*
* modello OP27 "vecchio", scaricato chissa' quando dal sito AD
*
* OP27 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 7E-9 to 3.5E-9
*     Added F1 and F2 to fix short circuit current limit.
*
*
* 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 OP27     1 2 99 50 39
*
* INPUT STAGE & POLE AT 80 MHZ
*
R3   5  97    0.0619
R4   6  97    0.0619
CIN  1   2    4E-12
C2   5   6    16.07E-9
I1   4  51    1
IOS  1   2    3.5E-9
EOS  9  10    POLY(1)  30 33  10E-6  1
Q1   5  2  7  QX
Q2   6  9  8  QX
R5   7   4    0.0107
R6   8   4    0.0107
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
*
* GAIN STAGE & DOMINANT POLE AT 4.0 HZ
*
R7   20 98     111.5E3
C3   20 98     357E-9
G1   98 20     5  6  16.15
V1   97 21     1.2
V2   22 51     1.2
D5   20 21     DX
D6   22 20     DX
*
* POLE - ZERO AT 2.9MHZ / 6MHZ
*
R8   23 98     1
R9   23 24     0.935
C4   24 98     28.4E-9
G2   98 23     20 33  1
*
* ZERO - POLE AT 6.8MHZ / 40MHZ
*
R10  25 26     1
R11  26 98     4.88
L1   26 98     19.4E-9
G3   98 25     23 33  1
*
* POLE AT 60 MHZ
*
R12  27 98     1
C5   27 98     2.65E-9
G4   98 27     25 33 1
*
* ZERO AT 28 MHZ
*
R13  28 29     1
C6   28 29     -5.68E-9
R14  29 98     1E-6
E1   28 98     27 33  1E6
*
* COMMON-MODE GAIN NETWORK WITH ZERO AT 3 KHZ
*
R15  30 31     1
L2   31 98     53.1E-6
G5   98 30     POLY(2) 2  33  1  33  0  250.5E-9  250.5E-9
D7   30 97     DX
D8   51 30     DX
*
* POLE AT 80 MHZ
*
R16  32 98     1
C7   32 98     1.99E-9
G6   98 32     29 33  1
*
* OUTPUT STAGE
*
R17  33 97     1
R18  33 51     1
GSY  99 50     POLY(1) 99 50 1.8E-3 40E-6
F1   34  0     V3  1
F2   0  34     V4  1
R19  34 99     180
R20  34 50     180
L3   34 39     1E-7
G7   37 50     32 34  5.56E-3
G8   38 50     34 32  5.56E-3
G9   34 99     99 32  5.56E-3
G10  50 34     32 50  5.56E-3
V3   35 34     2.5
V4   34 36     3.1
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=50E6)
.MODEL DX   D(IS=1E-15)
.MODEL DY   D(IS=1E-15 BV=50)
.MODEL DEN  D(IS=1E-12, RS=1.09K, KF=1.08E-16, AF=1)
.MODEL DIN  D(IS=1E-12, RS=19.3E-6, KF=4.28E-15, AF=1)
.ENDS


