********************************************************** * AIM-Spice Library version 1.0 * * * * The library contains SPICE parameter sets * * of selected elecronic devices from several * * well known companies. * * * * AIM-Software strongly belive that the SPICE * * parameter sets presented in the library are correct. * * According to this AIM-Software do not take any * * responsibility of incorrect use, and errors due to * * incorrect SPICE parameter sets that may occur. * * * * June 1997 AIM-Software * ********************************************************** * * * Please read the following restriction: * * * ********************************************************** * (©) National Semiconductor, Inc. * * Models developed and under copyright by: * * National Semiconductor, Inc. * * * * Reproduced with permission of National Semiconductor * * Corporation. * * * * The models and subcircuits in this file are provided * * as is, without any warranties of any kind. National * * Semiconductor does not assume any responsibility for * * the use of this file, and specifically disclaims all * * warranties, including the implied warranties of * * merchantability or fitness for any particular * * purpose. * * * ********************************************************** * * * AIM-Spice Library of SPICE parameter sets for Diodes, * * BJTs, JFETs and Operational Amplifiers from * * National Semiconductor. * * * * Notice that some of the component models are valid * * for other components as well. Use the FIND * * opportunity to search the component you wish. * * * * The following National Diodes are included in * * AIM-Spice Library: * * * * 1N914 1N4148 1N4305 MMBD914 * * 1N914B 1N4149 1N4446 MMBD1201 * * 1N916 1N4150 1N4448 MMBD4148 * * 1N916A 1N4151 1N4938 * * 1N3064 1N4152 * * 1N4009 1N4153 * * 1N4154 * * * * The following National BJTs are included in * * AIM-Spice Library: * * * * 2N3390 2N4410 MPSA92 PN930 PN4258 * * 2N3391A 2N5086 MPSH10 PN2222A PN4275 * * 2N3392 2N5088 MPSL01 PN2369A PN4355 * * 2N3393 2N5172 MPSL51 PN2484 PN4356 * * 2N3415 2N5210 MPS3702 PN2907A PN4917 * * 2N3416 2N5366 MPS3703 PN3565 PN5134 * * 2N3702 2N5400 MPS6513 PN3638A PN5138 * * 2N3703 2N5401 MPS6514 PN3640 PN5179 * * 2N3859A 2N5550 MPS6515 PN3642 TIS93 * * 2N3903 2N5551 MPS6518 PN3643 TIS97 * * 2N3904 2N5769 MPS6521 PN3644 TIS98 * * 2N3905 2N5771 MPS6523 PN3645 TN2219A * * 2N3906 2N5772 MPS6531 PN3646 TN2905A * * 2N4123 MPSA05 MPS6534 PN4121 TN6714A * * 2N4124 MPSA10 MPS6562 PN4122 TN6715A * * 2N4125 MPSA18 MPS8098 PN4141 TN6726A * * 2N4126 MPSA20 PN4143 TN6728A * * 2N4400 MPSA42 PN4249 * * 2N4401 MPSA55 PN4250A * * 2N4402 * * * * The following National JFETs are included in * * AIM-Spice Library: * * * * J2N2608 J2N4084 J2N4856 J2N5105 J2N5902 * * J2N3370 J2N4091 J2N4856A J2N5114 J2N5905 * * J2N3458 J2N4092 J2N4857 J2N5116 J2N5911 * * J2N3459 J2N4093 J2N4857A J2N5196 J2N6483 * * J2N3684 J2N4117 J2N4858 J2N5197 J401 * * J2N3685 J2N4117A J2N4858A J2N5199 J410 * * J2N3686 J2N4118A J2N4859 J2N5358 NF5101 * * J2N3687 J2N4119A J2N4859A J2N5397 NF5102 * * J2N3821 J2N4220A J2N4860 J2N5398 NF5103 * * J2N3822 J2N4221A J2N4860A J2N5432 NF5301 * * J2N3823 J2N4222A J2N4861 J2N5433 NDF9406 * * J2N3824 J2N4223 J2N4861A J2N5434 U257 * * J2N3921 J2N4338 J2N5018 J2N5452 U308 * * J2N3922 J2N4339 J2N5019 J2N5454 U309 * * J2N3954A J2N4340 J2N5020 J2N5515 U310 * * J2N3955A J2N4341 J2N5021 J2N5545 U401 * * J2N3966 J2N4381 J2N5045 J2N5556 U440 * * J2N3967 J2N4391 J2N5046 J2N5557 * * J2N3970 J2N4392 J2N5047 J2N5558 * * J2N3971 J2N4393 J2N5078 J2N5565 * * J2N3972 J2N4416A J2N5103 * * * * The following National OP-AMPs are included in * * AIM-Spice Library: * * * * Notice that these Operational Amplifiers are * * subckt models. * * * * LF155 LF411 LM111 LM6118 LM6361 * * LF156 LF412 LM118 LM6161 LM6362 * * LF157 LF441A LM124 LM6162 LM6365 * * LF255 LF441B LM158 LM6164 LM741 * * LF256 LF442A LM218 LM6165 * * LF257 LF442B LM224 LM6218 * * LF351 LF444A LM258 LM6261 * * LF353 LF444B LM318 LM6262 * * LF355 LF451 LM324 LM6264 * * LF356 LF453 LM358 LM6265 * * LF357 * * * ********************************************************** * .MODEL 1N914 D(Is=0.1p Rs=16 CJO=2p Tt=12n Bv=100 Ibv=0.1p) * National * .MODEL 1N914B D(Is=0.1p Rs=2 CJO=2p Tt=12n Bv=100 Ibv=0.1p) * National * .MODEL 1N916 D(Is=0.1p Rs=8 CJO=1p Tt=12n Bv=100 Ibv=0.1p) * National * .MODEL 1N916A D(Is=0.1p Rs=4 CJO=1p Tt=12n Bv=100 Ibv=0.1p) * Valid for: 1N916B, 1N4447, 1N4449 * National * .MODEL 1N3064 D(Is=0.1p Rs=4 CJO=1p Tt=8n Bv=100 Ibv=0.1p) * Valid for: 1N4454 * National * .MODEL 1N4009 D(Is=0.1p Rs=4 CJO=2p Tt=3n Bv=60 Ibv=0.1p) * National * .MODEL 1N4148 D(Is=0.1p Rs=16 CJO=2p Tt=12n Bv=100 Ibv=0.1p) * National * .MODEL 1N4149 D(Is=0.1p Rs=8 CJO=1p Tt=12n Bv=100 Ibv=0.1p) * National * .MODEL 1N4150 D(Is=10E-15 Rs=1.0 CJO=1.3p Tt=12n Bv=70 Ibv=0.1p) * National * .MODEL 1N4151 D(Is=0.1p Rs=3 CJO=1p Tt=3n Bv=100 Ibv=0.1p) * National * .MODEL 1N4152 D(Is=0.1p Rs=6 CJO=1p Tt=3n Bv=70 Ibv=0.1p) * National * .MODEL 1N4153 D(Is=0.1p Rs=6 CJO=1p Tt=3n Bv=100 Ibv=0.1p) * National * .MODEL 1N4154 D(Is=0.1p Rs=4 CJO=2p Tt=3n Bv=60 Ibv=0.1p) * National * .MODEL 1N4305 D(Is=0.1p Rs=4 CJO=1p Tt=8n Bv=100 Ibv=0.1p) * National * .MODEL 1N4446 D(Is=0.1p Rs=4 CJO=2p Tt=12n Bv=100 Ibv=0.1p) * National * .MODEL 1N4448 D(Is=0.1p Rs=2 CJO=2p Tt=12n Bv=100 Ibv=0.1p) * National * .MODEL 1N4938 D(Is=0.1p Rs=2 CJO=2.5p Tt=35n Bv=300 Ibv=0.1p) * National * .Model MMBD914 D(Is=10E-15 Rs=1.0 CJO=1.3p Tt=12n Bv=70 Ibv=0.1p) * National * .MODEL MMBD1201 D(Is=10E-15 Rs=1.0 CJO=1.3p Tt=12n Bv=70 Ibv=0.1p) * Valid for: MMBD1202, MMBD1203, MMBD1204, MMBD1205 * National * .MODEL MMBD4148 D(Is=10E-15 Rs=1.0 CJO=1.3p Tt=12n Bv=70 Ibv=0.1p) * National * .MODEL 2N3390 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=685.8 Ne=1.971 + Ise=1.842p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=5.777p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=685.3p Tf=385.4p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL 2N3391A NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=427.8 Ne=1.971 + Ise=2.953p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=5.777p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=701.7p Tf=385.4p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL 2N3392 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=254.8 Ne=1.971 + Ise=4.958p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=5.777p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=732.1p Tf=385.4p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL 2N3393 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=154.1 Ne=1.971 + Ise=8.195p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=5.777p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=783.8p Tf=385.4p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL 2N3415 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=377.5 Ne=1.971 + Ise=3.346p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=5.777p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=707.6p Tf=385.4p Itf=.17 Vtf=3 Xtf=8 Rb=10) * Valid for: 2N3417 * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL 2N3416 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=157.3 Ne=1.971 + Ise=8.031p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=5.777p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=781.1p Tf=385.4p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * * .MODEL 2N3702 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=133.8 Ne=1.832 + Ise=97.16f Ikf=1.081 Xtb=1.5 Br=3.73 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=114.1n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL 2N3703 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=66.92 Ne=1.829 + Ise=189.7f Ikf=1.079 Xtb=1.5 Br=4.197 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=120.6n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL 2N3859A NPN(Is=5.911f Xti=3 Eg=1.11 Vaf=62.37 Bf=393.6 Ne=1.271 + Ise=5.911f Ikf=12.43m Xtb=1.5 Br=1.372 Nc=2 Isc=0 Ikr=0 Rc=1.61 + Cjc=4.017p Mjc=.3174 Vjc=.75 Fc=.5 Cje=4.973p Mje=.4146 Vje=.75 + Tr=4.761n Tf=818.2p Itf=.35 Vtf=4 Xtf=7 Rb=10) * National pid=07 case=TO92 * 88-09-07 bam creation * .MODEL 2N3903 NPN(Is=6.734f Xti=3 Eg=1.11 Vaf=74.03 Bf=335.2 Ne=1.208 + Ise=6.734f Ikf=60.26m Xtb=1.5 Br=.8073 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.638p Mjc=.3085 Vjc=.75 Fc=.5 Cje=4.493p Mje=.2593 Vje=.75 + Tr=243.9n Tf=300.8p Itf=.4 Vtf=4 Xtf=2 Rb=10) * National pid=23 case=TO92 * 88-09-08 bam creation * .MODEL 2N3904 NPN(Is=6.734f Xti=3 Eg=1.11 Vaf=74.03 Bf=416.4 Ne=1.259 + Ise=6.734f Ikf=66.78m Xtb=1.5 Br=.7371 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.638p Mjc=.3085 Vjc=.75 Fc=.5 Cje=4.493p Mje=.2593 Vje=.75 + Tr=239.5n Tf=301.2p Itf=.4 Vtf=4 Xtf=2 Rb=10) * National pid=23 case=TO92 * 88-09-08 bam creation * .MODEL 2N3905 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=90.35 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=5.502 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=35.05n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL 2N3906 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=180.7 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=4.977 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=33.42n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL 2N4123 NPN(Is=6.734f Xti=3 Eg=1.11 Vaf=74.03 Bf=335.3 Ne=1.216 + Ise=6.734f Ikf=61.27m Xtb=1.5 Br=.7925 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.638p Mjc=.3085 Vjc=.75 Fc=.5 Cje=4.493p Mje=.2593 Vje=.75 + Tr=243.1n Tf=300.8p Itf=.4 Vtf=4 Xtf=2 Rb=10) * National pid=23 case=TO92 * 88-09-08 bam creation * .MODEL 2N4124 NPN(Is=6.734f Xti=3 Eg=1.11 Vaf=74.03 Bf=495 Ne=1.28 Ise=6.734f + Ikf=69.35m Xtb=1.5 Br=.7214 Nc=2 Isc=0 Ikr=0 Rc=1 Cjc=3.638p + Mjc=.3085 Vjc=.75 Fc=.5 Cje=4.493p Mje=.2593 Vje=.75 Tr=238.3n + Tf=301.3p Itf=.4 Vtf=4 Xtf=2 Rb=10) * National pid=23 case=TO92 * 88-09-08 bam creation * .MODEL 2N4125 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=85.04 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=5.576 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=35.25n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL 2N4126 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=203.7 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=4.924 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=33.23n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL 2N4400 NPN(Is=26.03f Xti=3 Eg=1.11 Vaf=90.7 Bf=7.756K Ne=1.204 + Ise=26.7f Ikf=.2397 Xtb=1.5 Br=1.06 Nc=2 Isc=0 Ikr=0 Rc=.5 + Cjc=11.01p Mjc=.3763 Vjc=.75 Fc=.5 Cje=24.07p Mje=.3641 Vje=.75 + Tr=244n Tf=573.2p Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=2N4400 case=TO92 * 88-09-13 bam creation * .MODEL 2N4401 NPN(Is=26.03f Xti=3 Eg=1.11 Vaf=90.7 Bf=4.292K Ne=1.244 + Ise=26.03f Ikf=.2061 Xtb=1.5 Br=1.01 Nc=2 Isc=0 Ikr=0 Rc=.5 + Cjc=11.01p Mjc=.3763 Vjc=.75 Fc=.5 Cje=24.07p Mje=.3641 Vje=.75 + Tr=233.7n Tf=466.5p Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=2N4400 case=TO92 * 88-09-13 bam creation * .MODEL 2N4402 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=108 Ne=1.86 + Ise=146.9f Ikf=1.115 Xtb=1.5 Br=3.83 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=115.7n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL 2N4403 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=216.2 Ne=1.829 + Ise=58.72f Ikf=1.079 Xtb=1.5 Br=3.578 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=111.6n Tf=603.7p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL 2N4410 NPN(Is=5.911f Xti=3 Eg=1.11 Vaf=62.37 Bf=413.6 Ne=1.278 + Ise=5.911f Ikf=12.6m Xtb=1.5 Br=1.361 Nc=2 Isc=0 Ikr=0 Rc=1.61 + Cjc=4.017p Mjc=.3174 Vjc=.75 Fc=.5 Cje=4.973p Mje=.4146 Vje=.75 + Tr=4.749n Tf=818.4p Itf=.35 Vtf=4 Xtf=7 Rb=10) * National pid=07 case=TO92 * 88-09-07 bam creation * .MODEL 2N5086 PNP(Is=6.734f Xti=3 Eg=1.11 Vaf=45.7 Bf=254.1 Ne=1.741 + Ise=6.734f Ikf=.1962 Xtb=1.5 Br=2.683 Nc=2 Isc=0 Ikr=0 Rc=1.67 + Cjc=6.2p Mjc=.301 Vjc=.75 Fc=.5 Cje=7.5p Mje=.2861 Vje=.75 + Tr=10.1n Tf=467.8p Itf=.17 Vtf=5 Xtf=8 Rb=10) * Valid for: 2N5087 * National pid=62 case=TO92 * 88-09-08 bam creation * .MODEL 2N5088 NPN(Is=5.911f Xti=3 Eg=1.11 Vaf=62.37 Bf=1.122K Ne=1.394 + Ise=5.911f Ikf=14.92m Xtb=1.5 Br=1.271 Nc=2 Isc=0 Ikr=0 Rc=1.61 + Cjc=4.017p Mjc=.3174 Vjc=.75 Fc=.5 Cje=4.973p Mje=.4146 Vje=.75 + Tr=4.673n Tf=821.7p Itf=.35 Vtf=4 Xtf=7 Rb=10) * Valid for: 2N5089 * National pid=07 case=TO92 * 88-09-07 bam creation * .MODEL 2N5172 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=308.3 Ne=1.971 + Ise=4.098p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=5.777p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=718.9p