********************************************************* * Spice file generated by gnetlist * * spice-SDB version 3.30.2003 by SDB -- * * provides advanced spice netlisting capability. * * Documentation at http://www.brorson.com/gEDA/SPICE/ * ********************************************************* * Batch command * ngspice -b -o output.log output.net * will generate a nice printer plot in output.log * (remember the old times !) * Interactive commands for usage: * run * plot vout1 vout2 * Command stuff .options gmin=1e-9 .options method=gear .options abstol=1e-11 * .ac dec 10 10MegHz 10 Ghz * Remainder of file R112 0 6 1Meg R111 0 8 10Meg R110 0 7 1Meg Rref2in 11 VU780out 25000 Rref2fb VU2bias+ 11 33 C201 0 9 1uF C202 10 0 1uF XU200 0 11 10 9 VU2bias+ OP177A R202 10 +5V 22 R201 -5V 9 22 Rref1in VU100in- VU780out 9130 Rref1fb VU1bias+ VU100in- 33 XU101 +5V 7 0 6 VU780out 8 AD780A * AD780A SPICE Macromodel 5/93, Rev. A * AAG / PMI * * This version of the AD780 voltage reference model simulates the worst case * parameters of the 'A' grade. The worst case parameters used * correspond to those in the data sheet. * * Copyright 1993 by Analog Devices, Inc. * * Refer to "README.DOC" file for License Statement. Use of this model * indicates your acceptance with the terms and provisions in the License Statement. * * NODE NUMBERS * VIN * | TEMP * | | GND * | | | TRIM * | | | | VOUT * | | | | | RANGE * | | | | | | .SUBCKT AD780A 2 3 4 5 6 8 * * BANDGAP REFERENCE * I1 4 40 DC 1.21174E-3 R1 40 4 1E3 TC=7E-6 EN 10 40 42 0 1 G1 4 10 2 4 4.85668E-9 F1 4 10 POLY(2) VS1 VS2 (0,2.42834E-5,3.8E-5) Q1 2 10 11 QT I2 11 4 DC 12.84E-6 R2 11 3 1E3 I3 3 4 DC 0 * * NOISE VOLTAGE GENERATOR * VN1 41 0 DC 2 DN1 41 42 DEN DN2 42 43 DEN VN2 0 43 DC 2 * * INTERNAL OP AMP * G2 4 12 10 20 1.93522E-4 R3 12 4 2.5837E9 C1 12 4 6.8444E-11 D1 12 13 DX V1 2 13 DC 1.2 * * SECONDARY POLE @ 508 kHz * G3 4 14 12 4 1E-6 R4 14 4 1E6 C2 14 4 3.1831E-13 * * OUTPUT STAGE * ISY 2 4 6.8282E-4 FSY 2 4 V1 -1 RSY 2 4 500E3 * G4 4 15 14 4 25E-6 R5 15 4 40E3 Q2 4 15 16 QP I4 2 16 DC 100E-6 Q3 4 16 18 QP R6 18 23 15 R7 16 21 150E3 R8 2 17 34.6 Q4 17 16 19 QN R9 21 20 6.46E3 R10 20 4 6.1E3 R11 20 5 53E3 R12 20 8 15.6E3 I5 5 4 DC 0 I6 8 4 DC 0 VS1 21 19 DC 0 VS2 23 21 DC 0 L1 21 6 1E-7 * * OUTPUT CURRENT LIMIT * FSC 15 4 VSC 1 VSC 2 22 DC 0 QSC 22 2 17 QN * .MODEL QT NPN(level=1 IS=1.68E-16 BF=1E4) .MODEL QN NPN(level=1 IS=1E-15 BF=1E3) .MODEL QP PNP(level=1 IS=1E-15 BF=1E3) .MODEL DX D(IS=1E-15) .MODEL DEN D(IS=1E-12 RS=2.425E+05 AF=1 KF=6.969E-16) .ENDS AD780A C101 0 U100V- 1uF C102 U100V+ 0 1uF XU100 0 VU100in- U100V+ U100V- VU1bias+ OP177A * OP177A SPICE Macro-model 12/90, Rev. B * JCB / PMI * * Revision History: * REV. B * Re-ordered subcircuit call out nodes to put the * output node last. * Changed Ios from 1E-9 to 0.5E-9 * Added F1 and F2 to fix short circuit current limit. * * * This version of the OP-177 model simulates the worst