* fine OP27


*==================================================================

*   This is a Wide band Low Cost, Low Power Monolithic
*   Current Feedback Op Amp.
*
* Version 1, Rev. C, Date 07-08-94, by KEB
*
* Connections: Non-Inverting Input
*              | Inverting
*              | | Output
*              | | | +Vcc
*              | | | | -Vee
*              | | | | |
*              | | | | |
*              | | | | |
*              | | | | |
.SUBCKT CLC406 3 2 6 7 4
*
* BIAS BLOCK
*
G1 7 10 POLY(1) 7 14 123U 1.674M
C2 10 0 644F
C3 10 14 143F
R1 7 14 524
*
G3 16 4 POLY(1) 13 4 0 1.649M
C5 16 0 551F
C4 13 16 84.0F
R2 13 4 532
*
* INPUT STAGE
*
C1 3 0 1.00P
E1 3 12 POLY(2) 50 0 51 0 -1.50M 1.00 1.00
G2 12 0 POLY(2) 52 0 53 0 0 1.00M 1.00M
*
D1 10 11 DX
Q1 13 12 11 QINP
Q2 14 12 15 QINN
D2 15 16 DX
*
G4 21 0 POLY(2) 54 0 55 0 -14.0U 1.00M 1.00M
Q3 21 10 22 QINN
D3 22 2 DX
C6 2 0 2.07P
D4 2 23 DX
Q4 24 16 23 QINP
*
* GAIN STAGE
*
R3 7 20 591
V1 20 21 1.96
C7 21 31 131F
G5 7 31 POLY(2) 7 20 7 31 0 3.881M 7.32U
V3 7 30 1.96
D5 31 30 DOR
G7 7 40 POLY(1) 7 20 0 4.633M
C10 21 40 217F
C11 40 0 475F
C14 21 6 300F
*
R4 25 4 589
V2 24 25 2.05
C9 24 31 76.6F
G6 31 4 POLY(2) 25 4 31 4 0 3.997M 1.05U
V4 32 4 2.44
D6 32 31 DOR
G8 42 4 POLY(1) 25 4 0 2.229M
C12 24 42 139F
C13 42 0 634F
C16 24 6 300F
*
* OUTPUT STAGE
*
C8 31 0 474F
Q5 4 31 40 QOUTP1
Q6 7 31 41 QOUTN1 0.67
D7 41 42 DX 1.88
Q7 7 31 43 QOUTN1 0.33
Q8 4 42 43 QOUTP1 0.50
*
Q9 7 40 6 QOUTN2
C15 6 0 2.50P
Q10 4 43 6 QOUTP2
*
* NOISE BLOCKS
*
I1 51 50 DC 121U
D8 50 0 DN1
D9 0 51 DN1
*
I2 53 52 DC 413U
D10 52 0 DN2
D11 0 53 DN2
*
I3 55 54 DC 14.3U
D12 54 0 DN3
D13 0 55 DN3
*
* MODELS
*
.MODEL DN1 D IS=0.166F KF=4.48F AF=1.00
.MODEL DN2 D IS=0.166F KF=82.4F AF=1.00
.MODEL DN3 D IS=0.166F KF=47.6F AF=1.00
.MODEL DOR D TT=100N
.MODEL DX D IS=0.165F RS=583M CJO=159F M=495M VJ=797M TT=25.5P
*
.MODEL QINN NPN
+ IS =1.652E-16 BF =3.239E+02 NF =1.000E+00 VAF=4.229E+01
+ IKF=2.462E-02 ISE=2.956E-17 NE =1.197E+00 BR =3.719E+01
+ NR =1.000E+00 VAR=1.696E+00 IKR=3.964E-02 ISC=1.835E-19
+ NC =1.700E+00 RB =1.180E+02 IRB=0.000E+00 RBM=6.506E+01
+ RE =5.613E-01 RC =2.645E+01 CJE=1.588E-13 VJE=7.973E-01
+ MJE=4.950E-01 TF =1.948E-11 XTF=1.873E+01 VTF=2.825E+00
+ ITF=5.955E-02 PTF=0.000E+00 CJC=1.720E-13 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=8.61E-01 TR =4.212E-10 CJS=1.136E-12
+ VJS=5.723E-01 MJS=0.000E+00 FC =9.765E-01
*
.MODEL QOUTN1 NPN
+ IS =7.822E-16 BF =3.239E+02 NF =1.000E+00 VAF=8.457E+01
+ IKF=9.079E-02 ISE=1.090E-16 NE =1.197E+00 BR =3.960E+01
+ NR =1.000E+00 VAR=1.696E+00 IKR=1.462E-01 ISC=5.656E-19
+ NC =1.700E+00 RB =1.843E+01 IRB=0.000E+00 RBM=4.083E+00
+ RE =1.522E-01 RC =6.141E+00 CJE=5.858E-13 VJE=7.973E-01
+ MJE=4.950E-01 TF =1.874E-11 XTF=1.873E+01 VTF=2.825E+00
+ ITF=2.196E-01 PTF=0.000E+00 CJC=5.143E-13 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=1.71E-01 TR =1.069E-09 CJS=8.567E-13
+ VJS=5.723E-01 MJS=4.105E-01 FC =9.765E-01
*
.MODEL QOUTN2 NPN
+ IS =1.880E-15 BF =3.239E+02 NF =1.000E+00 VAF=8.457E+01
+ IKF=2.182E-01 ISE=2.620E-16 NE =1.197E+00 BR =3.971E+01
+ NR =1.000E+00 VAR=1.696E+00 IKR=3.513E-01 ISC=1.348E-18
+ NC =1.700E+00 RB =3.267E+01 IRB=0.000E+00 RBM=2.670E+01
+ RE =1.006E+01 RC =3.738E+00 CJE=1.408E-12 VJE=7.973E-01
+ MJE=4.950E-01 TF =1.871E-11 XTF=1.873E+01 VTF=2.825E+00
+ ITF=5.278E-01 PTF=0.000E+00 CJC=1.224E-12 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=9.27E-01 TR =1.296E-09 CJS=1.496E-12
+ VJS=5.723E-01 MJS=4.105E-01 FC =9.765E-01
*
.MODEL QINP PNP
+ IS =1.652E-16 BF =7.165E+01 NF =1.000E+00 VAF=1.720E+01
+ IKF=1.882E-02 ISE=6.380E-16 NE =1.366E+00 BR =1.833E+01
+ NR =1.000E+00 VAR=1.805E+00 IKR=1.321E-01 ISC=3.666E-18
+ NC =1.634E+00 RB =7.876E+01 IRB=0.000E+00 RBM=5.757E+01
+ RE =6.118E-01 RC =3.739E+01 CJE=1.588E-13 VJE=7.975E-01
+ MJE=5.000E-01 TF =3.156E-11 XTF=5.386E+00 VTF=2.713E+00
+ ITF=5.084E-02 PTF=0.000E+00 CJC=2.725E-13 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=8.61E-01 TR =1.096E-09 CJS=1.136E-12
+ VJS=6.691E-01 MJS=0.000E+00 FC =8.803E-01
*
.MODEL QOUTP1 PNP
+ IS =4.744E-16 BF =7.165E+01 NF =1.000E+00 VAF=3.439E+01
+ IKF=6.940E-02 ISE=2.353E-15 NE =1.366E+00 BR =1.948E+01
+ NR =1.000E+00 VAR=1.805E+00 IKR=4.873E-01 ISC=1.322E-17
+ NC =1.634E+00 RB =7.797E+00 IRB=0.000E+00 RBM=2.052E+00
+ RE =1.659E-01 RC =1.037E+01 CJE=5.858E-13 VJE=7.975E-01
+ MJE=5.000E-01 TF =3.073E-11 XTF=5.386E+00 VTF=2.713E+00
+ ITF=1.875E-01 PTF=0.000E+00 CJC=8.147E-13 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=1.71E-01 TR =2.119E-09 CJS=1.364E-12
+ VJS=6.691E-01 MJS=3.950E-01 FC =8.803E-01
*
.MODEL QOUTP2 PNP
+ IS =1.140E-15 BF =7.165E+01 NF =1.000E+00 VAF=3.439E+01
+ IKF=1.668E-01 ISE=5.655E-15 NE =1.366E+00 BR =1.953E+01
+ NR =1.000E+00 VAR=1.805E+00 IKR=1.171E+00 ISC=3.173E-17
+ NC =1.634E+00 RB =2.825E+01 IRB=0.000E+00 RBM=2.585E+01
+ RE =1.006E+01 RC =6.213E+00 CJE=1.408E-12 VJE=7.975E-01
+ MJE=5.000E-01 TF =3.070E-11 XTF=5.386E+00 VTF=2.713E+00
+ ITF=4.506E-01 PTF=0.000E+00 CJC=1.939E-12 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=9.27E-01 TR =2.704E-09 CJS=2.351E-12
+ VJS=6.691E-01 MJS=3.950E-01 FC =8.803E-01
*
.ENDS CLC406
* fine CLC406

