.0428125 + TT = 4.32E-8 + CJO = 1.6956E-10 + VJ = 0.6058029 + M = 0.3441553 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5525 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. .SUBCKT D1N5525 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 1.315012 RC 2 1 4.607634 TC = 3.848381E-04 , -1.254362E-07 * .MODEL DBLOCK D( + IS = 1.014076E-12 + RS = 3.172217E-03 + N = .2003611 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1060121 + XTI = -.4306087 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 6.40683E-14 + RS = .1089366 + N = 18.45053 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1376185 + XTI = 310.0037 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 7.587E-15 + RS = 0.2470116 + N = 1.0741594 + TT = 1.76E-8 + CJO = 1.29835E-10 + VJ = 0.6455345 + M = 0.3315823 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 38.93NS, SIMULATED TRR = 31.02NS. * * TEMP= -15 * .SUBCKT D1N5525/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 4.03 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.66955E-14 + RS = 0.3723163 + N = 21.5285323 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.1513E-26 + RS = 2.0079722 + N = 1.6344447 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.86058E-15 + RS = 0.2631942 + N = 1.0630978 + TT = 1.581E-8 + CJO = 1.25935E-10 + VJ = 0.6994637 + M = 0.3323033 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 38.20NS, SIMULATED TRR = 30.61NS. * * RAD: PRE * TEMP= -55 * .SUBCKT D1N5525/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 3.93 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.2495E-15 + RS = 0.3723163 + N = 21.8789254 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.83843E-26 + RS = 2.4851337 + N = 1.7672521 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.26192E-14 + RS = 0.2823091 + N = 1.0954256 + TT = 1.625E-8 + CJO = 1.23122E-10 + VJ = 0.7454531 + M = 0.3325374 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 21.4NS, SIMULATED TRR = 22.65NS. * TYPE: NEUTRON * TEMP= -55 * .SUBCKT D1N5525/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.46 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.98326E-11 + RS = 0.166459 + N = 28.6627222 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.85246E-13 + RS = 1.4428738 + N = 0.7738195 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.25058E-11 + RS = 0.2864503 + N = 1.3002456 + TT = 6.55E-9 + CJO = 1.22361E-10 + VJ = 0.748287 + M = 0.3252746 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 62.40NS, SIMULATED TRR = 34.85NS. * * TEMP= 125 * .SUBCKT D1N5525/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.16 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.04729E-11 + RS = 0.3723163 + N = 27.7656287 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.67625E-20 + RS = 2.5428516 + N = 1.2594984 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.73442E-15 + RS = 0.262003 + N = 1.0596418 + TT = 1.863E-8 + CJO = 1.4129E-10 + VJ = 0.6003298 + M = 0.3615048 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 21.07NS, SIMULATED TRR = 24.42NS. * TYPE: NEUTRON * TEMP= 125 * .SUBCKT D1N5525/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.19 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.18906E-8 + RS = 0.3723163 + N = 34.7998698 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.88897E-20 + RS = 1.4351941 + N = 0.5591036 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.50366E-12 + RS = 0.2046822 + N = 1.2619953 + TT = 6.41E-9 + CJO = 1.38418E-10 + VJ = 0.6229895 + M = 0.3516381 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5525 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * MEASURED TRR = 40.8NS SIMULATED TRR = 31.92NS * RAD: PRE * TEMP= 27 * .SUBCKT D1N5525/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.33 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.65739E-12 + RS = 0.2875 + N = 25 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.4069E-26 + RS = 4.6709699 + N = 0.6101615 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.587E-15 + RS = 0.2470116 + N = 1.0741594 + TT = 1.76E-8 + CJO = 1.29835E-10 + VJ = 0.6455345 + M = 0.3315823 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5525 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS FILE CONTAINS 6 PARAMETER SETS AT VARIOUS RADIATION LEVELS AND * TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 21.0NS, SIMULATED TRR = 23.98NS. * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5525/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.99 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.75382E-10 + RS = 0.166459 + N = 29.1437752 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.86012E-13 + RS = 1.5860782 + N = 0.5404145 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 9.86486E-12 + RS = 0.1967262 + N = 1.3160178 + TT = 6.46E-9 + CJO = 1.28023E-10 + VJ = 0.6556165 + M = 0.3243292 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 32.6NS, SIMULATED TRR = 28.09NS. * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5525/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.59 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.42976E-11 + RS = 0.1899132 + N = 34.8173344 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.85674E-14 + RS = 3.7687315 + N = 0.9491518 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.38068E-14 + RS = 0.2101098 + N = 1.1124579 + TT = 9.88E-9 + CJO = 1.33329E-10 + VJ = 0.6457637 + M = 0.3250982 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 21.4NS, SIMULATED TRR = 24.69NS. * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5525/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.68 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.21225E-10 + RS = 0.1885517 + N = 24.8842262 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.67916E-14 + RS = 2.6 + N = 0.7642077 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.47876E-12 + RS = 0.2085654 + N = 1.2561236 + TT = 6.65E-9 + CJO = 1.31021E-10 + VJ = 0.6463109 + M = 0.3277947 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 20.5NS, SIMULATED TRR = 22.82NS. * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5525/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.01 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.95723E-10 + RS = 0.1723647 + N = 25.9531033 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.42415E-14 + RS = 5.0034287 + N = 0.4259324 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.34477E-11 + RS = 0.1940234 + N = 1.3622304 + TT = 6.28E-9 + CJO = 1.25384E-10 + VJ = 0.6460372 + M = 0.3299793 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 59.33NS, SIMULATED TRR = 39.36NS. * * TEMP= 75 * .SUBCKT D1N5525/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 5.04 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.17938E-12 + RS = 0.3723163 + N = 24.7840218 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.68967E-20 + RS = 2.7484467 + N = 1.2501181 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.98965E-15 + RS = 0.2449604 + N = 1.0623148 + TT = 2.596E-8 + CJO = 1.34667E-10 + VJ = 0.6191986 + M = 0.3441206 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5526 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. .SUBCKT D1N5526 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 1.592092 RC 2 1 4.21207 TC = 3.828731E-04 , -3.668221E-07 * .MODEL DBLOCK D( + IS = 1.006703E-12 + RS = 3.240985E-02 + N = .201827 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1060803 + XTI = -4.733322 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 2.913461E-13 + RS = 2.053163E-03 + N = 21.51591 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = 355.3691 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 2.7107E-15 + RS = 0.2718297 + N = 1.0372194 + TT = 1.550E-8 + CJO = 1.33824E-10 + VJ = 0.6814036 + M = 0.3369589 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * MEASURED TRR = 61.00NS, SIMULATED TRR = 31.47NS. * * TEMP= -15 .SUBCKT D1N5526/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.23 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.2146E-15 + RS = 0.3723163 + N = 19.4110629 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5E-15 + RS = 1.46 + N = 0.5 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.41485E-15 + RS = 0.2689011 + N = 1.0361223 + TT = 1.569E-8 + CJO = 1.30514E-10 + VJ = 0.7121832 + M = 0.3359887 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 40.40NS, SIMULATED TRR = 30.61NS. * * TEMP= -55 .SUBCKT D1N5526/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.06 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.27844E-15 + RS = 0.3723163 + N = 20.2409675 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.4421E-11 + RS = 1.5280118 + N = 0.5763098 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.37968E-15 + RS = 0.2871698 + N = 1.0517196 + TT = 1.532E-8 + CJO = 1.27589E-10 + VJ = 0.762598 + M = 0.3369698 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 21.60NS, SIMULATED TRR = 23.85NS. * TYPE: NEUTRON * TEMP= -55 .SUBCKT D1N5526/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.02 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.79136E-11 + RS = 0.199028 + N = 29.995602 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.20065E-12 + RS = 1.2802123 + N = 0.5641623 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.3335E-11 + RS = 0.2659695 + N = 1.3108356 + TT = 6.890E-9 + CJO = 1.26555E-10 + VJ = 0.7560321 + M = 0.3314774 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 82.83NS, SIMULATED TRR = 39.39NS. * TEMP= 125 .SUBCKT D1N5526/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.98 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.2E-10 + RS = 0.3723163 + N = 24.095 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.1632E-22 + RS = 1.9104529 + N = 0.3410878 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.76108E-15 + RS = 0.2751266 + N = 1.0224207 + TT = 2.433E-8 + CJO = 1.45046E-10 + VJ = 0.6018896 + M = 0.3572504 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 21.20NS, SIMULATED TRR = 25.35NS. * * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N5526/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.89 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.90456E-8 + RS = 0.148047 + N = 30.7240562 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.27578E-19 + RS = 1.2328652 + N = 0.464337 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.12045E-12 + RS = 0.2393867 + N = 1.231585 + TT = 6.440E-9 + CJO = 1.43125E-10 + VJ = 0.6603644 + M = 0.3654419 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5526 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 5 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARIOUS TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * MEASURED TRR = 68.94NS, SIMULATED TRR = 31.25NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT. SIMULATED TRR ARE * DIFFERENT * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT. SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * RAD: PRE * TEMP= 27 .SUBCKT D1N5526/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.61 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.16003E-14 + RS = 0.2375728 + N = 19.8892122 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.38629E-12 + RS = 2.3269277 + N = 0.3677784 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.71073E-15 + RS = 0.2718297 + N = 1.0372194 + TT = 1.550E-8 + CJO = 1.33824E-10 + VJ = 0.6814036 + M = 0.3369589 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5526 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 6 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * MEASURED TRR = 21.20NS, SIMULATED TRR = 24.62NS. * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5526/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.49 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.081E-9 + RS = 0.199028 + N = 30.4717961 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.56165E-12 + RS = 1.0095895 + N = 0.5633458 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.75141E-12 + RS = 0.2236101 + N = 1.2864667 + TT = 6.380E-9 + CJO = 1.32541E-10 + VJ = 0.6604219 + M = 0.3301164 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 33.27NS, SIMULATED TRR = 28.43NS. * * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5526/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.49 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.09485E-11 + RS = 0.2771289 + N = 29.1672188 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5E-21 + RS = 4.5655346 + N = 0.33 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.41925E-14 + RS = 0.2735181 + N = 1.0791413 + TT = 1.115E-8 + CJO = 1.30816E-10 + VJ = 0.6737181 + M = 0.3327308 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 20.40NS, SIMULATED TRR = 22.16NS. * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5526/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.52 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.55146E-10 + RS = 0.245762 + N = 28.6691291 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.20199E-15 + RS = 2.5789925 + N = 0.3866129 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.58291E-12 + RS = 0.2674454 + N = 1.2495986 + TT = 6.24E-9 + CJO = 1.16452E-10 + VJ = 0.6814617 + M = 0.3227654 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 21.00NS, SIMULATED TRR = 23.96NS. * * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5526/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.40 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.126E-10 + RS = 0.1 + N = 20.9092985 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.04342E-19 + RS = 2.5958655 + N = 0.48 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.37555E-11 + RS = 0.2266559 + N = 1.3275969 + TT = 6.31E-9 + CJO = 1.31163E-10 + VJ = 0.6521147 + M = 0.3244908 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 78.00NS, SIMULATED TRR = 37.12NS. * * TEMP= 75 .SUBCKT D1N5526/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.68 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.74656E-12 + RS = 0.3723163 + N = 21.6720857 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 4.65063E-20 + RS = 1.6878268 + N = 0.4107228 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.89012E-15 + RS = 0.2654067 + N = 1.0368833 + TT = 2.11E-8 + CJO = 1.38514E-10 + VJ = 0.6004391 + M = 0.3316816 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5527 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODELS REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. .SUBCKT D1N5527 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 1.996386 RC 2 1 3.697512 TC = 5.393318E-04 , -2.234323E-07 * .MODEL DBLOCK D( + IS = 3.409846E-11 + RS = 3.227876E-03 + N = .2017427 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1008957 + XTI = -.4114339 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 5.892022E-12 + RS = 2.781325E-03 + N = 40.39205 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1008519 + XTI = 598.897 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 6.09432E-15 + RS = 0.3019203 + N = 1.0549419 + TT = 3.332E-8 + CJO = 1.03606E-10 + VJ = 0.6864333 + M = 0.3234913 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 85.33NS, SIMULATED TRR = 37.15NS. * RAD: PRE * TEMP= -15 .SUBCKT D1N5527/-15C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.99 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.03187E-16 + RS = 0.3723163 + N = 17.3998857 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.04456E-10 + RS = 1.7125367 + N = 0.3989047 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.32584E-15 + RS = 0.2925589 + N = 1.0616655 + TT = 2.967E-8 + CJO = 1.0074E-10 + VJ = 0.726487 + M = 0.3236062 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 62.125NS, SIMULATED TRR = 25.36NS. * RAD: PRE * TYPE: * TEMP= -55 .SUBCKT D1N5527/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.58 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.89809E-18 + RS = 0.3723163 + N = 17.135164 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.3479E-11 + RS = 1.1187321 + N = 0.7631937 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.57525E-15 + RS = 0.3058047 + N = 1.0674275 + TT = 1.4325E-8 + CJO = 9.84198E-11 + VJ = 0.781572 + M = 0.3244199 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 17.73NS, SIMULATED TRR = 18.55NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= -55 .SUBCKT D1N5527/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.82 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.5E-12 + RS = 0.9 + N = 30 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.52675E-12 + RS = 2.9078814 + N = 0.27 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.01397E-11 + RS = 0.3133147 + N = 1.2894055 + TT = 6.003E-9 + CJO = 9.58966E-11 + VJ = 0.8102661 + M = 0.3335152 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 187.66NS, SIMULATED TRR = 50.82NS. * RAD: PRE * TEMP= 125 .SUBCKT D1N5527/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.65 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.72354E-11 + RS = 0.3723163 + N = 31.6728516 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 9.68769E-20 + RS = 1.7125329 + N = 0.4507636 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.41283E-15 + RS = 0.334853 + N = 1.0492185 + TT = 4.386E-8 + CJO = 1.17382E-10 + VJ = 0.4054944 + M = 0.3106614 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.585443 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 17.70NS, SIMULATED TRR = 19.27NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N5527/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.75 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.87526E-8 + RS = 0.2934461 + N = 50.7952934 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.40296E-26 + RS = 2.6 + N = 0.31 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.49863E-15 + RS = 0.4508908 + N = 0.9754179 + TT = 5.540E-9 + CJO = 1.09177E-10 + VJ = 0.7010451 + M = 0.3701674 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5527 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A LIBRARY OF 5 PARAMETER SETS AT VARIOUS TEMPERATURES * PARAMETER M0DELS EXTRACTED FROM MEASURED DATA. * MEASURED TRR = 114.5NS, SIMULATED TRR = 38.18NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE * * RAD: PRE * TEMP= 27 .SUBCKT D1N5527/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.23 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.22339E-12 + RS = 0.311909 + N = 34.2169672 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 6.36449E-13 + RS = 2.4942243 + N = 0.4030885 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.09432E-15 + RS = 0.3019203 + N = 1.0549419 + TT = 3.332E-8 + CJO = 1.03606E-10 + VJ = 0.6864333 + M = 0.3234913 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5527 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A LIBRARY OF 6 PARAMETER SETS AT VARIOUS RADIATION LEVELS * AND TEMPERATURES. * PARAMETER M0DELS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5527/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.39 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.94108E-10 + RS = 0.2934461 + N = 37.4681933 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.41074E-13 + RS = 2.5145176 + N = 0.291385 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.06579E-12 + RS = 0.30214 + N = 1.2582631 + TT = 5.970E-9 + CJO = 1.0085E-10 + VJ = 0.6968075 + M = 0.3319606 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 33.00NS, SIMULATED TRR = 23.76NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5527/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.24 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.62531E-12 + RS = 0.3410392 + N = 28.8168933 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.11816E-14 + RS = 1.6114318 + N = 0.4195989 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.53155E-14 + RS = 0.3249671 + N = 1.090727 + TT = 1.063E-8 + CJO = 1.02881E-10 + VJ = 0.7013463 + M = 0.333793 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 18.20NS, SIMULATED TRR = 19.27NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5527/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.31 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.67606E-11 + RS = 0.276931 + N = 27.2427304 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.88787E-14 + RS = 1.6878881 + N = 0.4104822 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.34637E-12 + RS = 0.2951652 + N = 1.2569807 + TT = 6.05E-9 + CJO = 1.00729E-10 + VJ = 0.6782579 + M = 0.3190636 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 17.20NS, SIMULATED TRR = 18.22NS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5527/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.44 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.23676E-10 + RS = 0.2675964 + N = 29.8018187 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.34283E-13 + RS = 2.0000775 + N = 0.3342296 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.71991E-11 + RS = 0.3102626 + N = 1.3416707 + TT = 5.61E-9 + CJO = 9.67681E-11 + VJ = 0.676681 + M = 0.3224494 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 150.75NS, SIMULATED TRR = 44.00NS. * RAD: PRE * TYPE: * TEMP= 75 .SUBCKT D1N5527/75C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.34 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.20934E-12 + RS = 0.3723163 + N = 25.4270309 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.22472E-19 + RS = 1.6847719 + N = 0.4434771 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.7991E-15 + RS = 0.3054262 + N = 1.0633128 + TT = 3.935E-8 + CJO = 1.0782E-10 + VJ = 0.6271408 + M = 0.3317677 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5528 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. * .SUBCKT D1N5528 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 .9882486 RC 2 1 8.135973 TC = 5.647933E-04 , -4.239672E-07 * .MODEL DBLOCK D( + IS = 1.053208E-12 + RS = 4.154612E-03 + N = .2000389 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .100487 + XTI = -.3627512 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 7.30044E-13 + RS = 8.451557E-05 + N = 40.57518 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = 709.5667 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.11857E-13 + RS = .3375685 + N = 1.178789 + TT = 6.387E-8 + CJO = 9.00549E-11 + VJ = .7592107 + M = .3641609 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) + .ENDS *$ * * MEASURED TRR = 120.5NS, SIMULATED TRR = 19.01NS. * * TEMP= -55 .SUBCKT D1N5528/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 6.91 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5E-23 + RS = 20 + N = 13 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 7.07882E-19 + RS = 5.8036877 + N = 0.807479 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.21014E-14 + RS = 0.3420285 + N = 1.1332611 + TT = 9.400E-9 + CJO = 8.50296E-11 + VJ = 0.8812818 + M = 0.3670505 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 16.86NS, SIMULATED TRR = 17.49NS. * * TYPE: NEUTRON * TEMP= -55 .SUBCKT D1N5528/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.37 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.85608E-12 + RS = 0.4395019 + N = 33.2125274 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.15894E-12 + RS = 1.88 + N = 0.44 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 9.40741E-12 + RS = 0.4393418 + N = 1.2842063 + TT = 5.887E-9 + CJO = 9.16519E-11 + VJ = 0.8760971 + M = 0.3577848 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 322.0NS, SIMULATED TRR = 47.34NS. * * TEMP= 125 .SUBCKT D1N5528/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.74 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.81598E-10 + RS = 30 + N = 56.7408457 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-19 + RS = 6.4110951 + N = 0.9647652 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.03452E-14 + RS = 0.4046518 + N = 1.1284524 + TT = 4.660E-8 + CJO = 9.80038E-11 + VJ = 0.601805 + M = 0.3648333 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 17.00NS, SIMULATED TRR = 18.95NS. * * * TYPE: NEUTRON * TEMP= 125 .SUBCKT D1N5528/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 8.57 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.71851E-8 + RS = 0.4395019 + N = 38 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.10311E-26 + RS = 3.0749334 + N = 0.2619364 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 7.73561E-13 + RS = 0.5631244 + N = 1.1774965 + TT = 5.850E-9 + CJO = 1.04258E-10 + VJ = 0.6000756 + M = 0.3501605 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5528 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 196.5NS, SIMULATED TRR = 54.37NS. * * TEMP= 27 .SUBCKT D1N5528/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.25 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 9.1E-18 + RS = 0.3723 + N = 15.986 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.12181E-25 + RS = 7.8246206 + N = 0.6790878 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.11857E-13 + RS = 0.3375685 + N = 1.178789 + TT = 6.387E-8 + CJO = 9.00549E-11 + VJ = 0.7592107 + M = 0.3641609 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5528 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION CONTAINS 6 PARAMETER SETS AT VARIOUS POST * NEUTRON RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * * MEASURED TRR = 16.86NS, SIMULATED TRR = 18.22NS. * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5528/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.97 