Tf=385.4p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL 2N5210 NPN(Is=5.911f Xti=3 Eg=1.11 Vaf=62.37 Bf=809.9 Ne=1.358 + Ise=5.911f Ikf=14.26m Xtb=1.5 Br=1.287 Nc=2 Isc=0 Ikr=0 Rc=1.61 + Cjc=4.017p Mjc=.3174 Vjc=.75 Fc=.5 Cje=4.973p Mje=.4146 Vje=.75 + Tr=4.68n Tf=820.9p Itf=.35 Vtf=4 Xtf=7 Rb=10) * National pid=07 case=TO92 * 88-09-07 bam creation * .MODEL 2N5366 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=166.3 Ne=1.853 + Ise=90.78f Ikf=1.105 Xtb=1.5 Br=3.649 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=112.8n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL 2N5400 PNP(Is=21.48f Xti=3 Eg=1.11 Vaf=100 Bf=93.44 Ne=1.344 + Ise=21.48f Ikf=.1798 Xtb=1.5 Br=3.874 Nc=2 Isc=0 Ikr=0 Rc=1.6 + Cjc=17.63p Mjc=.5312 Vjc=.75 Fc=.5 Cje=73.39p Mje=.3777 Vje=.75 + Tr=1.512n Tf=641.5p Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=74 case=TO92 * 88-09-09 bam creation * .MODEL 2N5401 PNP(Is=21.48f Xti=3 Eg=1.11 Vaf=100 Bf=132.1 Ne=1.375 + Ise=21.48f Ikf=.1848 Xtb=1.5 Br=3.661 Nc=2 Isc=0 Ikr=0 Rc=1.6 + Cjc=17.63p Mjc=.5312 Vjc=.75 Fc=.5 Cje=73.39p Mje=.3777 Vje=.75 + Tr=1.476n Tf=641.9p Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=74 case=TO92 * 88-09-09 bam creation * .MODEL 2N5550 NPN(Is=2.511f Xti=3 Eg=1.11 Vaf=100 Bf=213.4 Ne=1.241 + Ise=2.511f Ikf=.3495 Xtb=1.5 Br=3.24 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=4.883p Mjc=.3047 Vjc=.75 Fc=.5 Cje=18.79p Mje=.3416 Vje=.75 + Tr=1.212n Tf=560.1p Itf=50m Vtf=5 Xtf=8 Rb=10) * National pid=16 case=TO92 * 88-09-07 bam creation * .MODEL 2N5551 NPN(Is=2.511f Xti=3 Eg=1.11 Vaf=100 Bf=242.6 Ne=1.249 + Ise=2.511f Ikf=.3458 Xtb=1.5 Br=3.197 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=4.883p Mjc=.3047 Vjc=.75 Fc=.5 Cje=18.79p Mje=.3416 Vje=.75 + Tr=1.202n Tf=560p Itf=50m Vtf=5 Xtf=8 Rb=10) * National pid=16 case=TO92 * 88-09-07 bam creation * .MODEL 2N5769 NPN(Is=44.14f Xti=3 Eg=1.11 Vaf=100 Bf=78.32 Ne=1.389 + Ise=91.95f Ikf=.3498 Xtb=1.5 Br=12.69m Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=2.83p Mjc=86.19m Vjc=.75 Fc=.5 Cje=4.5p Mje=.2418 Vje=.75 + Tr=1.073u Tf=227.6p Itf=.3 Vtf=4 Xtf=4 Rb=10) * National pid=21 case=TO92 * 88-09-07 bam creation * .MODEL 2N5771 PNP(Is=545.6E-18 Xti=3 Eg=1.11 Vaf=100 Bf=76.77 Ne=1.5 Ise=0 + Ikf=50m Xtb=1.5 Br=1.365 Nc=2 Isc=0 Ikr=0 Rc=3.75 Cjc=2.77p + Mjc=.1416 Vjc=.75 Fc=.5 Cje=2.65p Mje=.3083 Vje=.75 Tr=4.033n + Tf=118.5p Itf=.5 Vtf=3 Xtf=6 Rb=10) * National pid=65 case=TO92 * 88-09-08 bam creation * .MODEL 2N5772 NPN(Is=44.14f Xti=3 Eg=1.11 Vaf=100 Bf=75.97 Ne=1.389 + Ise=94.79f Ikf=.3498 Xtb=1.5 Br=12.76m Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=2.83p Mjc=86.19m Vjc=.75 Fc=.5 Cje=4.5p Mje=.2418 Vje=.75 + Tr=1.076u Tf=227.6p Itf=.3 Vtf=4 Xtf=4 Rb=10) * National pid=21 case=TO92 * 88-09-07 bam creation * .MODEL MPSA05 NPN(Is=8.324f Xti=3 Eg=1.11 Vaf=100 Bf=12.16K Ne=1.368 + Ise=73.27f Ikf=.1096 Xtb=1.5 Br=11.1 Nc=2 Isc=0 Ikr=0 Rc=.25 + Cjc=18.36p Mjc=.3843 Vjc=.75 Fc=.5 Cje=55.61p Mje=.3834 Vje=.75 + Tr=72.15n Tf=516.1p Itf=.5 Vtf=4 Xtf=6 Rb=10) * Valid for: MPSA06 * National pid=MPSA05 case=TO92 * 88-09-13 bam creation * .MODEL MPSA10 NPN(Is=61.01f Xti=3 Eg=1.11 Vaf=57.37 Bf=193 Ne=1.305 + Ise=76.83f Ikf=97.79m Xtb=1.5 Br=.2195 Nc=2 Isc=0 Ikr=0 Rc=2.14 + Cjc=6.072p Mjc=.3333 Vjc=.75 Fc=.5 Cje=5.928p Mje=.3333 Vje=.75 + Tr=1.573u Tf=316.3p Itf=.2 Vtf=5 Xtf=8 Rb=10) * National pid=27 case=TO92 * 88-09-08 bam creation * .MODEL MPSA18 NPN(Is=33.58f Xti=3 Eg=1.11 Vaf=100 Bf=2.365K Ne=1.579 + Ise=166.7f Ikf=.1172 Xtb=1.5 Br=5.774 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=4.948p Mjc=.4109 Vjc=.75 Fc=.5 Cje=7.547p Mje=.3765 Vje=.75 + Tr=800.3p Tf=310.1p Itf=.6 Vtf=6 Xtf=35 Rb=10) * National pid=MPSA18 case=TO92 * 88-09-14 bam creation * .MODEL MPSA20 NPN(Is=1.949f Xti=3 Eg=1.11 Vaf=30.7 Bf=873.5 Ne=1.203 + Ise=2.059f Ikf=73.69m Xtb=1.5 Br=3.237 Nc=2 Isc=0 Ikr=0 Rc=4 + Cjc=3.898p Mjc=.2858 Vjc=.75 Fc=.5 Cje=6.726p Mje=.3467 Vje=.75 + Tr=1.207n Tf=637.5p Itf=.15 Vtf=4 Xtf=14 Rb=10) * National pid=02 case=TO92 * 88-09-07 bam creation * .MODEL MPSA42 NPN(Is=34.9f Xti=3 Eg=1.11 Vaf=100 Bf=2.65K Ne=1.708 Ise=16.32p + Ikf=23.79m Xtb=1.5 Br=9.769 Nc=2 Isc=0 Ikr=0 Rc=7 Cjc=14.23p + Mjc=.5489 Vjc=.75 Fc=.5 Cje=49.62p Mje=.4136 Vje=.75 Tr=934.3p + Tf=1.69n Itf=5 Vtf=20 Xtf=150 Rb=10) * Valid for: MPSA43 * National pid=MPSA42 case=TO92 * 88-09-14 bam creation * .MODEL MPSA55 PNP(Is=12.27p Xti=3 Eg=1.11 Vaf=100 Bf=91.63 Ne=1.531 + Ise=12.27p Ikf=1.009 Xtb=1.5 Br=1.287 Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=48.28p Mjc=.5615 Vjc=.75 Fc=.5 Cje=106.7p Mje=.5168 Vje=.75 + Tr=496.3n Tf=865.8p Itf=.2 Vtf=2 Xtf=.8 Rb=10) * Valid for: MPSA56 * National pid=67 case=TO92 * 88-09-09 bam creation * .MODEL MPSA92 PNP(Is=218.9f Xti=3 Eg=1.11 Vaf=100 Bf=99 Ne=1.307 Ise=218.9f + Ikf=.2016 Xtb=1.5 Br=24.67 Nc=2 Isc=0 Ikr=0 Rc=7 Cjc=19.88p + Mjc=.4876 Vjc=.75 Fc=.5 Cje=81.49p Mje=.3493 Vje=.75 Tr=516.9p + Tf=1.395n Itf=1.5 Vtf=22 Xtf=270 Rb=10) * Valid for: MPSA93 * National pid=MPSA92 case=TO92 * 88-09-14 bam creation * .MODEL MPSH10 NPN(Is=69.28E-18 Xti=3 Eg=1.11 Vaf=100 Bf=308.6 Ne=1.197 + Ise=69.28E-18 Ikf=22.83m Xtb=1.5 Br=1.11 Nc=2 Isc=0 Ikr=0 Rc=4 + Cjc=1.042p Mjc=.2468 Vjc=.75 Fc=.5 Cje=1.52p Mje=.3223 Vje=.75 + Tr=1.558n Tf=135.8p Itf=.27 Vtf=10 Xtf=30 Rb=10) * National pid=42 case=TO92 * 88-09-07 bam creation * .MODEL MPSL01 NPN(Is=2.511f Xti=3 Eg=1.11 Vaf=100 Bf=213.4 Ne=1.241 + Ise=2.511f Ikf=.3495 Xtb=1.5 Br=3.24 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=4.883p Mjc=.3047 Vjc=.75 Fc=.5 Cje=18.79p Mje=.3416 Vje=.75 + Tr=1.212n Tf=560.1p Itf=50m Vtf=5 Xtf=8 Rb=10) * National pid=16 case=TO92 * 88-09-07 bam creation * .MODEL MPSL51 PNP(Is=21.48f Xti=3 Eg=1.11 Vaf=100 Bf=116.7 Ne=1.362 + Ise=21.48f Ikf=.1803 Xtb=1.5 Br=3.728 Nc=2 Isc=0 Ikr=0 Rc=1.6 + Cjc=21.16p Mjc=.5312 Vjc=.75 Fc=.5 Cje=73.39p Mje=.3777 Vje=.75 + Tr=1.487n Tf=639.1p Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=74 case=TO92 * 88-09-09 bam creation * .MODEL MPS3702 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=133.8 Ne=1.832 + Ise=97.16f Ikf=1.081 Xtb=1.5 Br=3.73 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=114.1n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL MPS3703 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=66.92 Ne=1.829 + Ise=189.7f Ikf=1.079 Xtb=1.5 Br=4.197 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=120.6n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL MPS6513 NPN(Is=6.734f Xti=3 Eg=1.11 Vaf=74.03 Bf=383.9 Ne=1.247 + Ise=6.734f Ikf=65.32m Xtb=1.5 Br=.7482 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.118p Mjc=.3086 Vjc=.75 Fc=.5 Cje=4.493p Mje=.2593 Vje=.75 + Tr=240.3n Tf=301.5p Itf=.4 Vtf=4 Xtf=2 Rb=10) * National pid=23 case=TO92 * 88-09-08 bam creation * .MODEL MPS6514 NPN(Is=6.734f Xti=3 Eg=1.11 Vaf=74.03 Bf=522 Ne=1.286 + Ise=6.734f Ikf=70.02m Xtb=1.5 Br=.7179 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.118p Mjc=.3086 Vjc=.75 Fc=.5 Cje=4.493p Mje=.2593 Vje=.75 + Tr=238n Tf=301.8p Itf=.4 Vtf=4 Xtf=2 Rb=10) * National pid=23 case=TO92 * 88-09-08 bam creation * .MODEL MPS6515 NPN(Is=6.734f Xti=3 Eg=1.11 Vaf=74.03 Bf=760.5 Ne=1.325 + Ise=6.734f Ikf=74.54m Xtb=1.5 Br=.7009 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.118p Mjc=.3086 Vjc=.75 Fc=.5 Cje=4.493p Mje=.2593 Vje=.75 + Tr=236.6n Tf=302p Itf=.4 Vtf=4 Xtf=2 Rb=10) * National pid=23 case=TO92 * 88-09-08 bam creation * .MODEL MPS6518 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=292.3 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=4.802 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=32.79n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL MPS6521 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=490.7 Ne=1.971 + Ise=2.574p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.123p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=696.1p Tf=390p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL MPS6523 PNP(Is=6.734f Xti=3 Eg=1.11 Vaf=45.7 Bf=446.6 Ne=1.83 + Ise=6.734f Ikf=.2112 Xtb=1.5 Br=2.624 Nc=2 Isc=0 Ikr=0 Rc=1.67 + Cjc=6.2p Mjc=.301 Vjc=.75 Fc=.5 Cje=7.5p Mje=.2861 Vje=.75 + Tr=9.802n Tf=468p Itf=.17 Vtf=5 Xtf=8 Rb=10) * National pid=62 case=TO92 * 88-09-08 bam creation * .MODEL MPS6531 NPN(Is=26.03f Xti=3 Eg=1.11 Vaf=90.7 Bf=69.05K Ne=1.228 + Ise=26.03f Ikf=.2044 Xtb=1.5 Br=1.027 Nc=2 Isc=0 Ikr=0 Rc=.5 + Cjc=11.01p Mjc=.3763 Vjc=.75 Fc=.5 Cje=24.07p Mje=.3641 Vje=.75 + Tr=235.2n Tf=466.4p Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=2N4400 case=TO92 * 88-09-13 bam creation * .MODEL MPS6534 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=173.2 Ne=1.851 + Ise=85.79f Ikf=1.103 Xtb=1.5 Br=3.637 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=112.6n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL MPS6562 PNP(Is=12.27p Xti=3 Eg=1.11 Vaf=100 Bf=121 Ne=1.573 Ise=12.27p + Ikf=1.05 Xtb=1.5 Br=1.238 Nc=2 Isc=0 Ikr=0 Rc=.6 Cjc=48.28p + Mjc=.5615 Vjc=.75 Fc=.5 Cje=106.7p Mje=.5168 Vje=.75 Tr=486n + Tf=866.3p Itf=.2 Vtf=2 Xtf=.8 Rb=10) * National pid=67 case=TO92 * 88-09-09 bam creation * .MODEL MPS8098 NPN(Is=4.872f Xti=3 Eg=1.11 Vaf=100 Bf=9.599K Ne=1.315 + Ise=14.65f Ikf=.1434 Xtb=1.5 Br=6.935 Nc=2 Isc=0 Ikr=0 Rc=.7 + Cjc=5.805p Mjc=.4312 Vjc=.75 Fc=.5 Cje=10.49p Mje=.4602 Vje=.75 + Tr=565p Tf=407p Itf=.18 Vtf=3 Xtf=2.5 Rb=10) * National pid=18 case=TO92 * 88-09-07 bam creation * .MODEL PN930 NPN(Is=5.911f Xti=3 Eg=1.11 Vaf=62.37 Bf=578.3 Ne=1.32 + Ise=5.911f Ikf=13.5m Xtb=1.5 Br=1.313 Nc=2 Isc=0 Ikr=0 Rc=1.61 + Cjc=4.017p Mjc=.3174 Vjc=.75 Fc=.5 Cje=4.973p Mje=.4146 Vje=.75 + Tr=4.701n Tf=819.8p Itf=.35 Vtf=4 Xtf=7 Rb=10) * National pid=07 case=TO92 * 88-09-07 bam creation * .MODEL PN2222A NPN(Is=14.34f Xti=3 Eg=1.11 Vaf=74.03 Bf=255.9 Ne=1.307 + Ise=14.34f Ikf=.2847 Xtb=1.5 Br=6.092 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=7.306p Mjc=.3416 Vjc=.75 Fc=.5 Cje=22.01p Mje=.377 Vje=.75 + Tr=46.91n Tf=411.1p Itf=.6 Vtf=1.7 Xtf=3 Rb=10) * Valid for: PN2222 * National pid=19 case=TO92 * 88-09-07 bam creation * .MODEL PN2369A NPN(Is=44.14f Xti=3 Eg=1.11 Vaf=100 Bf=78.32 Ne=1.389 + Ise=91.95f Ikf=.3498 Xtb=1.5 Br=12.69m Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=2.83p Mjc=86.19m Vjc=.75 Fc=.5 Cje=4.5p Mje=.2418 Vje=.75 + Tr=1.073u Tf=227.6p Itf=.3 Vtf=4 Xtf=4 Rb=10) * Valid for: PN2369 * National pid=21 case=TO92 * 88-09-07 bam creation * .MODEL PN2484 NPN(Is=5.911f Xti=3 Eg=1.11 Vaf=62.37 Bf=697.1 Ne=1.342 + Ise=5.911f Ikf=13.93m Xtb=1.5 Br=1.297 Nc=2 Isc=0 Ikr=0 Rc=1.61 + Cjc=4.017p Mjc=.3174 Vjc=.75 Fc=.5 Cje=4.973p Mje=.4146 Vje=.75 + Tr=4.687n Tf=820.4p Itf=.35 Vtf=4 Xtf=7 Rb=10) * National pid=07 case=TO92 * 88-09-07 bam creation * .MODEL PN2907A PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=231.7 Ne=1.829 + Ise=54.81f Ikf=1.079 Xtb=1.5 Br=3.563 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=111.3n Tf=603.7p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * Valid for: PN2907 * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL PN3565 NPN(Is=5.911f Xti=3 Eg=1.11 Vaf=62.37 Bf=697.1 Ne=1.342 + Ise=5.911f Ikf=13.93m Xtb=1.5 Br=1.297 Nc=2 Isc=0 Ikr=0 Rc=1.61 + Cjc=4.017p Mjc=.3174 Vjc=.75 Fc=.5 Cje=4.973p Mje=.4146 Vje=.75 + Tr=4.687n Tf=820.4p Itf=.35 Vtf=4 Xtf=7 Rb=10) * National pid=07 case=TO92 * 88-09-07 bam creation * .MODEL PN3638A PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=63.49 Ne=1.829 + Ise=200f Ikf=1.079 Xtb=1.5 Br=4.254 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=121.3n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * Valid for: PN3638 * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL PN3640 PNP(Is=545.6E-18 Xti=3 Eg=1.11 Vaf=100 Bf=59.22 Ne=1.5 Ise=0 + Ikf=50m Xtb=1.5 Br=1.438 Nc=2 Isc=0 Ikr=0 Rc=3.75 Cjc=2.77p + Mjc=.1416 Vjc=.75 Fc=.5 Cje=2.65p Mje=.3083 Vje=.75 Tr=4.123n + Tf=118.5p Itf=.5 Vtf=3 Xtf=6 Rb=10) * National pid=65 case=TO92 * 88-09-08 bam creation * .MODEL PN3642 NPN(Is=14.34f Xti=3 Eg=1.11 Vaf=74.03 Bf=118.6 Ne=1.236 + Ise=14.34f Ikf=.2524 Xtb=1.5 Br=7.134 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=7.306p Mjc=.3416 Vjc=.75 Fc=.5 Cje=22.01p Mje=.377 Vje=.75 + Tr=50.96n Tf=410.3p Itf=.6 Vtf=1.7 Xtf=3 Rb=10) * National pid=19 case=TO92 * 88-09-07 bam creation * .MODEL PN3643 NPN(Is=14.34f Xti=3 Eg=1.11 Vaf=74.03 Bf=255.9 Ne=1.307 + Ise=14.34f Ikf=.2847 Xtb=1.5 Br=6.092 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=7.306p Mjc=.3416 Vjc=.75 Fc=.5 Cje=22.01p Mje=.377 Vje=.75 + Tr=46.91n Tf=411.1p Itf=.6 Vtf=1.7 Xtf=3 Rb=10) * National pid=19 case=TO92 * 88-09-07 bam creation * .MODEL PN3644 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=231.7 Ne=1.829 + Ise=54.81f Ikf=1.079 Xtb=1.5 Br=3.563 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=111.3n