case * parameters of the 'A' grade. The worst case parameters * used correspond to those in the data book. * * * Copyright 1990 by Analog Devices, Inc. * * Refer to "README.DOC" file for License Statement. Use of this model * indicates your acceptance with the terms and provisions in the License Statement. * * Node assignments * non-inverting input * | inverting input * | | positive supply * | | | negative supply * | | | | output * | | | | | .SUBCKT OP177A 1 2 99 50 39 * * INPUT STAGE & POLE AT 6 MHZ * R1 2 3 5E11 R2 1 3 5E11 R3 5 97 0.0606 R4 6 97 0.0606 CIN 1 2 4E-12 C2 5 6 218.9E-9 I1 4 51 1 IOS 1 2 0.5E-9 EOS 9 10 POLY(1) 30 33 10E-6 1 Q1 5 2 7 QX Q2 6 9 8 QX R5 7 4 0.009 R6 8 4 0.009 D1 2 1 DX D2 1 2 DX EN 10 1 12 0 1 GN1 0 2 15 0 1 GN2 0 1 18 0 1 * EREF 98 0 33 0 1 EPLUS 97 0 99 0 1 ENEG 51 0 50 0 1 * * VOLTAGE NOISE SOURCE WITH FLICKER NOISE * DN1 11 12 DEN DN2 12 13 DEN VN1 11 0 DC 2 VN2 0 13 DC 2 * * CURRENT NOISE SOURCE WITH FLICKER NOISE * DN3 14 15 DIN DN4 15 16 DIN VN3 14 0 DC 2 VN4 0 16 DC 2 * * SECOND CURRENT NOISE SOURCE * DN5 17 18 DIN DN6 18 19 DIN VN5 17 0 DC 2 VN6 0 19 DC 2 * * FIRST GAIN STAGE * R7 20 98 1 G1 98 20 5 6 119.8 D3 20 21 DX D4 22 20 DX E1 97 21 POLY(1) 97 33 -2.4 1 E2 22 51 POLY(1) 33 51 -2.4 1 * * GAIN STAGE & DOMINANT POLE AT 0.127 HZ * R8 23 98 1.253E9 C3 23 98 1E-9 G2 98 23 20 33 33.3E-6 V1 97 24 1.8 V2 25 51 1.8 D5 23 24 DX D6 25 23 DX * * NEGATIVE ZERO AT -4MHZ * R9 26 27 1 C4 26 27 -39.75E-9 R10 27 98 1E-6 E3 26 98 23 33 1E6 * * COMMON-MODE GAIN NETWORK WITH ZERO AT 63 HZ * R13 30 31 1 L2 31 98 2.52E-3 G4 98 30 3 33 0.316E-6 D7 30 97 DX D8 51 30 DX * * POLE AT 2 MHZ * R14 32 98 1 C5 32 98 79.5E-9 G5 98 32 27 33 1 * * OUTPUT STAGE * R15 33 97 1 R16 33 51 1 GSY 99 50 POLY(1) 99 50 0.725E-3 0.0425E-3 F1 34 0 V3 1 F2 0 34 V4 1 R17 34 99 400 R18 34 50 400 L3 34 39 2E-7 G6 37 50 32 34 2.5E-3 G7 38 50 34 32 2.5E-3 G8 34 99 99 32 2.5E-3 G9 50 34 32 50 2.5E-3 V3 35 34 6.8 V4 34 36 4.4 D9 32 35 DX D10 36 32 DX D11 99 37 DX D12 99 38 DX D13 50 37 DY D14 50 38 DY * * MODELS USED * .MODEL QX NPN(level=1 BF=333.3E6) .MODEL DX D(IS=1E-15) .MODEL DY D(IS=1E-15 BV=50) .MODEL DEN D(IS=1E-12, RS=14.61K, KF=2E-17, AF=1) .MODEL DIN D(IS=1E-12, RS=7.55E-6, KF=3E-15, AF=1) .ENDS R102 U100V+ +5V 22 R101 -5V U100V- 22 R98 0 VU2bias+ 1K R99 0 VU1bias+ 1K C95 VU2bias+ 0 100pF * C96 0 5 1uF * C97 4 0 1uF Cphotodiode 0 Vinput 0.9pF C99 0 VU1bias+ 100pF R25 Vout2 2 250 C24 Vout1 VU1in- 1pF R24 VU1in- 1 150 * C21 0 3 1uF Cc Vout2 VU2in- 1pF Rc Vout1 VU2in- 10 RL 0 Vout2 50 .TEMP 0 25 50 75 100 C12 2 0 1.5pF C11 0 V2- .01uF C10 V2+ 0 .01uF R13 +5V V2+ 5 R12 V2- -5V 5 R26 2 VU2in- 150 R11 Vout2 VU2in- 180 XU2 VU2bias+ VU2in- V2+ V2- Vout2 AD8009an XU1 VU1bias+ VU1in- V1+ V1- Vout1 AD8009an ***** AD8009 SPICE model Rev B SMR/ADI 8-21-97 * Copyright 1997 by Analog Devices, Inc. * Refer to "README.DOC" file for License Statement. Use of this model * indicates your acceptance