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 5.20301E-10 + RS = 0.4395019 + N = 37.8564667 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 9.48891E-18 + RS = 2.4260343 + N = 0.289726 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.96101E-12 + RS = 0.4420795 + N = 1.2746368 + TT = 5.850E-9 + CJO = 9.6357E-11 + VJ = 0.7525521 + M = 0.3534594 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 34.93NS, SIMULATED TRR = 24.12NS. * * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5528/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.93 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 3.32226E-13 + RS = 0.3230223 + N = 27.4125923 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5E-17 + RS = 10.7060657 + N = 0.3608633 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.63055E-13 + RS = 0.2631794 + N = 1.1727687 + TT = 1.379E-8 + CJO = 9.49498E-11 + VJ = 0.6568644 + M = 0.3521037 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 16.60NS, SIMULATED TRR = 18.18NS. * * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5528/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 8.21 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.961E-11 + RS = 0.3581 + N = 27.742 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.13436E-13 + RS = 15.2404318 + N = 0.1006535 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.65586E-12 + RS = 0.3215739 + N = 1.2356183 + TT = 5.84E-9 + CJO = 9.5928E-11 + VJ = 0.7218188 + M = 0.3631378 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 16.05NS, SIMULATED TRR = 17.16NS. * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5528/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 7.98 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.49026E-11 + RS = 0.3377879 + N = 25.6242667 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.48419E-16 + RS = 11.1434193 + N = 0.26 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.45144E-11 + RS = 0.3485082 + N = 1.311457 + TT = 5.79E-9 + CJO = 9.30167E-11 + VJ = 0.747647 + M = 0.3587212 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5529 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMTS OF THE PRODUCT * SPCIFICATION. .SUBCKT D1N5529 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 .6666973 RC 2 1 13.43124 TC = 6.473252E-04 , -2.931681E-07 * .MODEL DBLOCK D( + IS = 9.158323E-13 + RS = 4.93882E-03 + N = .2 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1021469 + XTI = -.3068743 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 6.531121E-12 + RS = .4290088 + N = 57.097 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1035136 + XTI = 925.671 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.89977E-13 + RS = .3996061 + N = 1.1874001 + TT = 6.782E-8 + CJO = 9.903E-11 + VJ = .6613005 + M = .288223 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .ENDS *$ * * MEASURED TRR = 130.25NS, SIMULATED TRR = 35.83NS. * * TEMP= -15 * * .SUBCKT D1N5529/-15C 99 2 R1 2 99 1E9 V2 5 99 8.41 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 9.92185E-13 + RS = 9.1500758 + N = 0.5181763 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.61689E-13 + RS = 0.3746241 + N = 1.2253782 + TT = 2.865E-8 + CJO = 9.6362E-11 + VJ = 0.7534944 + M = 0.2948708 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 90.25NS, SIMULATED TRR = 29.39NS. * * TEMP= -55 * * .SUBCKT D1N5529/-55C 99 2 R1 2 99 1E9 V2 5 99 8.1 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 9.70645E-13 + RS = 9.4289293 + N = 0.4250592 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.19893E-13 + RS = 0.3486869 + N = 1.243631 + TT = 2.035E-8 + CJO = 9.40622E-11 + VJ = 0.7829304 + M = 0.2893471 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 14.60NS, SIMULATED TRR = 18.29NS. * * TYPE: NEUTRON * TEMP= -55 * * .SUBCKT D1N5529/-55C/RAD 99 2 R1 2 99 1E9 V2 5 99 7.94 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 9.84074E-13 + RS = 1.6481363 + N = 1.2379368 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.51258E-13 + RS = 0.5028203 + N = 1.1461942 + TT = 5.91E-9 + CJO = 9.31109E-11 + VJ = 0.792047 + M = 0.2951265 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 276.0NS, SIMULATED TRR = 59.00NS. * * TEMP= 125 * * .SUBCKT D1N5529/125C 99 2 R1 2 99 1E9 V2 5 99 9.24 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 3.85397E-15 + RS = 9.0883513 + N = 0.8162871 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.30635E-13 + RS = 0.5080674 + N = 1.1921545 + TT = 6.06E-8 + CJO = 1.07237E-10 + VJ = 0.5110119 + M = 0.2893647 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 14.80NS, SIMULATED TRR = 19.31NS. * * TYPE: NEUTRON * TEMP= 125 * * .SUBCKT D1N5529/125C/RAD 99 2 R1 2 99 1E9 V2 5 99 9.33 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 1.50299E-13 + RS = 1.5252784 + N = 1.0775704 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 8.59897E-13 + RS = 0.7040669 + N = 1.1036814 + TT = 5.89E-9 + CJO = 1.06782E-10 + VJ = 0.5137448 + M = 0.2944757 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5529 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWING SECTION 5 PARAMETER SETS FOR NON-IRRADIATED DEVICES * AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS IF * USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 187.0NS, SIMULATED TRR = 59.27NS. * * TEMP= 27 * * .SUBCKT D1N5529/27C 99 2 R1 2 99 1E9 V2 5 99 8.79 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 1.04736E-12 + RS = 9.4701822 + N = 0.4989761 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.89977E-13 + RS = 0.3996061 + N = 1.1874001 + TT = 6.782E-8 + CJO = 9.903E-11 + VJ = 0.6613005 + M = 0.288223 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5529 * TYPE: DIODE * SUBTYPE: VOLTAGE REG GP * THE FOLLOWINGE SECTION CONTRAINES 6 PARAMETER SETS AT VARIOUS POST * NEUTRON LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 43.60NS, SIMULATED TRR = 28.10NS. * * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 * * .SUBCKT D1N5529/27C/RAD1 99 2 R1 2 99 1E9 V2 5 99 8.77 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 3.32795E-12 + RS = 2.5449984 + N = 0.8158561 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.74725E-13 + RS = 0.4546921 + N = 1.2015086 + TT = 1.684E-8 + CJO = 1.00851E-10 + VJ = 0.7036975 + M = 0.3072992 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 14.50NS, SIMULATED TRR = 18.65NS. * * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5529/27C/RAD2 99 2 R1 2 99 1E9 V2 5 99 8.69 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 1.03177E-12 + RS = 6.0954526 + N = 0.7982962 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.72525E-13 + RS = 0.5890903 + N = 1.0917239 + TT = 5.74E-9 + CJO = 9.76808E-11 + VJ = 0.6837467 + M = 0.2979842 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 15.50NS, SIMULATED TRR = 19.67NS. * * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5529/27C/RAD3 99 2 R1 2 99 1E9 V2 5 99 8.93 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 3.24045E-12 + RS = 2.3726142 + N = 0.4639228 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.1732E-13 + RS = 0.5123005 + N = 1.1493719 + TT = 6.02E-9 + CJO = 1.02315E-10 + VJ = 0.6910069 + M = 0.2987614 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 14.50NS, SIMULATED TRR = 18.98NS. * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5529/27C/RAD4 99 2 R1 2 99 1E9 V2 5 99 8.96 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 1.08012E-12 + RS = 3.1629123 + N = 0.518474 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.01307E-13 + RS = 0.5528449 + N = 1.115246 + TT = 5.84E-9 + CJO = 9.82074E-11 + VJ = 0.6771507 + M = 0.2950711 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 230.0NS, SIMULATED TRR = 52.64NS. * * TEMP= 75 * * .SUBCKT D1N5529/75C 99 2 R1 2 99 1E9 V2 5 99 9.14 D1 2 5 DBLOCK D2 99 2 DFOR .MODEL DBLOCK D ( + IS = 4.68112E-13 + RS = 9.3158158 + N = 0.5734794 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 3.07865E-13 + RS = 0.455149 + N = 1.1945548 + TT = 5.16E-8 + CJO = 1.02393E-10 + VJ = 0.6004294 + M = 0.291402 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5530 * TYPE: DIODE * SUBTYPE:VOLTAGE REG GP * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA . THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. * SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. .SUBCKT D1N5530 1 3 D1 1 3 DFOR D2 3 2 DBLOCK D3 3 1 DLEAK IC 1 2 1.604362 RC 2 1 6.129675 TC = 6.896787E-04 , 1.074616E-07 * .MODEL DBLOCK D( + IS = 1.015091E-12 + RS = 3.863043E-03 + N = .2017452 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1005954 + XTI = -.4337054 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) * .MODEL DLEAK D( + IS = 1.26744E-15 + RS = 3.277192E-02 + N = 26.75633 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = .1 + XTI = 575.0336 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D( + IS = 1.27703E-14 + RS = .4861642 + N = 1.0644815 + TT = 3.245E-8 + CJO = 8.21000E-11 + VJ = .7533000 + M = .3812736 + EG = .4861642 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 67.67NS, SIMULATED TRR = 22.09NS. * * TEMP= -55 * .SUBCKT D1N5530/-55C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 8.98 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.29963E-13 + RS = 30 + N = 67.0805969 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1.95E-17 + RS = 3.85 + N = 0.4965714 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.64088E-14 + RS = 0.4129186 + N = 1.0749306 + TT = 1.558E-8 + CJO = 7.38653E-11 + VJ = 0.8763208 + M = 0.3837743 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 12.87NS, SIMULATED TRR = 13.67NS. * * TYPE: NEUTRON * TEMP= -55 * .SUBCKT D1N5530/-55C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.04 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.94365E-13 + RS = 0.3302994 + N = 34.7067727 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.54452E-12 + RS = 9.8696165 + N = 0.3598047 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.89733E-11 + RS = 0.4672464 + N = 1.3265743 + TT = 5.67E-9 + CJO = 7.10359E-11 + VJ = 0.8813373 + M = 0.3840537 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 181.75NS, SIMULATED TRR = 61.32NS. * * TEMP= 125 * .SUBCKT D1N5530/125C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.6 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1E-9 + RS = 50 + N = 66.084 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2E-20 + RS = 5.93 + N = 0.409 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 2.56988E-14 + RS = 0.5453643 + N = 1.1012559 + TT = 7.095E-8 + CJO = 8.54758E-11 + VJ = 0.6016314 + M = 0.3812632 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 13.05NS, SIMULATED TRR = 15.01NS. * * TYPE: NEUTRON * TEMP= 125 * .SUBCKT D1N5530/125C/RAD 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.49 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 7.25209E-9 + RS = 0.3302994 + N = 42.072018 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.89402E-20 + RS = 6.9021802 + N = 0.4246358 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 4.46926E-12 + RS = 0.7477885 + N = 1.2331543 + TT = 5.56E-9 + CJO = 8.3409E-11 + VJ = 0.6043099 + M = 0.3853262 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5530 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 117.4NS, SIMULATED TRR = 32.70NS. * * TEMP= 27 * * * .SUBCKT D1N5530/27C 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.21 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 1.86946E-11 + RS = 1.95897E-3 + N = 113.8247095 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 8.67484E-13 + RS = 2.9995673 + N = 1.6467606 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.27703E-14 + RS = 0.4861642 + N = 1.0644815 + TT = 3.245E-8 + CJO = 8.21000E-11 + VJ = 0.7533000 + M = 0.3812736 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5530 * TYPE: DIODE * SUBTYPE:VOLTAGE _REG_GP * THE FOLLOWING SECTION CONTAINS 6 PARAMETER SETS AT VARIOUS POST * NEUTRON LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * * MEASURED TRR = 32.87NS, SIMULATED TRR = 20.43NS. * * RAD: 5.13E12 * TYPE: NEUTRON * TEMP= 27 .SUBCKT D1N5530/27C/RAD1 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.41 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 6.33714E-13 + RS = 0.4916318 + N = 33.7535797 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 5.03897E-21 + RS = 3.133148 + N = 0.4816989 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.39914E-14 + RS = 0.5080868 + N = 1.1194931 + TT = 1.178E-8 + CJO = 8.13329E-11 + VJ = 0.7675473 + M = 0.383648 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 13.65NS, SIMULATED TRR = 15.25NS. * * RAD: 1.13E15 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5530/27C/RAD2 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 10.02 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 2.80626E-10 + RS = 0.5190356 + N = 38.6424067 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 3.386E-12 + RS = 6.9532999 + N = 0.4348194 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 5.73124E-11 + RS = 0.5583542 + N = 1.3591415 + TT = 5.69E-9 + CJO = 8.20374E-11 + VJ = 0.7772309 + M = 0.396793 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 13.90NS, SIMULATED TRR = 15.18NS. * * RAD: 2.27E14 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5530/27C/RAD3 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.99 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 4.83893E-11 + RS = 0.495602 + N = 38.2042588 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 2.2518E-14 + RS = 11.6024939 + N = 0.165586 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 6.39411E-12 + RS = 0.5642076 + N = 1.2780598 + TT = 5.76E-9 + CJO = 7.93756E-11 + VJ = 0.7634433 + M = 0.3831228 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * MEASURED TRR = 12.90NS, SIMULATED TRR = 14.44NS. * * RAD: 5.59E14 * TYPE: NEUTRON * TEMP= 27 * .SUBCKT D1N5530/27C/RAD4 99 2 D1 2 99 DLEAK R1 2 99 1E12 V2 5 99 9.83 D2 2 5 DBLOCK D3 99 2 DFOR .MODEL DLEAK D ( + IS = 8.53403E-11 + RS = 0.5584691 + N = 38.7611711 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 7.6965386 + N = 0.3894542 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 1E5 + IBV = .001 + ) .MODEL DFOR D ( + IS = 1.6215E-11 + RS = 0.6018509 + N = 1.3026618 + TT = 5.56E-9 + CJO = 7.54199E-11 + VJ = 0.74439 + M = 0.3784674 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = .001 + ) .ENDS *$ * * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * MEASURED TRR = 60.5NS, SIMULATED TRR = 63.45NS. * * TEMP: -55 * * .MODEL D1N5617/-55C D ( + IS = 4.1857E-7 + RS = 0.1300384 + N = 2.402374 + TT = 8.81E-8 + CJO = 2.30368E-11 + VJ = 0.4 + M = 0.3894777 + EG = 1.11 + XTI = 2.908969 + KF = 0 + AF = 1 + FC = 0.8191792 + BV = 660 + IBV = 1E-6 + ) *$ * * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 11NS, SIMULATED TRR = 10.8NS. * RAD: 3.07E14 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N5617/27C/RAD3 D ( + IS = 3.29942E-7 + RS = 1.325395 + N = 3.208138 + TT = 1.4E-8 + CJO = 9.12522E-12 + VJ = 0.6162574 + M = 0.239753 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 664 + IBV = 5E-6 + ) *$ * * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * MEASURED TRR = 395.96NS, SIMULATED TRR = 398.6NS. * * TEMP: 125 * .MODEL D1N5617/125C D ( + IS = 4.81211E-8 + RS = 0.1138 + N = 2.020945 + TT = 5.43E-7 + CJO = 2.30368E-11 + VJ = 0.4 + M = 0.3894777 + EG = 1.11 + XTI = 4.021451 + KF = 0 + AF = 1 + FC = 0.8191792 + BV = 660 + IBV = 1E-6 + ) *$ * * GENERIC FUNCTIONAL EQUIVALENT: 1N5617 * MANUFACTURER: MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER_GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED * DEVICES AT VARYING TEMPERATURES OF THE 1N5617. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 146.75NS, SIMULATED TRR = 141.9NS. * RAD: PRE * TEMP: 27 * .MODEL D1N5617/27C D ( + IS = 4.63766E-8 + RS = 0.1716372 + N = 2 + TT = 8.3E-8 + CJO = 2.30368E-11 + VJ = 0.4 + M = 0.3894777 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8191792 + BV = 660 + IBV = 1E-6 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5617 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER_GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETERS SETS AT VARIOUS * POST NEUTRON RADIATION LEVELS OF THE 1N5617 * PARAMETER SETS EXTRACTED FROM MEASURED DATA * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * MEASURED TRR = 134.1NS, SIMULATED TRR = 133.2NS. * RAD: 2E12 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N5617/27C/RAD1 D ( + IS = 8.45286E-7 + RS = 0.1 + N = 2.503232 + TT = 1.82E-7 + CJO = 2.21568E-11 + VJ = 0.4 + M = 0.3735421 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 609 + IBV = 1E-6 + ) *$ * * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 51.36NS, SIMULATED TRR = 50.59NS. * * RAD: 3.08E13 * TYPE: NEUTRON * TEMP: 27 * .MODEL D1N5617/27C/RAD2 D ( + IS = 5.24482E-6 + RS = 0.1867392 + N = 3.105922 + TT = 6.9E-8 + CJO = 1.9208E-11 + VJ = 0.4 + M = 0.3578039 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 664 + IBV = 5E-6 + ) *$ * * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * MEASURED TRR = 59.2NS, SIMULATED TRR = 56.7NS. * * TEMP: -55 * * .MODEL D1N5619/-55C D ( + IS = 1E-6 + RS = 0.1758414 + N = 2.220375 + TT = 7.8E-8 + CJO = 2.16151E-11 + VJ = 0.4 + M = 0.4035847 + EG = 1.11 + XTI = 14 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 664 + IBV = 1E-6 + ) *$ * * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * MEASURED TRR = 375NS, SIMULATED TRR = 371.5NS. * * TEMP: 125 * * .MODEL D1N5619/125C D ( + IS = 4.05299E-8 + RS = 0.1198184 + N = 1.990765 + TT = 5E-7 + CJO = 2.16151E-11 + VJ = 0.4 + M = 0.4035847 + EG = 1.11 + XTI = 2.881086 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 664 + IBV = 1E-6 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5619 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER_GP * THIS FILE CONTAINS 4 MODELS AT VARIOUS TEMPS AND RAD LEVELS OF THE 1N5619 * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * * MEASURED TRR = 149NS, SIMULATED TRR = 141.8NS. * * * RAD: PRE * TEMP: 27 * * .MODEL D1N5619/27C D ( + IS = 4.79255E-8 + RS = 0.1726482 + N = 1.999953 + TT = 1.96E-7 + CJO = 2.16151E-11 + VJ = 0.4 + M = 0.4035847 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 664 + IBV = 1E-6 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5619 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER_GP * THE FOLLOWING SECTION CONTAINS 1 POST NEUTRON RADIATION SET OF THE * 1N5619. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 130.75NS, SIMULATED TRR = 128.8NS. * * RAD: 2E12 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N5619/27C/RAD D ( + IS = 8.16781E-7 + RS = 0.1 + N = 2.502747 + TT = 1.77E-7 + CJO = 1.91363E-11 + VJ = 0.4 + M = 0.3727131 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 671 + IBV = 1E-6 + ) *$ * * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * MEASURED TRR = 246NS, SIMULATED TRR = 240NS. * * TEMP: -55 * .MODEL D1N5621/-55C D ( + IS = 3.7E-7 + RS = 0.1075 + N = 2.392 + TT = 3.42E-7 + CJO = 1.412E-11 + VJ = 0.4 + M = 0.3106 + EG = 1.11 + XTI = 7.636 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 660 + IBV = 1E-6 + ) *$ * * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * MEASURED TRR = 913NS, SIMULATED TRR = 913.6NS. * * TEMP: 125 * .MODEL D1N5621/125C D ( + IS = 1.33555E-8 + RS = 0.1825 + N = 1.943557 + TT = 1.25E-6 + CJO = 1.412E-11 + VJ = 0.4 + M = 0.3106 + EG = 1.11 + XTI = 2.542739 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 660 + IBV = 1E-6 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5621 * TYPE: DIODE * SUBTYPE: RECTIFIER_GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED DEVICES * AT VARYING TEMPERATURE OF THE 1N5621. * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 474NS, SIMULATED TRR = 463.1NS. * * TEMP: 27 * * .MODEL D1N5621/27C D ( + IS = 1.14436E-7 + RS = 0.1 + N = 2.300601 + TT = 6.52E-7 + CJO = 1.412E-11 + VJ = 0.4 + M = 0.3106097 + EG = 1.11 + XTI = 7.636 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1.028E3 + IBV = 1E-6 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5621 * TYPE: DIODE * SUBTYPE: RECTIFIER_GP * THE FOLLOWING SECTION CONTAINS 1 POST NEUTRON PARAMETER SET OF THE 1N5621. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERAUTRE WILL PRODUCE INCORRECT RESULTS. * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 387.5NS, SIMULATED TRR = 396.6NS. * * TYPE: NEUTRON * TEMP: 27 * * .SUBCKT D1N5621/27C/RAD 99 2 D1 99 2 DFOR C1 2 99 5.17E-12 .MODEL DFOR D ( + IS = 2.45189E-7 + RS = 0.1221966 + N = 2.464084 + TT = 5.65E-7 + CJO = 5.26E-12 + VJ = 0.4 + M = 1.229 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1.1E3 + IBV = 1E-6 + ) .ENDS *$ * * MANUFACTURER NUMBER = 1N5633 * MANUFACTURER = UNITRODE * LIBRARY FILE FOR 1N5633 10V ZENER * * THE MODEL IN THIS LIBRARY CONTAINS PARAMETERS THAT WERE OPTIMIZED TO * MEASURED DATA USING IC-CAP VERSION 4.20. PARAMETERS EG AND XTI FOR MODELS * DFOR AND DLEAK HAVE NOT BEEN EXTRACTED AND ARE SET TO THEIR DEFAULT VALUES. * THIS IS NOT A TEMPERATURE COMPENSATED MODEL AND SHOULD NOT BE USED IN * CIRCUIT SIMULATIONS OTHER THAN TEMP.=27C. * .SUBCKT D1N5633/27C 1 2 D1 1 2 + DFOR D2 2 1 + DLEAK D3 2 3 + DBLOCK IC 1 3 240 RC 1 3 .035 .MODEL DFOR D ( + IS = 3.558E-12 + RS = 0.006895 + N = 1.177 + TT = 0 + CJO = 6.583E-09 + VJ = 0.5353 + M = 0.3313 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1000 + IBV = 0.001 + 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 DLEAK D ( + IS = 1.031E-09 + RS = 0 + N = 49.33 + 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 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 0 + N = 2.45 + 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 *$ .model D1N5666A D(Is=10f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=1p M=.3333 Vj=.75 + Fc=.5 Isr=3.417u Nr=2 Bv=1.971 Ibv=.7411 Tt=5n) *$ .model D1N5711 D(Is=22.31n N=1.347 Rs=17.29 Ikf=42.09 Xti=5 Eg=.7 Cjo=1.397p + M=.1659 Vj=.3914 Fc=.5 Isr=23.92n Nr=4.99 Bv=70 Ibv=10u + Tt=144.3p) *$ * * * MEASURED TRR = 1.538NS, SIMULATED TRR = 995.3PS. * * * RAD: PRERAD * TEMP: -55 .MODEL D1N5711/-55C D ( + IS = 1E-6 + RS = 17.113715 + N = 1.053479 + TT = 9.35035E-10 + CJO = 1.67685E-12 + VJ = 0.30 + M = 0.3395694 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8583689 + BV = 1E5 + IBV = 1.0E-10 + ) *$ * * * MEASURED TRR = 15.05NS, SIMULATED TRR = 4.151NS. * * * RAD: PRERAD * TEMP: 125 .MODEL D1N5711/125C D ( + IS = 1.01641E-5 + RS = 1E-3 + N = 4.0138026 + TT = 2.42E-9 + CJO = 1.66199E-12 + VJ = 0.40 + M = 0.3768642 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 1E5 + IBV = 1.0E-10 + ) *$ * * GENERIC FUNCTIONAL EQUIVALENT = 1N5711 * MANUFACTURER = HP * TYPE: DIODE * SUBTYPE: SCHOTTKY * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED DEVICES * AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 1.616NS, SIMULATED TRR = 1.152NS. * * * RAD: PRERAD * TEMP: 27 * .MODEL D1N5711/27C D ( + IS = 2.96259E-9 + RS = 29.8348444 + N = 1.04094001 + TT = 9.55310E-10 + CJO = 1.67685E-12 + VJ = 0.30 + M = 0.3395694 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8583689 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5711 * MANUFACTURER = HP * TYPE: DIODE * SUBTYPE: SCHOTTKY * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS AT VARIOUS POST NEUTRON * RADIATION LEVELS. * PARAMETER SETS EXTRACTED FROM MEASURED DATA. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 11.53NS, SIMULATED TRR = 11.29NS. * * RAD: 1E12 * TYPE: NEUTRON * TMEP: 27 * * .SUBCKT D1N5711/27C/RAD1 99 2 D1 99 2 DFOR C1 2 99 4.27449E-13 .MODEL DFOR D ( + IS = 3.52978E-9 + RS = 26.61268 + N = 1.024597 + TT = 1.69E-8 + CJO = 1.27621E-12 + VJ = 0.4 + M = 0.6973953 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 1E5 + IBV = 1E-3 + ) .ENDS *$ * * * MEASURED TRR = 9.45NS, SIMULATED TRR = 9.17NS. * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * RAD: 2E13 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N5711/27C/RAD2 D ( + IS = 1.47675E-9 + RS = 27.58028 + N = 1.000623 + TT = 1.51E-8 + CJO = 1.61139E-12 + VJ = 0.4 + M = 0.3770652 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5000066 + BV = 73.9 + IBV = 1E-6 + ) *$ * * * MEASURED TRR = 4.23NS, SIMULATED TRR = 4.05NS. * IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * RAD: 2E14 * TYPE: NEUTRON * TEMP 27 * * .MODEL D1N5711/27C/RAD3 D ( + IS = 2.14047E-9 + RS = 29.48613 + N = 1.043577 + TT = 5.73E-9 + CJO = 1.59052E-12 + VJ = 0.4 + M = 0.3227504 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 195 + IBV = 5E-6 + ) *$ .model D1N5712 D(Is=432.8p N=1 Rs=12.15 Ikf=0 Xti=5 Eg=.7 Cjo=1.175p M=.1845 + Vj=.3907 Fc=.5 Isr=2.86n Nr=1.966 Bv=20 Ibv=10u Tt=144.3p) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5765 * TYPE: GAASP LED * SUBTYPE: SOLID STATE LAMP * THIS IS A MODEL AT VARIOUS TEST CONDITIONS OF THE 1N5765. * * THIS MODEL SIMULATES ONLY THE ELECTRICAL CHARACTERISTICS OF THE DEVICE * THIS IS A TEMPERATURE COMPENSATED MODEL INTENDED FOR USE FROM -55 TO * 125 DEG C. * PARAMETER MODEL EXTRACTED FROM MEASURED DATA * * .SUBCKT D1N5765 2 99 * | | * | | * | CATHODE * ANODE I1 99 4 7.0 D1 2 99 DLOW D2 2 4 DHIGH R1 4 99 .1 TC=-6.27E-3,-2.33E-7 * .MODEL DLOW D ( + IS = 1.0E-15 + RS = 100 + N = 2.15 + TT = 10.0E-09 + CJO = 8.285237E-11 + VJ = 1.2076937 + M = 0.4053107 + EG = 1.664 + XTI = 10.78 + KF = 0 + AF = 1 + FC = 0.4340008 + BV = 5.0 + IBV = 1E-4 + ) .MODEL DHIGH D ( + IS = 9.0E-15 + RS = 0.30 + N = 1.2 + TT = 0 + CJO = 0 + VJ = 1 + M = .5 + EG = 0.1 + XTI = -3.84 + KF = 0 + AF = 1 + FC = .5 + BV = 9.9999E+13 + IBV = .001 + ) .ENDS *$ * * * MEASURED TRR = 13.14NS, SIMULATED TRR = 10.17NS. * * TEMP: -55 .MODEL D1N5806/-55C D ( + IS = 5.34578E-8 + RS = 0.0640264 + N = 1.7823373 + TT = 7.65E-9 + CJO = 3.21228E-11 + VJ = 0.3 + M = 0.2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * MEASURED TRR = 36.8NS, SIMULATED TRR = 27.00NS. * * TEMP: 125 .MODEL D1N5806/125C D ( + IS = 1.82094E-8 + RS = 0.1187774 + N = 1.6444874 + TT = 2.96E-8 + CJO = 3.15091E-11 + VJ = 0.4 + M = 0.2078398 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5806 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER_FAST_RECOV * THIS FILE CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED DEVICES AT * VARYING TEMPERATURES OF THE 1N5806. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 26.08NS, SIMULATED TRR = 15.09NS. * RAD: PRERAD * TEMP: 27 .MODEL D1N5806/27C D ( + IS = 1.82777E-8 + RS = 0.1367235 + N = 1.6126814 + TT = 1.343E-8 + CJO = 3.21228E-11 + VJ = 0.3 + M = 0.2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5806 * MANUFACTURERS PART NO. = 1N5806 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER_FAST_RECOV * THIS FILE CONTAINS 3 PARAMETER SETS AT VARIOUS POST NUETRON RADIATION * LEVELS OF THE 1N5806. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA. *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * MEASURED TRR = 17.7NS, SIMULATED TRR = 17.2NS. * * RAD: 5E12 * TYPE: NEUTRON * TEMP 27 * .MODEL D1N5806/27C/RAD1 D ( + IS = 3.51316E-8 + RS = 0.120717 + N = 1.663007 + TT = 1.85E-8 + CJO = 2.7476E-11 + VJ = 0.4 + M = 0.204799 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 213.5 + IBV = 5E-6 + ) *$ * * * MEASURED TRR = 17.68NS, SIMULATED TRR = 17.97NS. * * RAD: 2E13 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N5806/27C/RAD2 D ( + IS = 2.76017E-8 + RS = 0.113459 + N = 1.645347 + TT = 1.9E-8 + CJO = 3.25853E-11 + VJ = 0.4359477 + M = 0.233045 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-3 + ) *$ * * * MEASURED TRR = 11.7NS, SIMULATED TRR = 11.8NS. * * RAD: 2.73E14 * TYPE: NEUTRON * TEMP: 27 * * .MODEL D1N5806/27C/RAD3 D ( + IS = 5.69489E-8 + RS = 0.1455731 + N = 1.709307 + TT = 9.3E-9 + CJO = 5.31594E-11 + VJ = 0.4 + M = 0.4023053 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1E5 + IBV = 1E-3 + ) *$ * * * MEASURED TRR = 28.33NS, SIMULATED TRR = 29.39NS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * RAD: PRERAD * TEMP= -55 .MODEL D1N5811/-55C D ( + IS = 9.02353E-8 + RS = 0.0280087 + N = 1.6968846 + TT = 1.1413E-8 + CJO = 1.48755E-10 + VJ = 0.5130456 + M = 0.4810824 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.998001 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * MEASURED TRR = 61.13NS, SIMULATED TRR = 66.31NS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * RAD: PRERAD * TEMP= 125 .MODEL D1N5811/125C D ( + IS = 3.55358E-8 + RS = 0.0315851 + N = 1.6183596 + TT = 4.1413E-8 + CJO = 1.52193E-10 + VJ = 0.4 + M = 0.4927103 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N5811 * TYPE: DIODE * SUBTYPE: RECTIFIER-FAST-RECOV * THIS FILE CONTAINS 6 PARAMETER SETS AT PRE-IRRADIATION LEVELS * AND TEMPERATURES OF THE 1N5811. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * * MEASURED TRR = 49.20NS, SIMULATED TRR = 67.03NS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * RAD: PRERAD * TEMP= 27 .MODEL D1N5811/27C D ( + IS = 2.23137E-8 + RS = 0.0679124 + N = 1.5116445 + TT = 2.263E-8 + CJO = 1.48755E-10 + VJ = 0.5130456 + M = 0.4810824 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.998001 + BV = 1E5 + IBV = 1E-10 + ) *$ * * RAD: 2.73E14 * TYPE: NEUTRON * TEMP: 27 * * BV, IBV, XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * * MEASURED TRR = 26.6NS, SIMULATED TRR = 26.13NS. * .MODEL D1N5811/27C/RAD1 D ( + IS = 2.1791E-7 + RS = 0.0685813 + N = 1.697998 + TT = 1.96E-8 + CJO = 1.1036E-10 + VJ = 0.4 + M = 0.3289155 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 1E5 + IBV = 1E-3 + ) *$ * * RAD: 5E12 * TYPE: NEUTRON * TEMP: 27 * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * * MEASURED TRR = 38.5NS, SIMULATED TRR = 37.61NS. * .MODEL D1N5811/27C/RAD2 D ( + IS = 5.80795E-8 + RS = 0.046108 + N = 1.604571 + TT = 3.E-8 + CJO = 1.35157E-10 + VJ = 0.4 + M = 0.2968859 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 202 + IBV = 5E-6 + ) *$ * * * RAD: 2E13 * TYPE: NEUTRON * TEMP: 27 * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * * MEASURED TRR = 35.07NS, SIMULATED TRR = 35.38NS. * .SUBCKT D1N5811/27C/RAD3 99 2 D1 99 2 DFOR C1 2 99 3.95197E-11 .MODEL DFOR D ( + IS = 5.83097E-8 + RS = 0.0496566 + N = 1.605941 + TT = 2.6E-8 + CJO = 9.05771E-11 + VJ = 0.4 + M = 0.5200793 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 196 + IBV = 5E-6 + ) .ENDS *$ .model D1N5817 D(Is=2.835u Rs=47.12m Ikf=.3227 N=1 Xti=0 Eg=1.11 Cjo=472.4p + M=.6215 Vj=.75 Fc=.5 Isr=37.75u Nr=2) * Motorola pid=1N5817 case=59-04 * 88-09-12 rmn *$ .model D1N5818 D(Is=2.835u Rs=47.12m Ikf=.3227 N=1 Xti=0 Eg=1.11 Cjo=359.3p + M=.6513 Vj=.75 Fc=.5 Isr=26.46u Nr=2) * Motorola pid=1N5817 case=59-04 * 88-09-12 rmn *$ .model D1N5819 D(Is=2.835u Rs=47.12m Ikf=.3227 N=1 Xti=0 Eg=1.11 Cjo=302.5p + M=.7206 Vj=.75 Fc=.5 Isr=16.98u Nr=2) * Motorola pid=1N5817 case=59-04 * 88-09-12 rmn *$ .model D1N5820 D(Is=8.425u Rs=34.63m Ikf=2.37 N=1 Xti=0 Eg=1.11 Cjo=1.288n + M=.5324 Vj=.75 Fc=.5 Isr=58.32u Nr=2) * Motorola pid=1N5820 case=267-01 * 88-09-13 rmn *$ .model D1N5821 D(Is=8.425u Rs=34.63m Ikf=2.37 N=1 Xti=0 Eg=1.11 Cjo=1.132n + M=.6043 Vj=.75 Fc=.5 Isr=31.98u Nr=2) * Motorola pid=1N5820 case=267-01 * 88-09-13 rmn *$ .model D1N5822 D(Is=8.425u Rs=34.63m Ikf=2.37 N=1 Xti=0 Eg=1.11 Cjo=1.032n + M=.6736 Vj=.75 Fc=.5 Isr=9.599u Nr=2) * Motorola pid=1N5820 case=267-01 * 88-09-13 rmn *$ .model D1N5823 D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=2.224n + M=.465 Vj=.75 Fc=.5 Isr=845.5u Nr=2) * Motorola pid=1N5823 case=60-01 * 88-09-13 rmn *$ .model D1N5824 D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=1.782n + M=.4666 Vj=.75 Fc=.5 Isr=699.9u Nr=2) * Motorola pid=1N5823 case=60-01 * 88-09-13 rmn *$ .model D1N5825 D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=1.537n + M=.4545 Vj=.75 Fc=.5 Isr=673.4u Nr=2) * Motorola pid=1N5823 case=60-01 * 88-09-13 rmn *$ .model D1N5826 D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=2.248n + M=.465 Vj=.75 Fc=.5 Isr=845.5u Nr=2) * Motorola pid=1N5826 case=DO4 * 88-09-13 rmn *$ .model D1N5827 D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=1.814n + M=.468 Vj=.75 Fc=.5 Isr=696.4u Nr=2) * Motorola pid=1N5826 case=DO4 * 88-09-13 rmn *$ .model D1N5828 D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=1.541n + M=.4553 Vj=.75 Fc=.5 Isr=666.5u Nr=2) * Motorola pid=1N5826 case=DO4 * 88-09-13 rmn *$ .model D1N5829 D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=0 Eg=1.11 Cjo=5.046n + M=.5192 Vj=.75 Fc=.5 Isr=1.5m Nr=2) * Motorola pid=1N5829 case=DO4 * 88-09-13 rmn *$ .model D1N5830 D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=0 Eg=1.11 Cjo=4.091n + M=.5169 Vj=.75 Fc=.5 Isr=1.175m Nr=2) * Motorola pid=1N5829 case=DO4 * 88-09-13 rmn *$ .model D1N5831 D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=0 Eg=1.11 Cjo=3.488n + M=.5044 Vj=.75 Fc=.5 Isr=1.188m Nr=2) * Motorola pid=1N5829 case=DO4 * 88-09-13 rmn *$ .model D1N5832 D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=3 Eg=1.11 Cjo=5.046n + M=.5192 Vj=.75 Fc=.5 Isr=1.5m Nr=2) * Motorola pid=1N5832 case=257-01 * 88-09-13 rmn *$ .model D1N5833 D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=3 Eg=1.11 Cjo=4.091n + M=.5169 Vj=.75 Fc=.5 Isr=1.175m Nr=2) * Motorola pid=1N5832 case=257-01 * 88-09-13 rmn *$ .model D1N5834 D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=3 Eg=1.11 Cjo=3.488n + M=.5044 Vj=.75 Fc=.5 Isr=1.188m Nr=2) * Motorola pid=1N5832 case=257-01 * 88-09-13 rmn *$ .model D1N6036 D(Is=84.5f N=1 Rs=.1 Ikf=0 Xti=3 Eg=1.11 Cjo=7.287n M=.3333 + Vj=.75 Fc=.5 Isr=493.3u Nr=2 Bv=7.503 Ibv=11.76m Tt=144.3n) *$ .model D1N6095 D(Is=1.133u Rs=2.964m Ikf=4.886 N=1 Xti=0 Eg=1.11 Cjo=2.139n + M=.4916 Vj=.75 Fc=.5 Isr=4.409u Nr=2) * Motorola pid=1N6095 case=DO4 * 88-09-13 rmn *$ .model D1N6096 D(Is=1.133u Rs=2.964m Ikf=4.886 N=1 Xti=0 Eg=1.11 Cjo=2.139n + M=.4916 Vj=.75 Fc=.5 Isr=6.645u Nr=2) * Motorola pid=1N6095 case=DO4 * 88-09-13 rmn *$ .model D1N6097 D(Is=793.4n Rs=3.036m Ikf=8.242 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=16.81u Nr=2) * Motorola pid=1N6097 case=DO5 * 88-09-15 rmn *$ .model D1N6098 D(Is=793.4n Rs=3.036m Ikf=8.242 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=29.51u Nr=2) * Motorola pid=1N6097 case=DO5 * 88-09-15 rmn *$ * * * GENERIC FUNCTIONAL EQUIVALENT = 1N821 * MANUFACTURER = MICROSEMI * * TYPE: DIODE * SUBTYPE: 6.2 T.C. ZENER * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT * THE RESPONSES OF NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE * LIMITS OF THE PRODUCT SPECIFICATION. * * RAD: PRERAD * TEMP: 27 * .SUBCKT D1N821 1 2 D1 1 2 DFOR D2 2 1 DLEAK D3 2 3 DBLOCK IC 1 3 1.574 RC 1 3 2.978 TC = -0.001066 , -2.711E-07 * .MODEL DFOR D ( + IS = 1E-14 + RS = 100 + N = 500 + CJO = 2.459E-11 + VJ = 1.258 + M = 0.1137 + EG = 1.11 + XTI = 3 + FC = 0.5 + BV = 1000 + IBV = 0.001 + ) * .MODEL DLEAK D ( + IS = 4.486E-13 + RS = 1 + N = 14.13 + EG = 5.64 + XTI = 5.606 + ) .MODEL DBLOCK D ( + IS = 1E-12 + RS = 0 + N = 3.007 + CJO = 0 + EG = 0.1 + XTI = -3.86 + + ) .ENDS *$ * * * RAD: PRE * TEMP: -55 * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * .MODEL DLA3622-99/-55C D ( + IS = 3.26655E-11 + RS = 0.0759784 + N = 1.574182 + TT = 2.41E-7 + CJO = 5.95944E-13 + VJ = 0.6957356 + M = 0.2 + EG = 1.11 + XTI = 6.561277 + KF = 0 + AF = 1 + FC = 0.8993638 + BV = 230 + IBV = 1E-6 + ) *$ * * * RAD: PRE * TEMP: 125 * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * .MODEL DLA3622-99/125C D ( + IS = 8.18168E-11 + RS = 0.0880267 + N = 1.639311 + TT = 3.54E-7 + CJO = 5.95944E-13 + VJ = 0.6957356 + M = 0.2 + EG = 1.11 + XTI = 4.635288 + KF = 0 + AF = 1 + FC = 0.8993638 + BV = 230 + IBV = 1E-6 + ) *$ * * * TYPE: DIODE * SUBTYPE: MICROWAVE * THIS FILE CONTAINS 3 PRE-RAD MODELS AT VARIOUS TEMPS. * THESE ARE LOW FREQUENCY MODELS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * RAD: PRE * TEMP: 27 * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * .MODEL DLA3622-99/27C D ( + IS = 6.37147E-11 + RS = 0.1 + N = 1.618177 + TT = 2.95E-7 + CJO = 5.95944E-13 + VJ = 0.6957356 + M = 0.2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8993638 + BV = 230 + IBV = 1E-6 + ) *$ .model MBD101 D(Is=192.1p Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=893.8f M=98.29m + Vj=.75 Fc=.5 Isr=16.91n Nr=2 Bv=5 Ibv=10u) * Motorola pid=MBD101 case=182-03 * 88-09-22 bam creation *$ .model MBD201 D(Is=1.684p Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=2.034p M=.2771 + Vj=.75 Fc=.5 Isr=4.301n Nr=2 Bv=20 Ibv=10u) * Motorola pid=MBD201 case=182-03 * 88-09-22 bam creation *$ .model MBD301 D(Is=1.684p Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=2.034p M=.2771 + Vj=.75 Fc=.5 Isr=4.879n Nr=2 Bv=30 Ibv=10u) * Motorola pid=MBD201 case=182-03 * 88-09-22 bam creation *$ .model MBD501 D(Is=276.7E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=1.778p M=.3694 + Vj=.75 Fc=.5 Isr=2.031n Nr=2 Bv=50 Ibv=10u) * Motorola pid=MBD501 case=TO92 * 88-09-22 bam creation *$ .model MBD701 D(Is=276.7E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=1.778p M=.3694 + Vj=.75 Fc=.5 Isr=2.573n Nr=2 Bv=70 Ibv=10u) * Motorola pid=MBD501 case=TO92 * 88-09-22 bam creation *$ .model MBR030 D(Is=12.29n Rs=.102 Ikf=15.89m N=1 Xti=0 Eg=1.11 Cjo=90p + M=.1112 Vj=.75 Fc=.5 Isr=1.977u Nr=2) * Motorola pid=MBR030 case=DO35 * 88-09-15 rmn *$ .model MBR040 D(Is=12.29n Rs=.102 Ikf=15.89m N=1 Xti=0 Eg=1.11 Cjo=90p + M=.1112 Vj=.75 Fc=.5 Isr=1.916u Nr=2) * Motorola pid=MBR030 case=DO35 * 88-09-15 rmn *$ .model MBR115P D(Is=2.835u Rs=47.12m Ikf=.3227 N=1 Xti=0 Eg=1.11 Cjo=472.4p + M=.6215 Vj=.75 Fc=.5 Isr=37.26u Nr=2) * Motorola pid=1N5817 case=59-04 * 88-09-12 rmn *$ .model MBR120P D(Is=2.835u Rs=47.12m Ikf=.3227 N=1 Xti=0 Eg=1.11 Cjo=472.4p + M=.6215 Vj=.75 Fc=.5 Isr=37.75u Nr=2) * Motorola pid=1N5817 case=59-04 * 88-09-12 rmn *$ .model MBR130P D(Is=2.835u Rs=47.12m Ikf=.3227 N=1 Xti=0 Eg=1.11 Cjo=359.3p + M=.6513 Vj=.75 Fc=.5 Isr=26.46u Nr=2) * Motorola pid=1N5817 case=59-04 * 88-09-12 rmn *$ .model MBR140P D(Is=2.835u Rs=47.12m Ikf=.3227 N=1 Xti=0 Eg=1.11 Cjo=302.5p + M=.7206 Vj=.75 Fc=.5 Isr=16.98u Nr=2) * Motorola pid=1N5817 case=59-04 * 88-09-12 rmn *$ .model MBR320 D(Is=823.9n Rs=18.27m Ikf=.5654 N=1 Xti=0 Eg=1.11 Cjo=477.2p + M=.4787 Vj=.75 Fc=.5 Isr=382.9n Nr=2) * Motorola pid=MBR320 case=267-01 * 88-09-15 rmn *$ .model MBR320M D(Is=15.65u Rs=5.102m Ikf=5.993 N=1 Xti=0 Eg=1.11 Cjo=2.22n + M=.4625 Vj=.75 Fc=.5 Isr=858.1u Nr=2) * Motorola pid=MBR320M case=60 * 88-09-15 rmn *$ .model MBR320P D(Is=8.425u Rs=34.63m Ikf=2.37 N=1 Xti=0 Eg=1.11 Cjo=1.288n + M=.5324 Vj=.75 Fc=.5 Isr=58.32u Nr=2) * Motorola pid=1N5820 case=267-01 * 88-09-13 rmn *$ .model MBR330 D(Is=823.9n Rs=18.27m Ikf=.5654 N=1 Xti=0 Eg=1.11 Cjo=477.2p + M=.4787 Vj=.75 Fc=.5 Isr=486.2n Nr=2) * Motorola pid=MBR320 case=267-01 * 88-09-15 rmn *$ .model MBR330M D(Is=15.65u Rs=5.102m Ikf=5.993 N=1 Xti=0 Eg=1.11 Cjo=1.701n + M=.4567 Vj=.75 Fc=.5 Isr=730.8u Nr=2) * Motorola pid=MBR320M case=60 * 88-09-15 rmn *$ .model MBR330P D(Is=8.425u Rs=34.63m Ikf=2.37 N=1 Xti=0 Eg=1.11 Cjo=1.132n + M=.6043 Vj=.75 Fc=.5 Isr=31.98u Nr=2) * Motorola pid=1N5820 case=267-01 * 88-09-13 rmn *$ .model MBR340 D(Is=823.9n Rs=18.27m Ikf=.5654 N=1 Xti=0 Eg=1.11 Cjo=477.2p + M=.4787 Vj=.75 Fc=.5 Isr=838.6n Nr=2) * Motorola pid=MBR320 case=267-01 * 88-09-15 rmn *$ .model MBR340M D(Is=15.65u Rs=5.102m Ikf=5.993 N=1 Xti=0 Eg=1.11 Cjo=1.543n + M=.4614 Vj=.75 Fc=.5 Isr=730.8u Nr=2) * Motorola pid=MBR320M case=60 * 88-09-15 rmn *$ .model MBR340P D(Is=8.425u Rs=34.63m Ikf=2.37 N=1 Xti=0 Eg=1.11 Cjo=1.032n + M=.6736 Vj=.75 Fc=.5 Isr=9.599u Nr=2) * Motorola pid=1N5820 case=267-01 * 88-09-13 rmn *$ .model MBR350 D(Is=403.6n Rs=36.68m Ikf=.6653 N=1 Xti=0 Eg=1.11 Cjo=502.8p + M=.5778 Vj=.75 Fc=.5 Isr=577.8n Nr=2) * Motorola pid=MBR320 case=267-01 * 88-09-15 rmn *$ .model MBR360 D(Is=403.6n Rs=36.68m Ikf=.6653 N=1 Xti=0 Eg=1.11 Cjo=502.8p + M=.5778 Vj=.75 Fc=.5 Isr=718.2n Nr=2) * Motorola pid=MBR320 case=267-01 * 88-09-15 rmn *$ .model MBR1035 D(Is=168.4n Rs=8.013m Ikf=1.121 N=1 Xti=0 Eg=1.11 Cjo=888.9p + M=.4639 Vj=.75 Fc=.5 Isr=6.634u Nr=2) * Motorola pid=MBR1035 case=TO220AC * 88-09-15 rmn *$ .model MBR1045 D(Is=168.4n Rs=8.013m Ikf=1.121 N=1 Xti=0 Eg=1.11 Cjo=888.9p + M=.4639 Vj=.75 Fc=.5 Isr=10.37u Nr=2) * Motorola pid=MBR1035 case=TO220AC * 88-09-15 rmn *$ .model MBR1520 D(Is=4.091u Rs=4.683m Ikf=3.519 N=1 Xti=0 Eg=1.11 Cjo=2.216n + M=.4608 Vj=.75 Fc=.5 Isr=865.4u Nr=2) * Motorola pid=MBR1520 case=DO4 * 88-09-15 rmn *$ .model MBR1530 D(Is=4.091u Rs=4.683m Ikf=3.519 N=1 Xti=0 Eg=1.11 Cjo=1.782n + M=.4666 Vj=.75 Fc=.5 Isr=706.4u Nr=2) * Motorola pid=MBR1520 case=DO4 * 88-09-15 rmn *$ .model MBR1540 D(Is=4.091u Rs=4.683m Ikf=3.519 N=1 Xti=0 Eg=1.11 Cjo=1.583n + M=.4619 Vj=.75 Fc=.5 Isr=655u Nr=2) * Motorola pid=MBR1520 case=DO4 * 88-09-15 rmn *$ *model MBR2035CT anode1 * | anode2 * | | cathode * | | | .subckt MBR2035CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=196.8n Rs=8.535m Ikf=7.25 N=1 Xti=0 Eg=1.11 Cjo=892.3p + M=.4684 Vj=.75 Fc=.5 Isr=10.18u Nr=2) * Motorola pid=MBR2035CT case=TO220AB * 88-09-20 rmn .ends *$ *model MBR2045CT anode1 * | anode2 * | | cathode * | | | .subckt MBR2045CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=196.8n Rs=8.535m Ikf=7.25 N=1 Xti=0 Eg=1.11 Cjo=892.3p + M=.4684 Vj=.75 Fc=.5 Isr=6.84u Nr=2) * Motorola pid=MBR2035CT case=TO220AB * 88-09-20 rmn .ends *$ .model MBR2520 D(Is=21u Rs=5.011m Ikf=69.6 N=1 Xti=0 Eg=1.11 Cjo=5.088n + M=.5217 Vj=.75 Fc=.5 Isr=1.482m Nr=2) * Motorola pid=MBR2520 case=DO4 * 88-09-20 rmn *$ .model MBR2530 D(Is=21u Rs=5.011m Ikf=69.6 N=1 Xti=0 Eg=1.11 Cjo=4.111n + M=.5182 Vj=.75 Fc=.5 Isr=1.179m Nr=2) * Motorola pid=MBR2520 case=DO4 * 88-09-20 rmn *$ .model MBR2540 D(Is=21u Rs=5.011m Ikf=69.6 N=1 Xti=0 Eg=1.11 Cjo=3.507n + M=.5031 Vj=.75 Fc=.5 Isr=1.176m Nr=2) * Motorola pid=MBR2520 case=DO4 * 88-09-20 rmn *$ *model MBR3020CT anode1 * | anode2 * | | cathode * | | | .subckt MBR3020CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=489n Rs=7.299m Ikf=80.79 N=1 Xti=0 Eg=1.11 Cjo=2.144n + M=.4923 Vj=.75 Fc=.5 Isr=2.535u Nr=2) * Motorola pid=MBR3020CT case=TO204AA * 88-09-20 rmn .ends *$ *model MBR3035CT anode1 * | anode2 * | | cathode * | | | .subckt MBR3035CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=489n Rs=7.299m Ikf=80.79 N=1 Xti=0 Eg=1.11 Cjo=2.144n + M=.4923 Vj=.75 Fc=.5 Isr=3.879u Nr=2) * Motorola pid=MBR3020CT case=TO204AA * 88-09-20 rmn .ends *$ *model MBR3035PT anode1 * | anode2 * | | cathode * | | | .subckt MBR3035PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=489n Rs=7.299m Ikf=80.79 N=1 Xti=0 Eg=1.11 Cjo=2.144n + M=.4923 Vj=.75 Fc=.5 Isr=3.879u Nr=2) * Motorola pid=MBR3020PT case=TO204AA * 88-09-20 rmn .ends *$ *model MBR3045CT anode1 * | anode2 * | | cathode * | | | .subckt MBR3045CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=489n Rs=7.299m Ikf=80.79 N=1 Xti=0 Eg=1.11 Cjo=2.144n + M=.4923 Vj=.75 Fc=.5 Isr=7.268u Nr=2) * Motorola pid=MBR3020CT case=TO204AA * 88-09-20 rmn .ends *$ *model MBR3045PT anode1 * | anode2 * | | cathode * | | | .subckt MBR3045PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=489n Rs=7.299m Ikf=80.79 N=1 Xti=0 Eg=1.11 Cjo=2.144n + M=.4923 Vj=.75 Fc=.5 Isr=7.268u Nr=2) * Motorola pid=MBR3020PT case=TO204AA * 88-09-20 rmn .ends *$ .model MBR3520 D(Is=271.1n Rs=2.727m Ikf=4.793 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=12.22u Nr=2) * Motorola pid=MBR3520 case=DO4 * 88-09-21 rmn *$ .model MBR3535 D(Is=271.1n Rs=2.727m Ikf=4.793 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=22.08u Nr=2) * Motorola pid=MBR3520 case=DO4 * 88-09-21 rmn *$ .model MBR3545 D(Is=271.1n Rs=2.727m Ikf=4.793 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.25u Nr=2) * Motorola pid=MBR3520 case=DO4 * 88-09-21 rmn *$ .model MBR3545H D(Is=271.1n Rs=2.727m Ikf=4.793 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.25u Nr=2) * Motorola pid=MBR3520 case=DO4 * 88-09-21 rmn *$ .model MBR3545H1 D(Is=271.1n Rs=2.727m Ikf=4.793 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.25u Nr=2) * Motorola pid=MBR3520 case=DO4 * 88-09-21 rmn *$ .model MBR4020 D(Is=27.51u Rs=5.244m Ikf=124.2 N=1 Xti=0 Eg=1.11 Cjo=5.088n + M=.5217 Vj=.75 Fc=.5 Isr=1.481m Nr=2) * Motorola pid=MBR4020 case=DO5 * 88-09-21 rmn *$ .model MBR4030 D(Is=27.51u Rs=5.244m Ikf=124.2 N=1 Xti=0 Eg=1.11 Cjo=4.111n + M=.5182 Vj=.75 Fc=.5 Isr=1.164m Nr=2) * Motorola pid=MBR4020 case=DO5 * 88-09-21 rmn *$ .model MBR4040 D(Is=27.51u Rs=5.244m Ikf=124.2 N=1 Xti=0 Eg=1.11 Cjo=3.468n + M=.5003 Vj=.75 Fc=.5 Isr=1.175m Nr=2) * Motorola pid=MBR4020 case=DO5 * 88-09-21 rmn *$ .model MBR5825H D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=1.537n + M=.4545 Vj=.75 Fc=.5 Isr=673.4u Nr=2) * Motorola pid=1N5823 case=60-01 * 88-09-13 rmn *$ .model MBR5825H1 D(Is=40.53u Rs=4.338m Ikf=58.4 N=1 Xti=0 Eg=1.11 Cjo=1.537n + M=.4545 Vj=.75 Fc=.5 Isr=673.4u Nr=2) * Motorola pid=1N5823 case=60-01 * 88-09-13 rmn *$ .model MBR5831H D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=0 Eg=1.11 Cjo=3.488n + M=.5044 Vj=.75 Fc=.5 Isr=1.188m Nr=2) * Motorola pid=1N5829 case=DO4 * 88-09-13 rmn *$ .model MBR5831H1 D(Is=89.43u Rs=3.991m Ikf=163.5 N=1 Xti=0 Eg=1.11 Cjo=3.488n + M=.5044 Vj=.75 Fc=.5 Isr=1.188m Nr=2) * Motorola pid=1N5829 case=DO4 * 88-09-13 rmn *$ .model MBR6035 D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=21.96u Nr=2) * Motorola pid=MBR6035 case=257-01 * 88-09-21 rmn *$ .model MBR6035B D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=21.96u Nr=2) * Motorola pid=MBR6035 case=257-01 * 88-09-21 rmn *$ .model MBR6035PF D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=21.96u Nr=2) * Motorola pid=MBR6035PF case=DO21 * 88-09-21 rmn *$ .model MBR6045 D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.14u Nr=2) * Motorola pid=MBR6035 case=257-01 * 88-09-21 rmn *$ .model MBR6045B D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.14u Nr=2) * Motorola pid=MBR6035 case=257-01 * 88-09-21 rmn *$ .model MBR6045H D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.14u Nr=2) * Motorola pid=MBR6035 case=257-01 * 88-09-21 rmn *$ .model MBR6045H1 D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.14u Nr=2) * Motorola pid=MBR6035 case=257-01 * 88-09-21 rmn *$ .model MBR6045PF D(Is=792.9n Rs=3.092m Ikf=8.666 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=39.14u Nr=2) * Motorola pid=MBR6035PF case=DO21 * 88-09-21 rmn *$ .model MBR6535 D(Is=183.5n Rs=1.6m Ikf=5.736 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=791.2n Nr=2) * Motorola pid=MBR6535 case=DO5 * 88-09-21 rmn *$ .model MBR6545 D(Is=183.5n Rs=1.6m Ikf=5.736 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=1.376u Nr=2) * Motorola pid=MBR6535 case=DO5 * 88-09-21 rmn *$ .model MBR7520 D(Is=4.014u Rs=1.915m Ikf=20.97 N=1 Xti=0 Eg=1.11 Cjo=11.08n + M=.5 Vj=.75 Fc=.5 Isr=31.56u Nr=2) * Motorola pid=MBR7520 case=DO5 * 88-09-21 rmn *$ .model MBR7530 D(Is=4.014u Rs=1.915m Ikf=20.97 N=1 Xti=0 Eg=1.11 Cjo=11.08n + M=.5 Vj=.75 Fc=.5 Isr=46.23u Nr=2) * Motorola pid=MBR7520 case=DO5 * 88-09-21 rmn *$ .model MBR7535 D(Is=4.014u Rs=1.915m Ikf=20.97 N=1 Xti=0 Eg=1.11 Cjo=11.08n + M=.5 Vj=.75 Fc=.5 Isr=57.36u Nr=2) * Motorola pid=MBR7520 case=DO5 * 88-09-21 rmn *$ .model MBR7540 D(Is=4.014u Rs=1.915m Ikf=20.97 N=1 Xti=0 Eg=1.11 Cjo=11.08n + M=.5 Vj=.75 Fc=.5 Isr=71.36u Nr=2) * Motorola pid=MBR7520 case=DO5 * 88-09-21 rmn *$ .model MBR7545 D(Is=4.014u Rs=1.915m Ikf=20.97 N=1 Xti=0 Eg=1.11 Cjo=11.08n + M=.5 Vj=.75 Fc=.5 Isr=91.68u Nr=2) * Motorola pid=MBR7520 case=DO5 * 88-09-21 rmn *$ .model MBR8035 D(Is=980.4n Rs=1.254m Ikf=3.283 N=1 Xti=0 Eg=1.11 Cjo=6.349n + M=.4915 Vj=.75 Fc=.5 Isr=1.649u Nr=2) * Motorola pid=MBR8035 case=DO5 * 88-09-21 rmn *$ .model MBR8045 D(Is=980.4n Rs=1.254m Ikf=3.283 N=1 Xti=0 Eg=1.11 Cjo=6.349n + M=.4915 Vj=.75 Fc=.5 Isr=2.787u Nr=2) * Motorola pid=MBR8035 case=DO5 * 88-09-21 rmn *$ *model MBR12035CT anode1 * | anode2 * | | cathode * | | | .subckt MBR12035CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=4.052n + M=.5058 Vj=.75 Fc=.5 Isr=2.363u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR12045CT anode1 * | anode2 * | | cathode * | | | .subckt MBR12045CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=4.052n + M=.5058 Vj=.75 Fc=.5 Isr=4.962u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR12050CT anode1 * | anode2 * | | cathode * | | | .subckt MBR12050CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=4.052n + M=.5058 Vj=.75 Fc=.5 Isr=4.962u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR12060CT anode1 * | anode2 * | | cathode * | | | .subckt MBR12060CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=4.052n + M=.5058 Vj=.75 Fc=.5 Isr=4.962u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR20035CT anode1 * | anode2 * | | cathode * | | | .subckt MBR20035CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=8.95n + M=.4719 Vj=.75 Fc=.5 Isr=1.434u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR20045CT anode1 * | anode2 * | | cathode * | | | .subckt MBR20045CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=8.95n + M=.4719 Vj=.75 Fc=.5 Isr=2.47u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR20050CT anode1 * | anode2 * | | cathode * | | | .subckt MBR20050CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=8.95n + M=.4719 Vj=.75 Fc=.5 Isr=3.652u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR20060CT anode1 * | anode2 * | | cathode * | | | .subckt MBR20060CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=315.7n Rs=1.179m Ikf=2.094 N=1 Xti=0 Eg=1.11 Cjo=8.95n + M=.4719 Vj=.75 Fc=.5 Isr=3.652u Nr=2) * Motorola pid=MBR12035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR30035CT anode1 * | anode2 * | | cathode * | | | .subckt MBR30035CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=832.5n Rs=262.1u Ikf=3.986 N=1 Xti=0 Eg=1.11 Cjo=12.18n + M=.4673 Vj=.75 Fc=.5 Isr=5.616u Nr=2) * Motorola pid=MBR30035CT case=357B-01 * 88-09-22 rmn .ends *$ *model MBR30045CT anode1 * | anode2 * | | cathode * | | | .subckt MBR30045CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=832.5n Rs=262.1u Ikf=3.986 N=1 Xti=0 Eg=1.11 Cjo=12.18n + M=.4673 Vj=.75 Fc=.5 Isr=9.398u Nr=2) * Motorola pid=MBR30035CT case=357B-01 * 88-09-22 rmn .ends *$ * * RAD: PRERAD * TEMP= -55 *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 167.0NS, SIMULATED TRR = 35.06NS. .SUBCKT FJT1148/-55C 99 2 D1 99 2 DFOR C1 2 99 7.08659E-13 .MODEL DFOR D ( + IS = 1.58529E-16 + RS = 2.387872 + N = 1.098053 + TT = 5.0E-8 + CJO = 5.56E-13 + VJ = 0.4224 + M = 0.2157 + EG = 1.11 + XTI = 3.0 + KF = 0 + AF = 1 + FC = 0.75234 + BV = 43 + IBV = 5E-6 + ) .ENDS *$ * * RAD: PRERAD * TEMP= 125 *** CAUTION: THE MEASURED TRR AND THE PSPICE CKT. SIMULATED TRR ARE DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CKT. SIMULATIONS IF USED * AS A RECTIFIER OR SWITCHING DIODE * MEASURED TRR = 182.0NS, SIMULATED TRR = 38.98NS. .SUBCKT FJT1148/125C 99 2 D1 99 2 DFOR C1 2 99 7.08659E-13 .MODEL DFOR D ( + IS = 1.79467E-16 + RS = 2.876067 + N = 1.096355 + TT = 5.5E-8 + CJO = 5.56E-13 + VJ = 0.4224 + M = 0.2157 + EG = 1.11 + XTI = 4.998583 + KF = 0 + AF = 1 + FC = 0.751 + BV = 43 + IBV = 5E-6 + ) .ENDS *$ * * * MANUFACTURERS PART NO. = FJT1148 * * TYPE: DIODE * SUBTYPE: RECTIFIER * THIS FILE CONTAINS 3 PRE-RAD MODELS AT VARIOUS TEMPS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * RAD: PRERAD * TEMP= 25 *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT * SIMULATIONS IF USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 176.0NS, SIMULATED TRR = 38.41NS. .SUBCKT FJT1148/25C 99 2 D1 99 2 DFOR C1 2 99 7.08659E-13 .MODEL DFOR D ( + IS = 1.48352E-16 + RS = 2.55616 + N = 1.091932 + TT = 5.4E-8 + CJO = 5.56E-13 + VJ = 0.4224 + M = 0.2157 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.75234 + BV = 43 + IBV = 5E-6 + ) .ENDS *$ .model MBRL030 D(Is=12.29n Rs=.102 Ikf=15.89m N=1 Xti=0 Eg=1.11 Cjo=90p + M=.1112 Vj=.75 Fc=.5 Isr=1.977u Nr=2) * Motorola pid=MBRL030 case=362-01 * 88-09-15 rmn *$ .model MBRL040 D(Is=12.29n Rs=.102 Ikf=15.89m N=1 Xti=0 Eg=1.11 Cjo=90p + M=.1112 Vj=.75 Fc=.5 Isr=1.916u Nr=2) * Motorola pid=MBRL030 case=362-01 * 88-09-15 rmn *$ * * * MEASURED TRR = 63.333NS, SIMULATED TRR = 25.45NS. * * * RAD: PRERAD * TEMP: -55 * .MODEL MC510223/-55C D ( + IS = 3.05997E-9 + RS = 0.2160427 + N = 15.2934824 + TT = 3.4473E-8 + CJO = 3.65002E-12 + VJ = 2 + M = 0.3050032 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * MEASURED TRR = 470.0NS, SIMULATED TRR = 101.7NS. * * * RAD: PRERAD * TEMP: 125 .MODEL MC510223/125C D ( + IS = 1.20723E-6 + RS = 1.0749821 + N = 10.1273098 + TT = 1.327E-7 + CJO = 3.65002E-12 + VJ = 2 + M = 0.3050032 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-10 + ) *$ * * * MANUFACTURERS PART NO. = MC510223 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER-GP * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATED DEVICES * AT VARYING TEMPERATURES. * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * MEASURED TRR = 157.0NS, SIMULATED TRR = 48.55NS. * RAD: PRERAD * TEMP: 27 * * .MODEL MC510223/27C D ( + IS = 6.65495E-9 + RS = 3.7721316 + N = 9.985313 + TT = 6.905E-8 + CJO = 3.65002E-12 + VJ = 2 + M = 0.3050032 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-10 + ) *$ * * MANUFACTURERS PART NO. = MC510223 * MANUFACTURER = MICROSEMI * TYPE: DIODE * SUBTYPE: RECTIFIER-GP * THE FOLLOWING SECTION CONTAINS 2 PARAMETER SETS AT VARIOUS POST NEUTRON * RADIATION LEVELS. * **** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * AS A RECTIFIER OR SWITCHING DIODE. * * RAD: 3E12 * TYPE: NEUTRON * TEMP: 27 * * * MEASURED TRR = 120.56NS, SIMULATED TRR = 128NS. * .MODEL MC510223/27C/RAD1 D ( + IS = 1E-6 + RS = 0.5952435 + N = 15.64601 + TT = 1.97E-7 + CJO = 3.42078E-12 + VJ = 1.2 + M = 0.3359982 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.4561396 + BV = 1E5 + IBV = 1E-3 + ) *$ * * * RAD: 2E14 * TYPE: NEUTRON * TMEP:27 * * MEASURED TRR = 12.8NS, SIMULATED TRR = 12.71NS. * .MODEL MC510223/27C/RAD2 D ( + IS = 6.050554E-8 + RS = 3E3 + N = 9.9413829 + TT = 1E-9 + CJO = 1.819831E-12 + VJ = 2.7176878 + M = 0.2 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 1E5 + IBV = 1E-3 + ) *$ .model MPN3404 D(Is=271.5E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=3p M=.3141 + Vj=.75 Fc=.5 Isr=10.38n Nr=2 Bv=20 Ibv=10u) * Motorola pid=MPN3404 case=182-03 * 88-09-22 bam creation *$ .model MPN3700 D(Is=266.9E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=2.2p M=.4301 + Vj=.75 Fc=.5 Isr=7.29n Nr=2 Bv=200 Ibv=10u) * Motorola pid=MPN3700 case=182-03 * 88-09-22 bam creation *$ .model MR327 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=1.186u Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model MR328 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=993.6n Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model MR330 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=751.1n Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model MR331 D(Is=68.65f Rs=3.786m Ikf=1.774 N=1 Xti=2 Eg=1.11 Cjo=1.457n + M=.9735 Vj=.75 Fc=.5 Isr=604.6n Nr=2 Tt=6.059u) * Motorola pid=1N3491 case=DO21 * 88-08-24 rmn *$ .model MR500 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=61.08p + M=.4421 Vj=.75 Fc=.5 Isr=15.52n Nr=2 Tt=6.81u) * Motorola pid=MR500 case=267-01 * 88-09-22 rmn *$ .model MR501 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=61.08p + M=.4421 Vj=.75 Fc=.5 Isr=11.46n Nr=2 Tt=6.81u) * Motorola pid=MR500 case=267-01 * 88-09-22 rmn *$ .model MR502 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=61.08p + M=.4421 Vj=.75 Fc=.5 Isr=8.449n Nr=2 Tt=6.81u) * Motorola pid=MR500 case=267-01 * 88-09-22 rmn *$ .model MR504 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=61.08p + M=.4421 Vj=.75 Fc=.5 Isr=6.224n Nr=2 Tt=6.81u) * Motorola pid=MR500 case=267-01 * 88-09-22 rmn *$ .model MR506 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=61.08p + M=.4421 Vj=.75 Fc=.5 Isr=5.204n Nr=2 Tt=6.81u) * Motorola pid=MR500 case=267-01 * 88-09-22 rmn *$ .model MR508 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=61.08p + M=.4421 Vj=.75 Fc=.5 Isr=4.583n Nr=2 Tt=6.81u) * Motorola pid=MR500 case=267-01 * 88-09-22 rmn *$ .model MR510 D(Is=11.5f Rs=8.254m Ikf=3.87 N=1 Xti=3 Eg=1.11 Cjo=61.08p + M=.4421 Vj=.75 Fc=.5 Isr=4.153n Nr=2 Tt=6.81u) * Motorola pid=MR500 case=267-01 * 88-09-22 rmn *$ .model MR750 D(Is=643.5f Rs=1.82m Ikf=4.537 N=1 Xti=3 Eg=1.11 Cjo=1.453n + M=.9134 Vj=.75 Fc=.5 Isr=5.322u Nr=2 Tt=6.131u) * Motorola pid=MR750 case=194-05 * 88-09-22 rmn *$ .model MR751 D(Is=643.5f Rs=1.82m Ikf=4.537 N=1 Xti=3 Eg=1.11 Cjo=1.453n + M=.9134 Vj=.75 Fc=.5 Isr=2.845u Nr=2 Tt=6.131u) * Motorola pid=MR750 case=194-05 * 88-09-22 rmn *$ .model MR752 D(Is=643.5f Rs=1.82m Ikf=4.537 N=1 Xti=3 Eg=1.11 Cjo=1.453n + M=.9134 Vj=.75 Fc=.5 Isr=1.516u Nr=2 Tt=6.131u) * Motorola pid=MR750 case=194-05 * 88-09-22 rmn *$ .model MR754 D(Is=643.5f Rs=1.82m Ikf=4.537 N=1 Xti=3 Eg=1.11 Cjo=1.453n + M=.9134 Vj=.75 Fc=.5 Isr=806n Nr=2 Tt=6.131u) * Motorola pid=MR750 case=194-05 * 88-09-22 rmn *$ .model MR756 D(Is=643.5f Rs=1.82m Ikf=4.537 N=1 Xti=3 Eg=1.11 Cjo=1.453n + M=.9134 Vj=.75 Fc=.5 Isr=556.9n Nr=2 Tt=6.131u) * Motorola pid=MR750 case=194-05 * 88-09-22 rmn *$ .model MR810 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=79.7n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR811 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=63.85n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR812 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=52.54n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR813 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=49.93n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR814 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=50.86n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR816 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=53.5n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR817 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=57.5n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR818 D(Is=1.568f Rs=27.67m Ikf=8.762m N=1 Xti=3 Eg=1.11 Cjo=27.48p + M=.4357 Vj=.75 Fc=.5 Isr=71.75n Nr=2 Tt=625.5n) * Motorola pid=MR810 case=59-04 * 88-09-22 rmn *$ .model MR820 D(Is=441.8f Rs=5.044m Ikf=.1535 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=848.9n Nr=2 Tt=369.9n) * Motorola pid=MR820 case=194-04 * 88-09-22 rmn *$ .model MR821 D(Is=441.8f Rs=5.044m Ikf=.1535 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=759.4n Nr=2 Tt=369.9n) * Motorola pid=MR820 case=194-04 * 88-09-22 rmn *$ .model MR822 D(Is=441.8f Rs=5.044m Ikf=.1535 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=749.9n Nr=2 Tt=369.9n) * Motorola pid=MR820 case=194-04 * 88-09-22 rmn *$ .model MR824 D(Is=441.8f Rs=5.044m Ikf=.1535 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=973.4n Nr=2 Tt=369.9n) * Motorola pid=MR820 case=194-04 * 88-09-22 rmn *$ .model MR826 D(Is=441.8f Rs=5.044m Ikf=.1535 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=1.331u Nr=2 Tt=369.9n) * Motorola pid=MR820 case=194-04 * 88-09-22 rmn *$ .model MR831 D(Is=111.5f Rs=7.494m Ikf=.1157 N=1 Xti=3 Eg=1.11 Cjo=72.84p + M=.4441 Vj=.75 Fc=.5 Isr=47.65n Nr=2 Tt=369.9n) * Motorola pid=MR850 case=60-1 * 88-09-22 rmn *$ .model MR850 D(Is=111.5f Rs=7.494m Ikf=.1157 N=1 Xti=3 Eg=1.11 Cjo=72.84p + M=.4441 Vj=.75 Fc=.5 Isr=56.92n Nr=2 Tt=369.9n) * Motorola pid=MR850 case=60-1 * 88-09-22 rmn *$ .model MR852 D(Is=111.5f Rs=7.494m Ikf=.1157 N=1 Xti=3 Eg=1.11 Cjo=72.84p + M=.4441 Vj=.75 Fc=.5 Isr=58.47n Nr=2 Tt=369.9n) * Motorola pid=MR850 case=60-1 * 88-09-22 rmn *$ .model MR854 D(Is=111.5f Rs=7.494m Ikf=.1157 N=1 Xti=3 Eg=1.11 Cjo=72.84p + M=.4441 Vj=.75 Fc=.5 Isr=71.28n Nr=2 Tt=369.9n) * Motorola pid=MR850 case=60-1 * 88-09-22 rmn *$ .model MR856 D(Is=111.5f Rs=7.494m Ikf=.1157 N=1 Xti=3 Eg=1.11 Cjo=72.84p + M=.4441 Vj=.75 Fc=.5 Isr=79.57n Nr=2 Tt=369.9n) * Motorola pid=MR850 case=60-1 * 88-09-22 rmn *$ .model MR860 D(Is=1.705p Rs=3.151m Ikf=.1029 N=1 Xti=0 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.086u Nr=2 Tt=369.9n) * Motorola pid=MR860 case=DO5 * 88-09-22 rmn *$ .model MR861 D(Is=1.705p Rs=3.151m Ikf=.1029 N=1 Xti=0 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.041u Nr=2 Tt=369.9n) * Motorola pid=MR860 case=DO5 * 88-09-22 rmn *$ .model MR862 D(Is=1.705p Rs=3.151m Ikf=.1029 N=1 Xti=0 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.076u Nr=2 Tt=369.9n) * Motorola pid=MR860 case=DO5 * 88-09-22 rmn *$ .model MR864 D(Is=1.705p Rs=3.151m Ikf=.1029 N=1 Xti=0 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.339u Nr=2 Tt=369.9n) * Motorola pid=MR860 case=DO5 * 88-09-22 rmn *$ .model MR866 D(Is=1.705p Rs=3.151m Ikf=.1029 N=1 Xti=0 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.888u Nr=2 Tt=369.9n) * Motorola pid=MR860 case=DO5 * 88-09-22 rmn *$ .model MR870 D(Is=2.553p Rs=2.727m Ikf=81.7m N=1 Xti=2 Eg=1.11 Cjo=114.4p + M=.2829 Vj=.75 Fc=.5 Isr=804.3n Nr=2 Tt=369.9n) * Motorola pid=MR870 case=DO5 * 88-09-22 rmn *$ .model MR871 D(Is=2.553p Rs=2.727m Ikf=81.7m N=1 Xti=2 Eg=1.11 Cjo=114.4p + M=.2829 Vj=.75 Fc=.5 Isr=749.9n Nr=2 Tt=369.9n) * Motorola pid=MR870 case=DO5 * 88-09-22 rmn *$ .model MR872 D(Is=2.553p Rs=2.727m Ikf=81.7m N=1 Xti=2 Eg=1.11 Cjo=114.4p + M=.2829 Vj=.75 Fc=.5 Isr=740.4n Nr=2 Tt=369.9n) * Motorola pid=MR870 case=DO5 * 88-09-22 rmn *$ .model MR874 D(Is=2.553p Rs=2.727m Ikf=81.7m N=1 Xti=2 Eg=1.11 Cjo=114.4p + M=.2829 Vj=.75 Fc=.5 Isr=879.5n Nr=2 Tt=369.9n) * Motorola pid=MR870 case=DO5 * 88-09-22 rmn *$ .model MR876 D(Is=2.553p Rs=2.727m Ikf=81.7m N=1 Xti=2 Eg=1.11 Cjo=114.4p + M=.2829 Vj=.75 Fc=.5 Isr=1.207u Nr=2 Tt=369.9n) * Motorola pid=MR870 case=DO5 * 88-09-22 rmn *$ .model MR1366 D(Is=1.058E-18 Rs=11.56m Ikf=2.349 N=1 Xti=14 Eg=1.11 Cjo=113.2p + M=.2834 Vj=.75 Fc=.5 Isr=1.188u Nr=2 Tt=369.9n) * Motorola pid=1N3879 case=DO4 * 88-08-25 rmn *$ .model MR1376 D(Is=15.03f Rs=9.606m Ikf=.2003 N=1 Xti=3 Eg=1.11 Cjo=117.8p + M=.2976 Vj=.75 Fc=.5 Isr=1.094u Nr=2 Tt=369.9n) * Motorola pid=1N3889 case=DO4 * 88-08-25 rmn *$ .model MR1386 D(Is=5.62f Rs=6.414m Ikf=9.692 N=1 Xti=2 Eg=1.11 Cjo=144.1p + M=.2272 Vj=.75 Fc=.5 Isr=1.752u Nr=2 Bv=100 Ibv=100u Tt=521.4n) * Motorola pid=1N3899 case=DO5 * 88-08-30 rmn *$ .model MR1396 D(Is=20.07f Rs=3.842m Ikf=2.963 N=1 Xti=3 Eg=1.11 Cjo=111.7p + M=.2683 Vj=.75 Fc=.5 Isr=1.331u Nr=2 Tt=369.9n) * Motorola pid=1N3909 case=DO5 * 88-08-30 rmn *$ .model MR2400 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=16.52u Nr=2 Tt=5.41u) * Motorola pid=MR2400 case=339-02 * 88-09-22 rmn *$ .model MR2400F D(Is=193.2f Rs=4.941m Ikf=56.72m N=1 Xti=8 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.086u Nr=2 Tt=672.2n) * Motorola pid=MR2400F case=339-02 * 88-09-22 rmn *$ .model MR2401 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=12.33u Nr=2 Tt=5.41u) * Motorola pid=MR2400 case=339-02 * 88-09-22 rmn *$ .model MR2401F D(Is=193.2f Rs=4.941m Ikf=56.72m N=1 Xti=8 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.041u Nr=2 Tt=672.2n) * Motorola pid=MR2400F case=339-02 * 88-09-22 rmn *$ .model MR2402 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=9.182u Nr=2 Tt=5.41u) * Motorola pid=MR2400 case=339-02 * 88-09-22 rmn *$ .model MR2402F D(Is=193.2f Rs=4.941m Ikf=56.72m N=1 Xti=8 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.076u Nr=2 Tt=672.2n) * Motorola pid=MR2400F case=339-02 * 88-09-22 rmn *$ .model MR2404 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=6.834u Nr=2 Tt=5.41u) * Motorola pid=MR2400 case=339-02 * 88-09-22 rmn *$ .model MR2404F D(Is=193.2f Rs=4.941m Ikf=56.72m N=1 Xti=8 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.365u Nr=2 Tt=672.2n) * Motorola pid=MR2400F case=339-02 * 88-09-22 rmn *$ .model MR2406 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=5.749u Nr=2 Tt=5.41u) * Motorola pid=MR2400 case=339-02 * 88-09-22 rmn *$ .model MR2406F D(Is=193.2f Rs=4.941m Ikf=56.72m N=1 Xti=8 Eg=1.11 Cjo=144.1p + M=.216 Vj=.75 Fc=.5 Isr=1.888u Nr=2 Tt=672.2n) * Motorola pid=MR2400F case=339-02 * 88-09-22 rmn *$ .model MR2500 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=16.52u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=139-03 * 88-09-22 rmn *$ .model MR2500M D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=16.52u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=193-04 * 88-09-22 rmn *$ .model MR2501 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=12.33u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=139-03 * 88-09-22 rmn *$ .model MR2501M D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=12.33u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=193-04 * 88-09-22 rmn *$ .model MR2502 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=9.182u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=139-03 * 88-09-22 rmn *$ .model MR2502M D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=9.182u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=193-04 * 88-09-22 rmn *$ .model MR2504 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=6.834u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=139-03 * 88-09-22 rmn *$ .model MR2504M D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=6.834u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=193-04 * 88-09-22 rmn *$ .model MR2506 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=5.749u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=139-03 * 88-09-22 rmn *$ .model MR2506M D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=5.749u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=193-04 * 88-09-22 rmn *$ .model MR2508 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=5.085u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=139-03 * 88-09-22 rmn *$ .model MR2508M D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=5.085u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=193-04 * 88-09-22 rmn *$ .model MR2510 D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=4.623u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=139-03 * 88-09-22 rmn *$ .model MR2510M D(Is=639.2f Rs=1.833m Ikf=6.473 N=1 Xti=3 Eg=1.11 Cjo=423.7p + M=.4272 Vj=.75 Fc=.5 Isr=4.623u Nr=2 Tt=5.338u) * Motorola pid=MR2500 case=193-04 * 88-09-22 rmn *$ .model MT5100 D(Is=10f N=1 Rs=0 Ikf=1MEG Xti=3 Eg=1.11 Cjo=6p M=.2603 Vj=.75 + Fc=.5 Isr=4.209p Nr=2 Bv=75.03 Ibv=344.9u Tt=14.43n) *$ .model MUR105 D(Is=5.547p Rs=20.1m Ikf=14.47m N=1 Xti=0 Eg=1.11 Cjo=67.21p + M=.4934 Vj=.75 Fc=.5 Isr=461.8p Nr=2 Tt=61.66n) * Motorola pid=MUR105 case=59-04 * 88-09-22 rmn *$ .model MUR110 D(Is=5.547p Rs=20.1m Ikf=14.47m N=1 Xti=0 Eg=1.11 Cjo=67.21p + M=.4934 Vj=.75 Fc=.5 Isr=462.9p Nr=2 Tt=61.66n) * Motorola pid=MUR105 case=59-04 * 88-09-22 rmn *$ .model MUR115 D(Is=5.547p Rs=20.1m Ikf=14.47m N=1 Xti=0 Eg=1.11 Cjo=67.21p + M=.4934 Vj=.75 Fc=.5 Isr=605.8p Nr=2 Tt=61.66n) * Motorola pid=MUR105 case=59-04 * 88-09-22 rmn *$ .model MUR120 D(Is=1.043p Rs=74.44m Ikf=2.705m N=1 Xti=2 Eg=1.11 Cjo=28.43p + M=.6225 Vj=.75 Fc=.5 Isr=416.1p Nr=2 Tt=123.3n) * Motorola pid=MUR120 case=59-04 * 88-09-22 rmn *$ .model MUR130 D(Is=1.043p Rs=74.44m Ikf=2.705m N=1 Xti=2 Eg=1.11 Cjo=28.43p + M=.6225 Vj=.75 Fc=.5 Isr=659.1p Nr=2 Tt=123.3n) * Motorola pid=MUR120 case=59-04 * 88-09-22 rmn *$ .model MUR140 D(Is=1.043p Rs=74.44m Ikf=2.705m N=1 Xti=2 Eg=1.11 Cjo=28.43p + M=.6225 Vj=.75 Fc=.5 Isr=1.163n Nr=2 Tt=123.3n) * Motorola pid=MUR120 case=59-04 * 88-09-22 rmn *$ .model MUR150 D(Is=1.043p Rs=74.44m Ikf=2.705m N=1 Xti=2 Eg=1.11 Cjo=28.43p + M=.6225 Vj=.75 Fc=.5 Isr=2.094n Nr=2 Tt=123.3n) * Motorola pid=MUR120 case=59-04 * 88-09-22 rmn *$ .model MUR160 D(Is=1.043p Rs=74.44m Ikf=2.705m N=1 Xti=2 Eg=1.11 Cjo=28.43p + M=.6225 Vj=.75 Fc=.5 Isr=7.011n Nr=2 Tt=123.3n) * Motorola pid=MUR120 case=59-04 * 88-09-22 rmn *$ .model MUR170 D(Is=4.5f Rs=.1249 Ikf=7.308m N=1 Xti=10 Eg=1.11 Cjo=23.31p + M=.525 Vj=.75 Fc=.5 Isr=2.536n Nr=2 Tt=185n) * Motorola pid=MUR170 case=59-04 * 88-09-22 rmn *$ .model MUR180 D(Is=4.5f Rs=.1249 Ikf=7.308m N=1 Xti=10 Eg=1.11 Cjo=23.31p + M=.525 Vj=.75 Fc=.5 Isr=3.342n Nr=2 Tt=185n) * Motorola pid=MUR170 case=59-04 * 88-09-22 rmn *$ .model MUR190 D(Is=4.5f Rs=.1249 Ikf=7.308m N=1 Xti=10 Eg=1.11 Cjo=23.31p + M=.525 Vj=.75 Fc=.5 Isr=4.833n Nr=2 Tt=185n) * Motorola pid=MUR170 case=59-04 * 88-09-22 rmn *$ .model MUR405 D(Is=1.693p Rs=6.903m Ikf=.3668 N=1 Xti=0 Eg=1.11 Cjo=128.7p + M=.299 Vj=.75 Fc=.5 Isr=1.644n Nr=2 Tt=61.66n) * Motorola pid=MUR405 case=267-01 * 88-09-22 rmn *$ .model MUR410 D(Is=1.693p Rs=6.903m Ikf=.3668 N=1 Xti=0 Eg=1.11 Cjo=128.7p + M=.299 Vj=.75 Fc=.5 Isr=1.57n Nr=2 Tt=61.66n) * Motorola pid=MUR405 case=267-01 * 88-09-22 rmn *$ .model MUR415 D(Is=1.693p Rs=6.903m Ikf=.3668 N=1 Xti=0 Eg=1.11 Cjo=128.7p + M=.299 Vj=.75 Fc=.5 Isr=2.007n Nr=2 Tt=61.66n) * Motorola pid=MUR405 case=267-01 * 88-09-22 rmn *$ .model MUR420 D(Is=289.1f Rs=33.23m Ikf=5.678m N=1 Xti=5 Eg=1.11 Cjo=70.72p + M=.5733 Vj=.75 Fc=.5 Isr=710.2p Nr=2 Tt=123.3n) * Motorola pid=MUR420 case=267-01 * 88-09-22 rmn *$ .model MUR430 D(Is=289.1f Rs=33.23m Ikf=5.678m N=1 Xti=5 Eg=1.11 Cjo=70.72p + M=.5733 Vj=.75 Fc=.5 Isr=965.7p Nr=2 Tt=123.3n) * Motorola pid=MUR420 case=267-01 * 88-09-22 rmn *$ .model MUR440 D(Is=289.1f Rs=33.23m Ikf=5.678m N=1 Xti=5 Eg=1.11 Cjo=70.72p + M=.5733 Vj=.75 Fc=.5 Isr=1.556n Nr=2 Tt=123.3n) * Motorola pid=MUR420 case=267-01 * 88-09-22 rmn *$ .model MUR450 D(Is=289.1f Rs=33.23m Ikf=5.678m N=1 Xti=5 Eg=1.11 Cjo=70.72p + M=.5733 Vj=.75 Fc=.5 Isr=2.451n Nr=2 Tt=123.3n) * Motorola pid=MUR420 case=267-01 * 88-09-22 rmn *$ .model MUR460 D(Is=289.1f Rs=33.23m Ikf=5.678m N=1 Xti=5 Eg=1.11 Cjo=70.72p + M=.5733 Vj=.75 Fc=.5 Isr=6.495n Nr=2 Tt=123.3n) * Motorola pid=MUR420 case=267-01 * 88-09-22 rmn *$ .model MUR470 D(Is=92.91f Rs=58.12m Ikf=16.23m N=1 Xti=5 Eg=1.11 Cjo=66.41p + M=.5022 Vj=.75 Fc=.5 Isr=10.96n Nr=2 Tt=185n) * Motorola pid=MUR470 case=267-01 * 88-09-22 rmn *$ .model MUR480 D(Is=92.91f Rs=58.12m Ikf=16.23m N=1 Xti=5 Eg=1.11 Cjo=66.41p + M=.5022 Vj=.75 Fc=.5 Isr=18.09n Nr=2 Tt=185n) * Motorola pid=MUR470 case=267-01 * 88-09-22 rmn *$ .model MUR490 D(Is=92.91f Rs=58.12m Ikf=16.23m N=1 Xti=5 Eg=1.11 Cjo=66.41p + M=.5022 Vj=.75 Fc=.5 Isr=27n Nr=2 Tt=185n) * Motorola pid=MUR470 case=267-01 * 88-09-22 rmn *$ .model MUR805 D(Is=12.4f Rs=79.85m Ikf=54.2m N=1 Xti=15 Eg=1.11 Cjo=471.3p + M=.4206 Vj=.75 Fc=.5 Isr=40.54n Nr=2 Tt=185n) * Motorola pid=MUR805 case=TO220AC * 88-09-22 rmn *$ .model MUR810 D(Is=4.433p Rs=5.91m Ikf=92.2m N=1 Xti=3 Eg=1.11 Cjo=265.3p + M=.4253 Vj=.75 Fc=.5 Isr=49.76n Nr=2 Tt=61.66n) * Motorola pid=MUR805 case=TO220AC * 88-09-22 rmn *$ .model MUR815 D(Is=4.433p Rs=5.91m Ikf=92.2m N=1 Xti=3 Eg=1.11 Cjo=265.3p + M=.4253 Vj=.75 Fc=.5 Isr=324.9n Nr=2 Tt=61.66n) * Motorola pid=MUR805 case=TO220AC * 88-09-22 rmn *$ .model MUR820 D(Is=1.026p Rs=36.34m Ikf=17.71m N=1 Xti=10 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=10.29n Nr=2 Tt=123.3n) * Motorola pid=MUR820 case=TO220AC * 88-09-22 rmn *$ .model MUR830 D(Is=1.026p Rs=36.34m Ikf=17.71m N=1 Xti=10 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=32.31n Nr=2 Tt=123.3n) * Motorola pid=MUR820 case=TO220AC * 88-09-22 rmn *$ .model MUR840 D(Is=1.026p Rs=36.34m Ikf=17.71m N=1 Xti=10 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=132.1n Nr=2 Tt=123.3n) * Motorola pid=MUR820 case=TO220AC * 88-09-22 rmn *$ .model MUR850 D(Is=853.7f Rs=41.35m Ikf=21.56m N=1 Xti=3 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=85.16n Nr=2 Tt=123.3n) * Motorola pid=MUR850 case=TO220AC * 88-09-22 rmn *$ .model MUR860 D(Is=853.7f Rs=41.35m Ikf=21.56m N=1 Xti=3 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=217.5n Nr=2 Tt=123.3n) * Motorola pid=MUR850 case=TO220AC * 88-09-22 rmn *$ .model MUR870 D(Is=12.4f Rs=79.85m Ikf=54.2m N=1 Xti=15 Eg=1.11 Cjo=471.3p + M=.4206 Vj=.75 Fc=.5 Isr=40.55n Nr=2 Tt=185n) * Motorola pid=MUR870 case=TO220AC * 88-09-22 rmn *$ .model MUR880 D(Is=12.4f Rs=79.85m Ikf=54.2m N=1 Xti=15 Eg=1.11 Cjo=471.3p + M=.4206 Vj=.75 Fc=.5 Isr=62.82n Nr=2 Tt=185n) * Motorola pid=MUR870 case=TO220AC * 88-09-22 rmn *$ .model MUR890 D(Is=12.4f Rs=79.85m Ikf=54.2m N=1 Xti=15 Eg=1.11 Cjo=471.3p + M=.4206 Vj=.75 Fc=.5 Isr=116.5n Nr=2 Tt=185n) * Motorola pid=MUR870 case=TO220AC * 88-09-22 rmn *$ .model MUR1100 D(Is=4.5f Rs=.1249 Ikf=7.308m N=1 Xti=10 Eg=1.11 Cjo=23.31p + M=.525 Vj=.75 Fc=.5 Isr=9.146n Nr=2 Tt=185n) * Motorola pid=MUR170 case=59-04 * 88-09-22 rmn *$ .model MUR1505 D(Is=6.318n Rs=17.32m Ikf=6.39m N=1 Xti=3 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=7.631n Nr=2 Tt=86.32n) * Motorola pid=MUR1505 case=TO220AC * 88-09-22 rmn *$ .model MUR1510 D(Is=6.318n Rs=17.32m Ikf=6.39m N=1 Xti=3 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=15.22n Nr=2 Tt=86.32n) * Motorola pid=MUR1505 case=TO220AC * 88-09-22 rmn *$ .model MUR1515 D(Is=6.318n Rs=17.32m Ikf=6.39m N=1 Xti=3 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=47.16n Nr=2 Tt=86.32n) * Motorola pid=MUR1505 case=TO220AC * 88-09-22 rmn *$ .model MUR1520 D(Is=146p Rs=22.09m Ikf=11.37m N=1 Xti=3 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=39.53n Nr=2 Tt=148n) * Motorola pid=MUR1520 case=TO220AC * 88-09-22 rmn *$ .model MUR1530 D(Is=146p Rs=22.09m Ikf=11.37m N=1 Xti=3 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=129.6n Nr=2 Tt=148n) * Motorola pid=MUR1520 case=TO220AC * 88-09-22 rmn *$ .model MUR1540 D(Is=146p Rs=22.09m Ikf=11.37m N=1 Xti=3 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=519.8n Nr=2 Tt=148n) * Motorola pid=MUR1520 case=TO220AC * 88-09-22 rmn *$ .model MUR1550 D(Is=95.51p Rs=46.69m Ikf=8.883m N=1 Xti=6 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=63.65n Nr=2 Tt=148n) * Motorola pid=MUR1550 case=TO220AC * 88-09-22 rmn *$ .model MUR1560 D(Is=95.51p Rs=46.69m Ikf=8.883m N=1 Xti=6 Eg=1.11 Cjo=525.4p + M=.414 Vj=.75 Fc=.5 Isr=251.2n Nr=2 Tt=148n) * Motorola pid=MUR1550 case=TO220AC * 88-09-22 rmn *$ *model MUR1605CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1605CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=3.387p Rs=5.971m Ikf=.1093 N=1 Xti=2.5 Eg=1.11 Cjo=262p + M=.4108 Vj=.75 Fc=.5 Isr=21.24n Nr=2 Tt=61.66n) * Motorola pid=MUR1605CT case=TO220AB * 88-09-22 rmn .ends *$ *model MUR1610CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1610CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=3.387p Rs=5.971m Ikf=.1093 N=1 Xti=2.5 Eg=1.11 Cjo=262p + M=.4108 Vj=.75 Fc=.5 Isr=53.43n Nr=2 Tt=61.66n) * Motorola pid=MUR1605CT case=TO220AB * 88-09-22 rmn .ends *$ *model MUR1615CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1615CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=3.387p Rs=5.971m Ikf=.1093 N=1 Xti=2.5 Eg=1.11 Cjo=262p + M=.4108 Vj=.75 Fc=.5 Isr=362.2n Nr=2 Tt=61.66n) * Motorola pid=MUR1605CT case=TO220AB * 88-09-22 rmn .ends *$ *model MUR1620CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1620CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=16.33p Rs=48.08m Ikf=13.56m N=1 Xti=4 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=10.29n Nr=2 Tt=123.3n) * Motorola pid=MUR1620CT case=TO220AB * 88-09-22 rmn .ends *$ *model MUR1630CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1630CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=16.33p Rs=48.08m Ikf=13.56m N=1 Xti=4 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=30.56n Nr=2 Tt=123.3n) * Motorola pid=MUR1620CT case=TO220AB * 88-09-22 rmn .ends *$ *model MUR1640CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1640CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=16.33p Rs=48.08m Ikf=13.56m N=1 Xti=4 Eg=1.11 Cjo=367p + M=.4068 Vj=.75 Fc=.5 Isr=132.1n Nr=2 Tt=123.3n) * Motorola pid=MUR1620CT case=TO220AB * 88-09-22 rmn .ends *$ *model MUR1650CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1650CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=5.654p Rs=97.05m Ikf=0 N=1 Xti=0 Eg=1.11 Cjo=367p M=.4068 + Vj=.75 Fc=.5 Isr=85.16n Nr=2 Tt=123.3n) * Motorola pid=MUR1650CT case=TO220AB * 88-09-22 rmn .ends *$ *model MUR1660CT anode1 * | anode2 * | | cathode * | | | .subckt MUR1660CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=5.654p Rs=97.05m Ikf=0 N=1 Xti=0 Eg=1.11 Cjo=367p M=.4068 + Vj=.75 Fc=.5 Isr=217.5n Nr=2 Tt=123.3n) * Motorola pid=MUR1650CT case=TO220AB * 88-09-22 rmn .ends *$ .model MUR2505 D(Is=67.39p Rs=4.351m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=38.29n Nr=2 Tt=123.3n) * Motorola pid=MUR2505 case=DO4 * 88-09-23 rmn *$ .model MUR2510 D(Is=67.39p Rs=4.351m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=100.8n Nr=2 Tt=123.3n) * Motorola pid=MUR2505 case=DO4 * 88-09-23 rmn *$ .model MUR2515 D(Is=67.39p Rs=4.351m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=262n Nr=2 Tt=123.3n) * Motorola pid=MUR2505 case=DO4 * 88-09-23 rmn *$ .model MUR2520 D(Is=67.39p Rs=4.351m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=759.3n Nr=2 Tt=123.3n) * Motorola pid=MUR2505 case=DO4 * 88-09-23 rmn *$ *model MUR3005PT anode1 * | anode2 * | | cathode * | | | .subckt MUR3005PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=40.28p Rs=11.6m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=516.5p M=.3938 + Vj=.75 Fc=.5 Isr=9.503n Nr=2 Tt=86.32n) * Motorola pid=MUR3005PT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR3010PT anode1 * | anode2 * | | cathode * | | | .subckt MUR3010PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=40.28p Rs=11.6m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=516.5p M=.3938 + Vj=.75 Fc=.5 Isr=17.85n Nr=2 Tt=86.32n) * Motorola pid=MUR3005PT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR3015PT anode1 * | anode2 * | | cathode * | | | .subckt MUR3015PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=40.28p Rs=11.6m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=516.5p M=.3938 + Vj=.75 Fc=.5 Isr=53.27n Nr=2 Tt=86.32n) * Motorola pid=MUR3005PT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR3020PT anode1 * | anode2 * | | cathode * | | | .subckt MUR3020PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=3.026p Rs=19.2m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=516.5p M=.3938 + Vj=.75 Fc=.5 Isr=44.27n Nr=2 Tt=148n) * Motorola pid=MUR3020PT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR3030PT anode1 * | anode2 * | | cathode * | | | .subckt MUR3030PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=3.026p Rs=19.2m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=516.5p M=.3938 + Vj=.75 Fc=.5 Isr=146.3n Nr=2 Tt=148n) * Motorola pid=MUR3020PT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR3040PT anode1 * | anode2 * | | cathode * | | | .subckt MUR3040PT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=3.026p Rs=19.2m Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=516.5p M=.3938 + Vj=.75 Fc=.5 Isr=590.1n Nr=2 Tt=148n) * Motorola pid=MUR3020PT case=TO218AC * 88-09-23 rmn .ends *$ .model MUR4100 D(Is=92.91f Rs=58.12m Ikf=16.23m N=1 Xti=5 Eg=1.11 Cjo=66.41p + M=.5022 Vj=.75 Fc=.5 Isr=48.52n Nr=2 Tt=185n) * Motorola pid=MUR470 case=267-01 * 88-09-22 rmn *$ .model MUR5005 D(Is=546.8p Rs=4.299m Ikf=29.53m N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=61.04n Nr=2 Tt=123.3n) * Motorola pid=MUR5005 case=DO5 * 88-09-23 rmn *$ .model MUR5010 D(Is=546.8p Rs=4.299m Ikf=29.53m N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=164.7n Nr=2 Tt=123.3n) * Motorola pid=MUR5005 case=DO5 * 88-09-23 rmn *$ .model MUR5015 D(Is=546.8p Rs=4.299m Ikf=29.53m N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=356.4n Nr=2 Tt=123.3n) * Motorola pid=MUR5005 case=DO5 * 88-09-23 rmn *$ .model MUR5020 D(Is=546.8p Rs=4.299m Ikf=29.53m N=1 Xti=3 Eg=1.11 Cjo=243.6p + M=.1593 Vj=.75 Fc=.5 Isr=902.8n Nr=2 Tt=123.3n) * Motorola pid=MUR5005 case=DO5 * 88-09-23 rmn *$ .model MUR8100 D(Is=12.4f Rs=79.85m Ikf=54.2m N=1 Xti=15 Eg=1.11 Cjo=471.3p + M=.4206 Vj=.75 Fc=.5 Isr=232.7n Nr=2 Tt=185n) * Motorola pid=MUR870 case=TO220AC * 88-09-22 rmn *$ *model MUR10005CT anode1 * | anode2 * | | cathode * | | | .subckt MUR10005CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=325.8p Rs=5.154m Ikf=55.19m N=1 Xti=3 Eg=1.11 Cjo=10.93n + M=.4052 Vj=.75 Fc=.5 Isr=507.5n Nr=2 Tt=123.3n) * Motorola pid=MUR10005CT case=357B-01 * 88-09-23 rmn .ends *$ *model MUR10010CT anode1 * | anode2 * | | cathode * | | | .subckt MUR10010CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=325.8p Rs=5.154m Ikf=55.19m N=1 Xti=3 Eg=1.11 Cjo=10.93n + M=.4052 Vj=.75 Fc=.5 Isr=686.4n Nr=2 Tt=123.3n) * Motorola pid=MUR10005CT case=357B-01 * 88-09-23 rmn .ends *$ *model MUR10015CT anode1 * | anode2 * | | cathode * | | | .subckt MUR10015CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=325.8p Rs=5.154m Ikf=55.19m N=1 Xti=3 Eg=1.11 Cjo=10.93n + M=.4052 Vj=.75 Fc=.5 Isr=839.6n Nr=2 Tt=123.3n) * Motorola pid=MUR10005CT case=357B-01 * 88-09-23 rmn .ends *$ *model MUR10020CT anode1 * | anode2 * | | cathode * | | | .subckt MUR10020CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=325.8p Rs=5.154m Ikf=55.19m N=1 Xti=3 Eg=1.11 Cjo=10.93n + M=.4052 Vj=.75 Fc=.5 Isr=1.08u Nr=2 Tt=123.3n) * Motorola pid=MUR10005CT case=357B-01 * 88-09-23 rmn .ends *$ *model MUR20005CT anode1 * | anode2 * | | cathode * | | | .subckt MUR20005CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=9.944p Rs=4.756m Ikf=0 N=1 Xti=4 Eg=1.11 Cjo=1.113n + M=.3502 Vj=.75 Fc=.5 Isr=29.71n Nr=2 Tt=123.3n) * Motorola pid=MUR20005CT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR20010CT anode1 * | anode2 * | | | .subckt MUR20010CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=9.944p Rs=4.756m Ikf=0 N=1 Xti=4 Eg=1.11 Cjo=1.113n + M=.3502 Vj=.75 Fc=.5 Isr=57.52n Nr=2 Tt=123.3n) * Motorola pid=MUR20005CT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR20015CT anode1 * | anode2 * | | cathode * | | | .subckt MUR20015CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=9.944p Rs=4.756m Ikf=0 N=1 Xti=4 Eg=1.11 Cjo=1.113n + M=.3502 Vj=.75 Fc=.5 Isr=148.3n Nr=2 Tt=123.3n) * Motorola pid=MUR20005CT case=TO218AC * 88-09-23 rmn .ends *$ *model MUR20020CT anode1 * | anode2 * | | cathode * | | | .subckt MUR20020CT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=9.944p Rs=4.756m Ikf=0 N=1 Xti=4 Eg=1.11 Cjo=1.113n + M=.3502 Vj=.75 Fc=.5 Isr=705.9n Nr=2 Tt=123.3n) * Motorola pid=MUR20005CT case=TO218AC * 88-09-23 rmn .ends *$ *model R710XPT anode1 * | anode2 * | | cathode * | | | .subckt R710XPT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=33.87p Rs=12.15m Ikf=.1142 N=1 Xti=3 Eg=1.11 Cjo=519.9p + M=.3951 Vj=.75 Fc=.5 Isr=510.7n Nr=2 Tt=246.6n) * Motorola pid=R710XPT case=TO218AC * 88-09-23 rmn .ends *$ *model R711XPT anode1 * | anode2 * | | cathode * | | | .subckt R711XPT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=33.87p Rs=12.15m Ikf=.1142 N=1 Xti=3 Eg=1.11 Cjo=519.9p + M=.3951 Vj=.75 Fc=.5 Isr=432.8n Nr=2 Tt=246.6n) * Motorola pid=R710XPT case=TO218AC * 88-09-23 rmn .ends *$ *model R712XPT anode1 * | anode2 * | | cathode * | | | .subckt R712XPT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=33.87p Rs=12.15m Ikf=.1142 N=1 Xti=3 Eg=1.11 Cjo=519.9p + M=.3951 Vj=.75 Fc=.5 Isr=395.5n Nr=2 Tt=246.6n) * Motorola pid=R710XPT case=TO218AC * 88-09-23 rmn .ends *$ *model R714XPT anode1 * | anode2 * | | cathode * | | | .subckt R714XPT 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=33.87p Rs=12.15m Ikf=.1142 N=1 Xti=3 Eg=1.11 Cjo=519.9p + M=.3951 Vj=.75 Fc=.5 Isr=459.8n Nr=2 Tt=246.6n) * Motorola pid=R710XPT case=TO218AC * 88-09-23 rmn .ends *$ .model SD41 D(Is=1.133u Rs=2.964m Ikf=4.886 N=1 Xti=0 Eg=1.11 Cjo=2.139n + M=.4916 Vj=.75 Fc=.5 Isr=7.934u Nr=2) * Motorola pid=1N6095 case=DO4 * 88-09-13 rmn *$ .model SD51 D(Is=793.4n Rs=3.036m Ikf=8.242 N=1 Xti=0 Eg=1.11 Cjo=4.498n + M=.478 Vj=.75 Fc=.5 Isr=32.13u Nr=2) * Motorola pid=1N6097 case=DO5 * 88-09-15 rmn *$ *model SD241 anode1 * | anode2 * | | cathode * | | | .subckt SD241 1 2 3 d1 1 3 dx d2 2 3 dx .model dx D(Is=489n Rs=7.299m Ikf=80.79 N=1 Xti=0 Eg=1.11 Cjo=2.144n + M=.4923 Vj=.75 Fc=.5 Isr=7.268u Nr=2) * Motorola pid=MBR3020CT case=TO204AA * 88-09-20 rmn .ends *$ *** Current-regulator diodes * The parameters in this model library were derived from the data sheets for * each part. Each part was characterize using the Parts option. * *model D1N5283 anode * | cathode * | | .subckt D1N5283 1 2 j1 1 2 2 jx .model jx NJF(Beta=340u Betatce=-.5 Rd=1 Rs=0 Lambda=395.5u Vto=-.8108 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5284 anode * | cathode * | | .subckt D1N5284 1 2 j1 1 2 2 jx .model jx NJF(Beta=326u Betatce=-.5 Rd=1 Rs=0 Lambda=400u Vto=-.8575 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5285 anode * | cathode * | | .subckt D1N5285 1 2 j1 1 2 2 jx .model jx NJF(Beta=295u Betatce=-.5 Rd=1 Rs=0 Lambda=392.6u Vto=-.9576 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5286 anode * | cathode * | | .subckt D1N5286 1 2 j1 1 2 2 jx .model jx NJF(Beta=265u Betatce=-.5 Rd=1 Rs=0 Lambda=393.3u Vto=-1.063 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5287 anode * | cathode * | | .subckt D1N5287 1 2 j1 1 2 2 jx .model jx NJF(Beta=234u Betatce=-.5 Rd=1 Rs=0 Lambda=387.9u Vto=-1.188 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5288 anode * | cathode * | | .subckt D1N5288 1 2 j1 1 2 2 jx .model jx NJF(Beta=197u Betatce=-.5 Rd=1 Rs=0 Lambda=371.8u Vto=-1.413 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5289 anode * | cathode * | | .subckt D1N5289 1 2 j1 1 2 2 jx .model jx NJF(Beta=187.5u Betatce=-.5 Rd=1 Rs=0 Lambda=381.4u Vto=-1.518 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5290 anode * | cathode * | | .subckt D1N5290 1 2 j1 1 2 2 jx .model jx NJF(Beta=178.5u Betatce=-.5 Rd=1 Rs=0 Lambda=380.9u Vto=-1.621 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5291 anode * | cathode * | | .subckt D1N5291 1 2 j1 1 2 2 jx .model jx NJF(Beta=152u Betatce=-.5 Rd=1 Rs=0 Lambda=357.1u Vto=-1.916 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5292 anode * | cathode * | | .subckt D1N5292 1 2 j1 1 2 2 jx .model jx NJF(Beta=134u Betatce=-.5 Rd=1 Rs=0 Lambda=366.1u Vto=-2.149 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKL case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5293 anode * | cathode * | | .subckt D1N5293 1 2 j1 1 2 2 jx .model jx NJF(Beta=315u Betatce=-.5 Rd=1 Rs=0 Lambda=173.5u Vto=-1.470 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5294 anode * | cathode * | | .subckt D1N5294 1 2 j1 1 2 2 jx .model jx NJF(Beta=293.5u Betatce=-.5 Rd=1 Rs=0 Lambda=185.3u Vto=-1.60 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5295 anode * | cathode * | | .subckt D1N5295 1 2 j1 1 2 2 jx .model jx NJF(Beta=277.5u Betatce=-.5 Rd=1 Rs=0 Lambda=203.3u Vto=-1.721 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5296 anode * | cathode * | | .subckt D1N5296 1 2 j1 1 2 2 jx .model jx NJF(Beta=275u Betatce=-.5 Rd=1 Rs=0 Lambda=211.0u Vto=-1.8205 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5297 anode * | cathode * | | .subckt D1N5297 1 2 j1 1 2 2 jx .model jx NJF(Beta=260u Betatce=-.5 Rd=1 Rs=0 Lambda=227u Vto=-1.954 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5298 anode * | cathode * | | .subckt D1N5298 1 2 j1 1 2 2 jx .model jx NJF(Beta=218u Betatce=-.5 Rd=1 Rs=0 Lambda=239.1u Vto=-2.252 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5299 anode * | cathode * | | .subckt D1N5299 1 2 j1 1 2 2 jx .model jx NJF(Beta=200u Betatce=-.5 Rd=1 Rs=0 Lambda=252.5u Vto=-2.453 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5300 anode * | cathode * | | .subckt D1N5300 1 2 j1 1 2 2 jx .model jx NJF(Beta=185u Betatce=-.5 Rd=1 Rs=0 Lambda=240.4u Vto=-2.650 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5301 anode * | cathode * | | .subckt D1N5301 1 2 j1 1 2 2 jx .model jx NJF(Beta=184u Betatce=-.5 Rd=1 Rs=0 Lambda=285.7u Vto=-2.761 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5302 anode * | cathode * | | .subckt D1N5302 1 2 j1 1 2 2 jx .model jx NJF(Beta=182u Betatce=-.5 Rd=1 Rs=0 Lambda=303u Vto=-2.866 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKM case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5303 anode * | cathode * | | .subckt D1N5303 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.45m Betatce=-.5 Rd=1 Rs=0 Lambda=625u Vto=-1.052 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5304 anode * | cathode * | | .subckt D1N5304 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.345m Betatce=-.5 Rd=1 Rs=0 Lambda=585u Vto=-1.158 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5305 anode * | cathode * | | .subckt D1N5305 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.25m Betatce=-.5 Rd=1 Rs=0 Lambda=568u Vto=-1.267 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5306 anode * | cathode * | | .subckt D1N5306 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.16m Betatce=-.5 Rd=1 Rs=0 Lambda=568.2u Vto=-1.3785 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5307 anode * | cathode * | | .subckt D1N5307 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.09m Betatce=-.5 Rd=1 Rs=0 Lambda=554.2u Vto=-1.485 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5308 anode * | cathode * | | .subckt D1N5308 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.06m Betatce=-.5 Rd=1 Rs=0 Lambda=544.8u Vto=-1.598 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5309 anode * | cathode * | | .subckt D1N5309 1 2 j1 1 2 2 jx .model jx NJF(Beta=.93m Betatce=-.5 Rd=1 Rs=0 Lambda=556.7u Vto=-1.797 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5310 anode * | cathode * | | .subckt D1N5310 1 2 j1 1 2 2 jx .model jx NJF(Beta=.92m Betatce=-.5 Rd=1 Rs=0 Lambda=541.2u Vto=-1.897 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5311 anode * | cathode * | | .subckt D1N5311 1 2 j1 1 2 2 jx .model jx NJF(Beta=885u Betatce=-.5 Rd=1 Rs=0 Lambda=534.2u Vto=-2.020 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5312 anode * | cathode * | | .subckt D1N5312 1 2 j1 1 2 2 jx .model jx NJF(Beta=870u Betatce=-.5 Rd=1 Rs=0 Lambda=534.1u Vto=-2.120 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5313 anode * | cathode * | | .subckt D1N5313 1 2 j1 1 2 2 jx .model jx NJF(Beta=790u Betatce=-.5 Rd=1 Rs=0 Lambda=516.3u Vto=-2.336 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model D1N5314 anode * | cathode * | | .subckt D1N5314 1 2 j1 1 2 2 jx .model jx NJF(Beta=750u Betatce=-.5 Rd=1 Rs=0 Lambda=531.9u Vto=-2.506 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Motorola pid=NKO case=DO7 * 88-07-25 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR022 anode * | cathode * | | .subckt CR022 1 2 j1 1 2 2 jx .model jx NJF(Beta=340u Betatce=-.5 Rd=1 Rs=0 Lambda=395.5u Vto=-.8108 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR024 anode * | cathode * | | .subckt CR024 1 2 j1 1 2 2 jx .model jx NJF(Beta=326u Betatce=-.5 Rd=1 Rs=0 Lambda=400u Vto=-.8575 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR027 anode * | cathode * | | .subckt CR027 1 2 j1 1 2 2 jx .model jx NJF(Beta=295u Betatce=-.5 Rd=1 Rs=0 Lambda=392.6u Vto=-.9576 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR030 anode * | cathode * | | .subckt CR030 1 2 j1 1 2 2 jx .model jx NJF(Beta=265u Betatce=-.5 Rd=1 Rs=0 Lambda=393.3u Vto=-1.063 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR033 anode * | cathode * | | .subckt CR033 1 2 j1 1 2 2 jx .model jx NJF(Beta=234u Betatce=-.5 Rd=1 Rs=0 Lambda=387.9u Vto=-1.188 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR039 anode * | cathode * | | .subckt CR039 1 2 j1 1 2 2 jx .model jx NJF(Beta=197u Betatce=-.5 Rd=1 Rs=0 Lambda=371.8u Vto=-1.413 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR043 anode * | cathode * | | .subckt CR043 1 2 j1 1 2 2 jx .model jx NJF(Beta=187.5u Betatce=-.5 Rd=1 Rs=0 Lambda=381.4u Vto=-1.518 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR047 anode * | cathode * | | .subckt CR047 1 2 j1 1 2 2 jx .model jx NJF(Beta=178.5u Betatce=-.5 Rd=1 Rs=0 Lambda=380.9u Vto=-1.621 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR056 anode * | cathode * | | .subckt CR056 1 2 j1 1 2 2 jx .model jx NJF(Beta=152u Betatce=-.5 Rd=1 Rs=0 Lambda=357.1u Vto=-1.916 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR062 anode * | cathode * | | .subckt CR062 1 2 j1 1 2 2 jx .model jx NJF(Beta=134u Betatce=-.5 Rd=1 Rs=0 Lambda=366.1u Vto=-2.149 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR068 anode * | cathode * | | .subckt CR068 1 2 j1 1 2 2 jx .model jx NJF(Beta=315u Betatce=-.5 Rd=1 Rs=0 Lambda=173.5u Vto=-1.470 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR075 anode * | cathode * | | .subckt CR075 1 2 j1 1 2 2 jx .model jx NJF(Beta=293.5u Betatce=-.5 Rd=1 Rs=0 Lambda=185.3u Vto=-1.60 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR082 anode * | cathode * | | .subckt CR082 1 2 j1 1 2 2 jx .model jx NJF(Beta=277.5u Betatce=-.5 Rd=1 Rs=0 Lambda=203.3u Vto=-1.721 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR091 anode * | cathode * | | .subckt CR091 1 2 j1 1 2 2 jx .model jx NJF(Beta=275u Betatce=-.5 Rd=1 Rs=0 Lambda=211.0u Vto=-1.8205 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR100 anode * | cathode * | | .subckt CR100 1 2 j1 1 2 2 jx .model jx NJF(Beta=260u Betatce=-.5 Rd=1 Rs=0 Lambda=227u Vto=-1.954 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR110 anode * | cathode * | | .subckt CR110 1 2 j1 1 2 2 jx .model jx NJF(Beta=218u Betatce=-.5 Rd=1 Rs=0 Lambda=239.1u Vto=-2.252 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR120 anode * | cathode * | | .subckt CR120 1 2 j1 1 2 2 jx .model jx NJF(Beta=200u Betatce=-.5 Rd=1 Rs=0 Lambda=252.5u Vto=-2.453 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR130 anode * | cathode * | | .subckt CR130 1 2 j1 1 2 2 jx .model jx NJF(Beta=185u Betatce=-.5 Rd=1 Rs=0 Lambda=240.4u Vto=-2.650 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR140 anode * | cathode * | | .subckt CR140 1 2 j1 1 2 2 jx .model jx NJF(Beta=184u Betatce=-.5 Rd=1 Rs=0 Lambda=285.7u Vto=-2.761 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR150 anode * | cathode * | | .subckt CR150 1 2 j1 1 2 2 jx .model jx NJF(Beta=182u Betatce=-.5 Rd=1 Rs=0 Lambda=303u Vto=-2.866 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR160 anode * | cathode * | | .subckt CR160 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.45m Betatce=-.5 Rd=1 Rs=0 Lambda=625u Vto=-1.052 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR180 anode * | cathode * | | .subckt CR180 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.345m Betatce=-.5 Rd=1 Rs=0 Lambda=585u Vto=-1.158 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR200 anode * | cathode * | | .subckt CR200 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.25m Betatce=-.5 Rd=1 Rs=0 Lambda=568u Vto=-1.267 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR220 anode * | cathode * | | .subckt CR220 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.16m Betatce=-.5 Rd=1 Rs=0 Lambda=568.2u Vto=-1.3785 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR240 anode * | cathode * | | .subckt CR240 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.09m Betatce=-.5 Rd=1 Rs=0 Lambda=554.2u Vto=-1.485 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR270 anode * | cathode * | | .subckt CR270 1 2 j1 1 2 2 jx .model jx NJF(Beta=1.06m Betatce=-.5 Rd=1 Rs=0 Lambda=544.8u Vto=-1.598 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR300 anode * | cathode * | | .subckt CR300 1 2 j1 1 2 2 jx .model jx NJF(Beta=.93m Betatce=-.5 Rd=1 Rs=0 Lambda=556.7u Vto=-1.797 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR330 anode * | cathode * | | .subckt CR330 1 2 j1 1 2 2 jx .model jx NJF(Beta=.92m Betatce=-.5 Rd=1 Rs=0 Lambda=541.2u Vto=-1.897 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR360 anode * | cathode * | | .subckt CR360 1 2 j1 1 2 2 jx .model jx NJF(Beta=885u Betatce=-.5 Rd=1 Rs=0 Lambda=534.2u Vto=-2.020 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR390 anode * | cathode * | | .subckt CR390 1 2 j1 1 2 2 jx .model jx NJF(Beta=870u Betatce=-.5 Rd=1 Rs=0 Lambda=534.1u Vto=-2.120 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR430 anode * | cathode * | | .subckt CR430 1 2 j1 1 2 2 jx .model jx NJF(Beta=790u Betatce=-.5 Rd=1 Rs=0 Lambda=516.3u Vto=-2.336 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR470 anode * | cathode * | | .subckt CR470 1 2 j1 1 2 2 jx .model jx NJF(Beta=750u Betatce=-.5 Rd=1 Rs=0 Lambda=531.9u Vto=-2.506 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CR530 anode * | cathode * | | .subckt CR530 1 2 j1 1 2 2 jx .model jx NJF(Beta=407.5u Betatce=-.5 Rd=1 Rs=0 Lambda=539.1u Vto=-3.607 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-21 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR0240 anode * | cathode * | | .subckt CRR0240 1 2 j1 1 2 2 jx .model jx NJF(Beta=127u Betatce=-.5 Rd=1 Rs=0 Lambda=320.8u Vto=-1.373 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR0360 anode * | cathode * | | .subckt CRR0360 1 2 j1 1 2 2 jx .model jx NJF(Beta=100u Betatce=-.5 Rd=1 Rs=0 Lambda=291.7u Vto=-1.898 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR0560 anode * | cathode * | | .subckt CRR0560 1 2 j1 1 2 2 jx .model jx NJF(Beta=63u Betatce=-.5 Rd=1 Rs=0 Lambda=298.2u Vto=-2.98 + Vtotc=-2.5m N=2 Xti=3 Cgd=3p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR0800 anode * | cathode * | | .subckt CRR0800 1 2 j1 1 2 2 jx .model jx NJF(Beta=150u Betatce=-.5 Rd=1 Rs=0 Lambda=240u Vto=-2.31 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR1250 anode * | cathode * | | .subckt CRR1250 1 2 j1 1 2 2 jx .model jx NJF(Beta=99u Betatce=-.5 Rd=1 Rs=0 Lambda=177.8u Vto=-3.562 + Vtotc=-2.5m N=2 Xti=3 Cgd=4.5p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKM case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR1950 anode * | cathode * | | .subckt CRR1950 1 2 j1 1 2 2 jx .model jx NJF(Beta=630u Betatce=-.5 Rd=1 Rs=0 Lambda=641u Vto=-1.752 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR2900 anode * | cathode * | | .subckt CRR2900 1 2 j1 1 2 2 jx .model jx NJF(Beta=480u Betatce=-.5 Rd=1 Rs=0 Lambda=615.9u Vto=-2.457 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model CRR4300 anode * | cathode * | | .subckt CRR4300 1 2 j1 1 2 2 jx .model jx NJF(Beta=282.5u Betatce=-.5 Rd=1 Rs=0 Lambda=664.4u Vto=-3.9 + Vtotc=-2.5m N=2 Xti=3 Cgd=6p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKO case=TO18mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model J500 anode * | cathode * | | .subckt J500 1 2 j1 1 2 2 jx .model jx NJF(Beta=82u Betatce=-.5 Rd=1 Rs=0 Lambda=520.8u Vto=-1.705 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J501 anode * | cathode * | | .subckt J501 1 2 j1 1 2 2 jx .model jx NJF(Beta=93u Betatce=-.5 Rd=1 Rs=0 Lambda=506.1u Vto=-1.878 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J502 anode * | cathode * | | .subckt J502 1 2 j1 1 2 2 jx .model jx NJF(Beta=79u Betatce=-.5 Rd=1 Rs=0 Lambda=527.9u Vto=-2.33 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J503 anode * | cathode * | | .subckt J503 1 2 j1 1 2 2 jx .model jx NJF(Beta=87.5u Betatce=-.5 Rd=1 Rs=0 Lambda=525u Vto=-2.527 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J504 anode * | cathode * | | .subckt J504 1 2 j1 1 2 2 jx .model jx NJF(Beta=87u Betatce=-.5 Rd=1 Rs=0 Lambda=533.3u Vto=-2.931 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J505 anode * | cathode * | | .subckt J505 1 2 j1 1 2 2 jx .model jx NJF(Beta=100u Betatce=-.5 Rd=1 Rs=0 Lambda=526u Vto=-3.158 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J506 anode * | cathode * | | .subckt J506 1 2 j1 1 2 2 jx .model jx NJF(Beta=96u Betatce=-.5 Rd=1 Rs=0 Lambda=510u Vto=-3.81 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J507 anode * | cathode * | | .subckt J507 1 2 j1 1 2 2 jx .model jx NJF(Beta=100u Betatce=-.5 Rd=1 Rs=0 Lambda=555.6u Vto=-4.24 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J508 anode * | cathode * | | .subckt J508 1 2 j1 1 2 2 jx .model jx NJF(Beta=108u Betatce=-.5 Rd=1 Rs=0 Lambda=595.4u Vto=-4.705 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J509 anode * | cathode * | | .subckt J509 1 2 j1 1 2 2 jx .model jx NJF(Beta=106.5u Betatce=-.5 Rd=1 Rs=0 Lambda=555.7u Vto=-5.3 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J510 anode * | cathode * | | .subckt J510 1 2 j1 1 2 2 jx .model jx NJF(Beta=104.5u Betatce=-.5 Rd=1 Rs=0 Lambda=555.6u Vto=-5.859 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J511 anode * | cathode * | | .subckt J511 1 2 j1 1 2 2 jx .model jx NJF(Beta=120u Betatce=-.5 Rd=1 Rs=0 Lambda=708.5u Vto=-6.246 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J552 anode * | cathode * | | .subckt J552 1 2 j1 1 2 2 jx .model jx NJF(Beta=30u Betatce=-.5 Rd=1 Rs=0 Lambda=477.9u Vto=-3.97 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NKL case=TO92mod * 88-07-22 bam POVmax=100 * 88-12-16 pwt .ends *$ *model J553 anode * | cathode * | | .subckt J553 1 2 j1 1 2 2 jx .model jx NJF(Beta=22u Betatce=-.5 Rd=1 Rs=0 Lambda=200u Vto=-4.761 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-22 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J554 anode * | cathode * | | .subckt J554 1 2 j1 1 2 2 jx .model jx NJF(Beta=141u Betatce=-.5 Rd=1 Rs=0 Lambda=1m Vto=-2.656 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-25 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J555 anode * | cathode * | | .subckt J555 1 2 j1 1 2 2 jx .model jx NJF(Beta=410u Betatce=-.5 Rd=1 Rs=0 Lambda=568u Vto=-2.208 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-25 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J556 anode * | cathode * | | .subckt J556 1 2 j1 1 2 2 jx .model jx NJF(Beta=875u Betatce=-.5 Rd=1 Rs=0 Lambda=555.7u Vto=-1.85 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-25 bam POVmax=50 * 88-12-16 pwt .ends *$ *model J557 anode * | cathode * | | .subckt J557 1 2 j1 1 2 2 jx .model jx NJF(Beta=323u Betatce=-.5 Rd=1 Rs=0 Lambda=462.9u Vto=-3.73 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=NCL case=TO92mod * 88-07-25 bam POVmax=50 * 88-12-16 pwt .ends *$ *model JR135V anode * | cathode * | | .subckt JR135V 1 2 j1 1 2 2 jx .model jx NJF(Beta=38u Betatce=-.5 Rd=1 Rs=0 Lambda=1.031m Vto=-3.562 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=VRMA case=TO92mod * 88-07-25 bam POVmax=135 * 88-12-16 pwt .ends *$ *model JR170V anode * | cathode * | | .subckt JR170V 1 2 j1 1 2 2 jx .model jx NJF(Beta=38u Betatce=-.5 Rd=1 Rs=0 Lambda=1.031m Vto=-3.562 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=VRMA case=TO92mod * 88-07-25 bam POVmax=170 * 88-12-16 pwt .ends *$ *model JR200V anode * | cathode * | | .subckt JR200V 1 2 j1 1 2 2 jx .model jx NJF(Beta=38u Betatce=-.5 Rd=1 Rs=0 Lambda=1.031m Vto=-3.562 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=VRMA case=TO92mod * 88-07-25 bam POVmax=200 * 88-12-16 pwt .ends *$ *model JR220V anode * | cathode * | | .subckt JR220V 1 2 j1 1 2 2 jx .model jx NJF(Beta=38u Betatce=-.5 Rd=1 Rs=0 Lambda=1.031m Vto=-3.562 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=VRMA case=TO92mod * 88-07-25 bam POVmax=220 * 88-12-16 pwt .ends *$ *model JR240V anode * | cathode * | | .subckt JR240V 1 2 j1 1 2 2 jx .model jx NJF(Beta=38u Betatce=-.5 Rd=1 Rs=0 Lambda=1.031m Vto=-3.562 + Vtotc=-2.5m N=2 Xti=3 Cgd=2p Is=10f M=.5 Pb=1 Fc=.5 Af=1) * Siliconix pid=VRMA case=TO92mod * 88-07-25 bam POVmax=240 * 88-12-16 pwt .ends *$ *** Voltage-variable capacitance diodes * The parameters in this model library were derived from the data sheets for * each part. Each part was characterize using the Parts option. *$ .model D1N5139 D(Is=55p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=16.26p M=.455 Vj=.75 + Fc=.5 Isr=543.1p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5139A D(Is=55p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=16.26p M=.455 Vj=.75 + Fc=.5 Isr=543.1p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5140 D(Is=54.2p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=23.92p M=.4554 + Vj=.75 Fc=.5 Isr=542.5p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5140A D(Is=54.2p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=23.92p M=.4554 + Vj=.75 Fc=.5 Isr=542.5p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5141 D(Is=54.