Tf=603.7p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL PN3645 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=231.7 Ne=1.829 + Ise=54.81f Ikf=1.079 Xtb=1.5 Br=3.563 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=111.3n Tf=603.7p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL PN3646 NPN(Is=1.017f Xti=3 Eg=1.11 Vaf=100 Bf=85.99 Ne=2.048 + Ise=34.11p Ikf=.2617 Xtb=1.5 Br=3.587 Nc=2 Isc=0 Ikr=0 Rc=1.75 + Cjc=4.256p Mjc=.1053 Vjc=.75 Fc=.5 Cje=8.359p Mje=.3504 Vje=.75 + Tr=5.32n Tf=289.3p Itf=.35 Vtf=5 Xtf=2 Rb=10) * National pid=22 case=TO92 * 88-09-07 bam creation * .MODEL PN4121 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=122.2 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=5.215 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=34.2n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL PN4122 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=219.7 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=4.894 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=33.13n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL PN4141 NPN(Is=14.34f Xti=3 Eg=1.11 Vaf=74.03 Bf=255.9 Ne=1.307 + Ise=14.34f Ikf=.2847 Xtb=1.5 Br=6.092 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=7.306p Mjc=.3416 Vjc=.75 Fc=.5 Cje=22.01p Mje=.377 Vje=.75 + Tr=46.91n Tf=411.1p Itf=.6 Vtf=1.7 Xtf=3 Rb=10) * National pid=19 case=TO92 * 88-09-07 bam creation * .MODEL PN4143 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=231.7 Ne=1.829 + Ise=54.81f Ikf=1.079 Xtb=1.5 Br=3.563 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=111.3n Tf=603.7p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL PN4249 PNP(Is=6.734f Xti=3 Eg=1.11 Vaf=45.7 Bf=161.4 Ne=1.672 + Ise=6.734f Ikf=.1806 Xtb=1.5 Br=2.767 Nc=2 Isc=0 Ikr=0 Rc=1.67 + Cjc=6.2p Mjc=.301 Vjc=.75 Fc=.5 Cje=7.5p Mje=.2861 Vje=.75 + Tr=10.54n Tf=467.4p Itf=.17 Vtf=5 Xtf=8 Rb=10) * National pid=62 case=TO92 * 88-09-08 bam creation * .MODEL PN4250A PNP(Is=6.734f Xti=3 Eg=1.11 Vaf=45.7 Bf=388.2 Ne=1.806 + Ise=6.734f Ikf=.205 Xtb=1.5 Br=2.635 Nc=2 Isc=0 Ikr=0 Rc=1.67 + Cjc=6.2p Mjc=.301 Vjc=.75 Fc=.5 Cje=7.5p Mje=.2861 Vje=.75 + Tr=9.861n Tf=467.9p Itf=.17 Vtf=5 Xtf=8 Rb=10) * Valid for: PN4250 * National pid=62 case=TO92 * 88-09-08 bam creation * .MODEL PN4258 PNP(Is=545.6E-18 Xti=3 Eg=1.11 Vaf=100 Bf=61.42 Ne=1.5 Ise=0 + Ikf=50m Xtb=1.5 Br=1.426 Nc=2 Isc=0 Ikr=0 Rc=3.75 Cjc=2.77p + Mjc=.1416 Vjc=.75 Fc=.5 Cje=2.65p Mje=.3083 Vje=.75 Tr=4.109n + Tf=118.5p Itf=.5 Vtf=3 Xtf=6 Rb=10) * National pid=65 case=TO92 * 88-09-08 bam creation * .MODEL PN4275 NPN(Is=44.14f Xti=3 Eg=1.11 Vaf=100 Bf=73.62 Ne=1.389 + Ise=97.82f Ikf=.3498 Xtb=1.5 Br=12.84m Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=2.83p Mjc=86.19m Vjc=.75 Fc=.5 Cje=4.5p Mje=.2418 Vje=.75 + Tr=1.079u Tf=227.6p Itf=.3 Vtf=4 Xtf=4 Rb=10) * National pid=21 case=TO92 * 88-09-07 bam creation * .MODEL PN4355 PNP(Is=12.27p Xti=3 Eg=1.11 Vaf=100 Bf=194.8 Ne=1.649 + Ise=12.27p Ikf=1.123 Xtb=1.5 Br=1.184 Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=48.28p Mjc=.5615 Vjc=.75 Fc=.5 Cje=106.7p Mje=.5168 Vje=.75 + Tr=474.5n Tf=867p Itf=.2 Vtf=2 Xtf=.8 Rb=10) * National pid=67 case=TO92 * 88-09-09 bam creation * .MODEL PN4356 PNP(Is=12.27p Xti=3 Eg=1.11 Vaf=100 Bf=110.2 Ne=1.558 + Ise=12.27p Ikf=1.036 Xtb=1.5 Br=1.252 Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=48.28p Mjc=.5615 Vjc=.75 Fc=.5 Cje=106.7p Mje=.5168 Vje=.75 + Tr=489.1n Tf=866.1p Itf=.2 Vtf=2 Xtf=.8 Rb=10) * National pid=67 case=TO92 * 88-09-09 bam creation * .MODEL PN4917 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=219.7 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=4.894 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=33.13n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL PN5134 NPN(Is=44.14f Xti=3 Eg=1.11 Vaf=100 Bf=61.88 Ne=1.389 + Ise=116.4f Ikf=.3498 Xtb=1.5 Br=13.33m Nc=2 Isc=0 Ikr=0 Rc=.6 + Cjc=2.83p Mjc=86.19m Vjc=.75 Fc=.5 Cje=4.5p Mje=.2418 Vje=.75 + Tr=1.097u Tf=227.6p Itf=.3 Vtf=4 Xtf=4 Rb=10) * National pid=21 case=TO92 * 88-09-07 bam creation * .MODEL PN5138 PNP(Is=1.41f Xti=3 Eg=1.11 Vaf=18.7 Bf=274.6 Ne=1.5 Ise=0 + Ikf=80m Xtb=1.5 Br=4.82 Nc=2 Isc=0 Ikr=0 Rc=2.5 Cjc=9.728p + Mjc=.5776 Vjc=.75 Fc=.5 Cje=8.063p Mje=.3677 Vje=.75 Tr=32.86n + Tf=179.3p Itf=.4 Vtf=4 Xtf=6 Rb=10) * National pid=66 case=TO92 * 88-09-09 bam creation * .MODEL PN5179 NPN(Is=69.28E-18 Xti=3 Eg=1.11 Vaf=100 Bf=282.1 Ne=1.177 + Ise=69.28E-18 Ikf=22.03m Xtb=1.5 Br=1.176 Nc=2 Isc=0 Ikr=0 Rc=4 + Cjc=1.042p Mjc=.2468 Vjc=.75 Fc=.5 Cje=1.52p Mje=.3223 Vje=.75 + Tr=1.588n Tf=135.6p Itf=.27 Vtf=10 Xtf=30 Rb=10) * National pid=42 case=TO92 * 88-09-07 bam creation * .MODEL TIS93 PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=168.2 Ne=1.831 + Ise=76.95f Ikf=1.081 Xtb=1.5 Br=3.647 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=112.7n Tf=761.3p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO92 * 88-09-09 bam creation * .MODEL TIS97 NPN(Is=12.03f Xti=3 Eg=1.11 Vaf=37.37 Bf=877.7 Ne=1.971 + Ise=1.439p Ikf=.1072 Xtb=1.5 Br=4.379 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=3.123p Mjc=.3199 Vjc=.75 Fc=.5 Cje=8.307p Mje=.384 Vje=.75 + Tr=679.5p Tf=390p Itf=.17 Vtf=3 Xtf=8 Rb=10) * National pid=04 case=TO92 * 88-09-07 bam creation * .MODEL TIS98 NPN(Is=4.872f Xti=3 Eg=1.11 Vaf=100 Bf=9.599K Ne=1.315 + Ise=14.65f Ikf=.1434 Xtb=1.5 Br=6.935 Nc=2 Isc=0 Ikr=0 Rc=.7 + Cjc=8.866p Mjc=.4312 Vjc=.75 Fc=.5 Cje=10.49p Mje=.4602 Vje=.75 + Tr=565p Tf=405.1p Itf=.18 Vtf=3 Xtf=2.5 Rb=10) * National pid=18 case=TO92 * 88-09-07 bam creation * .MODEL TN2219A NPN(Is=14.34f Xti=3 Eg=1.11 Vaf=74.03 Bf=255.9 Ne=1.307 + Ise=14.34f Ikf=.2847 Xtb=1.5 Br=6.092 Nc=2 Isc=0 Ikr=0 Rc=1 + Cjc=7.306p Mjc=.3416 Vjc=.75 Fc=.5 Cje=22.01p Mje=.377 Vje=.75 + Tr=46.91n Tf=411.1p Itf=.6 Vtf=1.7 Xtf=3 Rb=10) * National pid=19 case=TO237 * 88-09-07 bam creation * .MODEL TN2905A PNP(Is=650.6E-18 Xti=3 Eg=1.11 Vaf=115.7 Bf=231.7 Ne=1.829 + Ise=54.81f Ikf=1.079 Xtb=1.5 Br=3.563 Nc=2 Isc=0 Ikr=0 Rc=.715 + Cjc=14.76p Mjc=.5383 Vjc=.75 Fc=.5 Cje=19.82p Mje=.3357 Vje=.75 + Tr=111.3n Tf=603.7p Itf=.65 Vtf=5 Xtf=1.7 Rb=10) * National pid=63 case=TO237 * 88-09-09 bam creation * .MODEL TN6714A NPN(Is=62.33f Xti=3 Eg=1.11 Vaf=100 Bf=18.52K Ne=1.265 + Ise=62.33f Ikf=85.68m Xtb=1.5 Br=1.271 Nc=2 Isc=0 Ikr=0 Rc=.5 + Cjc=22.48p Mjc=.4937 Vjc=.75 Fc=.5 Cje=77.63p Mje=.3822 Vje=.75 + Tr=6.16n Tf=1.492n Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=MPSW01 case=TO92 * 88-09-14 bam creation * .MODEL TN6715A NPN(Is=62.33f Xti=3 Eg=1.11 Vaf=100 Bf=18.52K Ne=1.265 + Ise=62.33f Ikf=85.68m Xtb=1.5 Br=1.271 Nc=2 Isc=0 Ikr=0 Rc=.5 + Cjc=22.48p Mjc=.4937 Vjc=.75 Fc=.5 Cje=77.63p Mje=.3822 Vje=.75 + Tr=6.16n Tf=1.492n Itf=0 Vtf=0 Xtf=0 Rb=10) * National pid=MPSW01A case=TO92 * 88-09-14 bam creation * .MODEL TN6726A PNP(Is=24.64f Xti=3 Eg=1.11 Vaf=100 Bf=154.5 Ne=1.5 Ise=0 + Ikf=1.25 Xtb=1.5 Br=1.424 Nc=2 Isc=0 Ikr=0 Rc=.6 Cjc=63.67p + Mjc=.4749 Vjc=.75 Fc=.5 Cje=132.4p Mje=.4174 Vje=.75 Tr=5.721n + Tf=645.4p Itf=.8 Vtf=6 Xtf=4.5 Rb=10) * Valid for: TN6727A * National pid=MPSW51 case=TO92 * 88-09-14 bam creation * .MODEL TN6728A PNP(Is=9.348f Xti=3 Eg=1.11 Vaf=100 Bf=166.8 Ne=1.459 + Ise=12.45f Ikf=10.29 Xtb=1.5 Br=8.369 Nc=2 Isc=0 Ikr=0 Rc=.38 + Cjc=48p Mjc=.5152 Vjc=.75 Fc=.5 Cje=105.6p Mje=.4351 Vje=.75 + Tr=1.021n Tf=685.2p Itf=.3 Vtf=4 Xtf=10 Rb=10) * Valid for: TN6729A * National pid=MPSW55 case=TO92 * 88-09-14 bam creation * .MODEL J2N2608 PJF(Beta=423.6u Rd=1 Rs=1 Lambda=15m Vto=-2.45 + Is=222.4f Cgd=6.7p Pb=1 Fc=.5 Cgs=8.37p) * National pid=89 case=TO18 * 88-07-14 bam BVmin=25 * .MODEL J2N3370 NJF(Beta=766.8u Rd=1 Rs=1 Lambda=9m Vto=-.65 + Is=114.5f Cgd=2.8p Pb=.5 Fc=.5 Cgs=2.916p) * National pid=52 case=TO18 * 88-08-02 rmn BVmin=40 * .MODEL J2N3458 NJF(Beta=700u Rd=1 Rs=1 Lambda=6m Vto=-3.05 + Is=114.5f Cgd=2.8p Pb=.5 Fc=.5 Cgs=2.916p) * National pid=52 case=TO18 * 88-08-02 rmn BVmin=50 * .MODEL J2N3459 NJF(Beta=1.265m Rd=1 Rs=1 Lambda=4m Vto=-1.4 + Is=114.5f Cgd=2.8p Pb=.5 Fc=.5 Cgs=2.916p) * National pid=52 case=TO18 * 88-08-02 rmn BVmin=50 * .MODEL J2N3684 NJF(Beta=348.1u Rd=1 Rs=1 Lambda=11.67m Vto=-3.18 + Is=114.5f Cgd=2p Pb=.5 Fc=.5 Cgs=2.083p) * National pid=52 case=TO72 * 88-08-02 rmn BVmin=50 * .MODEL J2N3685 NJF(Beta=543.4u Rd=1 Rs=1 Lambda=5.833m Vto=-1.691 + Is=114.5f Cgd=2p Pb=.5 Fc=.5 Cgs=2.083p) * National pid=52 case=TO72 * 88-08-02 rmn BVmin=50 * .MODEL J2N3686 NJF(Beta=723.7u Rd=1 Rs=1 Lambda=2.333m Vto=-.957 + Is=114.5f Cgd=2p Pb=.5 Fc=.5 Cgs=2.083p) * National pid=52 case=TO72 * 88-08-02 rmn BVmin=50 * .MODEL J2N3687 NJF(Beta=840u Rd=1 Rs=1 Lambda=1.167m Vto=-.5102 + Is=114.5f Cgd=2p Pb=.5 Fc=.5 Cgs=2.083p) * National pid=52 case=TO72 * 88-08-02 rmn BVmin=50 * .MODEL J2N3821 NJF(Beta=1.517m Rd=1 Rs=1 Lambda=2.045m Vto=-.8467 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=4.627p) * National pid=55 case=TO72 * 88-08-03 rmn BVmin=50 * .MODEL J2N3822 NJF(Beta=1.1m Rd=1 Rs=1 Lambda=4.09m Vto=-1.962 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=4.627p) * National pid=55 case=TO72 * 88-08-03 rmn BVmin=50 * .MODEL J2N3823 NJF(Beta=1.17m Rd=1 Rs=1 Lambda=4m Vto=-3.3 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-01 rmn BVmin=30 * .MODEL J2N3824 NJF(Beta=436.4u Rd=1 Rs=1 Lambda=5.333m Vto=-2.139 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=4.627p) * National pid=55 case=TO72 * 88-08-03 rmn BVmin=50 * .MODEL J2N3921 NJF(Beta=1.57m Rd=1 Rs=1 Lambda=4m Vto=-1.799 + Is=24.55f Cgd=8.8p Pb=1 Fc=.5 Cgs=4.4p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N3922 NJF(Beta=1.57m Rd=1 Rs=1 Lambda=4m Vto=-1.799 + Is=24.55f Cgd=8.8p Pb=1 Fc=.5 Cgs=4.4p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N3954A NJF(Beta=768.3u Rd=1 Rs=1 Lambda=4.25m Vto=-2.033 + Is=24.55f Cgd=1.71p Pb=1 Fc=.5 Cgs=.86p) * Valid for: J2N3954 * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N3955A NJF(Beta=768.3u Rd=1 Rs=1 Lambda=4.25m Vto=-2.033 + Is=24.55f Cgd=1.71p Pb=1 Fc=.5 Cgs=.86p) * Valid for: J2N3955, J2N3956, J2N3957, J2N3958 * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N3966 NJF(Beta=650u Rd=1 Rs=1 Lambda=15m Vto=-4.876 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-01 rmn BVmin=30 * .MODEL J2N3967 NJF(Beta=754.7u Rd=1 Rs=1 Lambda=3.667m Vto=-2.49 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=3.742p) * National pid=55 case=TO72 * 88-08-03 rmn BVmin=30 * .MODEL J2N3970 NJF(Beta=4.032m Rd=1 Rs=1 Lambda=23m Vto=-4.514 + Is=205.2f Cgd=10.48p Pb=1 Fc=.5 Cgs=9.31p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N3971 NJF(Beta=6.313m Rd=1 Rs=1 Lambda=13m Vto=-2.598 + Is=205.2f Cgd=10.48p Pb=1 Fc=.5 Cgs=9.31p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N3972 NJF(Beta=9.109m Rd=1 Rs=1 Lambda=6m Vto=-1.403 + Is=205.2f Cgd=10.48p Pb=1 Fc=.5 Cgs=9.31p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4084 NJF(Beta=1.57m Rd=1 Rs=1 Lambda=4m Vto=-1.799 + Is=24.55f Cgd=8.8p Pb=1 Fc=.5 Cgs=4.4p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N4091 NJF(Beta=2.658m Rd=1 Rs=1 Lambda=11m Vto=-5.743 + Is=205.2f Cgd=7.94p Pb=1 Fc=.5 Cgs=7.06p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4092 NJF(Beta=4.032m Rd=1 Rs=1 Lambda=10m Vto=-2.933 + Is=205.2f Cgd=7.94p Pb=1 Fc=.5 Cgs=7.06p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4093 NJF(Beta=5.695m Rd=1 Rs=1 Lambda=8m Vto=-1.989 + Is=205.2f Cgd=7.94p Pb=1 Fc=.5 Cgs=7.06p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4117 NJF(Beta=33.07u Rd=1 Rs=1 Lambda=13m Vto=-1.2 + Is=5.261f Cgd=3.94p Pb=1 Fc=.5 Cgs=4.93p) * National pid=53 case=TO72 * 88-07-14 bam BVmin=40 * .MODEL J2N4117A NJF(Beta=49.01u Rd=1 Rs=1 Lambda=13m Vto=-1.1 + Is=5.261f Cgd=3.94p Pb=1 Fc=.5 Cgs=4.93p) * National pid=53 case=TO72 * 88-07-14 bam BVmin=40 * .MODEL J2N4118A NJF(Beta=52.58u Rd=1 Rs=1 Lambda=15m Vto=-1.732 + Is=5.261f Cgd=3.94p Pb=1 Fc=.5 Cgs=4.93p) * Valid for: J2N4118 * National pid=53 case=TO72 * 88-07-14 bam BVmin=40 * .MODEL J2N4119A NJF(Beta=68.08u Rd=1 Rs=1 Lambda=19m Vto=-2.536 + Is=5.261f Cgd=3.94p Pb=1 Fc=.5 Cgs=4.93p) * Valid for: J2N4119 * National pid=53 case=TO72 * 88-07-14 bam BVmin=40 * .MODEL J2N4220A NJF(Beta=819.8u Rd=1 Rs=1 Lambda=3.266m Vto=-1.195 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=4.627p) * Valid for: J2N4220 * National pid=55 case=TO72 * 88-08-03 rmn BVmin=30 * .MODEL J2N4221A NJF(Beta=726.3u Rd=1 Rs=1 Lambda=4.15m Vto=-2.139 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=4.627p) * Valid for: J2N4221 * National pid=55 case=TO72 * 88-08-03 rmn BVmin=30 * .MODEL J2N4222A NJF(Beta=436.4u Rd=1 Rs=1 Lambda=5.333m Vto=-4.1 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=4.627p) * Valid for: J2N4222 * National pid=55 case=TO72 * 88-08-03 rmn BVmin=30 * .MODEL J2N4223 NJF(Beta=1.04m Rd=1 Rs=1 Lambda=5.5m Vto=-3.05 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-01 rmn BVmin=30 * .MODEL J2N4338 NJF(Beta=781u Rd=1 Rs=1 Lambda=1.167m Vto=-.6606 + Is=114.5f Cgd=2.8p Pb=.5 Fc=.5 Cgs=2.916p) * National pid=52 case=TO18 * 88-08-02 rmn BVmin=50 * .MODEL J2N4339 NJF(Beta=555.8u Rd=1 Rs=1 Lambda=3.5m Vto=-1.218 + Is=114.5f Cgd=2.8p Pb=.5 Fc=.5 Cgs=2.916p) * National pid=52 case=TO18 * 88-08-02 rmn BVmin=50 * .MODEL J2N4340 NJF(Beta=471u Rd=1 Rs=1 Lambda=7m Vto=-2.001 + Is=114.5f Cgd=2.8p Pb=.5 Fc=.5 Cgs=2.916p) * National pid=52 case=TO18 * 88-08-02 rmn BVmin=50 * .MODEL J2N4341 NJF(Beta=387.1u Rd=1 Rs=1 Lambda=14m Vto=-3.336 + Is=114.5f Cgd=2.8p Pb=.5 Fc=.5 Cgs=2.916p) * National pid=52 case=TO18 * 88-08-02 rmn BVmin=50 * .MODEL J2N4381 PJF(Beta=2.658m Rd=1 Rs=1 Lambda=15m Vto=-1.8 + Is=222.4f Cgd=6.61p Pb=1 Fc=.5 Cgs=8.26p) * National pid=89 case=TO18 * 88-07-14 bam BVmin=25 * .MODEL J2N4391 NJF(Beta=2.658m Rd=1 Rs=1 Lambda=13m Vto=-5.803 + Is=205.2f Cgd=5.35p Pb=1 Fc=.5 Cgs=4.76p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4392 NJF(Beta=5.108m Rd=1 Rs=1 Lambda=10m Vto=-3.018 + Is=205.2f Cgd=4.83p Pb=1 Fc=.5 Cgs=4.29p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4393 NJF(Beta=9.109m Rd=1 Rs=1 Lambda=6m Vto=-1.422 + Is=205.2f Cgd=4.57p Pb=1 Fc=.5 Cgs=4.06p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4416A NJF(Beta=989.4u Rd=1 Rs=1 Lambda=5.5m Vto=-3.06 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * Valid for: J2N4416 * National pid=50 case=TO72 * 88-08-01 rmn BVmin=35 * .MODEL J2N4856 NJF(Beta=3.084m Rd=1 Rs=1 Lambda=11m Vto=-5.517 + Is=205.2f Cgd=15.92p Pb=1 Fc=.5 Cgs=14.16p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4856A NJF(Beta=3.084m Rd=1 Rs=1 Lambda=11m Vto=-5.517 + Is=205.2f Cgd=5.71p Pb=1 Fc=.5 Cgs=5.07p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4857 NJF(Beta=6.313m Rd=1 Rs=1 Lambda=9.5m Vto=-3.05 + Is=205.2f Cgd=15.92p Pb=1 Fc=.5 Cgs=14.16p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4857A NJF(Beta=6.313m Rd=1 Rs=1 Lambda=9.5m Vto=-3.05 + Is=205.2f Cgd=5.34p Pb=1 Fc=.5 Cgs=4.74p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4858 NJF(Beta=7.646m Rd=1 Rs=1 Lambda=8m Vto=-2.387 + Is=205.2f Cgd=15.92p Pb=1 Fc=.5 Cgs=14.16p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4858A NJF(Beta=7.646m Rd=1 Rs=1 Lambda=8m Vto=-2.387 + Is=205.2f Cgd=5.34p Pb=1 Fc=.5 Cgs=4.74p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4859 NJF(Beta=3.084m Rd=1 Rs=1 Lambda=12m Vto=-5.431 + Is=205.2f Cgd=15.92p Pb=1 Fc=.5 Cgs=14.16p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=30 * .MODEL J2N4859A NJF(Beta=3.084m Rd=1 Rs=1 Lambda=12m Vto=-5.431 + Is=205.2f Cgd=5.71p Pb=1 Fc=.5 Cgs=5.07p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=40 * .MODEL J2N4860 NJF(Beta=6.313m Rd=1 Rs=1 Lambda=10m Vto=-2.998 + Is=205.2f Cgd=15.92p Pb=1 Fc=.5 Cgs=14.16p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=30 * .MODEL J2N4860A NJF(Beta=6.313m Rd=1 Rs=1 Lambda=10m Vto=-2.998 + Is=205.2f Cgd=5.34p Pb=1 Fc=.5 Cgs=4.74p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=30 * .MODEL J2N4861 NJF(Beta=8.362m Rd=1 Rs=1 Lambda=8m Vto=-2.308 + Is=205.2f Cgd=15.92p Pb=1 Fc=.5 Cgs=14.16p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=30 * .MODEL J2N4861A NJF(Beta=8.362m Rd=1 Rs=1 Lambda=8m Vto=-2.308 + Is=205.2f Cgd=5.34p Pb=1 Fc=.5 Cgs=4.74p) * National pid=51 case=TO18 * 88-07-13 bam BVmin=30 * .MODEL J2N5018 PJF(Beta=772.5u Rd=1 Rs=1 Lambda=40m Vto=-4.15 + Is=461.5f Cgd=6.5p Pb=1 Fc=.5 Cgs=9p) * National pid=88 case=TO18 * 88-08-04 rmn BVmin=30 * .MODEL J2N5019 PJF(Beta=1.775m Rd=1 Rs=1 Lambda=24m Vto=-2.229 + Is=461.5f Cgd=6.5p Pb=1 Fc=.5 Cgs=9p) * National pid=88 case=TO18 * 88-08-04 rmn BVmin=30 * .MODEL J2N5020 PJF(Beta=1.004m Rd=1 Rs=1 Lambda=10m Vto=-.8406 + Is=222.4f Cgd=8.55p Pb=1 Fc=.5 Cgs=10.68p) * National pid=89 case=TO18 * 88-07-14 bam BVmin=25 * .MODEL J2N5021 PJF(Beta=2.658m Rd=1 Rs=1 Lambda=12m Vto=-.9996 + Is=222.4f Cgd=8.55p Pb=1 Fc=.5 Cgs=10.68p) * National pid=89 case=TO18 * 88-07-14 bam BVmin=25 * .MODEL J2N5045 NJF(Beta=1.271m Rd=1 Rs=1 Lambda=3.5m Vto=-1.95 + Is=24.55f Cgd=5.71p Pb=1 Fc=.5 Cgs=2.85p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5046 NJF(Beta=1.271m Rd=1 Rs=1 Lambda=3.5m Vto=-1.95 + Is=24.55f Cgd=5.71p Pb=1 Fc=.5 Cgs=2.85p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5047 NJF(Beta=1.271m Rd=1 Rs=1 Lambda=3.5m Vto=-1.95 + Is=24.55f Cgd=5.71p Pb=1 Fc=.5 Cgs=2.85p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5078 NJF(Beta=850.8u Rd=1 Rs=1 Lambda=6.75m Vto=-3.97 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-01 rmn BVmin=30 * .MODEL J2N5103 NJF(Beta=1.426m Rd=1 Rs=1 Lambda=3.167m Vto=-1.85 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-01 rmn BVmin=25 * .MODEL J2N5105 NJF(Beta=1.464m Rd=1 Rs=1 Lambda=3.167m Vto=-2.5 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-01 rmn BVmin=25 * .MODEL J2N5114 PJF(Beta=510.2u Rd=1 Rs=1 Lambda=40m Vto=-8.095 + Is=461.5f Cgd=6.5p Pb=1 Fc=.5 Cgs=9p) * National pid=88 case=TO18 * 88-08-04 rmn BVmin=30 * .MODEL J2N5116 PJF(Beta=1.71m Rd=1 Rs=1 Lambda=25m Vto=-2.373 + Is=461.5f Cgd=6.5p Pb=1 Fc=.5 Cgs=9p) * National pid=88 case=TO18 * 88-08-04 rmn BVmin=30 * .MODEL J2N5196 NJF(Beta=812.9u Rd=1 Rs=1 Lambda=5m Vto=-2.257 + Is=24.55f Cgd=3.28p Pb=1 Fc=.5 Cgs=1.64p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5197 NJF(Beta=812.9u Rd=1 Rs=1 Lambda=5m Vto=-2.257 + Is=24.55f Cgd=3.28p Pb=1 Fc=.5 Cgs=1.64p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5199 NJF(Beta=812.9u Rd=1 Rs=1 Lambda=5m Vto=-2.257 + Is=24.55f Cgd=3.28p Pb=1 Fc=.5 Cgs=1.64p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5358 NJF(Beta=1.064m Rd=1 Rs=1 Lambda=2.571m Vto=-.8005 + Is=181.3f Cgd=4p Pb=.5 Fc=.5 Cgs=4.627p) * National pid=55 case=TO72 * 88-08-03 rmn BVmin=40 * .MODEL J2N5397 NJF(Beta=1.242m Rd=1 Rs=1 Lambda=8m Vto=-3.679 + Is=101.9f Cgd=2.6p Pb=1 Fc=.5 Cgs=3.598p) * National pid=90 case=TO72 * 88-08-05 rmn BVmin=25 * .MODEL J2N5398 NJF(Beta=1.242m Rd=1 Rs=1 Lambda=8m Vto=-3.323 + Is=101.9f Cgd=3p Pb=1 Fc=.5 Cgs=3.383p) * National pid=90 case=TO72 * 88-08-05 rmn BVmin=25 * .MODEL J2N5432 NJF(Beta=9.109m Rd=1 Rs=1 Lambda=50m Vto=-5.397 + Is=533.7f Cgd=35.6p Pb=1 Fc=.5 Cgs=35.6p) * National pid=58 case=TO52 * 88-07-14 bam BVmin=25 * .MODEL J2N5433 NJF(Beta=12.42m Rd=1 Rs=1 Lambda=40m Vto=-4.16 + Is=533.7f Cgd=35.6p Pb=1 Fc=.5 Cgs=35.6p) * National pid=58 case=TO52 * 88-07-14 bam BVmin=25 * .MODEL J2N5434 NJF(Beta=18.37m Rd=1 Rs=1 Lambda=25m Vto=-1.906 + Is=533.7f Cgd=35.6p Pb=1 Fc=.5 Cgs=35.6p) * National pid=58 case=TO52 * 88-07-14 bam BVmin=25 * .MODEL J2N5452 NJF(Beta=768.3u Rd=1 Rs=1 Lambda=2.5m Vto=-2.017 + Is=24.55f Cgd=1.71p Pb=1 Fc=.5 Cgs=.86p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5454 NJF(Beta=768.3u Rd=1 Rs=1 Lambda=2.5m Vto=-2.017 + Is=24.55f Cgd=1.71p Pb=1 Fc=.5 Cgs=.86p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5515 NJF(Beta=518.5u Rd=1 Rs=1 Lambda=300u Vto=-2.5 + Is=52.8f Cgd=8p Pb=.5 Fc=.5 Cgs=14.64p) * Valid for: J2N5516-...J2N5524 * National pid=95 case=TO71 * 88-08-05 rmn BVmin=40 * .MODEL J2N5545 NJF(Beta=1.271m Rd=1 Rs=1 Lambda=4m Vto=-2 + Is=24.55f Cgd=3.28p Pb=1 Fc=.5 Cgs=1.64p) * National pid=83 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL J2N5556 NJF(Beta=2.194m Rd=1 Rs=1 Lambda=3.8m Vto=-.875 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-02 rmn BVmin=30 * .MODEL J2N5557 NJF(Beta=1.307m Rd=1 Rs=1 Lambda=4m Vto=-1.805 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-02 rmn BVmin=30 * .MODEL J2N5558 NJF(Beta=864u Rd=1 Rs=1 Lambda=6.75m Vto=-2.91 + Is=33.57f Cgd=1.6p Pb=1 Fc=.5 Cgs=2.414p) * National pid=50 case=TO72 * 88-08-02 rmn BVmin=30 * .MODEL J2N5565 NJF(Beta=9.109m Rd=1 Rs=1 Lambda=7.5m Vto=-1.447 + Is=94.42f Cgd=8.67p Pb=1 Fc=.5 Cgs=9.76p) * Valid for: J2N5566 * National pid=96 case=TO71 * 88-07-15 bam BVmin=40 * .MODEL J2N5902 NJF(Beta=120u Rd=1 Rs=1 Lambda=900u Vto=-1.652 + Is=16.33f Cgd=1.23p Pb=1 Fc=.5 Cgs=1.23p) * Valid for: J2N5904, J2N5906, J2N5907, J2N5909 * National pid=84 case=TO78 * 88-07-14 bam BVmin=40 * .MODEL J2N5905 NJF(Beta=120u Rd=1 Rs=1 Lambda=700u Vto=-1.652 + Is=16.33f Cgd=1.23p Pb=1 Fc=.5 Cgs=1.23p) * National pid=84 case=TO78 * 88-07-14 bam BVmin=40 * .MODEL J2N5911 NJF(Beta=2.203m Rd=1 Rs=1 Lambda=12m Vto=-2.694 + Is=94.35f Cgd=2.822p Pb=1 Fc=.5 Cgs=3.65p) * Valid for: J2N5912 * National pid=93 case=TO78 * 88-08-05 rmn BVmin=25 * .MODEL J2N6483 NJF(Beta=518.5u Rd=1 Rs=1 Lambda=300u Vto=-2.5 + Is=52.8f Cgd=8p Pb=.5 Fc=.5 Cgs=14.64p) * Valid for: J2N6484, J2N6485 * National pid=95 case=TO71 * 88-08-05 rmn BVmin=50 * .MODEL J401 NJF(Beta=1.577m Rd=1 Rs=1 Lambda=10m Vto=-1.316 + Is=19.73f Cgd=5.6p Pb=.5 Fc=.5 Cgs=6.044p) * Valid for: J402-...J406 * National pid=98 case=8-Pin DIP * 88-08-05 rmn BVmin=50 * .MODEL J410 NJF(Beta=858.8u Rd=1 Rs=1 Lambda=3.5m Vto=-2 + Is=24.55f Cgd=2p Pb=1 Fc=.5 Cgs=1p) * Valid for J411, J412 * National pid=83 case=8-Pin DIP * 88-07-15 bam BVmin=40 * .MODEL NF5101 NJF(Beta=12.42m Rd=1 Rs=1 Lambda=3m Vto=-.7414 + Is=205.2f Cgd=10.76p Pb=1 Fc=.5 Cgs=9.56p) * National pid=51 case=TO72 * 88-07-13 bam BVmin=40 * .MODEL NF5102 NJF(Beta=14.28m Rd=1 Rs=1 Lambda=8m Vto=-1.001 + Is=205.2f Cgd=10.76p Pb=1 Fc=.5 Cgs=9.56p) * National pid=51 case=TO72 * 88-07-13 bam BVmin=40 * .MODEL NF5103 NJF(Beta=14.28m Rd=1 Rs=1 Lambda=9m Vto=-1.4 + Is=205.2f Cgd=10.76p Pb=1 Fc=.5 Cgs=9.56p) * National pid=51 case=TO72 * 88-07-13 bam BVmin=40 * .MODEL NF5301 NJF(Beta=62.04u Rd=1 Rs=1 Lambda=15m Vto=-1.887 + Is=5.261f Cgd=3.94p Pb=1 Fc=.5 Cgs=4.93p) * National pid=53 case=TO72 * 88-07-14 bam BVmin=30 * .MODEL NDF9406 NJF(Beta=1.004m Rd=1 Rs=1 Lambda=2m Vto=-2.25 + Is=32.73f Cgd=4.2p Pb=1 Fc=.5 Cgs=2.1p) * Valid for: NDF9407, NDF9409, NDF9410 * National pid=94 case=TO71 * 88-07-15 bam BVmin=50 * .MODEL U257 NJF(Beta=2.203m Rd=1 Rs=1 Lambda=12m Vto=-2.475 + Is=94.35f Cgd=2.822p Pb=1 Fc=.5 Cgs=3.65p) * National pid=93 case=TO78 * 88-08-05 rmn BVmin=25 * .MODEL U308 NJF(Beta=4.337m Rd=1 Rs=1 Lambda=16m Vto=-2.852 + Is=193.9f Cgd=5p Pb=1 Fc=.5 Cgs=5p) * National pid=92 case=TO52 * 88-07-14 bam BVmin=25 * .MODEL U309 NJF(Beta=5.04m Rd=1 Rs=1 Lambda=14m Vto=-2.026 + Is=193.9f Cgd=5p Pb=1 Fc=.5 Cgs=5p) * National pid=92 case=TO52 * 88-07-14 bam BVmin=25 * .MODEL U310 NJF(Beta=3.688m Rd=1 Rs=1 Lambda=17m Vto=-3.324 + Is=193.9f Cgd=7.4p Pb=1 Fc=.5 Cgs=7.4p) * National pid=92 case=TO52 * 88-07-14 bam BVmin=25 * .MODEL U401 NJF(Beta=1.577m Rd=1 Rs=1 Lambda=10m Vto=-1.316 + Is=19.73f Cgd=5.6p Pb=.5 Fc=.5 Cgs=6.044p) * Valid for: U402-...U410 * National pid=98 case=TO71 * 88-08-05 rmn BVmin=50 * .MODEL U440 NJF(Beta=1.978m Rd=1 Rs=1 Lambda=30m Vto=-2.839 + Is=36.18f Cgd=2.11p Pb=1 Fc=.5 Cgs=2.47p) * Valid for: U441 * National pid=NZF-D case=TO71 * 88-07-18 bam BVmin=25 * *LF155 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF155 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV *NOTE:Asymetrical slew rate not modeled. *Use default gm=1e12 * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX155 J2 6 7 4 JX155 R3 5 50 20K R4 6 50 20K C4 5 6 1.9894E-13 I2 99 50 1.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX155 D2 10 9 DX155 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 9.6796E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 9.6796E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 67.154P G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX155 VA7 99 21 0 D6 23 99 DX155 E1 99 26 99 9 1 VA8 26 27 0 R16 27 28 25 V5 28 25 -.1V D4 25 9 DX155 V4 24 28 -.1V D3 9 24 DX155 .ENDS LF155 .MODEL DX155 D(IS=1E-15) .MODEL JX155 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF156 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF156 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX156 J2 6 7 4 JX156 R3 5 50 20K R4 6 50 20K C4 5 6 1.9894E-13 I2 99 50 4.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX156 D2 10 9 DX156 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 1.5944E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 1.5944E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 49.9798P G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX156 VA7 99 21 0 D6 23 99 DX156 E1 99 26 99 9 1 VA8 26 27 0 R16 27 28 20 V5 28 25 -.25 D4 25 9 DX156 V4 24 28 -.25 D3 9 24 DX156 .ENDS LF156 .MODEL DX156 D(IS=1E-15) .MODEL JX156 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF157 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF157 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX157 J2 6 7 4 JX157 R3 5 50 20K R4 6 50 20K C4 5 6 3.31573E-13 I2 99 50 4.