There are no reference for testing - moved to examples

17 years ago · 5ab7e9d384
4 changed files with 0 additions and 506 deletions
--- a/tests/TransImpedanceAmp/.cvsignore
+++ b/tests/TransImpedanceAmp/.cvsignore
@ -1,2 +0,0 @@
 Makefile.in
 Makefile
--- a/tests/TransImpedanceAmp/Makefile.am
+++ b/tests/TransImpedanceAmp/Makefile.am
@ -1,10 +0,0 @@
 ## Process this file with automake to produce Makefile.in
 TESTS = \
 	output.net
 TESTS_ENVIRONMENT = $(SHELL) $(srcdir)/../check.sh $(top_builddir)/src/ngspice
 EXTRA_DIST = output.net README
 MAINTAINERCLEANFILES = Makefile.in
--- a/tests/TransImpedanceAmp/README
+++ b/tests/TransImpedanceAmp/README
@ -1,41 +0,0 @@
 This directory holds a SPICE netlist with SPICE2 POLY constructs in
 controlled sources as typically found in vendor models.  The circuit
 is just a two-stage transimpedance amp using an AD8009,
 along with some slow components (AD780 and OP177A) to set bias
 points.  Vendor models are used for all active components.
 Successfully running this test shows that you have successfully built
 the XSpice stuff with the POLY codemodel, and that you should be able
 to simulate SPICE netlists with embedded vendor models.
 To run this netlist, just do the following:
 [localhost]# ngspice
 ngspice 1 -> source output.net
 ngspice 2 -> run
 ngspice 3 -> plot Vout2
 (Note that when you read in the netlist, you will get a bunch of 
 warnings saying stuff like:
 Warning -- Level not specified on line "()"
 Using level 1.
 Also, ngspice will complain about:
 Error on line 50 : r:u101:1 u101:40 0 1e3 tc=7e-6
         unknown parameter (tc)
 Error on line 283 : .temp 0 25 50 75 100
         Warning: .TEMP card obsolete - use .options TEMP and TNOM
 You can ignore all this stuff . . . .)
 You should get a pop-up window showing two square pulses (the second
 smaller than the first) with a little bit of overshoot on the rising
 and falling edges.
 This stuff was done as an adjunct to work on the gEDA project.
 Information about gEDA is available at http://geda.seul.org/ .
 Please direct all questions/suggestions/bugs/complaints about XSpice
 extensions to ngspice to Stuart Brorson -- mailto:sdb@cloud9.net.
 6.23.2002 -- SDB.
--- a/tests/TransImpedanceAmp/output.net
+++ b/tests/TransImpedanceAmp/output.net
@ -1,453 +0,0 @@
 *********************************************************
 * 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/   *
 *********************************************************
 * Command stuff
 .options gmin=1e-9 noacct
 .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(IS=1.68E-16 BF=1E4)
 .MODEL QN NPN(IS=1E-15 BF=1E3)
 .MODEL QP PNP(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(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()
 .model qp2 pnp()
 .model qn1 npn()
 .model qn2 npn()
 .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 Vout2
 .END