*==================================================================

* OA ideale (io)
* connections:   non-inverting input
*                | inverting input
*                | | positive power supply
*                | | | negative power supply
*                | | | | output
*                | | | | |
.subckt OAideale 1 2 3 4 5
*
rvup  3 0 1e3
rvdown 4 0 1e3
rvni  1 0 1e9 
rvii  2 0 1e9
* guadagno openloop 106dB come il 741
e1 5 0 1 2 2e5

.ends
* fine OAideale

*==================================================================

*==================================================================

* OA ideale_non_comp (io)
* connections:             non-inverting input
*                          | inverting input
*                          | | positive power supply
*                          | | | negative power supply
*                          | | | | output
*                          | | | | |
.subckt OA_ideale_non_comp 1 2 3 4 5
*
rvup  3 0 1e3
rvdown 4 0 1e3
rvni  1 0 1e9 
rvii  2 0 1e9

* poli (150, 15k, 1.5M Hz)

e10 10 0 1 2 1
r10 10 11 1k
c10 11  0 1u

e20 20 0 11 0 1
r20 20 21 1k
c20 21  0 10n
  
e30 30 0 21 0 1
r30 30 31 1k
c30 31  0 0.1n

* guadagno openloop 1e5=100dB
e1 5 0 31 0 1e5

.ends
* fine OA_ideale_non_comp

*==================================================================
* CFA ideale (io)
* connections:    non-inverting input
*                 | inverting input
*                 | | positive power supply
*                 | | | negative power supply
*                 | | | | output
*                 | | | | |
.subckt CFAideale 1 2 3 4 5
*
rvup  3 0 1e3
rvdown 4 0 1e3
rni  1 0 1e9 
ein 99 0 1 0 1
* finto generatore di tensione, serve per "leggere" la corrente che controlla "fout"
vdummy 99 2 0
* fxxxx: generatore di corrente controllato in corrente
fout 56 0 vdummy -1 
* cosi' il polo dominante e' a 800KHz
rcut 56 0 200k
ccut 56 0 1p
eout 5 0 56 0 1
.ends
* fine CFA ideale