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX157 D2 10 9 DX157 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 8.1291E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 8.1291E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 7.10513P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 8.3766E-15 G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX157 VA7 99 21 0 D6 23 99 DX157 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 25 V5 28 25 0.1V D4 25 15 DX157 V4 24 28 0.1V D3 15 24 DX157 .ENDS LF157 .MODEL DX157 D(IS=1E-15) .MODEL JX157 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF255 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF255 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV *NOTE:Asymetrical slew rate not modeled. * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX255 J2 6 7 4 JX255 R3 5 50 20K R4 6 50 20K C4 5 6 1.9894E-13 I2 99 50 1.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX255 D2 10 9 DX255 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 9.6796E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 8.1291E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 67.154P G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX255 VA7 99 21 0 D6 23 99 DX255 E1 99 26 99 9 1 VA8 26 27 0 R16 27 28 25 V5 28 25 -.1V D4 25 9 DX255 V4 24 28 -.1V D3 9 24 DX255 .ENDS LF255 .MODEL DX255 D(IS=1E-15) .MODEL JX255 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF256 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF256 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX256 J2 6 7 4 JX256 R3 5 50 20K R4 6 50 20K C4 5 6 1.9894E-13 I2 99 50 4.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX256 D2 10 9 DX256 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 1.5944E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 1.5944E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 49.9798P G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX256 VA7 99 21 0 D6 23 99 DX256 E1 99 26 99 9 1 VA8 26 27 0 R16 27 28 20 V5 28 25 -.25V D4 25 9 DX256 V4 24 28 -.25V D3 9 24 DX256 .ENDS LF256 .MODEL DX256 D(IS=1E-15) .MODEL JX256 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF257 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF257 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX257 J2 6 7 4 JX257 R3 5 50 20K R4 6 50 20K C4 5 6 3.31573E-13 I2 99 50 4.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX257 D2 10 9 DX257 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 8.1291E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 8.1291E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 7.10513P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 8.3766E-15 G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX257 VA7 99 21 0 D6 23 99 DX257 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 25 V5 28 25 0.1V D4 25 15 DX257 V4 24 28 0.1V D3 15 24 DX257 .ENDS LF257 .MODEL DX257 D(IS=1E-15) .MODEL JX257 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF351 Wide Bandwidth JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF351 1 2 99 50 28 * *Features: *Low supply current = 1.8mA *Wide bandwidth = 4MHz *High slew rate = 13V/uS *Low offset voltage = 10mV * IOS 2 1 25P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX351 J2 6 7 4 JX351 R3 5 50 20K R4 6 50 20K C4 5 6 3.31573E-13 I2 99 50 1.7MA *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.13 D1 9 8 DX351 D2 10 9 DX351 V3 10 50 2.13 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 1.0985E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 1.0985E7*i(VA3)^3 G1 98 9 5 6 1E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 39.493P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 3.7894E-15 G4 98 16 3 49 1E-8 L2 98 17 31.831M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX351 VA7 99 21 0 D6 23 99 DX351 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 35 V5 28 25 0.1V D4 25 15 DX351 V4 24 28 0.1V D3 15 24 DX351 .ENDS LF351 .MODEL DX351 D(IS=1E-15) .MODEL JX351 PJF(BETA=1.25E-5 VTO=-2.00 IS=50E-12) * *LF353 Wide Bandwidth Dual JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF353 1 2 99 50 28 * *Features: *Low supply current = 1.8mA *Wide bandwidth = 4MHz *High slew rate = 13V/uS *Low offset voltage = 10mV * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * IOS 2 1 25P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX353 J2 6 7 4 JX353 R3 5 50 20K R4 6 50 20K C4 5 6 3.31573E-13 I2 99 50 1.7MA *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.13 D1 9 8 DX353 D2 10 9 DX353 V3 10 50 2.13 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 1.0985E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 1.0985E7*i(VA3)^3 G1 98 9 5 6 1E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 39.493P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 3.7894E-15 G4 98 16 3 49 1E-8 L2 98 17 31.831M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX353 VA7 99 21 0 D6 23 99 DX353 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 35 V5 28 25 0.1V D4 25 15 DX353 V4 24 28 0.1V D3 15 24 DX353 .ENDS LF353 .MODEL DX353 D(IS=1E-15) .MODEL JX353 PJF(BETA=1.25E-5 VTO=-2.00 IS=50E-12) * *LF355 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF355 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV *NOTE:Asymetrical slew rate not modeled. * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX355 J2 6 7 4 JX355 R3 5 50 20K R4 6 50 20K C4 5 6 1.9894E-13 I2 99 50 1.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX355 D2 10 9 DX355 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 9.6796E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 9.6796E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 67.154P G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX355 VA7 99 21 0 D6 23 99 DX355 E1 99 26 99 9 1 VA8 26 27 0 R16 27 28 25 V5 28 25 -.1V D4 25 9 DX355 V4 24 28 -.1V D3 9 24 DX355 .ENDS LF355 .MODEL DX355 D(IS=1E-15) .MODEL JX355 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF356 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF356 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX356 J2 6 7 4 JX356 R3 5 50 20K R4 6 50 20K C4 5 6 1.9894E-13 I2 99 50 4.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX356 D2 10 9 DX356 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 1.5944E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 1.5944E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 49.9798P G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX356 VA7 99 21 0 D6 23 99 DX356 E1 99 26 99 9 1 VA8 26 27 0 R16 27 28 20 V5 28 25 -.25V D4 25 9 DX356 V4 24 28 -.25V D3 9 24 DX356 .ENDS LF356 .MODEL DX356 D(IS=1E-15) .MODEL JX356 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF357 Monolithic JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF357 1 2 99 50 28 * *Features: *Low input bias current = 30pA *Low input offset current = 3pA *High input impedance = 1Tohm *Low input offset voltage = 1mV * IOS 2 1 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX357 J2 6 7 4 JX357 R3 5 50 20K R4 6 50 20K C4 5 6 3.31573E-13 I2 99 50 4.65MA *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.63 D1 9 8 DX357 D2 10 9 DX357 V3 10 50 2.63 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 8.1291E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 8.1291E7*i(VA3)^3 G1 98 9 5 6 2E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 7.10513P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 8.3766E-15 G4 98 16 3 49 1E-8 L2 98 17 530.52M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX357 VA7 99 21 0 D6 23 99 DX357 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 25 V5 28 25 0.1V D4 25 15 DX357 V4 24 28 0.1V D3 15 24 DX357 .ENDS LF357 .MODEL DX357 D(IS=1E-15) .MODEL JX357 PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12) * *LF411 LOW OFFSET, LOW DRIFT JFET INPUT OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF411 1 2 99 50 28 * *Features: *Fast settling time (.01%) = 2uS *High bandwidth = 3MHz *High slew rate = 10V/uS *Low offset voltage = .5mV *Low supply current = 1.8mA * IOS 2 1 25.0P CI1 1 0 3P CI2 2 0 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 1.0M J1 5 2 4 JX411 J2 6 7 4 JX411 R3 5 50 650 R4 6 50 650 C4 5 6 4.372P I2 99 50 800UA *EOS 7 1 POLY(1) 16 49 .8E-3 1 BOS 7 1 v= 0.8E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 2.13 D1 9 8 DX411 D2 10 9 DX411 V3 10 50 2.13 EH 99 98 99 49 1 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 857.516P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 5.305E-15 G4 98 16 3 49 1E-8 L2 98 17 144.7M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX411 VA7 99 21 0 D6 23 99 DX411 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 50 V5 28 25 0.646V D4 25 15 DX411 V4 24 28 0.646V D3 15 24 DX411 .ENDS LF411 .MODEL DX411 D(IS=1E-15) .MODEL JX411 PJF(BETA=1.183E-3 VTO=-.65 IS=50E-12) * *LF412 LOW OFFSET, LOW DRIFT DUAL JFET INPUT OP-AMP MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF412 1 2 99 50 28 * *Features: *Fast settling time (.01%) = 2uS *High bandwidth = 3MHz *High slew rate = 10V/uS *Low offset voltage = 1mV *Low supply current = 1.8mA *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * IOS 2 1 25.0P CI1 1 0 3P CI2 2 0 3P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 1.0M J1 5 2 4 JX412 J2 6 7 4 JX412 R3 5 50 650 R4 6 50 650 C4 5 6 4.372P I2 99 50 800UA *EOS 7 1 POLY(1) 16 49 1E-3 1 BOS 7 1 v= 1E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 2.13 D1 9 8 DX412 D2 10 9 DX412 V3 10 50 2.13 EH 99 98 99 49 1 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 857.516P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 5.305E-15 G4 98 16 3 49 1E-8 L2 98 17 144.7M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX412 VA7 99 21 0 D6 23 99 DX412 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 50 V5 28 25 0.646V D4 25 15 DX412 V4 24 28 0.646V D3 15 24 DX412 .ENDS LF412 .MODEL DX412 D(IS=1E-15) .MODEL JX412 PJF(BETA=1.183E-3 VTO=-.65 IS=50E-12) * * LF441A Low Offset, Low Power JFET Input Operational Amplifier * * Connections: Non-inverting input * | Inverting input * | | Positive power supply * | | | Negative power supply * | | | | Output * | | | | | * | | | | | .SUBCKT LF441A 1 2 99 50 28 * * Features: * Low input bias current = 10pA * High bandwidth = 1MHz * High slew rate = 1V/uS * Low offset voltage (max) = 0.5mV * Low supply current = 150uA * IOS 2 1 2.5P CI1 1 50 2.5P CI2 2 50 2.5P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U IB1 4 7 48P IB2 4 2 48P J1 5 2 4 JX441A J2 6 7 4 JX441A R3 5 50 3.956K R4 6 50 3.956K C4 31 6 7P R20 31 5 1500 I2 99 50 44UA *EOS 7 1 POLY(1) 16 49 5E-4 1 BOS 7 1 v= 5E-4 + 1*v(16,49) R8 99 49 1.25E6 R9 49 50 1.25E6 V2 99 8 2.63 D1 9 8 DX441A D2 10 9 DX441A V3 10 50 2.63 D7 22 99 DX441A D8 50 22 DX441A EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 2E6 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 2E6*i(VA3)^3 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 1385P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1E-15 *G4 98 16 POLY(2) 1 49 2 49 0 0.5E-8 0.5E-8 B4 98 16 i= 0 + 0.5E-8*v(1,49) + 0.5E-8*v(2,49) L2 98 17 5.1 R13 17 16 1K *F6 50 99 POLY(1) V6 30U 1 B6 50 99 i= 30E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 675 D5 26 24 DX441A V6 26 22 0.63V R17 23 25 250 D6 25 27 DX441A V7 22 27 0.63V V5 22 30 6.35V R19 21 30 1.2E6 D4 21 15 DX441A V4 29 22 0.63V R18 20 29 24K D3 15 20 DX441A L3 22 28 1U .ENDS LF441A .MODEL DX441A D(IS=1E-15) .MODEL JX441A PJF(BETA=9.201E-5 VTO=-2.33 IS=10E-12) * * LF441B Low Power JFET Input Operational Amplifier * * Connections: Non-inverting input * | Inverting input * | | Positive power supply * | | | Negative power supply * | | | | Output * | | | | | * | | | | | .SUBCKT LF441B 1 2 99 50 28 * * Features: * Low input bias current = 10pA * High bandwidth = 1MHz * High slew rate = 1V/uS * Low offset voltage (max) = 5mV * Low supply current = 150uA * IOS 2 1 2.5P CI1 1 50 2.5P CI2 2 50 2.5P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U IB1 4 7 48P IB2 4 2 48P J1 5 2 4 JX441B J2 6 7 4 JX441B R3 5 50 3.956K R4 6 50 3.956K C4 31 6 7P R20 31 5 1500 I2 99 50 44UA *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 1.25E6 R9 49 50 1.25E6 V2 99 8 2.63 D1 9 8 DX441B D2 10 9 DX441B V3 10 50 2.63 D7 22 99 DX441B D8 50 22 DX441B EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 2E6 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 2E6*i(VA3)^3 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 1385P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1E-15 *G4 98 16 POLY(2) 1 49 2 49 0 0.5E-8 0.5E-8 B4 98 16 i= 0 + 0.5E-8*v(1,49) + 0.5E-8*v(2,49) L2 98 17 5.1 R13 17 16 1K *F6 50 99 POLY(1) V6 30U 1 B6 50 99 i= 30E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 675 D5 26 24 DX441B V6 26 22 0.63V