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=28.69p M=.4553 + Vj=.75 Fc=.5 Isr=542.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5141A D(Is=54.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=28.69p M=.4553 + Vj=.75 Fc=.5 Isr=542.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5142 D(Is=54.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=35.85p M=.455 + Vj=.75 Fc=.5 Isr=543.4p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5142A D(Is=54.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=35.85p M=.455 + Vj=.75 Fc=.5 Isr=543.4p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5143 D(Is=54.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=43.02p M=.455 + Vj=.75 Fc=.5 Isr=543.3p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5143A D(Is=54.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=43.02p M=.455 + Vj=.75 Fc=.5 Isr=543.3p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5144 D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=55.7p M=.4763 + Vj=.75 Fc=.5 Isr=499.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5144A D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=55.7p M=.4763 + Vj=.75 Fc=.5 Isr=499.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5145 D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68.37p M=.4763 + Vj=.75 Fc=.5 Isr=499.7p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5145A D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68.37p M=.4763 + Vj=.75 Fc=.5 Isr=499.7p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5146 D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=83.55p M=.4763 + Vj=.75 Fc=.5 Isr=499.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5146A D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=83.55p M=.4763 + Vj=.75 Fc=.5 Isr=499.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5147 D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=98.74p M=.4763 + Vj=.75 Fc=.5 Isr=499.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5147A D(Is=49.9p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=98.74p M=.4763 + Vj=.75 Fc=.5 Isr=499.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5148 D(Is=43.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120.6p M=.5123 + Vj=.75 Fc=.5 Isr=433.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5148A D(Is=43.3p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120.6p M=.5123 + Vj=.75 Fc=.5 Isr=433.6p Nr=2 Bv=70 Ibv=10u) * Motorola pid=1N5139 case=DO204AA * 88-09-22 bam creation *$ .model D1N5441A D(Is=4.85E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=14.93p M=.4261 + Vj=.75 Fc=.5 Isr=12.83p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5442A D(Is=7.14E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=18.01p M=.4261 + Vj=.75 Fc=.5 Isr=12.83p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5443A D(Is=10.51E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=21.95p M=.426 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5444A D(Is=15.47E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=26.34p M=.426 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5445A D(Is=22.77E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=31.95p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5446A D(Is=22.77E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=38.34p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5447A D(Is=33.52E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=42.6p M=.4097 + Vj=.75 Fc=.5 Isr=13.52p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5448A D(Is=49.35E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=46.85p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5449A D(Is=88.13E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=57.51p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5450A D(Is=292.2E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=74.34p M=.44 + Vj=.75 Fc=.5 Isr=12.27p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5451A D(Is=405.9E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=87.86p M=.44 + Vj=.75 Fc=.5 Isr=12.28p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5452A D(Is=563.8E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=111.7p M=.4691 + Vj=.75 Fc=.5 Isr=11.19p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5453A D(Is=783.1E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=133.1p M=.4689 + Vj=.75 Fc=.5 Isr=11.19p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5454A D(Is=1.088f Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=161.7p M=.4692 + Vj=.75 Fc=.5 Isr=11.18p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5455A D(Is=1.511f Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=195p M=.4692 + Vj=.75 Fc=.5 Isr=11.18p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5456A D(Is=2.099f Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=259.9p M=.5175 + Vj=.75 Fc=.5 Isr=9.585p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5441A case=DO204AA * 88-09-22 bam creation *$ .model D1N5461A D(Is=4.85E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=14.93p M=.4261 + Vj=.75 Fc=.5 Isr=12.83p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5462A D(Is=7.14E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=18.01p M=.4261 + Vj=.75 Fc=.5 Isr=12.83p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5463A D(Is=10.51E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=21.95p M=.426 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5464A D(Is=15.47E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=26.34p M=.426 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5465A D(Is=22.77E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=31.95p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5466A D(Is=22.77E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=38.34p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5467A D(Is=33.52E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=42.6p M=.4097 + Vj=.75 Fc=.5 Isr=13.52p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5468A D(Is=49.35E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=46.85p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5469A D(Is=88.13E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=57.51p M=.4096 + Vj=.75 Fc=.5 Isr=13.53p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5470A D(Is=292.2E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=74.34p M=.44 + Vj=.75 Fc=.5 Isr=12.27p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5471A D(Is=405.9E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=87.86p M=.44 + Vj=.75 Fc=.5 Isr=12.28p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5472A D(Is=563.8E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=111.7p M=.4691 + Vj=.75 Fc=.5 Isr=11.19p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5473A D(Is=783.1E-18 Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=133.1p M=.4689 + Vj=.75 Fc=.5 Isr=11.19p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5474A D(Is=1.088f Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=161.7p M=.4692 + Vj=.75 Fc=.5 Isr=11.18p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5475A D(Is=1.511f Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=195p M=.4692 + Vj=.75 Fc=.5 Isr=11.18p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .model D1N5476A D(Is=2.099f Rs=.1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=259.9p M=.5175 + Vj=.75 Fc=.5 Isr=9.585p Nr=2 Bv=30 Ibv=10u) * Motorola pid=1N5461A case=DO204AA * 88-09-22 bam creation *$ .SUBCKT MV104 1 2 3 * A1 A2 C D1 1 3 DMV104 D2 2 3 DMV104 .model DMV104 D(Is=1.465p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=83.22p M=.463 + Vj=.75 Fc=.5 Isr=14.3p Nr=2 Bv=32 Ibv=10u) * Motorola pid=MV104 case=TO92 * 88-09-22 bam creation *Changed to a 2 diode subcircuit 96-5-21 RAP .ENDS *$ .SUBCKT MV104G 1 2 3 * A1 A2 C D1 1 3 DMV104G D2 2 3 DMV104G .model DMV104G D(Is=1.465p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=76.93p M=.4633 + Vj=.75 Fc=.5 Isr=14.28p Nr=2 Bv=32 Ibv=10u) * Motorola pid=MV104 case=TO92 * 88-09-22 bam creation *Changed to a 2 diode subcircuit 96-5-21 RAP .ENDS *$ .model MV209 D(Is=434f Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=125p M=.9079 Vj=.75 + Fc=.5 Isr=4.395p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV209 case=182-03 * 88-09-22 bam creation *$ .model MV1866 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=22.2p M=.4322 + Vj=.75 Fc=.5 Isr=98.44p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1868 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=26.65p M=.4322 + Vj=.75 Fc=.5 Isr=98.44p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1870 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=33.31p M=.4322 + Vj=.75 Fc=.5 Isr=98.44p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1871 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=39.97p M=.4322 + Vj=.75 Fc=.5 Isr=98.44p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1872 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=51.35p M=.4592 + Vj=.75 Fc=.5 Isr=89.05p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1874 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=63.04p M=.4593 + Vj=.75 Fc=.5 Isr=88.99p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1876 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=77.02p M=.4592 + Vj=.75 Fc=.5 Isr=89.05p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1877 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=91p M=.4591 Vj=.75 + Fc=.5 Isr=89.08p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV1878 D(Is=10.04p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102.3p M=.4214 + Vj=.75 Fc=.5 Isr=102.5p Nr=2 Bv=75 Ibv=10u) * Motorola pid=MV1866 case=DO204AA * 88-09-22 bam creation *$ .model MV2101 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=14.93p M=.4261 + Vj=.75 Fc=.5 Isr=16.02p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2102 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=18.01p M=.4261 + Vj=.75 Fc=.5 Isr=16.02p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2103 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=21.95p M=.426 + Vj=.75 Fc=.5 Isr=16.03p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2104 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=26.34p M=.426 + Vj=.75 Fc=.5 Isr=16.03p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2105 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=34.49p M=.4511 + Vj=.75 Fc=.5 Isr=14.85p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2106 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=41.39p M=.4511 + Vj=.75 Fc=.5 Isr=14.85p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2107 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=50.59p M=.4511 + Vj=.75 Fc=.5 Isr=14.85p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2108 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=62.08p M=.4511 + Vj=.75 Fc=.5 Isr=14.85p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2109 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=82.03p M=.4933 + Vj=.75 Fc=.5 Isr=13.06p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2110 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=96.94p M=.4933 + Vj=.75 Fc=.5 Isr=13.06p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2111 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=116.8p M=.4933 + Vj=.75 Fc=.5 Isr=13.06p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2112 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=140.6p M=.4989 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2113 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=170.8p M=.499 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2114 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=205.9p M=.4988 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2115 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=225.2p M=.4399 + Vj=.75 Fc=.5 Isr=15.36p Nr=2 Bv=30 Ibv=10u) * Motorola pid=MV2101 case=182-03 * 88-09-22 bam creation *$ .model MV2201 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=14.93p M=.4261 + Vj=.75 Fc=.5 Isr=16.02p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ .model MV2203 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=21.95p M=.426 + Vj=.75 Fc=.5 Isr=16.03p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ .model MV2205 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=34.49p M=.4511 + Vj=.75 Fc=.5 Isr=14.85p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ .model MV2207 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=50.59p M=.4511 + Vj=.75 Fc=.5 Isr=14.85p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ .model MV2209 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=82.03p M=.4933 + Vj=.75 Fc=.5 Isr=13.06p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ .model MV2211 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=116.8p M=.4933 + Vj=.75 Fc=.5 Isr=13.06p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ .model MV2213 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=170.8p M=.499 + Vj=.75 Fc=.5 Isr=12.84p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ .model MV2215 D(Is=1.365p Rs=1 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=225.2p M=.4399 + Vj=.75 Fc=.5 Isr=15.36p Nr=2 Bv=25 Ibv=10u) * Motorola pid=MV2201 case=182-03 * 88-09-22 bam creation *$ *** Zener Diodes *** * The parameters Ibv, Ibvl, Nbv, and Nbvl, were characterized by matching the * manufacturer's Zener impedance at three current levels. The parameter Tbv1 * is calculated directly. The remaining parameters were characterize using * the Parts option. *$ .model D1N746 D(Is=31.47f Rs=9.494 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=220p M=.5959 + Vj=.75 Fc=.5 Isr=2.035n Nr=2 Bv=3.3 Ibv=45.862m Nbv=3.0477 + Ibvl=29.831m Nbvl=11.606 Tbv1=-636.4u) * Motorola pid=1N746 case=DO-35 * 89-9-18 gjg * Vz = 3.3 @ 20mA, Zz = 310 @ 1mA, Zz = 68 @ 5mA, Zz = 19 @ 20mA *$ .model D1N747 D(Is=1.242f Rs=1.137 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=210p M=.6063 + Vj=.75 Fc=.5 Isr=1.922n Nr=2 Bv=3.6 Ibv=13.987m Nbv=3.031 + Ibvl=10.212m Nbvl=12.73 Tbv1=-555.6u) * Motorola pid=1N747 case=DO-35 * 89-9-18 gjg * Vz = 3.6 @ 20mA, Zz = 330 @ 1mA, Zz = 52 @ 5mA, Zz = 7.3 @ 20mA *$ .model D1N748 D(Is=1.252f Rs=1.156 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=205p M=.6004 + Vj=.75 Fc=.5 Isr=1.867n Nr=2 Bv=3.9 Ibv=17.244m Nbv=2.4016 + Ibvl=8.619m Nbvl=13.283 Tbv1=-384.62u) * Motorola pid=1N748 case=DO-35 * 89-9-18 gjg * Vz = 3.9 @ 20mA, Zz = 345 @ 1mA, Zz = 49 @ 5mA, Zz = 5.8 @ 20mA *$ .model D1N749 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=190p M=.6124 + Vj=.75 Fc=.5 Isr=1.743n Nr=2 Bv=4.3 Ibv=16.748m Nbv=1.7936 + Ibvl=5.0382m Nbvl=12.554 Tbv1=-232.56u) * Motorola pid=1N749 case=DO-35 * 89-9-18 gjg * Vz = 4.3 @ 20mA, Zz = 325 @ 1mA, Zz = 24 @ 5mA, Zz = 3.2 @ 20mA *$ .model D1N750 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=175p M=.5516 + Vj=.75 Fc=.5 Isr=1.859n Nr=2 Bv=4.7 Ibv=20.245m Nbv=1.6989 + Ibvl=1.9556m Nbvl=14.976 Tbv1=-21.277u) * Motorola pid=1N750 case=DO-35 * 89-9-18 gjg * Vz = 4.7 @ 20mA, Zz = 300 @ 1mA, Zz = 12.5 @ 5mA, Zz =2.6 @ 20mA *$ .model D1N751 D(Is=1.004f Rs=.5875 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=160p M=.5484 + Vj=.75 Fc=.5 Isr=1.8n Nr=2 Bv=5.1 Ibv=27.721m Nbv=1.1779 + Ibvl=1.1646m Nbvl=21.894 Tbv1=176.47u) * Motorola pid=1N751 case=DO-35 * 89-9-18-gjg * Vz = 5.1 @ 20mA, Zz = 175 @ 1mA, Zz = 8.2 @ 5mA, Zz = 2.2 @ 20mA *$ .model D1N752 D(Is=1.154f Rs=.9471 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=150p M=.5788 + Vj=.75 Fc=.5 Isr=1.625n Nr=2 Bv=5.6 Ibv=62.583m Nbv=.62382 + Ibvl=631.96u Nbvl=50 Tbv1=267.86u) * Motorola pid=1N752 case=DO-35 * 89-9-18 gjg * Vz = 5.6 @ 20mA, Zz = 40 @ 1mA, Zz = 4.5 @ 5mA, Zz = 1.9 @ 20mA *$ .model D1N753 D(Is=1.536f Rs=1.687 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=130p M=.5259 + Vj=.75 Fc=.5 Isr=1.719n Nr=2 Bv=6.2 Ibv=1.9685 Nbv=.28384 + Ibvl=7.0094e-7 Nbvl=.29418 Tbv1=443.55u) * Motorola pid=1N753 case=DO-35 * 89-9-18 gjg * Vz = 6.2 @ 20mA, Zz = 9 @ 1mA, Zz = 3.4 @ 5mA, Zz = 1.85 @ 20mA *$ .model D1N754 D(Is=1.616f Rs=1.818 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120p M=.5117 + Vj=.75 Fc=.5 Isr=1.698n Nr=2 Bv=6.8 Ibv=2.8814 Nbv=.28248 + Ibvl=1.9426e-6 Nbvl=.27168 Tbv1=485.29u) * Motorola pid=1N754 case=DO-35 * 89-9-19 gjg * Vz = 6.8 @ 20mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model D1N755 D(Is=2.077f Rs=2.467 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=104p M=.5061 + Vj=.75 Fc=.5 Isr=1.645n Nr=2 Bv=7.5 Ibv=2.5701 Nbv=.39227 + Ibvl=4.0222e-5 Nbvl=.25042 Tbv1=533.33u) * Motorola pid=1N755 case=DO-35 * 89-9-18 gjg * Vz = 7.5 @ 20mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model D1N756 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.448 + Vj=.75 Fc=.5 Isr=1.803n Nr=2 Bv=8.2 Ibv=1.5593 Nbv=.51406 + Ibvl=8.3521e-5 Nbvl=.1313 Tbv1=585.366u) * Motorola pid=1N756 case=DO-35 * 89-9-19 gjg * Vz = 8.2 @ 20mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model D1N757 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=78p M=.4399 + Vj=.75 Fc=.5 Isr=1.762n Nr=2 Bv=9.1 Ibv=.48516 Nbv=.7022 + Ibvl=1m Nbvl=.13785 Tbv1=604.396u) * Motorola pid=1N757 case=DO-35 * 89-9-18 gjg * Vz = 9.1 @ 20mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model D1N758 D(Is=1.953f Rs=2.305 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3856 + Vj=.75 Fc=.5 Isr=1.939n Nr=2 Bv=10 Ibv=.16597 Nbv=.84122 + Ibvl=1.003m Nbvl=.20892 Tbv1=650u) * Motorola pid=1N758 case=DO-35 * 89-9-18 gjg * Vz = 10 @ 20mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model D1N759 D(Is=1.773f Rs=2.06 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102p M=.4868 + Vj=.75 Fc=.5 Isr=1.393n Nr=2 Bv=12 Ibv=79.489m Nbv=1.1528 + Ibvl=142.9n Nbvl=.95108 Tbv1=700u) * Motorola pid=1N759 case=DO-35 * 89-9-18 gjg * Vz = 12 @ 20mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model D1N957A D(Is=1.616f Rs=1.82 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120p M=.5117 + Vj=.75 Fc=.5 Isr=1.698n Nr=2 Bv=6.8 Ibv=1.8441 Nbv=.28243 + Ibvl=6.2172E-15 Nbvl=.50147 Tbv1=485.294u) * Motorola pid=1N957A case=DO-35 * 89-9-18 gjg * Vz = 6.8 @ 18.5mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model D1N958A D(Is=2.077f Rs=2.467 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=104p M=.5061 + Vj=.75 Fc=.5 Isr=1.645n Nr=2 Bv=7.5 Ibv=.90645 Nbv=.39227 + Ibvl=.5849n Nbvl=1.5122 Tbv1=533.33u) * Motorola pid=1N958A case=DO-35 * 89-9-18 gjg * Vz = 7.5 @ 16.5mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model D1N959A D(Is=2.491f Rs=2.938 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.448 + Vj=.75 Fc=.5 Isr=1.803n Nr=2 Bv=8.2 Ibv=.41558 Nbv=.51229 + Ibvl=.65179n Nbvl=1.1568 Tbv1=585.37u) * Motorola pid=1N959A case=DO-35 * 89-9-18 gjg * Vz = 8.2 @ 15mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model D1N960A D(Is=2.168f Rs=2.578 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=78p M=.4399 + Vj=.75 Fc=.5 Isr=1.762n Nr=2 Bv=9.1 Ibv=97.714m Nbv=.71712 + Ibvl=.58975n Nbvl=.98128 Tbv1=604.4u) * Motorola pid=1N960A case=DO-35 * 89-9-18 gjg * Vz = 9.1 @ 14mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model D1N961A D(Is=1.953f Rs=2.305 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3856 + Vj=.75 Fc=.5 Isr=1.939n Nr=2 Bv=10 Ibv=46.912m Nbv=.84122 + Ibvl=626.74p Nbvl=.78605 Tbv1=650u) * Motorola pid=1N961A case=DO-35 * 89-9-18 gjg * Vz = 10 @ 12.5mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model D1N962A D(Is=1.609f Rs=1.813 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=115p M=.4751 + Vj=.75 Fc=.5 Isr=1.493n Nr=2 Bv=11 Ibv=24.084m Nbv=1.1052 + Ibvl=149.27n Nbvl=.22862 Tbv1=672.73u) * Motorola pid=1N962A case=DO-35 * 89-9-18 gjg * Vz = 11 @ 11.5mA, Zz = 30.5 @ 1mA, Zz = 7.4 @ 5mA, Zz = 3.25 @ 20mA *$ .model D1N963A D(Is=1.773f Rs=2.061 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102p M=.4868 + Vj=.75 Fc=.5 Isr=1.393n Nr=2 Bv=12 Ibv=21.7m Nbv=1.1527 + Ibvl=29.343n Nbvl=.245 Tbv1=700u) * Motorola pid=1N963A case=DO-35 * 89-9-18 gjg * Vz = 12 @ 10.5mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model D1N964A D(Is=2.253f Rs=2.678 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.4558 + Vj=.75 Fc=.5 Isr=1.461n Nr=2 Bv=13 Ibv=21.761m Nbv=1.1851 + Ibvl=468.81n Nbvl=.65126 Tbv1=846.15u) * Motorola pid=1N964A case=DO-35 * 89-9-18 gjg * Vz = 13 @ 9.5mA, Zz = 33.5 @ 1mA, Zz = 8 @ 5mA, Zz = 4.9 @ 20mA *$ .model D1N965A D(Is=3.142f Rs=3.536 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=80.5p M=.4186 + Vj=.75 Fc=.5 Isr=1.527n Nr=2 Bv=15 Ibv=24.573m Nbv=1.0932 + Ibvl=7.1249u Nbvl=.65646 Tbv1=833.33u) * Motorola pid=1N965A case=DO-35 * 89-9-18 gjg * Vz = 15 @ 8.5mA, Zz = 32 @ 1mA, Zz = 8.25 @ 5mA, Zz = 5.75 @ 20mA *$ .model D1N966A D(Is=5.461f Rs=4.975 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=69p M=.4472 + Vj=.75 Fc=.5 Isr=1.371n Nr=2 Bv=16 Ibv=32.07m Nbv=1.0589 + Ibvl=44.191u Nbvl=.86786 Tbv1=875u) * Motorola pid=1N966A case=DO-35 * 89-9-18 gjg * Vz = 16 @ 7.8mA, Zz = 32.5 @ 1mA, Zz = 9.8 @ 5mA, Zz = 6.9 @ 20mA *$ .model D1N967A D(Is=7.021f Rs=5.619 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=60p M=.4093 + Vj=.75 Fc=.5 Isr=1.461n Nr=2 Bv=18 Ibv=23.333m Nbv=1.2074 + Ibvl=215.7u Nbvl=.71348 Tbv1=888.9u) * Motorola pid=1N967A case=DO-35 * 89-9-18 gjg * Vz = 18 @ 7mA, Zz = 37 @ 1mA, Zz = 11 @ 5mA, Zz = 7.9 @ 20mA *$ .model D1N968A D(Is=10.18f Rs=6.578 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=59p M=.4063 + Vj=.75 Fc=.5 Isr=1.415n Nr=2 Bv=20 Ibv=21.603m Nbv=1.2514 + Ibvl=218.21u Nbvl=1.2514 Tbv1=850u) * Motorola pid=1N968A case=DO-35 * 89-9-18 gjg * Vz = 20 @ 6.2mA, Zz = 39 @ 1mA, Zz = 13 @ 5mA, Zz = 8.25 @ 20mA *$ .model D1N969A D(Is=17.49f Rs=7.976 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=50p M=.4141 + Vj=.75 Fc=.5 Isr=1.33n Nr=2 Bv=22 Ibv=20.578m Nbv=1.315 + Ibvl=207.85u Nbvl=1.315 Tbv1=840.91u) * Motorola pid=1N969A case=DO-35 * 89-9-18 gjg * Vz = 22 @ 5.6mA, Zz = 42 @ 1mA, Zz = 15 @ 5mA, Zz = 9.5 @ 20mA *$ .model D1N970A D(Is=25.64f Rs=8.973 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=44p M=.3798 + Vj=.75 Fc=.5 Isr=1.438n Nr=2 Bv=24 Ibv=19.386m Nbv=1.3784 + Ibvl=162.43u Nbvl=8.7919 Tbv1=895.83u) * Motorola pid=1N970A case=DO-35 * 89-9-18 gjg * Vz = 24 @ 5.2mA, Zz = 48 @ 1mA, Zz = 16 @ 5mA, Zz = 11 @ 20mA *$ .model D1N971A D(Is=81.47f Rs=11.96 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=42p M=.3983 + Vj=.75 Fc=.5 Isr=1.294n Nr=2 Bv=27 Ibv=87.12m Nbv=.51025 + Ibvl=9.0498m Nbvl=2.0249 Tbv1=888.89u) * Motorola pid=1N971A case=DO-35 * 89-9-18 gjg * Vz = 27 @ 4.6mA, Zz = 52 @ 1mA, Zz = 21 @ 5mA, Zz = 12 @ 20mA *$ .model D1N4728 D(Is=11.11f Rs=6.808 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=315p M=.4346 + Vj=.75 Fc=.5 Isr=2.595n Nr=2 Bv=3.3 Ibv=5.8452 Nbv=3.6742 + Ibvl=.27224 Nbvl=11.715 Tbv1=-636.36u) * Motorola pid=1N4728 case=DO-41 * 89-9-19 gjg * Vz = 3.3 @ 76mA, Zz = 310 @ 1mA, Zz = 68 @ 5mA, Zz = 19 @ 20mA *$ .model D1N4729 D(Is=2.306f Rs=2.741 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=300p M=.4641 + Vj=.75 Fc=.5 Isr=2.405n Nr=2 Bv=3.6 Ibv=1.1936 Nbv=2.2747 + Ibvl=19.94m Nbvl=12.64 Tbv1=-555.56u) * Motorola pid=1N4729 case=DO-41 * 89-9-19 gjg * Vz = 3.6 @ 69mA, Zz = 330 @ 1mA, Zz = 52 @ 5mA, Zz = 7.3 @ 20mA *$ .model D1N4730 D(Is=1.379f Rs=1.406 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=280p M=.4369 + Vj=.75 Fc=.5 Isr=2.441n Nr=2 Bv=3.9 Ibv=.2473 Nbv=2.2758 + Ibvl=13.346m Nbvl=13.271 Tbv1=-384.62u) * Motorola pid=1N4730 case=DO-41 * 89-9-19 gjg * Vz = 3.9 @ 64mA, Zz = 345 @ 1mA, Zz = 49 @ 5mA, Zz = 5.8 @ 