*==================================================================


* OP37E SPICE Model                        1/90, Rev. A
*                                           ARG / PMI
*
* This version of the OP-37 model simulates the worst case 
* parameters of the 'E' grade.  The worst case parameters
* used correspond to those in the data sheet.
*
* 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 OP37E  1  2  99 50 49
*
* INPUT STAGE & POLE AT 100MHZ
*
R3   5  97    0.0516
R4   6  97    0.0516
CIN  1   2    4E-12
C2   5   6    15.42E-9
I1   4  51    1
IOS  1   2    17.5E-9
EOS  7   3    POLY(1)  30 43  25E-6  1
Q1   5  2  4  QX
Q2   6  7  4  QX
D1   2   1    DX
D2   1   2    DX
EN   3   1    9   0  1
GN1  0   2    12  0  1
GN2  0   1    15  0  1
EREF  98 0    43  0  1
EPLUS 97 0    99  0  1
ENEG  51 0    50  0  1 
*
* VOLTAGE NOISE SOURCE WITH FLICKER NOISE
*
DN1  8   9    DEN
DN2  9   10   DEN
VN1  8   0    DC 2
VN2  0   10   DC 2
*
* CURRENT NOISE SOURCE WITH FLICKER NOISE
*
DN3  11  12   DIN
DN4  12  13   DIN
VN3  11   0   DC 2
VN4  0   13   DC 2
*
* SECOND CURRENT NOISE SOURCE
*
DN5  14  15   DIN
DN6  15  16   DIN
VN5  14   0   DC 2
VN6  0   16   DC 2
*
* 1ST GAIN STAGE
*
R5   17 98    1
G1A  98 17    5  6  98.71
D3   17 18    DX
D4   19 17    DX
E1   97 18    POLY(1) 97 43 -2.14 1
E2   19 51    POLY(1) 43 51 -2.14 1
*
* 2ND GAIN STAGE & DOMINANT POLE AT 58HZ
*
R6   20 98    30.39E3
C3   20 98    90.91E-9
G1B  98 20    17 43  333.3E-3
V1   97 21    3.48
V2   22 51    3.48
D5   20 21    DX
D6   22 20    DX
*
* POLE - ZERO AT .4MHZ / 1.0MHZ
*
R8   23 98    1
R9   23 24    0.667
C4   24 98    238.7E-9
G2   98 23    20 43  1
*
* ZERO - POLE AT 10MHZ / 100MHZ
*
R10  25 26    1
R11  26 98    9
L1   26 98    14.32E-9
G3   98 25    23 43  1
*
* POLE AT 100MHZ
*
R12  27 98    1
C5   27 98    1.59E-9
G4   98 27    25 43  1
*
* POLE AT 100MHZ
*
R13  28 98    1
C6   28 98    1.59E-9
G5   98 28    27 43  1
*
* POLE AT 100MHZ
*
R14  29 98    1
C7   29 98    1.59E-9
G6   98 29    28 43  1
*
* COMMON-MODE GAIN NETWORK WITH ZERO AT 28KHZ
*
R15  30 31    1
L2   31 98    5.68E-6
G7   98 30    POLY(2) 1  43  2  43  0  997.6E-9  997.6E-9
D7   30 97    DX
D8   51 30    DX
*
* POLE AT 100MHZ
*
R16  32 98    1
C8   32 98    1.59E-9
G8   98 32    29 43  1
*
* POLE AT 100MHZ
*
R17  33 98    1
C9   33 98    1.59E-9
G9   98 33    32 43  1
*
* POLE AT 200MHZ
*
R18  34 98    1
C10  34 98    .796E-9
G10  98 34    33 43  1
*
* OUTPUT STAGE
*
F1   44 0     V3 1
F2   0  44    V4 1
R27  43 97    1
R28  43 51    1
GSY  99 50    POLY(1) 99 50 3.32E-3 45E-6
R29  44 99    140
R30  44 50    140
L4   44 49    1E-7
G11  47 50    34 44  7.14E-3
G12  48 50    44 34  7.14E-3
G13  44 99    99 34  7.14E-3
G14  50 44    34 50  7.14E-3
V3   45 44    1.2
V4   44 46    1.55
D9   34 45    DX
D10  46 34    DX
D11  99 47    DX
D12  99 48    DX
D13  50 47    DY
D14  50 48    DY
*
* MODELS USED
*
.MODEL QX NPN(BF=12.5E6)
.MODEL DX   D(IS=1E-15)
.MODEL DY   D(IS=1E-15 BV=50)
.MODEL DEN  D(IS=1E-12, RS=1.74K, KF=4.01E-16, AF=1)
.MODEL DIN  D(IS=1E-12, RS=43.5E-6, KF=11.1E-15, AF=1)
.ENDS
* fine OP37E

