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DP Tool Club 19
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CD_ASCQ_19_010295.iso
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vrac
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icap4c.zip
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DEMO2.LI_
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DEMO2.LI
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Text File
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1994-07-19
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8KB
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356 lines
**********************
*SYM=TICOMP2
* LM111 VOLTAGE COMPARATOR "MACROMODEL" SUBCIRCUIT
* REV (N/A)
* CONNECTIONS: NON-INVERTING INPUT
* | INVERTING INPUT
* | | POSITIVE POWER SUPPLY
* | | | NEGATIVE POWER SUPPLY
* | | | | OPEN COLLECTOR OUTPUT
* | | | | | OUTPUT GROUND
* | | | | | |
.SUBCKT LM111T 1 2 3 4 5 6
*
F1 9 3 V1 1
IEE 3 7 DC 100.0E-6
VI1 21 1 DC .45
VI2 22 2 DC .45
Q1 9 21 7 QIN
Q2 8 22 7 QIN
Q3 9 8 4 QMO
Q4 8 8 4 QMI
.MODEL QIN PNP(IS=800.0E-18 BF=666.7)
.MODEL QMI NPN(IS=800.0E-18 BF=1002)
.MODEL QMO NPN(IS=800.0E-18 BF=1000 CJC=1E-15 TR=102.5E-9)
E1 10 6 9 4 1
V1 10 11 DC 0
Q5 5 11 6 QOC
.MODEL QOC NPN(IS=800.0E-18 BF=103.5E3 CJC=1E-15 TF=11.60E-12 TR=48.19E-9)
DP 4 3 DX
RP 3 4 6.667E3
.MODEL DX D(IS=800.0E-18)
*
.ENDS
**********
*SYM=UA741
.SUBCKT UA741 2 3 6 7 4
* - IN + OUT VCC VEE
*
QNI1 10 2 13 QNI1
QNI2 12 3 13 QNI2
.MODEL QNI1 NPN(NF=1.5 BF=111 IS=8E-16 CJE=3PF)
.MODEL QNI2 NPN(NF=1.5 BF=144 IS=8.3E-16 CJE=3PF)
Q3 13 14 4 QN741
IEE 4 14 185NA
CCM 13 4 2.5PF
RCM 13 4 10MEG
RC1 11 10 1K
RC2 11 12 1K
CHF 10 12 55PF
D1 7 11 D741
RP 7 4 10K
GA 0 15 12 10 .9MMHO
GCM 0 15 13 0 6.3NMHOS
R2 15 0 100K
D2 15 0 D741 OFF
D3 0 15 D741 OFF
C2 15 16 30PF
GB 16 0 15 0 12.5
RO2 16 0 1000
D4 16 17 D741P OFF
EP 17 0 7 0 -1.8 1
D5 18 16 D741P OFF
EN 0 18 0 4 -2.3 1
.MODEL D741P D(RS=1M)
D6 19 16 D741
D7 16 20 D741
IRO 20 19 170UA
RR0 16 21 1MEG
Q4 7 19 21 QNO
Q5 4 20 21 QPO
.MODEL QNO NPN(BF=150 CJC=3P IS=1E-14)
.MODEL QPO PNP(BF=150 CJC=3P IS=1E-14)
L1 21 6 30UHY
RL1 21 6 1K
.MODEL D741 D(CJO=3PF)
.MODEL QN741 NPN
.ENDS
***************
*SYM=LF156
* NOTE RS1,RS2 ELIMINATED
*BETA AND ISS SET NOISE AND SLEW LIMIT
*BETA = .707*WT/((dV/dt)*Rn)
*ISS = 2/(BETA*Rn*Rn)
*where Rn is the equivalent noise resistor
* WT is the radian gain-bandwidth product
* dV/dt is the slew limit
.SUBCKT LF156 2 3 6 7 4
* - IN + OUT VCC VEE
*
RP 7 4 6K
ISS 7 13 660UA
J1 10 2 13 JFET1