R17 23 25 250 D6 25 27 DX441B V7 22 27 0.63V V5 22 30 6.35V R19 21 30 1.2E6 D4 21 15 DX441B V4 29 22 0.63V R18 20 29 24K D3 15 20 DX441B L3 22 28 1U .ENDS LF441B .MODEL DX441B D(IS=1E-15) .MODEL JX441B PJF(BETA=9.201E-5 VTO=-2.33 IS=10E-12) * * LF442A Dual Low Power JFET Input Operational Amplifier * * Connections: Non-inverting input * | Inverting input * | | Positive power supply * | | | Negative power supply * | | | | Output * | | | | | * | | | | | .SUBCKT LF442A 1 2 99 50 28 * * Features: * Low input bias current = 10pA * High bandwidth = 1MHz * High slew rate = 1V/uS * Low offset voltage (max) = 1mV * Low supply current = 150uA/Amplifier * * Note: Model is for single device only and simulated * supply current is 1/2 of total device current. * IOS 2 1 2.5P CI1 1 50 2.5P CI2 2 50 2.5P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U IB1 4 7 48P IB2 4 2 48P J1 5 2 4 JX442A J2 6 7 4 JX442A R3 5 50 3.956K R4 6 50 3.956K C4 31 6 7P R20 31 5 1500 I2 99 50 44UA *EOS 7 1 POLY(1) 16 49 1E-3 1 BOS 7 1 v= 1E-3 + 1*v(16,49) R8 99 49 1.25E6 R9 49 50 1.25E6 V2 99 8 2.63 D1 9 8 DX442A D2 10 9 DX442A V3 10 50 2.63 D7 22 99 DX442A D8 50 22 DX442A EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 2E6 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 2E6*i(VA3)^3 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 1385P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1E-15 *G4 98 16 POLY(2) 1 49 2 49 0 0.5E-8 0.5E-8 B4 98 16 i= 0 + 0.5E-8*v(1,49) + 0.5E-8*v(2,49) L2 98 17 5.1 R13 17 16 1K *F6 50 99 POLY(1) V6 30U 1 B6 50 99 i= 30E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 675 D5 26 24 DX442A V6 26 22 0.63V R17 23 25 250 D6 25 27 DX442A V7 22 27 0.63V V5 22 30 6.35V R19 21 30 1.2E6 D4 21 15 DX442A V4 29 22 0.63V R18 20 29 24K D3 15 20 DX442A L3 22 28 1U .ENDS LF442A .MODEL DX442A D(IS=1E-15) .MODEL JX442A PJF(BETA=9.201E-5 VTO=-2.33 IS=10E-12) * * LF442B Dual Low Power JFET Input Operational Amplifier * * Connections: Non-inverting input * | Inverting input * | | Positive power supply * | | | Negative power supply * | | | | Output * | | | | | * | | | | | .SUBCKT LF442B 1 2 99 50 28 * * Features: * Low input bias current = 10pA * High bandwidth = 1MHz * High slew rate = 1V/uS * Low offset voltage (max) = 5mV * Low supply current = 200uA/Amplifier * * Note: Model is for single device only and simulated * supply current is 1/2 of total device current. * IOS 2 1 2.5P CI1 1 50 2.5P CI2 2 50 2.5P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U IB1 4 7 48P IB2 4 2 48P J1 5 2 4 JX442B J2 6 7 4 JX442B R3 5 50 3.956K R4 6 50 3.956K C4 31 6 7P R20 31 5 1500 I2 99 50 94UA *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 1.25E6 R9 49 50 1.25E6 V2 99 8 2.63 D1 9 8 DX442B D2 10 9 DX442B V3 10 50 2.63 D7 22 99 DX442B D8 50 22 DX442B EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 2E6 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 2E6*i(VA3)^3 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 1385P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1E-15 *G4 98 16 POLY(2) 1 49 2 49 0 0.5E-8 0.5E-8 B4 98 16 i= 0 + 0.5E-8*v(1,49) + 0.5E-8*v(2,49) L2 98 17 5.1 R13 17 16 1K *F6 50 99 POLY(1) V6 30U 1 B6 50 99 i= 30E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 675 D5 26 24 DX442B V6 26 22 0.63V R17 23 25 250 D6 25 27 DX442B V7 22 27 0.63V V5 22 30 6.35V R19 21 30 1.2E6 D4 21 15 DX442B V4 29 22 0.63V R18 20 29 24K D3 15 20 DX442B L3 22 28 1U .ENDS LF442B .MODEL DX442B D(IS=1E-15) .MODEL JX442B PJF(BETA=9.201E-5 VTO=-2.33 IS=10E-12) * * LF444A Quad Low Power JFET Input Operational Amplifier * * Connections: Non-inverting input * | Inverting input * | | Positive power supply * | | | Negative power supply * | | | | Output * | | | | | * | | | | | .SUBCKT LF444A 1 2 99 50 28 * * Features: * Low input bias current = 10pA * High bandwidth = 1MHz * High slew rate = 1V/uS * Low offset voltage (max) = 5mV * Low supply current = 150uA/Amplifier * * Note: Model is for single device only and simulated * supply current is 1/4 of total device current. * IOS 2 1 2.5P CI1 1 50 2.5P CI2 2 50 2.5P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U IB1 4 7 48P IB2 4 2 48P J1 5 2 4 JX444A J2 6 7 4 JX444A R3 5 50 3.956K R4 6 50 3.956K C4 31 6 7P R20 31 5 1500 I2 99 50 44UA *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 1.25E6 R9 49 50 1.25E6 V2 99 8 2.63 D1 9 8 DX444A D2 10 9 DX444A V3 10 50 2.63 D7 22 99 DX444A D8 50 22 DX444A EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 2E6 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 2E6*i(VA3)^3 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 1385P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1E-15 *G4 98 16 POLY(2) 1 49 2 49 0 0.5E-8 0.5E-8 B4 98 16 i= 0 + 0.5E-8*v(1,49) + 0.5E-8*v(2,49) L2 98 17 5.1 R13 17 16 1K *F6 50 99 POLY(1) V6 30U 1 B6 50 99 i= 30E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 675 D5 26 24 DX444A V6 26 22 0.63V R17 23 25 187 D6 25 27 DX444A V7 22 27 0.63V V5 22 30 6.35V R19 21 30 1.2E6 D4 21 15 DX444A V4 29 22 0.63V R18 20 29 24K D3 15 20 DX444A L3 22 28 1U .ENDS LF444A .MODEL DX444A D(IS=1E-15) .MODEL JX444A PJF(BETA=9.201E-5 VTO=-2.33 IS=10E-12) * * LF444B Quad Low Power JFET Input Operational Amplifier * * Connections: Non-inverting input * | Inverting input * | | Positive power supply * | | | Negative power supply * | | | | Output * | | | | | * | | | | | .SUBCKT LF444B 1 2 99 50 28 * * Features: * Low input bias current = 10pA * High bandwidth = 1MHz * High slew rate = 1V/uS * Low offset voltage (max) = 10mV * Low supply current = 200uA/Amplifier * * Note: Model is for single device only and simulated * supply current is 1/4 of total device current. * IOS 2 1 2.5P CI1 1 50 2.5P CI2 2 50 2.5P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U IB1 4 7 48P IB2 4 2 48P J1 5 2 4 JX444B J2 6 7 4 JX444B R3 5 50 3.956K R4 6 50 3.956K C4 31 6 7P R20 31 5 1500 I2 99 50 94UA *EOS 7 1 POLY(1) 16 49 1E-2 1 BOS 7 1 v= 1E-2 + 1*v(16,49) R8 99 49 1.25E6 R9 49 50 1.25E6 V2 99 8 2.63 D1 9 8 DX444B D2 10 9 DX444B V3 10 50 2.63 D7 22 99 DX444B D8 50 22 DX444B EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 2E6 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 2E6*i(VA3)^3 G1 98 9 5 6 20E-3 R5 98 9 10MEG VA3 9 11 0 C3 98 11 1385P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1E-15 *G4 98 16 POLY(2) 1 49 2 49 0 0.5E-8 0.5E-8 B4 98 16 i= 0 + 0.5E-8*v(1,49) + 0.5E-8*v(2,49) L2 98 17 5.1 R13 17 16 1K *F6 50 99 POLY(1) V6 30U 1 B6 50 99 i= 30E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 675 D5 26 24 DX444B V6 26 22 0.63V R17 23 25 187 D6 25 27 DX444B V7 22 27 0.63V V5 22 30 6.35V R19 21 30 1.2E6 D4 21 15 DX444B V4 29 22 0.63V R18 20 29 24K D3 15 20 DX444B L3 22 28 1U .ENDS LF444B .MODEL DX444B D(IS=1E-15) .MODEL JX444B PJF(BETA=9.201E-5 VTO=-2.33 IS=10E-12) * *LF451 Wide-Bandwidth JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF451 1 2 99 50 28 * *Features: *Low supply current = 3.4mA(max) *Wide bandwidth = 4MHz *High slew rate = 13V/uS *Low offset voltage = 10mV * IOS 2 1 25P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX451 J2 6 7 4 JX451 R3 5 50 20K R4 6 50 20K C4 5 6 3.31573E-13 I2 99 50 2.1MA *EOS 7 1 POLY(1) 16 49 .3E-3 1 BOS 7 1 v= .3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.13 D1 9 8 DX451 D2 10 9 DX451 V3 10 50 2.13 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 1.0985E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 1.0985E7*i(VA3)^3 G1 98 9 5 6 1E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 39.493P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 3.7894E-15 G4 98 16 3 49 1E-8 L2 98 17 31.831M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX451 VA7 99 21 0 D6 23 99 DX451 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 35 V5 28 25 0.1V D4 25 15 DX451 V4 24 28 0.1V D3 15 24 DX451 .ENDS LF451 .MODEL DX451 D(IS=1E-15) .MODEL JX451 PJF(BETA=1.25E-5 VTO=-2.00 IS=50E-12) * *LF453 Wide-Bandwidth Dual JFET-Input OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LF453 1 2 99 50 28 * *Features: *Low supply current = 6.5mA(max) *Wide bandwidth = 4MHz *High slew rate = 13V/uS *Low offset voltage = 5mV(max) *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * IOS 2 1 25P R1 1 3 1E12 R2 3 2 1E12 I1 99 4 100U J1 5 2 4 JX453 J2 6 7 4 JX453 R3 5 50 20K R4 6 50 20K C4 5 6 3.31573E-13 I2 99 50 2.1MA *EOS 7 1 POLY(1) 16 49 .3E-3 1 BOS 7 1 v= .3E-3 + 1*v(16,49) R8 99 49 50K R9 49 50 50K V2 99 8 2.13 D1 9 8 DX453 D2 10 9 DX453 V3 10 50 2.13 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA3 0 0 0 1.0985E7 B1 9 98 i= 0 + 0*i(VA3) + 0*i(VA3)^2 + 1.0985E7*i(VA3)^3 G1 98 9 5 6 1E-3 R5 98 9 100MEG VA3 9 11 0 C3 98 11 39.493P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 3.7894E-15 G4 98 16 3 49 1E-8 L2 98 17 31.831M R13 17 16 1K F6 99 50 VA7 1 F5 99 23 VA8 1 D5 21 23 DX453 VA7 99 21 0 D6 23 99 DX453 E1 99 26 99 15 1 VA8 26 27 0 R16 27 28 35 V5 28 25 0.1V D4 25 15 DX453 V4 24 28 0.1V D3 15 24 DX453 .ENDS LF453 .MODEL DX453 D(IS=1E-15) .MODEL JX453 PJF(BETA=1.25E-5 VTO=-2.00 IS=50E-12) * * LM111 Voltage Comparator * * Connections: * Positive Input * | Negative Input * | | Output * | | | Positive power supply * | | | | Negative Power supply * | | | | | Ground or Emitter Output * | | | | | | .SUBCKT LM111 3 2 1 8 4 104 * * CAUTION: SET .OPTIONS GMIN=1E-16 TO CORRECTLY MODEL INPUT BIAS CURRENT. * Features: * Operates from single 5V supply * Very Low Input current * Very Low Power Consumption * * NOTE: - Noise is not modeled. * - Asymmetrical gain is not modeled. * vos 2 13 dc 0.0007 iee 8 10 dc 1e-4 rc_q1 11 4 1517.2 rc_q2 12 4 1517.2 re_q1 10 6 1000 re_q2 10 7 1000 q1 11 3 6 mq1111 q2 12 13 7 mq2111 gsup 8 4 33 4 1 rsup 8 45 33333.3 dsup 45 4 mds111 iis 4 33 dc 0.00395 ris 33 4 1 g1 4 25 12 11 10 rcl 25 4 10 dcl1 25 26 md0111 dcl2 27 25 md0111 vcl1 26 4 dc 9.4 vcl2 4 27 dc 9.4 g2 4 16 25 4 0.01 d3 16 18 md1111 d4 17 16 md1111 v1 18 4 dc 0 v2 4 17 dc 0 gb 4 20 12 11 100 rb 20 4 10 *h1 22 4 poly(1) v1 0 1089.83 -4491.35 b1 22 4 v= 0 + 1089.83*i(v1) - 4491.35*i(v1)^2 *h2 4 21 poly(1) v2 0 1089.83 -4491.35 b2 4 21 v= 0 + 1089.83*i(v2) - 4491.35*i(v2)^2 db1 20 22 mdb1111 db2 21 20 mdb1111 gt 4 30 20 4 1e-5 rt 30 4 100k ct 30 4 0.8116e-12 gc 4 35 30 4 0.003448 rc 35 4 1k go 104 40 35 4 -0.01 ro 104 40 10 eob 41 40 45 4 1 rr 1 104 1meg co 40 104 10p voe 42 104 dc -0.0477 qo 1 41 42 mqo111 .ENDS LM111 .MODEL mq1111 pnp (bf=805.452 xtb=1.1526) .MODEL mq2111 pnp (bf=861.069 xtb=1.1526) .MODEL md0111 d (is=1e-10 rs=0.01) .MODEL md1111 d (is=1e-12) .MODEL mdb1111 d .MODEL mds111 d (is=1e-16) .MODEL mqo111 npn (bf=100 rc=13.4286 isc=1.8e-10 br=10 nr=0.95 cjs=5p cjc=1p tf=2n) * *LM118 OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM118 1 2 99 50 28 * *Features: *Internal frequency compensation *High bandwidth = 15MHz *Minimum slew rate = 50V/uS *Low bias current = 250nA *Wide supply range = +-5V to +-20V * IOS 2 1 6N R1 1 3 1.5MEG R2 3 2 1.5MEG I1 4 50 100U R3 99 5 517 R4 99 6 517 Q1 5 2 4 QX118 Q2 6 7 4 QX118 C4 5 6 6.1569P I2 99 50 4.9M *EOS 7 1 POLY(1) 16 49 4E-3 1 BOS 7 1 v= 4E-3 + 1*v(16,49) R8 99 49 80.2K R9 49 50 80.2K V2 99 8 2.63 D1 9 8 DX118 D2 10 9 DX118 V3 10 50 2.63 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 3.0967E-4 0 596.674E-3 B1 98 9 i= 0 + 3.0967E-4*v(5,6) + 0*v(5,6)^2 + 596.674E-3*v(5,6)^3 R5 98 9 9.6877G C3 98 9 1.4286P G2 98 13 9 49 1E-6 R10 98 13 1MEG R11 98 14 1MEG C6 14 13 2.6526E-13 G3 98 15 13 49 1E-6 R12 98 15 1MEG C5 98 15 2.8937E-15 G4 98 16 3 49 1E-8 L2 98 17 53.1M R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 30 D5 26 24 DX118 V6 26 22 .63V R17 23 25 30 D6 25 27 DX118 V7 22 27 .63V C9 23 22 100P V5 22 21 0.2V D4 21 15 DX118 V4 20 22 0.2V D3 15 20 DX118 L3 22 28 100P RL3 22 28 100K .ENDS LM118 .MODEL DX118 D(IS=1E-15) .MODEL QX118 NPN(BF=333.333) * *LM124 Low Power Quad OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM124 1 2 99 50 28 * *Features: *Eliminates need for dual supplies *Large DC voltage gain = 100dB *High bandwidth = 1MHz *Low input offset voltage = 2mV *Wide supply range = +-1.5V to +-16V * *NOTE: Model is for single device only and simulated * supply current is 1/4 of total device current. * Output crossover distortion with dual supplies * is not modeled. * IOS 2 1 3N R1 1 3 500K R2 3 2 500K I1 99 4 100U R3 5 50 517 R4 6 50 517 Q1 5 2 4 QX124 Q2 6 7 4 QX124 C4 5 6 128.27P I2 99 50 75U *EOS 7 1 POLY(1) 16 49 1E-3 1 BOS 7 1 v= 1E-3 + 1*v(16,49) R8 99 49 60K R9 49 50 60K V2 99 8 1.63 D1 9 8 DX124 D2 10 9 DX124 V3 10 50 0.635 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 9.8772E-4 0 .3459 B1 98 9 i= 0 + 9.8772E-4*v(5,6) + 0*v(5,6)^2 + .3459*v(5,6)^3 R5 98 9 101.2433MEG C3 98 9 200P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.9577E-14 