with the terms and provisions in the License Statement. * rev B of this model corrects a problem in the output stage that would not * correctly reflect the output current to the voltage supplies * This model will give typical performance characteristics * for the following parameters; * closed loop gain and phase vs bandwidth * output current and voltage limiting * offset voltage (is static, will not vary with vcm) * ibias (again, is static, will not vary with vcm) * slew rate and step response performance * (slew rate is based on 10-90% of step response) * current on output will be reflected to the supplies * vnoise, referred to the input * inoise, referred to the input * distortion is not characterized * Node assignments * non-inverting input * | inverting input * | | positive supply * | | | negative supply * | | | | output * | | | | | .SUBCKT AD8009an 1 2 99 50 28 * input stage * q1 50 3 5 qp1 q2 99 5 4 qn1 q3 99 3 6 qn2 q4 50 6 4 qp2 i1 99 5 1.625e-3 i2 6 50 1.625e-3 cin1 1 98 2.6e-12 cin2 2 98 1e-12 v1 4 2 0 * input error sources * eos 3 1 poly(1) 20 98 2e-3 1 fbn 2 98 poly(1) vnoise3 50e-6 1e-3 fbp 1 98 poly(1) vnoise3 50e-6 1e-3 * slew limiting stage * fsl 98 16 v1 1 dsl1 98 16 d1 dsl2 16 98 d1 dsl3 16 17 d1 dsl4 17 16 d1 rsl 17 18 0.22 vsl 18 98 0 * gain stage * f1 98 7 vsl 2 rgain 7 98 2.5e5 cgain 7 98 1.25e-12 dcl1 7 8 d1 dcl2 9 7 d1 vcl1 99 8 1.83 vcl2 9 50 1.83 gcm 98 7 poly(2) 98 0 30 0 0 1e-5 1e-5 * second pole * epole 14 98 7 98 1 rpole 14 15 1 cpole 15 98 2e-10 * reference stage * eref 98 0 poly(2) 99 0 50 0 0 0.5 0.5 ecmref 30 0 poly(2) 1 0 2 0 0 0.5 0.5 * vnoise stage * rnoise1 19 98 4.6e-3 vnoise1 19 98 0 vnoise2 21 98 0.53 dnoise1 21 19 dn fnoise1 20 98 vnoise1 1 rnoise2 20 98 1 * inoise stage * rnoise3 22 98 8.18e-6 vnoise3 22 98 0 vnoise4 24 98 0.575 dnoise2 24 22 dn fnoise2 23 98 vnoise3 1 rnoise4 23 98 1 * buffer stage * gbuf 98 13 15 98 1e-2 rbuf 98 13 1e2 * output current reflected to supplies * fcurr 98 40 voc 1 vcur1 26 98 0 vcur2 98 27 0 dcur1 40 26 d1 dcur2 27 40 d1 * output stage * vo1 99 90 0 vo2 91 50 0 fout1 0 99 poly(2) vo1 vcur1 -9.27e-3 1 -1 fout2 50 0 poly(2) vo2 vcur2 -9.27e-3 1 -1 gout1 90 10 13 99 0.5 gout2 91 10 13 50 0.5 rout1 10 90 2 rout2 10 91 2 voc 10 28 0 rout3 28 98 1e6 dcl3 13 11 d1 dcl4 12 13 d1 vcl3 11 10 -0.445 vcl4 10 12 -0.445 .model qp1 pnp(level=1) .model qp2 pnp(level=1) .model qn1 npn(level=1) .model qn2 npn(level=1) .model d1 d() .model dn d(af=1 kf=1e-8) .ends R6 1 Vout1 250 C3 1 0 1.5pF V3 VU1in- Vinput DC 0V * .INCLUDE /home/sdb/OpticalReceiver/Simulation.cmd R5 -5V Vout1 1K I1 0 Vinput AC 1 PWL (0ns 0mA 1nS 0mA 1.01nS 1mA 10nS 1mA 10.01nS 0mA 20nS 0mA 20.01nS .1mA 30nS .1mA 30.01nS 0mA) R4 V1- -5V 5 C2 0 V1- .01uF V2 -5V 0 DC -5V R2 VU1in- Vout1 180 V1 +5V 0 DC 5V C1 V1+ 0 .01uF R1 +5V V1+ 5 * When run, this SPICE file should output a square waveform * with a little overshoot .tran 0.05ns 40ns .plot tran Vout2 .END