J2 12 3 13 JFET2
D1 10 12 DSLEW
.MODEL DSLEW D(IS=1E-8)
RD1 4 10 1500
RD2 4 12 1500
*GD1 10 4 10 4 .00115
*GD2 12 4 10 4 .00115
C1 10 12 8PF
.MODEL JFET1 PJF(VTO=-1 BETA=1.9E-4 IS=12E-12 CGD=6PF KF=8E-18)
.MODEL JFET2 PJF(VTO=-1.003 BETA=1.9E-4 IS=15E-12 CGD=6PF KF=8E-18)
GA 0 15 12 10 .29MMHO
GCM 0 15 13 0 2NMHOS
R2 15 0 80K
D2 15 0 D156 OFF
D3 0 15 D156 OFF
C2 15 16 7PF
GB 16 0 15 0 12.5
RO2 16 0 1000
D4 16 17 D156P OFF
EP 17 0 7 0 -3.0 1
D5 18 16 D156P OFF
EN 0 18 0 4 -3.0 1
.MODEL D156P D(RS=1M)
D6 19 16 D156
D7 16 20 D156
IRO 20 19 170UA
RR0 16 21 1MEG
Q4 7 19 21 QNO
Q5 4 20 21 QPO
.MODEL QNO NPN(BF=150 IS=1E-14 CJC=3P)
.MODEL QPO PNP(BF=150 IS=1E-14 CJC=3P)
L1 21 6 1UHY
RL1 21 6 100
.MODEL D156 D(CJO=3PF)
.ENDS
******************
*SYM=ADOPAMP
* LM324 OPERATIONAL AMPLIFIER
*
* CONNECTIONS:
* 1 - NON-INVERTING INPUT
* 2 - INVERTING INPUT
* 3 - POSITIVE POWER SUPPLY
* 4 - NEGATIVE POWER SUPPLY
* 5 - OUTPUT
*
.SUBCKT LM324M 1 2 3 4 5
*
C1 11 12 3.000E-12
C2 6 7 6.000E-12
CEE 10 99 315.8E-15
DC 5 53 DX
DE 54 5 DX
DLP 90 91 DX
DLN 92 90 DX
DP 4 3 DX
EGND 99 0 POLY(2) 3 0 4 0 0 .5 .5
FB 7 99 POLY(5) VB VC VE VLP VLN 0 53.05E6
+ -50E6 50E6 50E6 -50E6
GA 6 0 11 12 37.70E-6
GCM 0 6 10 99 11.92E-9
IEE 3 10 DC 2.476E-6
HLIM 90 0 VLIM 1K
Q1 11 2 13 QX
Q2 12 1 14 QX
R2 6 9 100.0E3
RC1 4 11 26.53E3
RC2 4 12 26.53E3
RE1 13 10 4.820E3
RE2 14 10 4.820E3
REE 10 99 80.78E6
RO1 8 5 50
RO2 7 99 50
RP 3 4 34.71E3
VB 9 0 DC 0
VC 3 53 DC 2
VE 54 4 DC .6
VLIM 7 8 DC 0
VLP 91 0 DC 40
VLN 0 92 DC 40
.MODEL DX D(IS=800.0E-18)
.MODEL QX PNP(IS=800.0E-18 BF=31.58)
.ENDS
**********
*SYM=COREZ
.SUBCKT TLMAG005 1 2 3 {BI=0 N=100 ACORE=.89 LM=11.23}
* TELMAG 'C' Cores 0.05mm type
* Default is Q 3.1 with 100 turns
*Units are CGS
*AC = {ACORE} Magnetic Cross Section Area in cm^2
*LPATH = {LM} Magnetic Path Length in cm
*N = {N} Turns
*BR = 13K Flux Density in Gauss at H = 0 for Saturated B-H Loop
*BI = {BI} Initial Flux density, Default = 0
*UMAX = 17400 Maximum Permeability, dB/dH
*UMIN = 99.6 Saturation Permeability, dB/dH
*FC = 50000 Frequency when LMAG Reactance = Loss Resistance
*VSEC/TURN = {2*13000*ACORE*1E-8}
*Lmax\turn-sq = {17400*1.25e-8*ACORE/LM}
*Lsat \turn-sq = {99.6*1.25e-8*ACORE/LM}
RX 3 2 1E12
CB 3 2 {N*2*13000*ACORE*1E-8/500} IC={BI/13000*500}
F1 1 2 VM1 1
G2 2 3 1 2 1
E1 4 2 3 2 1
VM1 4 5
RB 5 2 {.625*N*17400/(LM * 13000)*500}
RS 5 6 {.625*N*99.6/(LM * 13000)*500}
VP 7 2 250
D1 6 7 DCLAMP
VN 2 8 250
D2 8 6 DCLAMP
* MULTIPLIER 3 AND VJ=25 GO TOGETHER
.MODEL DCLAMP D(CJO={3*LM * 13000/(6.28*300*50000*.625*N*17400)} VJ=25)