*==================================================================

*  AD9632an Spice Macro-model                  3/7/97,SMR,Rev A
*
*  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.
*
* The following parameters are modeled;
*
*    open loop gain and phase vs frequency
*    output clamping voltage and current
*    input common mode range
*    CMRR vs freq
*    Slew rate
*    Output currents are reflected to V supplies
*    I bias is static and will not vary with Vcm
*    Vos is static and will not vary with Vcm 
*    Step response is modeled at gain of 2 w/1k load 
*    Slew rate is based on 10-90% change in output step
*
*    Node assignments
*                non-inverting input
*                | inverting input
*                | | positive supply
*                | | |  negative supply
*                | | |  |  output
*                | | |  |  |
.SUBCKT AD9632an 1 2 99 50 61   


* input stage *

gn 99 2 (36,98) 1
r1 1 18 250k
r2 2 18 250k
cin1 1 98 1.2e-12
cin2 2 98 1.2e-12
ibias1 50 1 8e-6
ibias2 99 2 8e-6
q1 5 17 6 qn1
q2 7 2 8 qn1
eos 17 1 poly(2) (23,98) (34,98) 2e-3 1 0
r3 99 5 50.23
r4 99 7 50.23
r5 6 9 47.63
r6 8 9 47.63
c2 5 7 2.26pf
itail 9 50 0.02
irev 50 99 0.019

* vnoise generation

dn1 30 31 dn
vn1 31 98 0
rn1 31 98 100e-5
vn2 30 98 0.4

hn1 34 98 vn1 1
rn2 34 98 1

* inoise generation

vn3 35 98 0
rn3 35 98 4k

hn2 36 98 vn3 1
rn4 36 98 1e-6

* gain stage,clamping - open loop gain=64dB * 

* pd at 105khz *

gm1 99 10 poly(1) 7 5 0 0.02 0 2.3e-3
gm2 50 10 poly(1) 7 5 0 0.02 0 2.3e-3
r7  99 10 79617
r8  10 50 79617
c3  99 10 13.33pf
c4  10 50 13.33pf
vcl1 99 14 1.65
vcl2 15 50 1.65
d1 10 14 dx
d2 15 10 dx

******** frequency shaping stage ********
***** zero at 200mhz, pole at 600mhz ****

e1 11 98 10 98 3
rz1 11 12 2
rz2 12 13 1
l1 13 98 0.8e-9

***** common mode reference

eref 98 0 poly(2) 99 0 50 0 0 0.5 0.5

***** vcm generation

ecm1 19 98 18 98 38e-5 
rvcm1 19 20 1.9e-9
rvcm2 20 21 1e-12
lcm1 21 98 1.516e-18

ecm2 22 98 20 98 25000
rvcm3 22 23 25e-8
rvcm4 23 24 1e-12
lcm2 24 98 1.990e-18

***** buffer to output stage

gbuf 98 16 12 98 1e-2
rbuf1 98 16 100

***** output current mirrored to supplies

fo1 98 110 vcd 1
do1 110 111 dx
do2 112 110 dx
vi1 111 98 0
vi2 98 112 0
fsy 99 50 poly(2) vi1 vi2 4.73e-3 1 1
iq 99 50 11e-3

***** output stage

go3 60 99 99 16 0.1
go4 50 60 16 50 0.1
r03 60 99 10
r04 60 50 10
vcd 60 62 0
lo1 62 61 0.75e-7
ro2 61 98 1e9
do5 16 70 dx
do6 71 16 dx
vo1 70 60 0.27
vo2 60 71 0.27

.model dx d(is=1e-15)
.model dn d(af=0.6 kf=1.4e-10 is=1e-15)
.model qn1 npn(af=0 kf=1e-30 is=1e-15 bf=1000)
.ends AD9632an
* fine AD9632