G4 98 16 3 49 5.6234E-8 L2 98 17 15.9M R13 17 16 1K *F6 50 99 POLY(1) V6 300U 1 B6 50 99 i= 300E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 17.5 D5 26 24 DX124 V6 26 22 .63V R17 23 25 17.5 D6 25 27 DX124 V7 22 27 .63V V5 22 21 0.27V D4 21 15 DX124 V4 20 22 0.27V D3 15 20 DX124 L3 22 28 500P RL3 22 28 100K .ENDS LM124 .MODEL DX124 D(IS=1E-15) .MODEL QX124 PNP(BF=1.111E3) * *LM158 DUAL OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM158 1 2 99 50 28 * *Features: *Eliminates need for dual supplies *Large DC voltage gain = 100dB *High bandwidth = 1MHz *Low input offset voltage = 2mV *Wide supply range = +-1.5V to +-16V * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * Output crossover distortion with dual supplies * is not modeled. * IOS 2 1 5N R1 1 3 500K R2 3 2 500K I1 99 4 100U R3 5 50 517 R4 6 50 517 Q1 5 2 4 QX158 Q2 6 7 4 QX158 C4 5 6 128.27P I2 99 50 75U *EOS 7 1 POLY(1) 16 49 2E-3 1 BOS 7 1 v= 2E-3 + 1*v(16,49) R8 99 49 60K R9 49 50 60K V2 99 8 1.63 D1 9 8 DX158 D2 10 9 DX158 V3 10 50 .635 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 9.8772E-4 0 .3459 B1 98 9 i= 0 + 9.8772E-4*v(5,6) + 0*v(5,6)^2 + .3459*v(5,6)^3 R5 98 9 101.2433MEG C3 98 9 200P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.9577E-14 G4 98 16 3 49 5.6234E-8 L2 98 17 15.9M R13 17 16 1K *F6 50 99 POLY(1) V6 300U 1 B6 50 99 i= 300E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 17.5 D5 26 24 DX158 V6 26 22 .63V R17 23 25 17.5 D6 25 27 DX158 V7 22 27 .63V V5 22 21 0.27V D4 21 15 DX158 V4 20 22 0.27V D3 15 20 DX158 L3 22 28 500P RL3 22 28 100K .ENDS LM158 .MODEL DX158 D(IS=1E-15) .MODEL QX158 PNP(BF=1.111E3) * *LM218 OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM218 1 2 99 50 28 * *Features: *Internal frequency compensation *High bandwidth = 15MHz *Minimum slew rate = 50V/uS *Low bias current = 250nA *Wide supply range = +-5V to +-20V * IOS 2 1 6N R1 1 3 1.5MEG R2 3 2 1.5MEG I1 4 50 100U R3 99 5 517 R4 99 6 517 Q1 5 2 4 QX218 Q2 6 7 4 QX218 C4 5 6 6.1569P I2 99 50 4.9M *EOS 7 1 POLY(1) 16 49 4E-3 1 BOS 7 1 v= 4E-3 + 1*v(16,49) R8 99 49 80.2K R9 49 50 80.2K V2 99 8 2.63 D1 9 8 DX218 D2 10 9 DX218 V3 10 50 2.63 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 3.0967E-4 0 596.674E-3 B1 98 9 i= 0 + 3.0967E-4*v(5,6) + 0*v(5,6)^2 + 596.674E-3*v(5,6)^3 R5 98 9 9.6877G C3 98 9 1.4286P G2 98 13 9 49 1E-6 R10 98 13 1MEG R11 98 14 1MEG C6 14 13 2.6526E-13 G3 98 15 13 49 1E-6 R12 98 15 1MEG C5 98 15 2.8937E-15 G4 98 16 3 49 1E-8 L2 98 17 53.1M R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 30 D5 26 24 DX218 V6 26 22 .63V R17 23 25 30 D6 25 27 DX218 V7 22 27 .63V C9 23 22 100P V5 22 21 0.2V D4 21 15 DX218 V4 20 22 0.2V D3 15 20 DX218 L3 22 28 100P RL3 22 28 100K .ENDS LM218 .MODEL DX218 D(IS=1E-15) .MODEL QX218 NPN(BF=333.333) * *LM224 Low Power Quad OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM224 1 2 99 50 28 * *Features: *Eliminates need for dual supplies *Large DC voltage gain = 100dB *High bandwidth = 1MHz *Low input offset voltage = 2mV *Wide supply range = +-1.5V to +-16V * *NOTE: Model is for single device only and simulated * supply current is 1/4 of total device current. * Output crossover distortion with dual supplies * is not modeled. * IOS 2 1 3N R1 1 3 500K R2 3 2 500K I1 99 4 100U R3 5 50 517 R4 6 50 517 Q1 5 2 4 QX224 Q2 6 7 4 QX224 C4 5 6 128.27P I2 99 50 75U *EOS 7 1 POLY(1) 16 49 2E-3 1 BOS 7 1 v= 2E-3 + 1*v(16,49) R8 99 49 60K R9 49 50 60K V2 99 8 1.63 D1 9 8 DX224 D2 10 9 DX224 V3 10 50 .635 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 9.8772E-4 0 .3459 B1 98 9 i= 0 + 9.8772E-4*v(5,6) + 0*v(5,6)^2 + .3459*v(5,6)^3 R5 98 9 101.2433MEG C3 98 9 200P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.9577E-14 G4 98 16 3 49 5.6234E-8 L2 98 17 15.9M R13 17 16 1K *F6 50 99 POLY(1) V6 300U 1 B6 50 99 i= 300E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 17.5 D5 26 24 DX224 V6 26 22 .63V R17 23 25 17.5 D6 25 27 DX224 V7 22 27 .63V V5 22 21 0.27V D4 21 15 DX224 V4 20 22 0.27V D3 15 20 DX224 L3 22 28 500P RL3 22 28 100K .ENDS LM224 .MODEL DX224 D(IS=1E-15) .MODEL QX224 PNP(BF=1.111E3) * *LM258 DUAL OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM258 1 2 99 50 28 * *Features: *Eliminates need for dual supplies *Large DC voltage gain = 100dB *High bandwidth = 1MHz *Low input offset voltage = 2mV *Wide supply range = +-1.5V to +-16V * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * Output crossover distortion with dual supplies * is not modeled. * IOS 2 1 5N R1 1 3 500K R2 3 2 500K I1 99 4 100U R3 5 50 517 R4 6 50 517 Q1 5 2 4 QX258 Q2 6 7 4 QX258 C4 5 6 128.27P I2 99 50 75U *EOS 7 1 POLY(1) 16 49 2E-3 1 BOS 7 1 v= 2E-3 + 1*v(16,49) R8 99 49 60K R9 49 50 60K V2 99 8 1.63 D1 9 8 DX258 D2 10 9 DX258 V3 10 50 .635 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 9.8772E-4 0 .3459 B1 98 9 i= 0 + 9.8772E-4*v(5,6) + 0*v(5,6)^2 + .3459*v(5,6)^3 R5 98 9 101.2433MEG C3 98 9 200P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.9577E-14 G4 98 16 3 49 5.6234E-8 L2 98 17 15.9M R13 17 16 1K *F6 50 99 POLY(1) V6 300U 1 B6 50 99 i= 300E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 17.5 D5 26 24 DX258 V6 26 22 .63V R17 23 25 17.5 D6 25 27 DX258 V7 22 27 .63V V5 22 21 0.27V D4 21 15 DX258 V4 20 22 0.27V D3 15 20 DX258 L3 22 28 500P RL3 22 28 100K .ENDS LM258 .MODEL DX258 D(IS=1E-15) .MODEL QX258 PNP(BF=1.111E3) * *LM318 OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM318 1 2 99 50 28 * *Features: *Internal frequency compensation *High bandwidth = 15MHz *Minimum slew rate = 50V/uS *Low bias current = 250nA *Wide supply range = +-5V to +-20V * IOS 2 1 30N R1 1 3 1.5MEG R2 3 2 1.5MEG I1 4 50 100U R3 99 5 517 R4 99 6 517 Q1 5 2 4 QX318 Q2 6 7 4 QX318 C4 5 6 6.1569P I2 99 50 4.9M *EOS 7 1 POLY(1) 16 49 4E-3 1 BOS 7 1 v= 4E-3 + 1*v(16,49) R8 99 49 80.2K R9 49 50 80.2K V2 99 8 2.63 D1 9 8 DX318 D2 10 9 DX318 V3 10 50 2.63 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 3.0967E-4 0 596.674E-3 B1 98 9 i= 0 + 3.0967E-4*v(5,6) + 0*v(5,6)^2 + 596.674E-3*v(5,6)^3 R5 98 9 9.6877G C3 98 9 1.4286P G2 98 13 9 49 1E-6 R10 98 13 1MEG R11 98 14 1MEG C6 14 13 2.6526E-13 G3 98 15 13 49 1E-6 R12 98 15 1MEG C5 98 15 2.8937E-15 G4 98 16 3 49 1E-8 L2 98 17 53.1M R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 30 D5 26 24 DX318 V6 26 22 .63V R17 23 25 30 D6 25 27 DX318 V7 22 27 .63V C9 23 22 100P V5 22 21 0.2V D4 21 15 DX318 V4 20 22 0.2V D3 15 20 DX318 L3 22 28 100P RL3 22 28 100K .ENDS LM318 .MODEL DX318 D(IS=1E-15) .MODEL QX318 NPN(BF=333.333) * *LM324 Low Power Quad OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM324 1 2 99 50 28 * *Features: *Eliminates need for dual supplies *Large DC voltage gain = 100dB *High bandwidth = 1MHz *Low input offset voltage = 2mV *Wide supply range = +-1.5V to +-16V * *NOTE: Model is for single device only and simulated * supply current is 1/4 of total device current. * Output crossover distortion with dual supplies * is not modeled. * IOS 2 1 5N R1 1 3 500K R2 3 2 500K I1 99 4 100U R3 5 50 517 R4 6 50 517 Q1 5 2 4 QX324 Q2 6 7 4 QX324 C4 5 6 128.27P I2 99 50 75U *EOS 7 1 POLY(1) 16 49 2E-3 1 BOS 7 1 v= 2E-3 + 1*v(16,49) R8 99 49 60K R9 49 50 60K V2 99 8 1.63 D1 9 8 DX324 D2 10 9 DX324 V3 10 50 .635 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 9.8772E-4 0 .3459 B1 98 9 i= 0 + 9.8772E-4*v(5,6) + 0*v(5,6)^2 + .3459*v(5,6)^3 R5 98 9 101.2433MEG C3 98 9 200P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.9577E-14 G4 98 16 3 49 5.6234E-8 L2 98 17 15.9M R13 17 16 1K *F6 50 99 POLY(1) V6 300U 1 B6 50 99 i= 300E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 17.5 D5 26 24 DX324 V6 26 22 .63V R17 23 25 17.5 D6 25 27 DX324 V7 22 27 .63V V5 22 21 0.27V D4 21 15 DX324 V4 20 22 0.27V D3 15 20 DX324 L3 22 28 500P RL3 22 28 100K .ENDS LM324 .MODEL DX324 D(IS=1E-15) .MODEL QX324 PNP(BF=1.111E3) * *LM358 DUAL OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM358 1 2 99 50 28 * *Features: *Eliminates need for dual supplies *Large DC voltage gain = 100dB *High bandwidth = 1MHz *Low input offset voltage = 2mV *Wide supply range = +-1.5V to +-16V * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * Output crossover distortion with dual supplies * is not modeled. * IOS 2 1 5N R1 1 3 500K R2 3 2 500K I1 99 4 100U R3 5 50 517 R4 6 50 517 Q1 5 2 4 QX358 Q2 6 7 4 QX358 C4 5 6 128.27P I2 99 50 75U *EOS 7 1 POLY(1) 16 49 2E-3 1 BOS 7 1 v= 2E-3 + 1*v(16,49) R8 99 49 60K R9 49 50 60K V2 99 8 1.63 D1 9 8 DX358 D2 10 9 DX358 V3 10 50 .635 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 9.8772E-4 0 .3459 B1 98 9 i= 0 + 9.8772E-4*v(5,6) + 0*v(5,6)^2 + .3459*v(5,6)^3 R5 98 9 101.2433MEG C3 98 9 200P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.9577E-14 G4 98 16 3 49 5.6234E-8 L2 98 17 15.9M R13 17 16 1K *F6 50 99 POLY(1) V6 300U 1 B6 50 99 i= 300E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 17.5 D5 26 24 DX358 V6 26 22 .63V R17 23 25 17.5 D6 25 27 DX358 V7 22 27 .63V V5 22 21 0.27V D4 21 15 DX358 V4 20 22 0.27V D3 15 20 DX358 L3 22 28 500P RL3 22 28 100K .ENDS LM358 .MODEL DX358 D(IS=1E-15) .MODEL QX358 PNP(BF=1.111E3) * *LM6118 Fast Settling Dual OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6118 1 2 99 50 28 * *Features: *Low offset voltage = .2mV *High bandwidth = 17MHz *Slew rate (Av=-1) = 140V/uS * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * IOS 2 1 20N CI1 1 0 2.5P CI2 2 0 2.5P R1 1 3 3.125G R2 3 2 3.125G I1 99 4 40U R43 45 4 1.25K R44 46 4 1.25K Q1 5 2 45 QX6118 Q2 6 7 46 QX6118 R3 50 5 2.54K R4 50 6 2.54K C4 5 6 1.0433P I2 99 50 2.71M *EOS 7 1 POLY(1) 16 49 .2E-3 1 BOS 7 1 v= .2E-3 + 1*v(16,49) R8 99 49 71.4K R9 49 50 71.4K V2 99 8 2.63 D1 9 8 DX6118 D2 10 9 DX6118 V3 10 50 2.63 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 5E-3 0 5.056 B1 98 9 i= 0 + 5E-3*v(5,6) + 0*v(5,6)^2 + 5.056*v(5,6)^3 R5 98 9 100MEG C3 98 9 41.62P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1.4469E-15 G4 98 16 3 49 1E-8 L2 98 17 26.526M R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 10 D5 26 24 DY6118 V6 26 22 .63V R17 23 25 10 D6 25 27 DY6118 C9 23 22 .001U V7 22 27 .63V V5 22 21 .63V D4 21 15 DX6118 V4 20 22 .63V D3 15 20 DX6118 L3 22 28 100P RL3 22 28 100K .ENDS LM6118 .MODEL DX6118 D(IS=1E-15) .MODEL DY6118 D(IS=1E-25) .MODEL QX6118 PNP(BF=100) * *LM6161 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6161 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 50MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 1.5P CI2 2 0 1.5P R1 1 3 162.5K R2 3 2 162.5K I1 4 50 1M R3 99 5 651.7 R4 99 6 651.7 Q1 5 2 45 QX6161 Q2 6 7 46 QX6161 R43 45 4 600 R44 46 4 600 C4 5 6 6.1054E-13 I2 99 50 4M *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.335 D1 9 8 DX6161 D2 10 9 DX6161 V3 10 50 2.155 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 20 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + 20*i(VA1)^3 *G2 98 9 POLY(1) 5 6 0 2.9E-3 0 5.062E-4 B2 98 9 i= 0 + 2.9E-3*v(5,6) + 0*v(5,6)^2 + 5.062E-4*v(5,6)^3 R5 98 9 1MEG C3 98 9 6.7668P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.84E-16 G4 98 16 3 49 1.9952E-8 L2 98 17 795.77U R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 15 1 R16 24 23 10 D5 26 24 DY6161 V6 26 22 .63V R17 23 25 10 D6 25 27 DY6161 C9 23 22 500P V7 22 27 .63V V5 22 21 .63V D4 21 15 DX6161 V4 20 22 .63V D3 15 20 DX6161 L3 22 28 100P RL3 22 28 100K .ENDS LM6161 .MODEL DX6161 D(IS=1E-15) .MODEL DY6161 D(IS=1E-25) .MODEL QX6161 NPN(BF=250) * *LM6162 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6162 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 100MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 2P CI2 2 0 2P R1 1 3 90K R2 3 2 90K I1 4 50 1M R3 99 5 351.7 R4 99 6 351.7 Q1 5 2 45 QX6162 Q2 6 7 46 QX6162 R43 45 4 300 R44 46 4 300 C4 5 6 9.8376E-13 I2 99 50 4M *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6162 D2 10 9 DX6162 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 .85 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + 0.85*i(VA1)^3 *G2 98 9 POLY(1) 5 6 0 6.5E-3 0 8.646E-3 B2 98 9 i= 0 + 6.5E-3*v(5,6) + 0*v(5,6)^2 + 8.646E-3*v(5,6)^3 R5 98 9 1MEG C3 98 9 8.874P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 6.9198E-16 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 6.3662E-16 G4 98 16 3 49 1E-8 L2 98 17 15.915E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6162 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6162 C9 23 22 200P V7 22 27 .63V V5 22 21 .23V D4 21 18 DX6162 V4 20 22 .23V D3 18 20 DX6162 L3 22 28 100P RL3 22 28 100K .ENDS LM6162 .MODEL DX6162 D(IS=1E-15) .MODEL QX6162 NPN(BF=227.3) * *LM6164 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6164 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 175MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 3P CI2 2 0 3P R1 1 3 50K R2 3 2 50K I1 4 50 1M R3 99 5 201.7 R4 99 6 201.7 Q1 5 2 45 QX6164 Q2 6 7 46 QX6164 R43 45 4 150 R44 46 4 150 C4 5 6 2.0765P I2 99 50 4M *EOS 7 1 POLY(1) 16 49 2E-3 1 BOS 7 1 v= 2E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6164 D2 10 9 DX6164 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 3.4 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + 3.4*i(VA1)^3 *G2 98 9 POLY(1) 5 6 0 9.0E-3 0 10.6E-3 B2 98 9 i= 0 + 9.0E-3*v(5,6) + 0*v(5,6)^2 + 10.6E-3*v(5,6)^3 R5 98 9 1MEG C3 98 9 6.3408P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 8.3766E-16 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 7.8401E-16 G4 98 16 3 49 5.6234E-9 L2 98 17 53.052E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6164 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6164 C9 23 22 500P V7 22 27 .63V V5 22 21 .23V D4 21 18 DX6164 V4 20 22 .23V D3 18 20 DX6164 L3 22 28 100P RL3 22 28 100K .ENDS LM6164 .MODEL DX6164 D(IS=1E-15) .MODEL QX6164 NPN(BF=200) * *LM6165 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6165 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 725MHz *High slew rate = 300V/uS IOS 2 1 150N CI1 1 0 6P CI2 2 0 6P R1 1 3 10K R2 3 2 10K I1 4 50 1M R3 99 5 51.7 R4 99 6 51.7 Q1 5 2 4 QX6165 Q2 6 7 4 QX6165 C4 5 6 12.827P I2 99 50 4M *EOS 7 1 POLY(1) 16 49 1E-3 1 BOS 7 1 v= 1E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6165 D2 10 9 DX6165 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(2) VA1 VA3 0 0 0 0 0 0 4.25 0 0 4.978143E5 B1 9 98 i= 0 + 4.25*i(VA1)^3 + 4.978143E5*i(VA3)^3 *G2 98 9 POLY(1) 5 6 0 38.0E-3 B2 98 9 i= 0 + 38.0E-3*v(5,6) R5 98 9 1MEG VA3 9 11 0 C3 98 11 3.897P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1.3263E-15 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 1.2835E-15 G4 98 16 3 49 7.94328E-9 L2 98 17 15.915E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6165 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6165 C9 23 22 500P V7 22 27 .63V V5 22 21 .25V D4 21 18 DX6165 V4 20 22 .25V D3 18 20 DX6165 L3 22 28 100P RL3 22 28 100K .ENDS LM6165 .MODEL DX6165 D(IS=1E-15) .MODEL QX6165 NPN(BF=200) * *LM6218 Fast Settling Dual OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6218 1 2 99 50 28 * *Features: *Low offset voltage = .2mV *High bandwidth = 17MHz *Slew rate (Av=-1) = 140V/uS * *NOTE: Model is for single device only and simulated * supply current is 1/2 of total device current. * IOS 2 1 20N CI1 1 0 2.5P CI2 2 0 2.5P R1 1 3 3.125G R2 3 2 3.125G I1 99 4 40U R43 45 4 1.25K R44 46 4 1.25K Q1 5 2 45 QX6218 Q2 6 7 46 QX6218 R3 50 5 2.54K R4 50 6 2.54K C4 5 6 1.0433P I2 99 50 2.71M *EOS 7 1 POLY(1) 16 49 .2E-3 1 BOS 7 1 v= .2E-3 + 1*v(16,49) R8 99 49 71.4K R9 49 50 71.4K V2 99 8 2.63 D1 9 8 DX6218 D2 10 9 DX6218 V3 10 50 2.63 EH 99 98 99 49 1 *G1 98 9 POLY(1) 5 6 0 5E-3 0 5.056 B1 98 9 i= 0 + 5E-3*v(5,6) + 0*v(5,6)^2 + 5.056*v(5,6)^3 R5 98 9 100MEG C3 98 9 41.62P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1.4469E-15 G4 98 16 3 49 1E-8 L2 98 17 26.526M R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 10 D5 26 24 DY6218 V6 26 22 .63V R17 23 25 10 D6 25 27 DY6218 C9 23 22 .001U V7 22 27 .63V V5 22 21 .63V D4 21 15 DX6218 V4 20 22 .63V D3 15 20 DX6218 L3 22 28 100P RL3 22 28 100K .ENDS LM6218 .MODEL DX6218 D(IS=1E-15) .MODEL DY6218 D(IS=1E-25) .MODEL QX6218 PNP(BF=100) * *LM6261 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6261 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 50MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 1.5P CI2 2 0 1.5P R1 1 3 162.5K R2 3 2 162.5K I1 4 50 1M R3 99 5 651.7 R4 99 6 651.7 Q1 5 2 45 QX6261 Q2 6 7 46 QX6261 R43 45 4 600 R44 46 4 600 C4 5 6 6.1054E-13 I2 99 50 4M *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.335 D1 9 8 DX6261 D2 10 9 DX6261 V3 10 50 2.155 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 20 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + 20*i(VA1)^3 *G2 98 9 POLY(1) 5 6 0 2.9E-3 0 5.062E-4 B2 98 9 i= 0 + 2.9E-3*v(5,6) + 0*v(5,6)^2 + 5.056E-4*v(5,6)^3 R5 98 9 1MEG C3 98 9 6.7668P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.84E-16 G4 98 16 3 49 1.9952E-8 L2 98 17 795.77U R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 15 1 R16 24 23 10 D5 26 24 DY6261 V6 26 22 .63V R17 23 25 10 D6 25 27 DY6261 C9 23 22 500P V7 22 27 .63V V5 22 21 .63V D4 21 15 DX6261 V4 20 22 .63V D3 15 20 DX6261 L3 22 28 100P RL3 22 28 100K .ENDS LM6261 .MODEL DX6261 D(IS=1E-15) .MODEL DY6261 D(IS=1E-25) .MODEL QX6261 NPN(BF=250) * *LM6262 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6262 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 100MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 2P CI2 2 0 2P R1 1 3 90K R2 3 2 90K I1 4 50 1M R3 99 5 351.7 R4 99 6 351.7 Q1 5 2 45 QX6262 Q2 6 7 46 QX6262 R43 45 4 300 R44 46 4 300 C4 5 6 9.8376E-13 I2 99 50 4M *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6262 D2 10 9 DX6262 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 .85 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + .85*i(VA1)^3 *G2 98 9 POLY(1) 5 6 0 6.5E-3 0 8.646E-3 B2 98 9 i= 0 + 6.5E-3*v(5,6) + 0*v(5,6)^2 + 8.646E-3*v(5,6)^3 R5 98 9 1MEG C3 98 9 8.874P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 6.9198E-16 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 6.3662E-16 G4 98 16 3 49 1E-8 L2 98 17 15.915E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6262 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6262 C9 23 22 200P V7 22 27 .63V V5 22 21 .23V D4 21 18 DX6262 V4 20 22 .23V D3 18 20 DX6262 L3 22 28 100P RL3 22 28 100K .ENDS LM6262 .MODEL DX6262 D(IS=1E-15) .MODEL QX6262 NPN(BF=227.3) * *LM6264 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6264 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 175MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 3P CI2 2 0 3P R1 1 3 50K R2 3 2 50K I1 4 50 1M R3 99 5 201.7 R4 99 6 201.7 Q1 5 2 45 QX6264 Q2 6 7 46 QX6264 R43 45 4 150 R44 46 4 150 C4 5 6 2.0765P I2 99 50 4M *EOS 7 1 POLY(1) 16 49 2E-3 1 BOS 7 1 v= 2E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6264 D2 10 9 DX6264 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 3.4 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + 3.4*i(VA1)^3 *G2 98 9 POLY(1) 5 6 0 9.0E-3 0 10.6E-3 B2 98 9 i= 0 + 9.0E-3*v(5,6) + 0*v(5,6)^2 + 3.4*v(5,6)^3 R5 98 9 1MEG C3 98 9 6.3408P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 8.3766E-16 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 7.8401E-16 G4 98 16 3 49 5.6234E-9 L2 98 17 53.052E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6264 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6264 C9 23 22 500P V7 22 27 .63V V5 22 21 .23V D4 21 18 DX6264 V4 20 22 .23V D3 18 20 DX6264 L3 22 28 100P RL3 22 28 100K .ENDS LM6264 .MODEL DX6264 D(IS=1E-15) .MODEL QX6264 NPN(BF=200) * *LM6265 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6265 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 725MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 6P CI2 2 0 6P R1 1 3 10K R2 3 2 10K I1 4 50 1M R3 99 5 51.7 R4 99 6 51.7 Q1 5 2 4 QX6265 Q2 6 7 4 QX6265 C4 5 6 12.827P I2 99 50 4M *EOS 7 1 POLY(1) 16 49 1E-3 1 BOS 7 1 v= 1E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6265 D2 10 9 DX6265 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(2) VA1 VA3 0 0 0 0 0 0 4.25 0 0 4.978143E5 B1 9 98 i= 0 + 4.25*i(VA1)^3 + 4.978143E5*i(VA3)^3 *G2 98 9 POLY(1) 5 6 0 38.0E-3 B2 98 9 i= 0 + 38.0E-3*v(5,6) R5 98 9 1MEG VA3 9 11 0 C3 98 11 3.897P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1.3263E-15 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 1.2835E-15 G4 98 16 3 49 7.94328E-9 L2 98 17 15.915E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6265 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6265 C9 23 22 500P V7 22 27 .63V V5 22 21 .25V D4 21 18 DX6265 V4 20 22 .25V D3 18 20 DX6265 L3 22 28 100P RL3 22 28 100K .ENDS LM6265 .MODEL DX6265 D(IS=1E-15) .MODEL QX6265 NPN(BF=200) * *LM6361 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6361 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 50MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 1.5P CI2 2 0 1.5P R1 1 3 162.5K R2 3 2 162.5K I1 4 50 1M R3 99 5 651.7 R4 99 6 651.7 Q1 5 2 45 QX6361 Q2 6 7 46 QX6361 R43 45 4 600 R44 46 4 600 C4 5 6 6.1054E-13 I2 99 50 4M *EOS 7 1 POLY(1) 16 49 5E-3 1 BOS 7 1 v= 5E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.335 D1 9 8 DX6361 D2 10 9 DX6361 V3 10 50 2.155 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 20 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + 20*i(VA1)^3 *G2 98 9 POLY(1) 5 6 0 2.9E-3 0 5.062E-4 B2 98 9 i= 0 + 2.9E-3*v(5,6) + 0*v(5,6)^2 + 5.062E-4*v(5,6)^3 R5 98 9 1MEG C3 98 9 6.7668P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 7.84E-16 G4 98 16 3 49 1.9952E-8 L2 98 17 795.77U R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 15 1 R16 24 23 10 D5 26 24 DY6361 V6 26 22 .63V R17 23 25 10 D6 25 27 DY6361 C9 23 22 500P V7 22 27 .63V V5 22 21 .63V D4 21 15 DX6361 V4 20 22 .63V D3 15 20 DX6361 L3 22 28 100P RL3 22 28 100K .ENDS LM6361 .MODEL DX6361 D(IS=1E-15) .MODEL DY6361 D(IS=1E-25) .MODEL QX6361 NPN(BF=250) * *LM6362 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6362 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 100MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 2P CI2 2 0 2P R1 1 3 90K R2 3 2 90K I1 4 50 1M R3 99 5 351.7 R4 99 6 351.7 Q1 5 2 45 QX6362 Q2 6 7 46 QX6362 R43 45 4 300 R44 46 4 300 C4 5 6 9.8376E-13 I2 99 50 4M *EOS 7 1 POLY(1) 16 49 3E-3 1 BOS 7 1 v= 3E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6362 D2 10 9 DX6362 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(1) VA1 0 0 0 .85 B1 9 98 i= 0 + 0*i(VA1) + 0*i(VA1)^2 + .85*i(VA1)^3 *G1 98 9 POLY(1) 5 6 0 6.5E-3 0 8.646E-3 B2 98 9 i= 0 + 6.5E-3*v(5,6) + 0*v(5,6)^2 + 8.646E-3*v(5,6)^3 R5 98 9 1MEG C3 98 9 8.874P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 6.9198E-16 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 6.3662E-16 G4 98 16 3 49 1E-8 L2 98 17 15.915E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6362 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6362 C9 23 22 200P V7 22 27 .63V V5 22 21 .23V D4 21 18 DX6362 V4 20 22 .23V D3 18 20 DX6362 L3 22 28 100P RL3 22 28 100K .ENDS LM6362 .MODEL DX6362 D(IS=1E-15) .MODEL QX6362 NPN(BF=227.3) * *LM6365 High Speed OP-AMP MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM6365 1 2 99 50 28 * *Features: *Low supply current = 5mA *High bandwidth = 725MHz *High slew rate = 300V/uS * IOS 2 1 150N CI1 1 0 6P CI2 2 0 6P R1 1 3 10K R2 3 2 10K I1 4 50 1M R3 99 5 51.7 R4 99 6 51.7 Q1 5 2 4 QX6365 Q2 6 7 4 QX6365 C4 5 6 12.827P I2 99 50 4M *EOS 7 1 POLY(1) 16 49 1E-3 1 BOS 7 1 v= 1E-3 + 1*v(16,49) R8 99 49 80K R9 49 50 80K V2 99 8 1.43 D1 9 8 DX6365 D2 10 9 DX6365 V3 10 50 2.23 EH 99 98 99 49 1 *F1 9 98 POLY(2) VA1 VA3 0 0 0 0 0 0 4.25 0 0 4.978143E5 B1 9 98 i= 0 + 4.25*i(VA1)^3 + 4.978143E5*i(VA3)^3 *G2 98 9 POLY(1) 5 6 0 38.0E-3 B2 98 9 i= 0 + 38.0E-3*v(5,6) R5 98 9 1MEG VA3 9 11 0 C3 98 11 3.897P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 1.3263E-15 G5 98 18 15 49 1E-6 R15 98 18 1MEG C6 98 18 1.2835E-15 G4 98 16 3 49 7.94328E-9 L2 98 17 15.915E-3 R13 17 16 1K *F6 50 99 POLY(1) V6 200U 1 B6 50 99 i= 200E-6 + 1*i(V6) VA1 99 93 0 E1 93 23 99 18 1 R16 24 23 10 D5 26 24 DX6365 V6 26 22 .63V R17 23 25 10 D6 25 27 DX6365 C9 23 22 500P V7 22 27 .63V V5 22 21 .25V D4 21 18 DX6365 V4 20 22 .25V D3 18 20 DX6365 L3 22 28 100P RL3 22 28 100K .ENDS LM6365 .MODEL DX6365 D(IS=1E-15) .MODEL QX6365 NPN(BF=200) * *LM741 OPERATIONAL AMPLIFIER MACRO-MODEL * * connections: non-inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | * | | | | | .SUBCKT LM741 1 2 99 50 28 * *Features: *Improved performance over industry standards *Plug-in replacement for LM709,LM201,MC1439,748 *Input and output overload protection * IOS 2 1 20N R1 1 3 250K R2 3 2 250K I1 4 50 100U R3 5 99 517 R4 6 99 517 Q1 5 2 4 QX741 Q2 6 7 4 QX741 C4 5 6 60.3614P I2 99 50 1.6MA *EOS 7 1 POLY(1) 16 49 1E-3 1 BOS 7 1 v= 1E-3 + 1*v(16,49) R8 99 49 40K R9 49 50 40K V2 99 8 1.63 D1 9 8 DX741 D2 10 9 DX741 V3 10 50 1.63 EH 99 98 99 49 1 G1 98 9 5 6 2.1E-3 R5 98 9 95.493MEG C3 98 9 333.33P G3 98 15 9 49 1E-6 R12 98 15 1MEG C5 98 15 5.3052E-15 G4 98 16 3 49 3.1623E-8 L2 98 17 530.5M R13 17 16 1K *F6 50 99 POLY(1) V6 450U 1 B6 50 99 i= 450E-6 + 1*i(V6) E1 99 23 99 15 1 R16 24 23 25 D5 26 24 DX741 V6 26 22 0.65V R17 23 25 25 D6 25 27 DX741 V7 22 27 0.65V V5 22 21 0.18V D4 21 15 DX741 V4 20 22 0.18V D3 15 20 DX741 L3 22 28 100P RL3 22 28 100K .ENDS LM741 .MODEL DX741 D(IS=1E-15) .MODEL QX741 NPN(BF=625) *