20mA *$ .model D1N4731 D(Is=837.3E-18 Rs=.1211 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=220p M=.389 + Vj=.75 Fc=.5 Isr=2.56n Nr=2 Bv=4.3 Ibv=60.167m Nbv=1.8815 + Ibvl=6.0358m Nbvl=12.57 Tbv1=-232.558u) * Motorola pid=1N4731 case=DO-41 * 89-9-19 gjg * Vz = 4.3 @ 58mA, Zz = 325 @ 1mA, Zz = 24 @ 5mA, Zz = 3.2 @ 20mA *$ .model D1N4732 D(Is=1.064f Rs=.741 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=208p M=.4176 + Vj=.75 Fc=.5 Isr=2.364n Nr=2 Bv=4.7 Ibv=.16902 Nbv=1.2344 + Ibvl=4.0082m Nbvl=11.59 Tbv1=-21.28u) * Motorola pid=1N4732 case=DO-41 * 89-9-19 gjg * Vz = 4.7 @ 53mA, Zz = 300 @ 1mA, Zz = 12.5 @ 5mA, Zz =2.6 @ 20mA *$ .model D1N4733 D(Is=1.214f Rs=1.078 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=185p M=.3509 + Vj=.75 Fc=.5 Isr=2.601n Nr=2 Bv=5.1 Ibv=.70507 Nbv=.74348 + Ibvl=4.8274m Nbvl=6.7393 Tbv1=176.471u) * Motorola pid=1N4733 case=DO-41 * 89-9-19 gjg * Vz = 5.1 @ 49mA, Zz = 175 @ 1mA, Zz = 8.2 @ 5mA, Zz = 2.2 @ 20mA *$ .model D1N4734 D(Is=1.085f Rs=.7945 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=157p M=.2966 + Vj=.75 Fc=.5 Isr=2.811n Nr=2 Bv=5.6 Ibv=.37157 Nbv=.64726 + Ibvl=1m Nbvl=6.5761 Tbv1=267.86u) * Motorola pid=1N4734 case=DO-41 * 89-9-19 gjg * Vz = 5.6 @ 45mA, Zz = 40 @ 1mA, Zz = 4.5 @ 5mA, Zz = 1.9 @ 20mA *$ .model D1N4735 D(Is=1.168f Rs=.9756 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=140p M=.3196 + Vj=.75 Fc=.5 Isr=2.613n Nr=2 Bv=6.2 Ibv=4.9984 Nbv=.32088 + Ibvl=184.78u Nbvl=.19558 Tbv1=443.55u) * Motorola pid=1N4735 case=DO-41 * 89-9-19 gjg * Vz = 6.2 @ 41mA, Zz = 9 @ 1mA, Zz = 3.4 @ 5mA, Zz = 1.85 @ 20mA *$ .model D1N4736 D(Is=1.327f Rs=1.306 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=125p M=.3144 + Vj=.75 Fc=.5 Isr=2.575n Nr=2 Bv=6.8 Ibv=15 Nbv=.31009 + Ibvl=149.2u Nbvl=.31028 Tbv1=485.29u) * Motorola pid=1N4736 case=DO-41 * 89-9-19 gjg * Vz = 6.8 @ 37mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model D1N4737 D(Is=1.699f Rs=1.955 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=106p M=.3176 + Vj=.75 Fc=.5 Isr=2.488n Nr=2 Bv=7.5 Ibv=15 Nbv=.42018 + Ibvl=1m Nbvl=.094527 Tbv1=533.33u) * Motorola pid=1N4737 case=DO-41 * 89-9-19 gjg * Vz = 7.5 @ 34mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model D1N4738 D(Is=2.102f Rs=2.5 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=100p M=.3503 + Vj=.75 Fc=.5 Isr=2.252n Nr=2 Bv=8.2 Ibv=8 Nbv=.53621 + Ibvl=213.52u Nbvl=.17879 Tbv1=585.37u) * Motorola pid=1N4738 case=DO-41 * 89-9-19 gjg * Vz = 8.2 @ 31mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model D1N4739 D(Is=2.11f Rs=2.512 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=89p M=.384 + Vj=.75 Fc=.5 Isr=2.012n Nr=2 Bv=9.1 Ibv=1.2 Nbv=.72056 + Ibvl=10m Nbvl=.21148 Tbv1=604.396u) * Motorola pid=1N4739 case=DO-41 * 89-9-19 gjg * Vz = 9.1 @ 28mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model D1N4740 D(Is=1.945f Rs=2.302 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=82p M=.3649 + Vj=.75 Fc=.5 Isr=2.04n Nr=2 Bv=10 Ibv=.35034 Nbv=.84137 + Ibvl=10m Nbvl=.17757 Tbv1=650u) * Motorola pid=1N4740 case=DO-41 * 89-9-19 gjg * Vz = 10 @ 25mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model D1N4741 D(Is=1.566f Rs=1.74 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=105p M=.4156 + Vj=.75 Fc=.5 Isr=1.737n Nr=2 Bv=11 Ibv=92.573m Nbv=1.1098 + Ibvl=440.66u Nbvl=.23096 Tbv1=672.73u) * Motorola pid=1N4741 case=DO-41 * 89-9-19 gjg * Vz = 11 @ 23mA, Zz = 30.5 @ 1mA, Zz = 7.4 @ 5mA, Zz = 3.25 @ 20mA *$ .model D1N4742 D(Is=1.773f Rs=2.06 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=100p M=.3894 + Vj=.75 Fc=.5 Isr=1.799n Nr=2 Bv=12 Ibv=89.447m Nbv=1.1527 + Ibvl=248.34n Nbvl=.8248 Tbv1=700u) * Motorola pid=1N4742 case=DO-41 * 89-9-19 gjg * Vz = 12 @ 21mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model D1N4743 D(Is=2.253f Rs=2.678 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=80p M=.3644 + Vj=.75 Fc=.5 Isr=1.87n Nr=2 Bv=13 Ibv=99.671m Nbv=1.1851 + Ibvl=8.4078u Nbvl=1.2407 Tbv1=846.15u) * Motorola pid=1N4743 case=DO-41 * 89-9-19 gjg * Vz = 13 @ 19mA, Zz = 33.5 @ 1mA, Zz = 8 @ 5mA, Zz = 4.9 @ 20mA *$ .model D1N4744 D(Is=3.142f Rs=3.544 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=72.5p M=.3282 + Vj=.75 Fc=.5 Isr=1.973n Nr=2 Bv=15 Ibv=.14467 Nbv=1.093 + Ibvl=.1m Nbvl=1.2722 Tbv1=001433.3u) * Motorola pid=1N4744 case=DO-41 * 89-9-19 gjg * Vz = 15 @ 17mA, Zz = 32 @ 1mA, Zz = 8.25 @ 5mA, Zz = 5.75 @ 20mA *$ .model D1N4745 D(Is=5.461f Rs=4.974 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3197 + Vj=.75 Fc=.5 Isr=1.982n Nr=2 Bv=16 Ibv=.25684 Nbv=1.0588 + Ibvl=1.029m Nbvl=1.0409 Tbv1=875u) * Motorola pid=1N4745 case=DO-41 * 89-9-19 gjg * Vz = 16 @ 15.5mA, Zz = 32.5 @ 1mA, Zz = 9.8 @ 5mA, Zz = 6.9 @ 20mA *$ .model D1N4746 D(Is=6.994f Rs=5.612 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=59p M=.2906 + Vj=.75 Fc=.5 Isr=2.088n Nr=2 Bv=18 Ibv=.17098 Nbv=1.2072 + Ibvl=2.002m Nbvl=1.1457 Tbv1=888.89u) * Motorola pid=1N4746 case=DO-41 * 89-9-19 gjg * Vz = 18 @ 14mA, Zz = 37 @ 1mA, Zz = 11 @ 5mA, Zz = 7.9 @ 20mA *$ .model D1N4747 D(Is=10.22f Rs=6.585 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=52p M=.2904 + Vj=.75 Fc=.5 Isr=2.029n Nr=2 Bv=20 Ibv=.15934 Nbv=1.2472 + Ibvl=211.18u Nbvl=1.9765 Tbv1=850u) * Motorola pid=1N4747 case=DO-41 * 89-9-19 gjg * Vz = 20 @ 12.5mA, Zz = 39 @ 1mA, Zz = 13 @ 5mA, Zz = 8.25 @ 20mA *$ .model D1N4748 D(Is=17.49f Rs=7.976 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=49p M=.2829 + Vj=.75 Fc=.5 Isr=2.024n Nr=2 Bv=22 Ibv=.16996 Nbv=1.315 + Ibvl=7.0073E-15 Nbvl=1.2735 Tbv1=840.91u) * Motorola pid=1N4748 case=DO-41 * 89-9-19 gjg * Vz = 22 @ 11.5mA, Zz = 42 @ 1mA, Zz = 15 @ 5mA, Zz = 9.5 @ 20mA *$ .model D1N4749 D(Is=25.94f Rs=9.006 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=41p M=.2715 + Vj=.75 Fc=.5 Isr=2.052n Nr=2 Bv=24 Ibv=.14951 Nbv=1.3684 + Ibvl=164.37u Nbvl=14 Tbv1=895.83u) * Motorola pid=1N4749 case=DO-41 * 89-9-19 gjg * Vz = 24 @ 10.5mA, Zz = 48 @ 1mA, Zz = 16 @ 5mA, Zz = 11 @ 20mA *$ .model D1N4750 D(Is=62.63f Rs=11.28 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=40p M=.2906 + Vj=.75 Fc=.5 Isr=1.864n Nr=2 Bv=27 Ibv=.13378 Nbv=1.5283 + Ibvl=3.4328m Nbvl=2.3046 Tbv1=888.89u) * Motorola pid=1N4750 case=DO-41 * 89-9-19 gjg * Vz = 27 @ 9.5mA, Zz = 52 @ 1mA, Zz = 21 @ 5mA, Zz = 12 @ 20mA *$ .model D1N5226 D(Is=31.47f Rs=9.494 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=220p M=.5959 + Vj=.75 Fc=.5 Isr=2.035n Nr=2 Bv=3.3 Ibv=45.862m Nbv=3.0477 + Ibvl=29.831m Nbvl=11.606 Tbv1=-636.36u) * Motorola pid=1N5226 case=DO-35 * 89-9-18 gjg * Vz = 3.3 @ 20mA, Zz = 310 @ 1mA, Zz = 68 @ 5mA, Zz = 19 @ 20mA *$ .model D1N5227 D(Is=1.242f Rs=1.137 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=210p M=.6063 + Vj=.75 Fc=.5 Isr=1.922n Nr=2 Bv=3.6 Ibv=13.987m Nbv=3.031 + Ibvl=10.212m Nbvl=12.73 Tbv1=-555.56u) * Motorola pid=1N5227 case=DO-35 * 89-9-18 gjg * Vz = 3.6 @ 20mA, Zz = 330 @ 1mA, Zz = 52 @ 5mA, Zz = 7.3 @ 20mA *$ .model D1N5228 D(Is=1.252f Rs=1.156 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=205p M=.6004 + Vj=.75 Fc=.5 Isr=1.867n Nr=2 Bv=3.9 Ibv=17.244m Nbv=2.4016 + Ibvl=8.619m Nbvl=13.283 Tbv1=-384.62u) * Motorola pid=1N5228 case=DO-35 * 89-9-18 gjg * Vz = 3.9 @ 20mA, Zz = 345 @ 1mA, Zz = 49 @ 5mA, Zz = 5.8 @ 20mA *$ .model D1N5229 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=190p M=.6124 + Vj=.75 Fc=.5 Isr=1.743n Nr=2 Bv=4.3 Ibv=16.748m Nbv=1.7936 + Ibvl=5.0382m Nbvl=12.554 Tbv1=-232.56u) * Motorola pid=1N5229 case=DO-35 * 89-9-18 gjg * Vz = 4.3 @ 20mA, Zz = 325 @ 1mA, Zz = 24 @ 5mA, Zz = 3.2 @ 20mA *$ .model D1N5230 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=175p M=.5516 + Vj=.75 Fc=.5 Isr=1.859n Nr=2 Bv=4.7 Ibv=20.245m Nbv=1.6989 + Ibvl=1.9556m Nbvl=14.976 Tbv1=-21.28u) * Motorola pid=1N5230 case=DO-35 * 89-9-18 gjg * Vz = 4.7 @ 20mA, Zz = 300 @ 1mA, Zz = 12.5 @ 5mA, Zz =2.6 @ 20mA *$ .model D1N5231 D(Is=1.004f Rs=.5875 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=160p M=.5484 + Vj=.75 Fc=.5 Isr=1.8n Nr=2 Bv=5.1 Ibv=27.721m Nbv=1.1779 + Ibvl=1.1646m Nbvl=21.894 Tbv1=176.47u) * Motorola pid=1N5231 case=DO-35 * 89-9-18-gjg * Vz = 5.1 @ 20mA, Zz = 175 @ 1mA, Zz = 8.2 @ 5mA, Zz = 2.2 @ 20mA *$ .model D1N5232 D(Is=1.154f Rs=.9471 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=150p M=.5788 + Vj=.75 Fc=.5 Isr=1.625n Nr=2 Bv=5.6 Ibv=62.583m Nbv=.62382 + Ibvl=631.96u Nbvl=50 Tbv1=267.86u) * Motorola pid=1N5232 case=DO-35 * 89-9-18 gjg * Vz = 5.6 @ 20mA, Zz = 40 @ 1mA, Zz = 4.5 @ 5mA, Zz = 1.9 @ 20mA *$ .model D1N5233 D(Is=629E-18 Rs=1.176 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=140p M=.5369 + Vj=.75 Fc=.5 Isr=1.707n Nr=2 Bv=6 Ibv=.10969 Nbv=.5351 + Ibvl=.11553 Nbvl=.049362 Tbv1=416.67u) * Motorola pid=1N5233 case=DO-35 * 89-9-18 gjg * Vz = 6 @ 20mA, Zz = 15 @ 1mA, Zz = 3.9 @ 5mA, Zz = 1.9 @ 20mA *$ .model D1N5234 D(Is=1.536f Rs=1.687 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=130p M=.5259 + Vj=.75 Fc=.5 Isr=1.719n Nr=2 Bv=6.2 Ibv=1.9685 Nbv=.28384 + Ibvl=7.0094e-7 Nbvl=.29418 Tbv1=443.55u) * Motorola pid=1N5234 case=DO-35 * 89-9-18 gjg * Vz = 6.2 @ 20mA, Zz = 9 @ 1mA, Zz = 3.4 @ 5mA, Zz = 1.85 @ 20mA *$ .model D1N5235 D(Is=1.616f Rs=1.818 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120p M=.5117 + Vj=.75 Fc=.5 Isr=1.698n Nr=2 Bv=6.8 Ibv=2.8814 Nbv=.28248 + Ibvl=1.9426e-6 Nbvl=.27168 Tbv1=485.29u) * Motorola pid=1N5235 case=DO-35 * 89-9-19 gjg * Vz = 6.8 @ 20mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model D1N5236 D(Is=2.077f Rs=2.467 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=104p M=.5061 + Vj=.75 Fc=.5 Isr=1.645n Nr=2 Bv=7.5 Ibv=2.5701 Nbv=.39227 + Ibvl=4.0222e-5 Nbvl=.25042 Tbv1=533.33u) * Motorola pid=1N5236 case=DO-35 * 89-9-18 gjg * Vz = 7.5 @ 20mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model D1N5237 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.448 + Vj=.75 Fc=.5 Isr=1.803n Nr=2 Bv=8.2 Ibv=1.5593 Nbv=.51406 + Ibvl=8.3521e-5 Nbvl=.1313 Tbv1=585.37u) * Motorola pid=1N5237 case=DO-35 * 89-9-19 gjg * Vz = 8.2 @ 20mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model D1N5238 D(Is=2.463f Rs=2.907 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=81p M=.3066 + Vj=.75 Fc=.5 Isr=2.447n Nr=2 Bv=8.7 Ibv=1.1648 Nbv=.55226 + Ibvl=16.469u Nbvl=.14431 Tbv1=586.21u) * Motorola pid=1N5238 case=DO-35 * 89-9-18 gjg * Vz = 8.7 @ 20mA, Zz = 17 @ 1mA, Zz = 7.1 @ 5mA, Zz = 2.5 @ 20mA *$ .model D1N5239 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=78p M=.4399 + Vj=.75 Fc=.5 Isr=1.762n Nr=2 Bv=9.1 Ibv=.48516 Nbv=.7022 + Ibvl=1m Nbvl=.13785 Tbv1=604.396u) * Motorola pid=1N5239 case=DO-35 * 89-9-18 gjg * Vz = 9.1 @ 20mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model D1N5240 D(Is=1.953f Rs=2.305 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3856 + Vj=.75 Fc=.5 Isr=1.939n Nr=2 Bv=10 Ibv=.16597 Nbv=.84122 + Ibvl=1.003m Nbvl=.20892 Tbv1=650u) * Motorola pid=1N5240 case=DO-35 * 89-9-18 gjg * Vz = 10 @ 20mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model D1N5241 D(Is=1.609f Rs=1.7386 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=115p M=.4751 + Vj=.75 Fc=.5 Isr=1.493n Nr=2 Bv=11 Ibv=67.039m Nbv=1.1099 + Ibvl=157.8u Nbvl=.23763 Tbv1=672.73u) * Motorola pid=1N5241 case=DO-35 * 89-9-18 gjg * Vz = 11 @ 20mA, Zz = 30.5 @ 1mA, Zz = 7.4 @ 5mA, Zz = 3.25 @ 20mA *$ .model D1N5242 D(Is=1.773f Rs=2.06 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102p M=.4868 + Vj=.75 Fc=.5 Isr=1.393n Nr=2 Bv=12 Ibv=79.489m Nbv=1.1528 + Ibvl=142.9n Nbvl=.95108 Tbv1=700u) * Motorola pid=1N5242 case=DO-35 * 89-9-18 gjg * Vz = 12 @ 20mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model D1N5243 D(Is=2.253f Rs=2.678 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.4558 + Vj=.75 Fc=.5 Isr=1.461n Nr=2 Bv=13 Ibv=21.761m Nbv=1.1851 + Ibvl=468.81n Nbvl=.65126 Tbv1=846.15u) * Motorola pid=1N5243 case=DO-35 * 89-9-18 gjg * Vz = 13 @ 9.5mA, Zz = 33.5 @ 1mA, Zz = 8 @ 5mA, Zz = 4.9 @ 20mA *$ .model D1N5244 D(Is=2.579f Rs=3.025 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=83p M=.4217 + Vj=.75 Fc=.5 Isr=1.556n Nr=2 Bv=14 Ibv=22.862m Nbv=1.1153 + Ibvl=25.632u Nbvl=.60946 Tbv1=785.71u) * Motorola pid=1N5244 case=DO-35 * 89-9-18 gjg * Vz = 14 @ 9mA, Zz = 32 @ 1mA, Zz = 8.1 @ 5mA, Zz = 5.1 @ 20mA *$ .model D1N5245 D(Is=3.142f Rs=3.536 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=80.5p M=.4186 + Vj=.75 Fc=.5 Isr=1.527n Nr=2 Bv=15 Ibv=24.573m Nbv=1.0932 + Ibvl=7.1249u Nbvl=.65646 Tbv1=833.33u) * Motorola pid=1N5245 case=DO-35 * 89-9-18 gjg * Vz = 15 @ 8.5mA, Zz = 32 @ 1mA, Zz = 8.25 @ 5mA, Zz = 5.75 @ 20mA *$ .model D1N5246 D(Is=5.461f Rs=4.975 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=69p M=.4472 + Vj=.75 Fc=.5 Isr=1.371n Nr=2 Bv=16 Ibv=32.07m Nbv=1.0589 + Ibvl=44.191u Nbvl=.86786 Tbv1=875u) * Motorola pid=1N5246 case=DO-35 * 89-9-18 gjg * Vz = 16 @ 7.8mA, Zz = 32.5 @ 1mA, Zz = 9.8 @ 5mA, Zz = 6.9 @ 20mA *$ .model D1N5247 D(Is=5.398f Rs=4.945 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=63p M=.4188 + Vj=.75 Fc=.5 Isr=1.453n Nr=2 Bv=17 Ibv=25.923m Nbv=1.1189 + Ibvl=324.66u Nbvl=.86905 Tbv1=823.53u) * Motorola pid=1N5247 case=DO-35 * 89-9-18 gjg * Vz = 17 @ 7.4mA, Zz = 34 @ 1mA, Zz = 10 @ 5mA, Zz = 7 @ 20mA *$ .model D1N5248 D(Is=7.021f Rs=5.619 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=60p M=.4093 + Vj=.75 Fc=.5 Isr=1.461n Nr=2 Bv=18 Ibv=23.333m Nbv=1.2074 + Ibvl=215.7u Nbvl=.71348 Tbv1=888.89u) * Motorola pid=1N5248 case=DO-35 * 89-9-18 gjg * Vz = 18 @ 7mA, Zz = 37 @ 1mA, Zz = 11 @ 5mA, Zz = 7.9 @ 20mA *$ .model D1N5249 D(Is=7.946f Rs=5.936 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=60p M=.4201 + Vj=.75 Fc=.5 Isr=1.384n Nr=2 Bv=19 Ibv=23.157m Nbv=1.1973 + Ibvl=302.56u Nbvl=.88158 Tbv1=894.74u) * Motorola pid=1N5249 case=DO-35 * 89-9-18 gjg * Vz = 19 @ 6.6mA, Zz = 37 @ 1mA, Zz = 11.5 @ 5mA, Zz = 8 @ 20mA *$ .model D1N5250 D(Is=10.18f Rs=6.578 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=59p M=.4063 + Vj=.75 Fc=.5 Isr=1.415n Nr=2 Bv=20 Ibv=21.603m Nbv=1.2514 + Ibvl=218.21u Nbvl=1.2514 Tbv1=850u) * Motorola pid=1N5250 case=DO-35 * 89-9-18 gjg * Vz = 20 @ 6.2mA, Zz = 39 @ 1mA, Zz = 13 @ 5mA, Zz = 8.25 @ 20mA *$ .model D1N5251 D(Is=17.49f Rs=7.976 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=50p M=.4141 + Vj=.75 Fc=.5 Isr=1.33n Nr=2 Bv=22 Ibv=20.578m Nbv=1.315 + Ibvl=207.85u Nbvl=1.315 Tbv1=840.91u) * Motorola pid=1N5251 case=DO-35 * 89-9-18 gjg * Vz = 22 @ 5.6mA, Zz = 42 @ 1mA, Zz = 15 @ 5mA, Zz = 9.5 @ 20mA *$ .model D1N5252 D(Is=25.64f Rs=8.973 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=44p M=.3798 + Vj=.75 Fc=.5 Isr=1.438n Nr=2 Bv=24 Ibv=19.386m Nbv=1.3784 + Ibvl=162.43u Nbvl=8.7919 Tbv1=895.83u) * Motorola pid=1N5252 case=DO-35 * 89-9-18 gjg * Vz = 24 @ 5.2mA, Zz = 48 @ 1mA, Zz = 16 @ 5mA, Zz = 11 @ 20mA *$ .model D1N5253 D(Is=34.8f Rs=9.761 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=43p M=.3908 + Vj=.75 Fc=.5 Isr=1.366n Nr=2 Bv=25 Ibv=16.176m Nbv=1.529 + Ibvl=687.1u Nbvl=2.256 Tbv1=880u) * Motorola pid=1N5253 case=DO-35 * 89-9-81 gjg * Vz = 25 @ 5mA, Zz = 50 @ 1mA, Zz = 19 @ 5mA, Zz = 11 @ 20mA *$ .model D1N5254 D(Is=81.47f Rs=11.96 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=42p M=.3983 + Vj=.75 Fc=.5 Isr=1.294n Nr=2 Bv=27 Ibv=87.12m Nbv=.51025 + Ibvl=9.0498m Nbvl=2.0249 Tbv1=888.89u) * Motorola pid=1N5254 case=DO-35 * 89-9-18 gjg * Vz = 27 @ 4.6mA, Zz = 52 @ 1mA, Zz = 21 @ 5mA, Zz = 12 @ 20mA *$ .model MLL746 D(Is=31.47f Rs=9.494 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=220p M=.5959 + Vj=.75 Fc=.5 Isr=2.035n Nr=2 Bv=3.3 Ibv=45.862m Nbv=3.0477 + Ibvl=29.831m Nbvl=11.606 Tbv1=-636.36u) * Motorola pid=MLL746 case=362-01 * 89-9-18 gjg * Vz = 3.3 @ 20mA, Zz = 310 @ 1mA, Zz = 68 @ 5mA, Zz = 19 @ 20mA *$ .model MLL747 D(Is=1.242f Rs=1.137 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=210p M=.6063 + Vj=.75 Fc=.5 Isr=1.922n Nr=2 Bv=3.6 Ibv=13.987m Nbv=3.031 + Ibvl=10.212m Nbvl=12.73 Tbv1=-555.56u) * Motorola pid=MLL747 case=362-01 * 89-9-18 gjg * Vz = 3.6 @ 20mA, Zz = 330 @ 1mA, Zz = 52 @ 5mA, Zz = 7.3 @ 20mA *$ .model MLL748 D(Is=1.252f Rs=1.156 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=205p M=.6004 + Vj=.75 Fc=.5 Isr=1.867n Nr=2 Bv=3.9 Ibv=17.244m Nbv=2.4016 + Ibvl=8.619m Nbvl=13.283 Tbv1=-384.62u) * Motorola pid=MLL748 case=362-01 * 89-9-18 gjg * Vz = 3.9 @ 20mA, Zz = 345 @ 1mA, Zz = 49 @ 5mA, Zz = 5.8 @ 20mA *$ .model MLL749 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=190p M=.6124 + Vj=.75 Fc=.5 Isr=1.743n Nr=2 Bv=4.3 Ibv=16.748m Nbv=1.7936 + Ibvl=5.0382m Nbvl=12.554 Tbv1=-232.56u) * Motorola pid=MLL749 case=362-01 * 89-9-18 gjg * Vz = 4.3 @ 20mA, Zz = 325 @ 1mA, Zz = 24 @ 5mA, Zz = 3.2 @ 20mA *$ .model MLL750 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=175p M=.5516 + Vj=.75 Fc=.5 Isr=1.859n Nr=2 Bv=4.7 Ibv=20.245m Nbv=1.6989 + Ibvl=1.9556m Nbvl=14.976 Tbv1=-21.277u) * Motorola pid=MLL750 case=362-01 * 89-9-18 gjg * Vz = 4.7 @ 20mA, Zz = 300 @ 1mA, Zz = 12.5 @ 5mA, Zz =2.6 @ 20mA *$ .model MLL751 D(Is=1.004f Rs=.5875 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=160p M=.5484 + Vj=.75 Fc=.5 Isr=1.8n Nr=2 Bv=5.1 Ibv=27.721m Nbv=1.1779 + Ibvl=1.1646m Nbvl=21.894 Tbv1=176.47u) * Motorola pid=MLL751 case=362-01 * 89-9-18-gjg * Vz = 5.1 @ 20mA, Zz = 175 @ 1mA, Zz = 8.2 @ 5mA, Zz = 2.2 @ 20mA *$ .model MLL752 D(Is=1.154f Rs=.9471 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=150p M=.5788 + Vj=.75 Fc=.5 Isr=1.625n Nr=2 Bv=5.6 Ibv=62.583m Nbv=.62382 + Ibvl=631.96u Nbvl=50 Tbv1=267.86u) * Motorola pid=MLL752 case=362-01 * 89-9-18 gjg * Vz = 5.6 @ 20mA, Zz = 40 @ 1mA, Zz = 4.5 @ 5mA, Zz = 1.9 @ 20mA *$ .model MLL753 D(Is=1.536f Rs=1.687 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=130p M=.5259 + Vj=.75 Fc=.5 Isr=1.719n Nr=2 Bv=6.2 Ibv=1.9685 Nbv=.28384 + Ibvl=7.0094e-7 Nbvl=.29418 Tbv1=443.55u) * Motorola pid=MLL753 case=362-01 * 89-9-18 gjg * Vz = 6.2 @ 20mA, Zz = 9 @ 1mA, Zz = 3.4 @ 5mA, Zz = 1.85 @ 20mA *$ .model MLL754 D(Is=1.616f Rs=1.818 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120p M=.5117 + Vj=.75 Fc=.5 Isr=1.698n Nr=2 Bv=6.8 Ibv=2.8814 Nbv=.28248 + Ibvl=1.9426e-6 Nbvl=.27168 Tbv1=485.29u) * Motorola pid=MLL754 case=362-01 * 89-9-19 gjg * Vz = 6.8 @ 20mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model MLL755 D(Is=2.077f Rs=2.467 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=104p M=.5061 + Vj=.75 Fc=.5 Isr=1.645n Nr=2 Bv=7.5 Ibv=2.5701 Nbv=.39227 + Ibvl=4.0222e-5 Nbvl=.25042 Tbv1=533.33u) * Motorola pid=MLL755 case=362-01 * 89-9-18 gjg * Vz = 7.5 @ 20mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model MLL756 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.448 + Vj=.75 Fc=.5 Isr=1.803n Nr=2 Bv=8.2 Ibv=1.5593 Nbv=.51406 + Ibvl=8.3521e-5 Nbvl=.1313 Tbv1=585.37u) * Motorola pid=MLL756 case=362-01 * 89-9-19 gjg * Vz = 8.2 @ 20mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model MLL757 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=78p M=.4399 + Vj=.75 Fc=.5 Isr=1.762n Nr=2 Bv=9.1 Ibv=.48516 Nbv=.7022 + Ibvl=1m Nbvl=.13785 Tbv1=604.396u) * Motorola pid=MLL757 case=362-01 * 89-9-18 gjg * Vz = 9.1 @ 20mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model MLL758 D(Is=1.953f Rs=2.305 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3856 + Vj=.75 Fc=.5 Isr=1.939n Nr=2 Bv=10 Ibv=.16597 Nbv=.84122 + Ibvl=1.003m Nbvl=.20892 Tbv1=650u) * Motorola pid=MLL758 case=362-01 * 89-9-18 gjg * Vz = 10 @ 20mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model MLL759 D(Is=1.773f Rs=2.06 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102p M=.4868 + Vj=.75 Fc=.5 Isr=1.393n Nr=2 Bv=12 Ibv=79.489m Nbv=1.1528 + Ibvl=142.9n Nbvl=.95108 Tbv1=700u) * Motorola pid=MLL759 case=362-01 * 89-9-18 gjg * Vz = 12 @ 20mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model MLL957A D(Is=1.616f Rs=1.82 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120p M=.5117 + Vj=.75 Fc=.5 Isr=1.698n Nr=2 Bv=6.8 Ibv=1.8441 Nbv=.28243 + Ibvl=6.2172E-15 Nbvl=.50147 Tbv1=485.29u) * Motorola pid=MLL957A case=362-01 * 89-9-18 gjg * Vz = 6.8 @ 18.5mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model MLL958A D(Is=2.077f Rs=2.467 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=104p M=.5061 + Vj=.75 Fc=.5 Isr=1.645n Nr=2 Bv=7.5 Ibv=.90645 Nbv=.39227 + Ibvl=.5849p Nbvl=1.5122 Tbv1=533.33u) * Motorola pid=MLL958A case=362-01 * 89-9-18 gjg * Vz = 7.5 @ 16.5mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model MLL959A D(Is=2.491f Rs=2.938 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.448 + Vj=.75 Fc=.5 Isr=1.803n Nr=2 Bv=8.2 Ibv=.41558 Nbv=.51229 + Ibvl=.65179p Nbvl=1.1568 Tbv1=585.37u) * Motorola pid=MLL959A case=362-01 * 89-9-18 gjg * Vz = 8.2 @ 15mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model MLL960A D(Is=2.168f Rs=2.578 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=78p M=.4399 + Vj=.75 Fc=.5 Isr=1.762n Nr=2 Bv=9.1 Ibv=97.714m Nbv=.71712 + Ibvl=.58975p Nbvl=.98128 Tbv1=604.396u) * Motorola pid=MLL960A case=362-01 * 89-9-18 gjg * Vz = 9.1 @ 14mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model MLL961A D(Is=1.953f Rs=2.305 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3856 + Vj=.75 Fc=.5 Isr=1.939n Nr=2 Bv=10 Ibv=46.912m Nbv=.84122 + Ibvl=626.74p Nbvl=.78605 Tbv1=650u) * Motorola pid=MLL961A case=362-01 * 89-9-18 gjg * Vz = 10 @ 12.5mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model MLL962A D(Is=1.609f Rs=1.813 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=115p M=.4751 + Vj=.75 Fc=.5 Isr=1.493n Nr=2 Bv=11 Ibv=24.084m Nbv=1.1052 + Ibvl=149.27n Nbvl=.22862 Tbv1=672.73u) * Motorola pid=MLL962A case=362-01 * 89-9-18 gjg * Vz = 11 @ 11.5mA, Zz = 30.5 @ 1mA, Zz = 7.4 @ 5mA, Zz = 3.25 @ 20mA *$ .model MLL963A D(Is=1.773f Rs=2.061 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102p M=.4868 + Vj=.75 Fc=.5 Isr=1.393n Nr=2 Bv=12 Ibv=21.7m Nbv=1.1527 + Ibvl=29.343n Nbvl=.245 Tbv1=700u) * Motorola pid=MLL963A case=362-01 * 89-9-18 gjg * Vz = 12 @ 10.5mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model MLL964A D(Is=2.253f Rs=2.678 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.4558 + Vj=.75 Fc=.5 Isr=1.461n Nr=2 Bv=13 Ibv=21.761m Nbv=1.1851 + Ibvl=468.81n Nbvl=.65126 Tbv1=008461.5u) * Motorola pid=MLL964A case=362-01 * 89-9-18 gjg * Vz = 13 @ 9.5mA, Zz = 33.5 @ 1mA, Zz = 8 @ 5mA, Zz = 4.9 @ 20mA *$ .model MLL965A D(Is=3.142f Rs=3.536 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=80.5p M=.4186 + Vj=.75 Fc=.5 Isr=1.527n Nr=2 Bv=15 Ibv=24.573m Nbv=1.0932 + Ibvl=7.1249u Nbvl=.65646 Tbv1=833.33u) * Motorola pid=MLL965A case=362-01 * 89-9-18 gjg * Vz = 15 @ 8.5mA, Zz = 32 @ 1mA, Zz = 8.25 @ 5mA, Zz = 5.75 @ 20mA *$ .model MLL966A D(Is=5.461f Rs=4.975 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=69p M=.4472 + Vj=.75 Fc=.5 Isr=1.371n Nr=2 Bv=16 Ibv=32.07m Nbv=1.0589 + Ibvl=44.191u Nbvl=.86786 Tbv1=875u) * Motorola pid=MLL966A case=362-01 * 89-9-18 gjg * Vz = 16 @ 7.8mA, Zz = 32.5 @ 1mA, Zz = 9.8 @ 5mA, Zz = 6.9 @ 20mA *$ .model MLL967A D(Is=7.021f Rs=5.619 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=60p M=.4093 + Vj=.75 Fc=.5 Isr=1.461n Nr=2 Bv=18 Ibv=23.333m Nbv=1.2074 + Ibvl=215.7u Nbvl=.71348 Tbv1=888.89u) * Motorola pid=MLL967A case=362-01 * 89-9-18 gjg * Vz = 18 @ 7mA, Zz = 37 @ 1mA, Zz = 11 @ 5mA, Zz = 7.9 @ 20mA *$ .model MLL968A D(Is=10.18f Rs=6.578 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=59p M=.4063 + Vj=.75 Fc=.5 Isr=1.415n Nr=2 Bv=20 Ibv=21.603m Nbv=1.2514 + Ibvl=218.21u Nbvl=1.2514 Tbv1=850u) * Motorola pid=MLL968A case=362-01 * 89-9-18 gjg * Vz = 20 @ 6.2mA, Zz = 39 @ 1mA, Zz = 13 @ 5mA, Zz = 8.25 @ 20mA *$ .model MLL969A D(Is=17.49f Rs=7.976 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=50p M=.4141 + Vj=.75 Fc=.5 Isr=1.33n Nr=2 Bv=22 Ibv=20.578m Nbv=1.315 + Ibvl=207.85u Nbvl=1.315 Tbv1=840.91u) * Motorola pid=MLL969A case=362-01 * 89-9-18 gjg * Vz = 22 @ 5.6mA, Zz = 42 @ 1mA, Zz = 15 @ 5mA, Zz = 9.5 @ 20mA *$ .model MLL970A D(Is=25.64f Rs=8.973 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=44p M=.3798 + Vj=.75 Fc=.5 Isr=1.438n Nr=2 Bv=24 Ibv=19.386m Nbv=1.3784 + Ibvl=162.43u Nbvl=8.7919 Tbv1=895.83u) * Motorola pid=MLL970A case=362-01 * 89-9-18 gjg * Vz = 24 @ 5.2mA, Zz = 48 @ 1mA, Zz = 16 @ 5mA, Zz = 11 @ 20mA *$ .model MLL971A D(Is=81.47f Rs=11.96 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=42p M=.3983 + Vj=.75 Fc=.5 Isr=1.294n Nr=2 Bv=27 Ibv=87.12m Nbv=.51025 + Ibvl=9.0498m Nbvl=2.0249 Tbv1=888.89u) * Motorola pid=MLL971A case=362-01 * 89-9-18 gjg * Vz = 27 @ 4.6mA, Zz = 52 @ 1mA, Zz = 21 @ 5mA, Zz = 12 @ 20mA *$ .model MLL4728 D(Is=11.11f Rs=6.808 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=220p M=.5959 + Vj=.75 Fc=.5 Isr=241.3p Nr=2 Bv=3.3 Ibv=5.8452 Nbv=3.6742 + Ibvl=.27224 Nbvl=11.715 Tbv1=-636.36u) * Motorola pid=MLL4728 case=362B-01 * 89-9-18 gjg * Vz = 3.3 @ 76mA, Zz = 310 @ 1mA, Zz = 68 @ 5mA, Zz = 19 @ 20mA *$ .model MLL4729 D(Is=2.306f Rs=2.741 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=210p M=.6063 + Vj=.75 Fc=.5 Isr=239.2p Nr=2 Bv=3.6 Ibv=1.1936 Nbv=2.2747 + Ibvl=19.94m Nbvl=12.64 Tbv1=-555.556u) * Motorola pid=MLL4729 case=362B-01 * 89-9-18 gjg * Vz = 3.6 @ 69mA, Zz = 330 @ 1mA, Zz = 52 @ 5mA, Zz = 7.3 @ 20mA *$ .model MLL4730 D(Is=1.379f Rs=1.406 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=205p M=.6004 + Vj=.75 Fc=.5 Isr=240.4p Nr=2 Bv=3.9 Ibv=.2473 Nbv=2.2758 + Ibvl=13.346m Nbvl=13.271 Tbv1=-384.62u) * Motorola pid=MLL4730 case=362B-01 * 89-9-18 gjg * Vz = 3.9 @ 64mA, Zz = 345 @ 1mA, Zz = 49 @ 5mA, Zz = 5.8 @ 20mA *$ .model MLL4731 D(Is=837.3E-18 Rs=.1211 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=190p + M=.6124 Vj=.75 Fc=.5 Isr=238p Nr=2 Bv=4.3 Ibv=60.167m Nbv=1.8815 + Ibvl=6.0358m Nbvl=12.57 Tbv1=-232.56u) * Motorola pid=MLL4731 case=362B-01 * 89-9-18 gjg * Vz = 4.3 @ 58mA, Zz = 325 @ 1mA, Zz = 24 @ 5mA, Zz = 3.2 @ 20mA *$ .model MLL4732 D(Is=1.064f Rs=.741 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=175p M=.5516 + Vj=.75 Fc=.5 Isr=250.6p Nr=2 Bv=4.7 Ibv=.16902 Nbv=1.2344 + Ibvl=4.0082m Nbvl=11.59 Tbv1=-21.28u) * Motorola pid=MLL4732 case=362B-01 * 89-9-18 gjg * Vz = 4.7 @ 53mA, Zz = 300 @ 1mA, Zz = 12.5 @ 5mA, Zz =2.6 @ 20mA *$ .model MLL4733 D(Is=1.214f Rs=1.078 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=160p M=.5484 + Vj=.75 Fc=.5 Isr=251.3p Nr=2 Bv=5.1 Ibv=.70507 Nbv=.74348 + Ibvl=4.8274m Nbvl=6.7393 Tbv1=176.47u) * Motorola pid=MLL4733 case=362B-01 * 89-9-18 gjg * Vz = 5.1 @ 49mA, Zz = 175 @ 1mA, Zz = 8.2 @ 5mA, Zz = 2.2 @ 20mA *$ .model MLL4734 D(Is=1.085f Rs=.7945 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=150p M=.5788 + Vj=.75 Fc=.5 Isr=188.6p Nr=2 Bv=5.6 Ibv=.37157 Nbv=.64726 + Ibvl=1m Nbvl=6.5761 Tbv1=267.86u) * Motorola pid=MLL4734 case=362B-01 * 89-9-18 gjg * Vz = 5.6 @ 45mA, Zz = 40 @ 1mA, Zz = 4.5 @ 5mA, Zz = 1.9 @ 20mA *$ .model MLL4735 D(Is=1.168f Rs=.9756 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=130p M=.5259 + Vj=.75 Fc=.5 Isr=171.6p Nr=2 Bv=6.2 Ibv=4.9984 Nbv=.32088 + Ibvl=184.78u Nbvl=.19558 Tbv1=443.55u) * Motorola pid=MLL4735 case=362B-01 * 89-9-18 gjg * Vz = 6.2 @ 41mA, Zz = 9 @ 1mA, Zz = 3.4 @ 5mA, Zz = 1.85 @ 20mA *$ .model MLL4736 D(Is=1.327f Rs=1.306 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120p M=.5117 + Vj=.75 Fc=.5 Isr=155.5p Nr=2 Bv=6.8 Ibv=15 Nbv=.31009 + Ibvl=149.2u Nbvl=.31028 Tbv1=485.29u) * Motorola pid=MLL4736 case=362B-01 * 89-9-18 gjg * Vz = 6.8 @ 37mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model MLL4737 D(Is=1.699f Rs=1.955 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=104p M=.5061 + Vj=.75 Fc=.5 Isr=142.7p Nr=2 Bv=7.5 Ibv=15 Nbv=.42018 + Ibvl=1m Nbvl=.094527 Tbv1=533.33u) * Motorola pid=MLL4737 case=362B-01 * 89-9-18 gjg * Vz = 7.5 @ 34mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model MLL4738 D(Is=2.102f Rs=2.5 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.448 + Vj=.75 Fc=.5 Isr=149.5p Nr=2 Bv=8.2 Ibv=8 Nbv=.53621 + Ibvl=213.52u Nbvl=.17879 Tbv1=585.37u) * Motorola pid=MLL4738 case=362B-01 * 89-9-18 gjg * Vz = 8.2 @ 31mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model MLL4739 D(Is=2.11f Rs=2.512 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=78p M=.4399 + Vj=.75 Fc=.5 Isr=143.2p Nr=2 Bv=9.1 Ibv=1.2 Nbv=.72056 + Ibvl=10m Nbvl=.21148 Tbv1=604.396u) * Motorola pid=MLL4739 case=362B-01 * 89-9-18 gjg * Vz = 9.1 @ 28mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model MLL4740 D(Is=1.945f Rs=2.302 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3856 + Vj=.75 Fc=.5 Isr=157.9p Nr=2 Bv=10 Ibv=.35034 Nbv=.84137 + Ibvl=10m Nbvl=.17757 Tbv1=650u) * Motorola pid=MLL4740 case=362B-01 * 89-9-18 gjg * Vz = 10 @ 25mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model MLL4741 D(Is=1.566f Rs=1.74 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=115p M=.4751 + Vj=.75 Fc=.5 Isr=121.9p Nr=2 Bv=11 Ibv=92.573m Nbv=1.1098 + Ibvl=440.66u Nbvl=.23096 Tbv1=672.73u) * Motorola pid=MLL4741 case=362B-01 * 89-9-18 gjg * Vz = 11 @ 23mA, Zz = 30.5 @ 1mA, Zz = 7.4 @ 5mA, Zz = 3.25 @ 20mA *$ .model MLL4742 D(Is=1.773f Rs=2.06 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102p M=.4868 + Vj=.75 Fc=.5 Isr=114.2p Nr=2 Bv=12 Ibv=89.447m Nbv=1.1527 + Ibvl=248.34n Nbvl=.8248 Tbv1=700u) * Motorola pid=MLL4742 case=362B-01 * 89-9-18 gjg * Vz = 12 @ 21mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model MLL4743 D(Is=2.253f Rs=2.678 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.4558 + Vj=.75 Fc=.5 Isr=119.4p Nr=2 Bv=13 Ibv=99.671m Nbv=1.1851 + Ibvl=8.4078u Nbvl=1.2407 Tbv1=846.15u) * Motorola pid=MLL4743 case=362B-01 * 89-9-18 gjg * Vz = 13 @ 19mA, Zz = 33.5 @ 1mA, Zz = 8 @ 5mA, Zz = 4.9 @ 20mA *$ .model MLL4744 D(Is=3.142f Rs=3.544 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=80.5p M=.4961 + Vj=.75 Fc=.5 Isr=100.5p Nr=2 Bv=15 Ibv=.14467 Nbv=1.093 + Ibvl=.1m Nbvl=1.2722 Tbv1=833.33u) * Motorola pid=MLL4744 case=362B-01 * 89-9-18 gjg * Vz = 15 @ 17mA, Zz = 32 @ 1mA, Zz = 8.25 @ 5mA, Zz = 5.75 @ 20mA *$ .model MLL4745 D(Is=5.461f Rs=4.974 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=69p M=.4472 + Vj=.75 Fc=.5 Isr=111.9p Nr=2 Bv=16 Ibv=.25684 Nbv=1.0588 + Ibvl=1.029m Nbvl=1.0409 Tbv1=875u) * Motorola pid=MLL4745 case=362B-01 * 89-9-18 gjg * Vz = 16 @ 15.5mA, Zz = 32.5 @ 1mA, Zz = 9.8 @ 5mA, Zz = 6.9 @ 20mA *$ .model MLL4746 D(Is=6.994f Rs=5.612 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=60p M=.4093 + Vj=.75 Fc=.5 Isr=119.2p Nr=2 Bv=18 Ibv=.17098 Nbv=1.2072 + Ibvl=2.002m Nbvl=1.1457 Tbv1=888.89u) * Motorola pid=MLL4746 case=362B-01 * 89-9-18 gjg * Vz = 18 @ 14mA, Zz = 37 @ 1mA, Zz = 11 @ 5mA, Zz = 7.9 @ 20mA *$ .model MLL4747 D(Is=10.22f Rs=6.585 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=59p M=.4063 + Vj=.75 Fc=.5 Isr=115.5p Nr=2 Bv=20 Ibv=.15934 Nbv=1.2472 + Ibvl=211.18u Nbvl=1.9765 Tbv1=850u) * Motorola pid=MLL4747 case=362B-01 * 89-9-18 gjg * Vz = 20 @ 12.5mA, Zz = 39 @ 1mA, Zz = 13 @ 5mA, Zz = 8.25 @ 20mA *$ .model MLL4748 D(Is=17.49f Rs=7.976 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=52p M=.4284 + Vj=.75 Fc=.5 Isr=103.9p Nr=2 Bv=22 Ibv=.16996 Nbv=1.315 + Ibvl=7.0073E-15 Nbvl=1.2735 Tbv1=840.91u) * Motorola pid=MLL4748 case=362B-01 * 89-9-18 gjg * Vz = 22 @ 11.5mA, Zz = 42 @ 1mA, Zz = 15 @ 5mA, Zz = 9.5 @ 20mA *$ .model MLL4749 D(Is=25.94f Rs=9.006 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=44p M=.3798 + Vj=.75 Fc=.5 Isr=123.2p Nr=2 Bv=24 Ibv=.14951 Nbv=1.3684 + Ibvl=164.37u Nbvl=14 Tbv1=895.84u) * Motorola pid=MLL4749 case=362B-01 * 89-9-19 gjg * Vz = 24 @ 10.5mA, Zz = 48 @ 1mA, Zz = 16 @ 5mA, Zz = 11 @ 20mA *$ .model MLL4750 D(Is=62.63f Rs=11.28 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=42p M=.3983 + Vj=.75 Fc=.5 Isr=110.6p Nr=2 Bv=27 Ibv=.13378 Nbv=1.52832 + Ibvl=3.4328m Nbvl=2.3046 Tbv1=888.89u) * Motorola pid=MLL4750 case=362B-01 * 89-9-18 gjg * Vz = 27 @ 9.5mA, Zz = 52 @ 1mA, Zz = 21 @ 5mA, Zz = 12 @ 20mA *$ .model MLL5226 D(Is=31.35f Rs=9.494 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=220p M=.5959 + Vj=.75 Fc=.5 Isr=241.3p Nr=2 Bv=3.3 Ibv=45.862m Nbv=3.0477 + Ibvl=29.831m Nbvl=11.606 Tbv1=-636.36u) * Motorola pid=MLL5226 case=362-01 * 89-9-18 gjg * Vz = 3.3 @ 20mA, Zz = 310 @ 1mA, Zz = 68 @ 5mA, Zz = 19 @ 20mA *$ .model MLL5227 D(Is=1.242f Rs=1.137 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=210p M=.6063 + Vj=.75 Fc=.5 Isr=239.2p Nr=2 Bv=3.6 Ibv=13.987m Nbv=3.031 + Ibvl=10.212m Nbvl=12.73 Tbv1=-555.56u) * Motorola pid=MLL5227 case=362-01 * 89-9-18 gjg * Vz = 3.6 @ 20mA, Zz = 330 @ 1mA, Zz = 52 @ 5mA, Zz = 7.3 @ 20mA *$ .model MLL5228 D(Is=1.252f Rs=1.156 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=205p M=.7147 + Vj=.75 Fc=.5 Isr=218.2p Nr=2 Bv=3.9 Ibv=17.244m Nbv=2.4016 + Ibvl=8.619m Nbvl=13.283 Tbv1=-384.62u) * Motorola pid=MLL5228 case=362-01 * 89-9-18 gjg * Vz = 3.9 @ 20mA, Zz = 345 @ 1mA, Zz = 49 @ 5mA, Zz = 5.8 @ 20mA *$ .model MLL5229 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=190p M=.6124 + Vj=.75 Fc=.5 Isr=238p Nr=2 Bv=4.3 Ibv=16.748m Nbv=1.7936 + Ibvl=5.0382m Nbvl=12.554 Tbv1=-232.56u) * Motorola pid=MLL5229 case=362-01 * 89-9-18 gjg * Vz = 4.3 @ 20mA, Zz = 325 @ 1mA, Zz = 24 @ 5mA, Zz = 3.2 @ 20mA *$ .model MLL5230 D(Is=880.5E-18 Rs=.25 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=175p M=.5516 + Vj=.75 Fc=.5 Isr=195.3p Nr=2 Bv=4.7 Ibv=20.245m Nbv=1.6989 + Ibvl=1.9556m Nbvl=14.796 Tbv1=-21.277u) * Motorola pid=MLL5230 case=362-01 * 89-9-81 gjg * Vz = 4.7 @ 20mA, Zz = 300 @ 1mA, Zz = 12.5 @ 5mA, Zz =2.6 @ 20mA *$ .model MLL5231 D(Is=1.004f Rs=.5875 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=160p M=.5484 + Vj=.75 Fc=.5 Isr=196.1p Nr=2 Bv=5.1 Ibv=27.721m Nbv=1.1779 + Ibvl=1.1646m Nbvl=21.894 Tbv1=176.47u) * Motorola pid=MLL5231 case=362-01 * 89-9-18 gjg * Vz = 5.1 @ 20mA, Zz = 175 @ 1mA, Zz = 8.2 @ 5mA, Zz = 2.2 @ 20mA *$ .model MLL5232 D(Is=1.154f Rs=.9471 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=150p M=.5788 + Vj=.75 Fc=.5 Isr=160.1p Nr=2 Bv=5.6 Ibv=1.062583 Nbv=.62382 + Ibvl=631.96u Nbvl=50 Tbv1=267.86u) * Motorola pid=MLL5232 case=362-01 * 89-9-18 gjg * Vz = 5.6 @ 20mA, Zz = 40 @ 1mA, Zz = 4.5 @ 5mA, Zz = 1.9 @ 20mA *$ .model MLL5233 D(Is=629E-18 Rs=1.176 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=140p M=.5369 + Vj=.75 Fc=.5 Isr=168.6p Nr=2 Bv=6 Ibv=.10969 Nbv=.5351 + Ibvl=.11553 Nbvl=.049362 Tbv1=416.67u) * Motorola pid=MLL5233 case=362-01 * 89-9-18 gjg * Vz = 6 @ 20mA, Zz = 15 @ 1mA, Zz = 3.9 @ 5mA, Zz = 1.9 @ 20mA *$ .model MLL5234 D(Is=1.536f Rs=1.687 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=130p M=.5259 + Vj=.75 Fc=.5 Isr=151.5p Nr=2 Bv=6.2 Ibv=1.9685 Nbv=.28384 + Ibvl=700.94n Nbvl=.29418 Tbv1=443.56u) * Motorola pid=MLL5234 case=362-01 * 89-9-18 gjg * Vz = 6.2 @ 20mA, Zz = 9 @ 1mA, Zz = 3.4 @ 5mA, Zz = 1.85 @ 20mA *$ .model MLL5235 D(Is=1.616f Rs=1.818 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=120p M=.5117 + Vj=.75 Fc=.5 Isr=141p Nr=2 Bv=6.8 Ibv=2.8814 Nbv=.28248 + Ibvl=1.9426u Nbvl=.27168 Tbv1=485.29u) * Motorola pid=MLL5235 case=362-01 * 89-9-18 gjg * Vz = 6.8 @ 20mA, Zz = 9.1 @ 1mA, Zz = 3.5 @ 5mA, Zz = 2 @ 20mA *$ .model MLL5236 D(Is=2.077f Rs=2.467 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=104p M=.5061 + Vj=.75 Fc=.5 Isr=131.6p Nr=2 Bv=7.5 Ibv=2.5701 Nbv=.39227 + Ibvl=40.222u Nbvl=.25042 Tbv1=533.33u) * Motorola pid=MLL5236 case=362-01 * 89-9-18 gjg * Vz = 7.5 @ 20mA, Zz = 12.5 @ 1mA, Zz = 5.3 @ 5mA, Zz = 2.3 @ 20mA *$ .model MLL5237 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.448 + Vj=.75 Fc=.5 Isr=144.8p Nr=2 Bv=8.2 Ibv=1.5593 Nbv=.51406 + Ibvl=83.521u Nbvl=.1313 Tbv1=585.37u) * Motorla pid=MLL5237 case=362-01 * 89-9-18 gjg * Vz = 8.2 @ 20mA, Zz = 16 @ 1mA, Zz = 6.9 @ 5mA, Zz = 2.5 @ 20mA *$ .model MLL5238 D(Is=2.463f Rs=2.907 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=81p M=.3066 + Vj=.75 Fc=.5 Isr=199.5p Nr=2 Bv=8.7 Ibv=1.1648 Nbv=.55226 + Ibvl=16.469u Nbvl=.14431 Tbv1=586.21u) * Motorola pid=MLL5238 case=362-01 * 89-9-18 gjg * Vz = 8.7 @ 20mA, Zz = 17 @ 1mA, Zz = 7.1 @ 5mA, Zz = 2.5 @ 20mA *$ .model MLL5239 D(Is=2.453f Rs=2.9 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=78p M=.4399 + Vj=.75 Fc=.5 Isr=143.2p Nr=2 Bv=9.1 Ibv=.48516 Nbv=.7022 + Ibvl=1m Nbvl=.13785 Tbv1=604.396u) * Motorola pid=MLL5239 case=362-01 * 89-9-18 gjg * Vz = 9.1 @ 20mA, Zz = 21 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.7 @ 20mA *$ .model MLL5240 D(Is=1.953f Rs=2.305 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=68p M=.3856 + Vj=.75 Fc=.5 Isr=155.1p Nr=2 Bv=10 Ibv=.16597 Nbv=.84122 + Ibvl=1.003m Nbvl=.20892 Tbv1=650u) * Motorola pid=MLL5240 case=362-01 * 89-9-18 gjg * Vz = 10 @ 20mA, Zz = 24 @ 1mA, Zz = 7.25 @ 5mA, Zz = 2.9 @ 20mA *$ .model MLL5241 D(Is=1.609f Rs=1.739 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=115p M=.4751 + Vj=.75 Fc=.5 Isr=121.9p Nr=2 Bv=11 Ibv=67.039m Nbv=1.1099 + Ibvl=157.8u Nbvl=.23763 Tbv1=672.73u) * Motorola pid=MLL5241 case=362-01 * 89-9-18 gjg * Vz = 11 @ 20mA, Zz = 30.5 @ 1mA, Zz = 7.4 @ 5mA, Zz = 3.25 @ 20mA *$ .model MLL5242 D(Is=1.773f Rs=2.06 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=102p M=.5136 + Vj=.75 Fc=.5 Isr=106.6p Nr=2 Bv=12 Ibv=79.489m Nbv=1.1528 + Ibvl=142.9n Nbvl=.95108 Tbv1=700u) * Motorola pid=MLL5242 case=362-01 * 89-9-18 gjg * Vz = 12 @ 20mA, Zz = 32 @ 1mA, Zz = 7.5 @ 5mA, Zz = 4 @ 20mA *$ .model MLL5243 D(Is=2.253f Rs=2.678 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=90p M=.4558 + Vj=.75 Fc=.5 Isr=119.4p Nr=2 Bv=13 Ibv=21.761m Nbv=1.1851 + Ibvl=468.81n Nbvl=.65126 Tbv1=846.15u) * Motorola pid=MLL5243 case=362-01 * 89-9-18 gjg * Vz = 13 @ 9.5mA, Zz = 33.5 @ 1mA, Zz = 8 @ 5mA, Zz = 4.9 @ 20mA *$ .model MLL5244 D(Is=2.579f Rs=3.025 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=83p M=.4217 + Vj=.75 Fc=.5 Isr=130.1p Nr=2 Bv=14 Ibv=22.862m Nbv=1.1153 + Ibvl=25.632u Nbvl=.60946 Tbv1=785.71u) * Motorola pid=MLL5244 case=362-01 * 89-9-18 gjg * Vz = 14 @ 9mA, Zz = 32 @ 1mA, Zz = 8.1 @ 5mA, Zz = 5.1 @ 20mA *$ .model MLL5245 D(Is=3.142f Rs=3.536 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=80.5p M=.4961 + Vj=.75 Fc=.5 Isr=102.1p Nr=2 Bv=15 Ibv=24.573m Nbv=1.0932 + Ibvl=7.1249u Nbvl=.65646 Tbv1=833.33u) * Motorola pid=MLL5245 case=362-01 * 89-9-18 gjg * Vz = 15 @ 8.5mA, Zz = 32 @ 1mA, Zz = 8.25 @ 5mA, Zz = 5.75 @ 20mA *$ .model MLL5246 D(Is=5.461f Rs=4.975 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=64p M=.4166 + Vj=.75 Fc=.5 Isr=122.9p Nr=2 Bv=16 Ibv=32.07m Nbv=1.0589 + Ibvl=44.191u Nbvl=.86786 Tbv1=875u) * Motorola pid=MLL5246 case=362-01 * 89-9-18 gjg * Vz = 16 @ 7.8mA, Zz = 32.5 @ 1mA, Zz = 9.8 @ 5mA, Zz = 6.9 @ 20mA *$ .model MLL5247 D(Is=5.398f Rs=4.945 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=63p M=.4188 + Vj=.75 Fc=.5 Isr=118.3p Nr=2 Bv=17 Ibv=25.923m Nbv=1.1189 + Ibvl=324.66u Nbvl=.86905 Tbv1=823.53u) * Motorola pid=MLL5247 case=362-01 * 89-9-18 gjg * Vz = 17 @ 7.4mA, Zz = 34 @ 1mA, Zz = 10 @ 5mA, Zz = 7 @ 20mA *$ .model MLL5248 D(Is=7.021f Rs=5.619 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=60p M=.4093 + Vj=.75 Fc=.5 Isr=118.2p Nr=2 Bv=18 Ibv=23.333m Nbv=1.2074 + Ibvl=215.7u Nbvl=.71348 Tbv1=888.89u) * Motorola pid=MLL5248 case=362-01 * 89-9-18 gjg * Vz = 18 @ 7mA, Zz = 37 @ 1mA, Zz = 11 @ 5mA, Zz = 7.9 @ 20mA *$ .model MLL5249 D(Is=7.946f Rs=5.936 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=60p M=.4201 + Vj=.75 Fc=.5 Isr=114.4p Nr=2 Bv=19 Ibv=23.157m Nbv=1.1973 + Ibvl=302.56u Nbvl=.88158 Tbv1=894.74u) * Motorola pid=MLL5249 case=362-01 * 89-9-18 gjg * Vz = 19 @ 6.6mA, Zz = 37 @ 1mA, Zz = 11.5 @ 5mA, Zz = 8 @ 20mA *$ .model MLL5250 D(Is=10.18f Rs=6.578 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=59p M=.4063 + Vj=.75 Fc=.5 Isr=116.1p Nr=2 Bv=20 Ibv=21.603m Nbv=1.2514 + Ibvl=218.21u Nbvl=1.2514 Tbv1=850u) * Motorola pid=MLL5250 case=362-01 * 89-9-18 gjg * Vz = 20 @ 6.2mA, Zz = 39 @ 1mA, Zz = 13 @ 5mA, Zz = 8.25 @ 20mA *$ .model MLL5251 D(Is=17.49f Rs=7.976 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=50p M=.4141 + Vj=.75 Fc=.5 Isr=107.9p Nr=2 Bv=22 Ibv=20.578m Nbv=1.315 + Ibvl=207.85u Nbvl=1.315 Tbv1=840.91u) * Motorola pid=MLL5251 case=362-01 * 89-9-18 gjg * Vz = 22 @ 5.6mA, Zz = 42 @ 1mA, Zz = 15 @ 5mA, Zz = 9.5 @ 20mA *$ .model MLL5252 D(Is=25.64f Rs=8.973 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=44p M=.3798 + Vj=.75 Fc=.5 Isr=117.8p Nr=2 Bv=24 Ibv=19.386m Nbv=1.3784 + Ibvl=162.43u Nbvl=8.7919 Tbv1=895.83u) * Motorola pid=MLL5252 case=362-01 * 89-9-18 gjg * Vz = 24 @ 5.2mA, Zz = 48 @ 1mA, Zz = 16 @ 5mA, Zz = 11 @ 20mA *$ .model MLL5253 D(Is=34.8f Rs=9.761 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=43p M=.3908 + Vj=.75 Fc=.5 Isr=111.4p Nr=2 Bv=25 Ibv=16.176m Nbv=1.529 + Ibvl=687.1u Nbvl=2.256 Tbv1=880u) * Motorola pid=MLL5253 case=362-01 * 89-9-18 gjg * Vz = 25 @ 5mA, Zz = 50 @ 1mA, Zz = 19 @ 5mA, Zz = 11 @ 20mA *$ .model MLL5254 D(Is=81.47f Rs=11.96 Ikf=0 N=1 Xti=3 Eg=1.11 Cjo=42p M=.3983 + Vj=.75 Fc=.5 Isr=104.6p Nr=2 Bv=27 Ibv=87.12m Nbv=.51025 + Ibvl=9.0498m Nbvl=2.0249 Tbv1=888.89u) * Motorola pid=MLL5254 case=362-01 * 89-9-81 gjg * Vz = 27 @ 4.6mA, Zz = 52 @ 1mA, Zz = 21 @ 5mA, Zz = 12 @ 20mA *$ * * * * RAD: PRE * TEMP: -55 * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * SANDIA NATIONAL LAB CLAIMS 1N4153 IS EQUIVALENT TO QPND-4153 * * MEASURED TRR = 22.5NS, SIMULATED TRR = 22.2NS. .SUBCKT QPND-4153/-55C 99 2 D1 99 2 DFOR C1 2 99 2.20104E-13 .MODEL DFOR D ( + IS = 8.22432E-13 + RS = 0.279452 + N = 1.482007 + TT = 3.2E-8 + CJO = 4.02061E-14 + VJ = 0.5000333 + M = 1.046613 + EG = 1.11 + XTI = 4.834 + KF = 0 + AF = 1 + FC = 0.9 + BV = 85 + IBV = 1E-6 + ) .ENDS *$ * * * * RAD: PRE * TEMP: 125 * * * MEASURED TRR = 29.22NS, SIMULATED TRR = 30NS. .SUBCKT QPND-4153/125C 99 2 D1 99 2 DFOR C1 2 99 2.20104E-13 .MODEL DFOR D ( + IS = 4.67679E-14 + RS = 0.4219722 + N = 1.326898 + TT = 4.2E-8 + CJO = 4.02061E-14 + VJ = 0.5000333 + M = 1.046613 + EG = 1.11 + XTI = 5.023337 + KF = 0 + AF = 1 + FC = 0.9 + BV = 85 + IBV = 1E-6 + ) .ENDS *$ * * * TYPE: DIODE * SUBTYPE: MICROWAVE * THIS FILE CONTAINS 3 PRE-RAD MODELS AT VARIOUS TEMPS OF THE QPND-4153 DIODE. * THESE ARE LOW FREQUENCY MODELS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * * RAD: PRE * TEMP: 27 * * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * MEASURED TRR = 26.2NS, SIMULATED TRR = 26.6NS. .SUBCKT QPND-4153/27C 99 2 D1 99 2 DFOR C1 2 99 2.20104E-13 .MODEL DFOR D ( + IS = 4.18002E-13 + RS = 0.2374986 + N = 1.458876 + TT = 3.8E-8 + CJO = 4.02061E-14 + VJ = 0.5000333 + M = 1.046613 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 85 + IBV = 1E-6 + ) .ENDS *$ * * * RAD: PRE * TEMP: -55 * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * TIME DOMAIN MEASURMENTS ARE NOT AVAILIABLE DUE TO INSTRUMENTATION * BANDWIDTH LIMITATIONS. * .SUBCKT QSCH-5545/-55C 99 2 D1 99 2 DFOR C1 2 99 4.10097E-13 .MODEL DFOR D ( + IS = 2.43078E-4 + RS = 4.419243 + N = 1.176985 + TT = 0 + CJO = 1.01671E-13 + VJ = 0.1 + M = 0.3505733 + EG = 1.11 + XTI = 1.508301 + KF = 0 + AF = 1 + FC = 0.8692132 + BV = 8 + IBV = 1E-3 + ) .ENDS *$ * * * RAD: PRE * TEMP: 125 * * EG HAS NOT BEEN EXTRACTED AND IS SET TO A DEFAULT VALUE. * * TIME DOMAIN MEASURMENTS ARE NOT AVAILIABLE DUE TO INSTRUMENTATION * BANDWIDTH LIMITATIONS. * .SUBCKT QSCH-5545/125C 99 2 D1 99 2 DFOR C1 2 99 4.10097E-13 .MODEL DFOR D ( + IS = 4.97929E-10 + RS = 6.35218 + N = 1.048707 + TT = 0 + CJO = 1.01671E-13 + VJ = 0.1 + M = 0.3505733 + EG = 1.11 + XTI = 0 + KF = 0 + AF = 1 + FC = 0.8692132 + BV = 8 + IBV = 1E-3 + ) .ENDS *$ * * * TYPE: DIODE * SUBTYPE: MICROWAVE * THIS FILE CONTAINS 3 PRE-RAD MODELS AT VARIOUS TEMPS OF THE QSCH-5545 DIODE. * THESE ARE LOW FREQUENCY MODELS. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * * * RAD: PRE * TEMP: 27 * * XTI AND EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * TIME DOMAIN MEASURMENTS ARE NOT AVAILIABLE DUE TO INSTRUMENTATION * BANDWIDTH LIMITATIONS. * .SUBCKT QSCH-5545/27C 99 2 D1 99 2 DFOR C1 2 99 4.10097E-13 .MODEL DFOR D ( + IS = 5.10622E-8 + RS = 5.345 + N = 1.036839 + TT = 0 + CJO = 1.01671E-13 + VJ = 0.1 + M = 0.3505733 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8692132 + BV = 8 + IBV = 1E-3 + ) .ENDS *$ * * * MANUFACTURERS PART NO. = SPD1511-1-11 * TYPE: DIODE * SUBTYPE: TRANSIENT_RAD_DETECT * THIS IS A PRE-RAD MODEL AT 27 C OF THE SPD1511-1-11 * CREATED FROM MEASURED DATA. * * .MODEL SPD1511-1-11 D ( + IS = 80.9E-9 + RS = 1.22 + N = 1.83 + TT = 1E-9 + CJO = 18.7E-12 + VJ = 0.2 + M = 0.034 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = .5 + BV = 175 + IBV = 5.474E-4 + ) *$ * * RAD: PRERAD * TEMP -55 * .SUBCKT TD3070/-55C 99 2 D1 99 2 DFOR C1 2 99 1.4E-12 .MODEL DFOR D ( + IS = 5.20486E-9 + RS = 0.3149482 + N = 1.835075 + TT = 3.2E-8 + CJO = 1.35853E-12 + VJ = 0.4 + M = 0.5702412 + EG = 1.11 + XTI = 5.12614 + KF = 0 + AF = 1 + FC = 0.9 + BV = 233 + IBV = 1E-7 + ) .ENDS *$ * * MANUFACTURERS PART NO. = THD3070 * MANUFACTURER = SPRAGUE * TYPE: DIODE * SUBTYPE: SWITCHING * THE FOLLOWING SECTION CONTAINS 1 POST NEUTRON RADIATION PARAMETER * SET OF THE 1N3070. * THIS MODEL CAN BE USED FOR THE FOLLOWING DEVICES: * 1N3070 * THD3070 * PARAMETER SETS EXTRACTED FROM MEASURED DATA * * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * MEASURED TRR = 50.00NS, SIMULATED TRR = 21.52NS. * RAD: 1E12 * TYPE: NEUTRON * TEMP: 27 * .SUBCKT TD3070/27C/RAD 99 2 D1 99 2 DFOR C1 2 99 9.71955E-13 .MODEL DFOR D ( + IS = 3.8605E-9 + RS = 1.181303 + N = 1.807997 + TT = 3.0E-8 + CJO = 1.86686E-12 + VJ = 0.601151 + M = 0.3761742 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.5 + BV = 236 + IBV = 1E-5 + ) .ENDS *$ * * RAD: PRERAD * TEMP: 125 * .SUBCKT TD3070/125C 99 2 D1 99 2 DFOR C1 2 99 1.4E-12 .MODEL DFOR D ( + IS = 6.04158E-9 + RS = 0.2757489 + N = 1.864347 + TT = 8.6E-8 + CJO = 1.35853E-12 + VJ = 0.4 + M = 0.5702412 + EG = 1.11 + XTI = 3.557 + KF = 0 + AF = 1 + FC = 0.9 + BV = 233 + IBV = 1E-7 + ) .ENDS *$ * * MANUFACTURERS PART NO. = THD3070 * MANUFACTURER = SPRAGUE * TYPE: DIODE * SUBTYPE: SWITCHING * THE FOLLOWING SECTION CONTAINS 3 PARAMETER SETS FOR NON-IRRADIATTED * DEVICES AT VARYING TEMPERATURES OF THE THD3070. * THIS MODEL CAN BE USED FOR THE FOLLOWING DEVICES: * 1N3070 * THD3070 * PARAMETER SETS EXTRACTED FROM MEASURED DATA *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * * RAD: PRERAD * TEMP: 27 * .SUBCKT TD3070/27C 99 2 D1 99 2 DFOR C1 2 99 1.4E-12 .MODEL DFOR D ( + IS = 1.62034E-8 + RS = 0.2129965 + N = 2 + TT = 5.96E-8 + CJO = 1.35853E-12 + VJ = 0.4 + M = 0.5702412 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.9 + BV = 233 + IBV = 1E-7 + ) .ENDS *$ * * * MEASURED TRR = 60.43NS, SIMULATED TRR = 45.94NS. * * RAD: PRERAD * TEMP: -55 * * .MODEL UES302L/-55C D ( + IS = 3.9863E-8 + RS = 1E-7 + N = 1.600617 + TT = 1.2E-8 + CJO = 2.7526E-10 + VJ = 0.6624396 + M = 0.2670965 + EG = 1.11 + XTI = 1.894048 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 188.6 + IBV = 1E-4 + ) *$ * * * MEASURED TRR = 89.13NS, SIMULATED TRR = 60.12NS. * * RAD: PRERAD * TEMP: 125 * * .MODEL UES302L/125C D ( + IS = 2.78135E-7 + RS = 0.025 + N = 1.742372 + TT = 2.8E-8 + CJO = 2.7526E-10 + VJ = 0.6624396 + M = 0.2670965 + EG = 1.11 + XTI = 2.152 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 188.6 + IBV = 1E-4 + ) *$ * * * MANUFACTURERS PART NO.= UES302L * MANUFACTURER = UNITRODE * TYPE: DIODE * SUBTYPE: RECTIFIER_FAST_RECOV * THE FOLLOWING SECTION CONTANS 3 PARMETER SETS OF NON-IRRADIATED DEVICES * AT VARIOUS TEMPERATURES. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERTURE WILL PRODUCE INCORRECT RESULTS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * * * MEASURED TRR = 78.61NS, SIMULATED TRR = 51.97NS. * RAD: PRERAD * TEMP: 27 * * .MODEL UES302L/27C D ( + IS = 6.92597E-8 + RS = 0.0269184 + N = 1.571084 + TT = 1.9E-8 + CJO = 2.7526E-10 + VJ = 0.6624396 + M = 0.2670965 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8991 + BV = 188.6 + IBV = 1E-4 + ) *$ * * * MANUFACTURERS PART NO.= UES302L * MANURFACTURER = UNITRODE * TYPE: DIODE * SUBTYPE: RECTIFIER_FAST_RECOV * THE FOLLOWING SECTION CONTANS 1 PARMETER SETS OF IRRADIATED DEVICES * AT VARIOUS TEMPERATURES. * PARAMETER MODELS EXTRACTED FROM MEASURED DATA * *** CAUTION: USE ONLY AT TEMPERATURE SPECIFIED. ANY DEVIATION FROM THIS * TEMPERATURE WILL PRODUCE INCORRECT RESULTS. * *** CAUTION: THE MEASURED TRR AND THE PSPICE CIRCUIT SIMULATED TRR ARE * DIFFERENT. * THIS COULD POTENTIALLY LEAD TO ERRORS IN CIRCUIT SIMULATIONS * IF USED AS A RECTIFIER OR SWITCHING DIODE. * * * MEASURED TRR = 64.9NS, SIMULATED TRR = 62.4NS. * XTI, EG HAVE NOT BEEN EXTRACTED AND ARE SET TO DEFAULT VALUES. * * RAD: 2E12 * TYPE: NEUTRON * TEMP: 27 * * .MODEL UES302L/27C/RAD D ( + IS = 5.81219E-8 + RS = 0.022226 + N = 1.525231 + TT = 3.6E-8 + CJO = 2.65638E-10 + VJ = 0.4 + M = 0.2026838 + EG = 1.11 + XTI = 3 + KF = 0 + AF = 1 + FC = 0.8981164 + BV = 170 + IBV = 5E-6 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = UT1165 * MANUFACTURER = UNITRODE * TYPE: DIODE * SUBTYPE: 200V RECTIFIER * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM MEASURED DATA. THE MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. * NO RADIATION EFFECTS ARE INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT * THE RESPONSES OF NOMINAL DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE * LIMITS OF THE PRODUCT SPECIFICATION. * THE FOLLOWING IS AN INDICATION OF SATURATED SWITCHING TIME ACCURACY FOR THIS * MODEL: * MEASURED TRR = 10.18US SIMULATED TRR = 10.15US * RAD: PRE * TEMP= 27 * * .MODEL UT1165/27C D ( + IS = 5.397E-09 + RS = 0.005451 + N = 1.635 + TT = 13.2E-6 + CJO = 2.224E-10 + VJ = 0.4683 + M = 0.4188 + EG = 1.124 + XTI = 2.261 + KF = 0 + AF = 1 + FC = 0.5 + BV = 200 + IBV = 0.001 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = UT268 * MANUFACTURER = UNITRODE * TYPE: DIODE * SUBTYPE: 10 CHIP RECTIFIER * RAD: PRE * TEMP = 27 * * THE FOLLOWING IS AN INDICATION OF SWITCHING TIME ACCURACY FOR THIS * MODEL: MEASURED TRR = 1.70185US SIMULATED TRR = 1.71US * .MODEL UT268 D ( + IS = 4.289E-09 + RS = 1.133 + N = 18.1 + TT = 2.34E-6 + CJO = 2.818E-12 + VJ = 5.55 + M = 0.3784 + EG = 11.11 + XTI = 30 + KF = 0 + AF = 1 + FC = 0.5 + BV = 6.5E+3 + IBV = 1E-6 + ) *$ * * * GENERIC FUNCTIONAL EQUIVALENT = UT4020 * MANUFACTURER = UNITRODE * TYPE: DIODE * SUBTYPE: 200V RECTIFIER ZENER * THIS IS A TEMPERATURE TRACKING MODEL WHICH WAS CONSTRUCTED * FROM PRODUCT SPECIFICATIONS LIMITS AND PREVIOUSLY EXTRACTED MODELS. THE * MODEL IS INTENDED FOR USE FROM -55 C TO 125 C. NO RADIATION EFFECTS ARE * INCLUDED. SIMULATIONS USING THIS MODEL REPRESENT THE RESPONSES OF NOMINAL * DEVICES AND SIMULATIONS ARE ACCURATE WITHIN THE LIMITS OF THE PRODUCT * SPECIFICATION. * * THE FOLLOWING IS AN INDICATION OF SWITCHING TIME ACCURACY FOR THIS * MODEL: MEASURED TRR = 3.809US SIMULATED TRR = 3.8US * * RAD: PRE * TEMP= 27 * .MODEL UT4020 D ( + IS = 1.978E-08 + RS = 0.0214 + N = 1.855 + TT = 5.15E-6 + CJO = 1.216E-10 + VJ = 0.5288 + M = 0.4425 + EG = 1.132 + XTI = 4.908 + KF = 0 + AF = 1 + FC = 0.5 + BV = 200 + IBV = 0.001 + ) *$ *** end of library file