*==================================================================


*==================================================================

*
*   This is a Wide band, High Gain Monolithic Current Feedback
*   Op Amp with Fast Settling (.01% in 10nS) and Low Power.
*
* Version 1, Rev. B, Date 03-11-92, By RRS
*
* Connections: Non-Inverting Input
*              | Inverting Input
*              | | Output
*              | | | +Vcc
*              | | | | -Vee
*              | | | | |
.SUBCKT CLC401 3 2 6 7 4 
*
* DC BIAS MIRROR
*
R1 7 9 1112 
R2 9 10 6.27K
R3 10 4 1172 
G1 7 12 POLY(1) 7 9 93.4U .906M
C2 12 0 .37P
G2 15 4 POLY(1) 10 4 0 .87M
C3 15 0 .16P
*
* INPUT VOLTAGE BUFFER
*
E1 3 11 POLY(1) 38 0 0 2.16
C51 11 0 750F
R5 19 4 1550
V1 13 19 2.2
C15 13 0 203F
Q1 13 11 12 QINP
R6 7 20 1478
V2 20 14 1.65 
C16 14 0 227F
Q2 14 11 15 QINN
Q7 2 2 12 QINP
Q8 2 2 15 QINN
G0 2 0 POLY(1) 39 0 0 15.14M
C0 2 0 1.5P
*
* CURRENT MIRROR GAIN BLOCKS
*
G4 16 4 POLY(1) 19 4 0 2.4187M 
G5 17 4 POLY(1) 19 4 0 2.4284M
G3 7 16 POLY(1) 7 20 0 2.904M
G6 7 18 POLY(1) 7 20 0 2.5984M 
R7 16 0 730.96K
C6 16 0 840F
*
* OUTPUT STAGE AND COMPENSATION CAPACITORS
*
C4 14 16 100F 
C5 13 16 100F 
V3 7 21 1.75
V4 22 4 1.5
D1 16 21 DX
D2 22 16 DX
Q3 7 16 17 QOUTN1
Q4 4 16 18 QOUTP1 0.333
Q5 7 118 46 QOUTN2
R10 46 6 10.0
R11 18 118 100
C12 18 0 1.48p
C13 17 0 1.21p
C7 46 0 1.50P
R112 17 117 100
Q6 4 117 46 QOUTP4
*
* NOISE BLOCKS
*
R19 38 0 122
R20 38 0 122
R21 39 0 122
R22 39 0 122
*
* MODELS
*
.MODEL DX D TT=10N
*
.MODEL QINN NPN
+ IS =2.121E-16 BF=3.239E+02   NF =1.000E+00 VAF=8.457E+01
+ IKF=2.462E-02 ISE=2.956E-17  NE =1.197E+00 BR =3.719E+01
+ NR =1.000E+00 VAR=1.696E+00  IKR=3.964E-02 ISC=1.835E-19
+ NC =1.700E+00 RB=6.796E+01   IRB=0.000E+00 RBM=1.506E+01
+ RE =5.613E-01 RC=2.645E+01   CJE=1.588E-13 VJE=7.973E-01
+ MJE=4.950E-01 TF=1.948E-11   XTF=1.873E+01 VTF=2.825E+00
+ ITF=5.955E-02 PTF=0.000E+00  CJC=1.720E-13 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=1.386E-01 TR =4.212E-10 CJS=3.938E-13
+ VJS=5.723E-01 MJS=4.105E-01  KF =2.000E-12 AF =1.000E+00
+ FC =9.765E-01
*
.MODEL QOUTN1 NPN
+ IS =7.822E-16 BF=3.239E+02   NF =1.000E+00 VAF=8.457E+01
+ IKF=9.079E-02 ISE=1.090E-16  NE =1.197E+00 BR =3.960E+01
+ NR =1.000E+00 VAR=1.696E+00  IKR=1.462E-01 ISC=5.656E-19
+ NC =1.700E+00 RB=1.843E+01   IRB=0.000E+00 RBM=4.083E+00
+ RE =1.522E-01 RC=6.141E+00   CJE=5.858E-13 VJE=7.973E-01
+ MJE=4.950E-01 TF=1.874E-11   XTF=1.873E+01 VTF=2.825E+00
+ ITF=2.196E-01 PTF=0.000E+00  CJC=5.143E-13 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=1.709E-01 TR =1.069E-09 CJS=8.567E-13
+ VJS=5.723E-01 MJS=4.105E-01  KF =2.000E-12 AF =1.000E+00
+ FC =9.765E-01
*
.MODEL QOUTN2 NPN
+ IS =1.880E-15 BF=3.239E+02   NF =1.000E+00 VAF=8.457E+01
+ IKF=2.182E-01 ISE=2.620E-16  NE =1.197E+00 BR =3.971E+01