.ENDS
*********************
*SYM=HC04
*DWG=C:\MODELS\DIGITAL\CMOS\HC\SUBCKTS\HC04.DWG
.SUBCKT HC04 11 8 2 7 {LIN=3.1N CIN=1.17P LOUT=2.9N COUT=1.03P }
* In Vcc Gnd Out
X9 3 8 2 5 HCINV
X10 5 8 2 4 HCINV
X11 4 8 2 6 HCINV
LIN 11 3 {LIN}
CIN 3 0 {CIN}
LOUT 6 7 {LOUT}
COUT 6 0 {COUT}
.ENDS
*******
*SYM=AND2
.SUBCKT AND2 1 2 3
* A B Out
B1 4 0 V= V(1)&V(2)
RD 4 3 1
CD 3 0 .87NF
.ENDS
******
*SYM=OR2
.SUBCKT OR2 1 2 3
* A B Out
B1 4 0 V= V(1)|V(2)
RD 4 3 1
CD 3 0 .87NF
.ENDS
******
*SYM=NAND2
.SUBCKT NAND2 1 2 3
* A B Out
B1 4 0 V= ~(V(1)&V(2))
RD 4 3 1
CD 3 0 .87NF
.ENDS
******
*SYM=NOR2
.SUBCKT NOR2 1 2 3
* A B Out
B1 4 0 V= ~(V(1)|V(2))
RD 4 3 1
CD 3 0 .87NF
.ENDS
******
*SYM=DFLOP
* PIN Outs are the same as the 7474
.SUBCKT DFLOP 1 2 3 4 5 6
*CLRN D CLK PREN Q QN
X1 4 12 11 13 NAND3 {IC=0}
X2 13 1 3 11 NAND3 {IC=1}
X3 11 3 12 10 NAND3 {IC=0}
X4 10 1 2 12 NAND3 {IC=1}
X5 4 11 6 5 NAND3 {IC=0}
X6 5 1 10 6 NAND3 {IC=1}
.ENDS
**************
*SYM=INV
.SUBCKT INV 1 2
* in out
B1 3 0 V= ~V(1)
RD 3 2 1
CD 2 0 .87NF
.ENDS
******
*SYM=7402
.SUBCKT SN7402 13 14 10 11 3
* CONNECTIONS A B O VC VE
Q2 6 1 14 QC
R1 1 11 4K
R2 11 5 4K
D1 3 13 DA
D2 3 14 DA
Q3 8 7 2 QC
Q4 8 6 2 QC
R3 11 8 1.6K
Q5 12 8 9 QC 5
D3 9 10 DA
R4 2 3 1.1K
Q6 10 2 3 QC 5
R5 11 12 133
Q1 7 5 13 QC
.MODEL QC NPN BF=20 BR=1 RB=70 RC=40 IS=1.0E-14 VA=50 CJE=10P
.MODEL DA D RS=40 IS=1.0E-14 CJO=1PF
.ENDS
**********
*SYM=POLE2
.SUBCKT POLE2 1 2
*PARAMS ARE: DC GAIN = {K}
* FREQ = {FN}
* DAMPING = {Z}
*
*TRANSFER FUNCTION: K*WN^2/(S^2 +2*Z*WN*S + WN^2)
* WHERE WN=2*PI*FN
RI 1 0 1E12
E1 3 0 1 0 {K}
R1 3 4 1MEG
E2 5 0 0 4 1E6
C1 4 5 {.159155U/FN} IC=0
RZ 4 5 {.5MEG/Z}
R2 5 7 -1MEG
E3 2 0 0 7 1E6
C2 2 7 {.159155U/FN} IC=0
R3 2 4 1MEG
.ENDS
***************
*SYM=PZ
.SUBCKT PZ 1 2
*PARAMS ARE DC GAIN = {K}
* POLE FREQ = {FP} HERTZ
* ZERO FREQ = {FO} HERTZ
*
E1 0 3 1 0 {K}
RI 1 0 1E12
R1 3 4 1MEG
R2 4 2 1MEG
C1 3 4 {1U/(6.28319*FO)}
C2 2 4 {1U/(6.28319*FP)}
E2 2 0 0 4 1E6
.ENDS
***************
*SYM=OPTO
.SUBCKT ON22 1 2 3 4 5
*OPTO ISOLATOR ANODE CATHODE COL BASE EMITTER
*TI 4N22
VM 1 6
D1 6 2 LED
H1 7 0 VM .8M
R1 7 8 1K
C1 8 0 100PF
G1 3 4 8 0 1
Q1 3 4 5 QOPTO
.MODEL LED D(N=2.50 RS=.0001 CJO=40PF IS=306E-12)
.MODEL QOPTO NPN(IS=7.0E-12 NF=1.23 CJC=4PF
+ CJE=14PF TF=10NS TR=10NS BF=500 BR=10
+ IKF=750MA VAF=40)
.ENDS
******************
*SYM=SWITCH
*OPEN WHEN V(3,0) = 0, CLOSED WHEN V(3,0) <> 0
*ON RESISTANCE IS 1 / V(3)
*OFF RESISTANCE IS 1E12
.SUBCKT SWITCH 1 2 3
R1 1 2 1E10
G1 1 2 POLY(2) 1 2 3 0 0 0 0 0 1
.ENDS
*********