+ NR =1.000E+00 VAR=1.696E+00  IKR=3.513E-01 ISC=1.348E-18
+ NC =1.700E+00 RB=1.076E+02   IRB=0.000E+00 RBM=1.699E+00
+ RE =6.333E-02 RC=3.738E+00   CJE=1.408E-12 VJE=7.973E-01
+ MJE=4.950E-01 TF=1.871E-11   XTF=1.873E+01 VTF=2.825E+00
+ ITF=5.278E-01 PTF=0.000E+00  CJC=1.224E-12 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=1.726E-01 TR =1.296E-09 CJS=1.496E-12
+ VJS=5.723E-01 MJS=4.105E-01  KF =2.000E-12 AF =1.000E+00
+ FC =9.765E-01
*
.MODEL QINP PNP
+ IS =1.286E-16 BF=7.165E+01   NF =1.000E+00 VAF=3.439E+01
+ IKF=1.882E-02 ISE=6.380E-16  NE =1.366E+00 BR =1.833E+01
+ NR =1.000E+00 VAR=1.805E+00  IKR=1.321E-01 ISC=3.666E-18
+ NC =1.634E+00 RB=2.876E+01   IRB=0.000E+00 RBM=7.568E+00
+ RE =6.118E-01 RC=3.739E+01   CJE=1.588E-13 VJE=7.975E-01
+ MJE=5.000E-01 TF=3.156E-11   XTF=5.386E+00 VTF=2.713E+00
+ ITF=5.084E-02 PTF=0.000E+00  CJC=2.725E-13 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=1.385E-01 TR =7.500E-11 CJS=7.417E-13
+ VJS=6.691E-01 MJS=3.950E-01  KF =2.000E-12 AF =1.000E+00
+ FC =8.803E-01
*
.MODEL QOUTP1 PNP
+ IS =4.744E-16 BF=7.165E+01   NF =1.000E+00 VAF=3.439E+01
+ IKF=6.940E-02 ISE=2.353E-15  NE =1.366E+00 BR =1.948E+01
+ NR =1.000E+00 VAR=1.805E+00  IKR=4.873E-01 ISC=1.322E-17
+ NC =1.634E+00 RB=7.797E+00   IRB=0.000E+00 RBM=2.052E+00
+ RE =1.659E-01 RC=1.037E+01   CJE=5.858E-13 VJE=7.975E-01
+ MJE=5.000E-01 TF=3.073E-11   XTF=5.386E+00 VTF=2.713E+00
+ ITF=1.875E-01 PTF=0.000E+00  CJC=8.147E-13 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=1.709E-01 TR =1.450E-10 CJS=1.364E-12
+ VJS=6.691E-01 MJS=3.950E-01  KF =2.000E-12 AF =1.000E+00
+ FC =8.803E-01
*
.MODEL QOUTP4 PNP
+ IS =1.158E-15 BF=7.165E+01   NF =1.000E+00 VAF=3.439E+01
+ IKF=1.694E-01 ISE=5.742E-15  NE =1.366E+00 BR =1.923E+01 
+ NR =1.000E+00 VAR=1.805E+00  IKR=1.189E+00 ISC=3.240E-17 
+ NC =1.634E+00 RB=1.031E+02   IRB=0.000E+00 RBM=8.410E-01 
+ RE =6.797E-02 RC=8.267E+00   CJE=1.430E-12 VJE=7.975E-01 
+ MJE=5.000E-01 TF=3.090E-11   XTF=5.386E+00 VTF=2.713E+00
+ ITF=4.575E-01 PTF=0.000E+00  CJC=2.083E-12 VJC=7.130E-01 
+ MJC=4.200E-01 XCJC=1.631E-01 TR =1.150E-10 CJS=3.993E-12 
+ VJS=6.691E-01 MJS=3.950E-01  KF =2.000E-12 AF =1.000E+00 
+ FC =8.803E-01 
*
.MODEL QOUTP3 PNP
+ IS =1.140E-15 BF=7.165E+01   NF =1.000E+00 VAF=3.439E+01
+ IKF=1.668E-01 ISE=5.655E-15  NE =1.366E+00 BR =1.953E+01
+ NR =1.000E+00 VAR=1.805E+00  IKR=1.171E+00 ISC=3.173E-17
+ NC =1.634E+00 RB=3.245E+00   IRB=0.000E+00 RBM=8.539E-01
+ RE =6.902E-02 RC=6.213E+00   CJE=1.408E-12 VJE=7.975E-01
+ MJE=5.000E-01 TF=3.070E-11   XTF=5.386E+00 VTF=2.713E+00
+ ITF=4.506E-01 PTF=0.000E+00  CJC=1.939E-12 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=1.726E-01 TR =1.850E-10 CJS=2.351E-12
+ VJS=6.691E-01 MJS=3.950E-01  KF =2.000E-12 AF =1.000E+00
+ FC =8.803E-01
*
.ENDS CLC401
* fine CLC401


*==================================================================





*   This is a Very Wide band, Low Distortion Monolithic
*   Current Feedback Op Amp.
*
* Version 1, Rev. A, Date 04-09-92, By RRS
*
* Connections: Non-Inverting Input
*              | Inverting Input
*              | | Output
*              | | | +Vcc
*              | | | | -Vcc
*              | | | | |
.SUBCKT CLC409 3 2 6 7 4
*
* DC BIAS MIRROR
*
R1 7 4 28K
R2 7 9 271
R3 10 4 335
*
G1 7 11 POLY(2) 7 9 7 4 0 3.15M 21.5U
C3 11 0 128F
*
G2 14 4 POLY(1) 10 4 0 2.95M
C4 14 0 104F
*
* INPUT VOLTAGE BUFFER
*
E1 3 17 POLY(1) 35 0 1.0M 1.673
C6 17 0 1.00P
*
Q1 10 17 12 QINP
D3 11 12 DY
Q2 9 17 13 QINN
D4 13 14 DY
*
G3 2 0 POLY(1) 36 0 0 9.282M
C10 2 0 2.9P
*
D5 22 2 DY
Q3 21 11 22 QINN
D6 2 23 DY
Q4 24 14 23 QINP
*
* CURRENT MIRROR GAIN BLOCKS
*
R10 7 20 640
V1 20 21 1.9
C8 21 28 294F
G4 7 28 POLY(1) 7 20 0 4.3M
R15 7 28 102K
C13 28 0 641F
D1 28 26 DX
V3 7 26 1.65
G6 7 30 POLY(1) 7 20 0 2.74M
C15 30 0 676F
*
R13 25 4 640
V2 24 25 1.85
C12 24 29 294F
G5 29 4 POLY(1) 25 4 0 4.5M
R16 29 4 761K
C14 29 0 312F
D2 27 29 DX
V4 27 4 1.55
G7 31 4 POLY(1) 25 4 0 6.74M
C16 31 0 330F
*
* OUTPUT STAGE AND COMPENSATION CAPACITORS
*
R14 28 29 45.0
Q5 4 29 30 QOUTP1
Q6 7 28 31 QOUTN1
*
C9 21 33 .935P
C11 24 33 .935P
C17 33 0 4.00P
R19 33 6 10
*
Q7 7 30 33 QOUTN2
Q8 4 31 33 QOUTP2
*
* NOISE BLOCKS
*
R20 35 0 122
R21 35 0 122
*
R22 36 0 122
R23 36 0 122
*
* MODELS
*
.MODEL DX D TT=200N
.MODEL DY D IS=0.166F
*
.MODEL QINN NPN
+ IS =0.166f    BF =3.239E+02 NF =1.000E+00 VAF=8.457E+01
+ IKF=2.462E-02 ISE=2.956E-17 NE =1.197E+00 BR =3.719E+01
+ NR =1.000E+00 VAR=1.696E+00 IKR=3.964E-02 ISC=1.835E-19
+ NC =1.700E+00 RB =118       IRB=0.000E+00 RBM=65.1
+ RC =2.645E+01 CJE=1.632E-13 VJE=7.973E-01
+ MJE=4.950E-01 TF =1.948E-11 XTF=1.873E+01 VTF=2.825E+00
+ ITF=5.955E-02 PTF=0.000E+00 CJC=1.720E-13 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=589m     TR =4.212E-10 CJS=629f
+ MJS=0         KF =2.000E-12 AF =1.000E+00 FC =9.765E-01
*
.MODEL QOUTN1 NPN
+ IS =3.954E-16 BF =3.239E+02  NF =1.000E+00 VAF=8.457E+01
+ IKF=4.590E-02 ISE=5.512E-17  NE =1.197E+00 BR =3.719E+01
+ NR =1.000E+00 VAR=1.696E+00  IKR=7.392E-02 ISC=3.087E-19
+ NC =1.700E+00 RB =3.645E+01  IRB=0.000E+00 RBM=8.077E+00
+ RE =3.010E-01 RC =2.702E+01  CJE=2.962E-13
+ MJE=4.950E-01 TF =1.904E-11  XTF=1.873E+01 VTF=2.825E+00
+ ITF=1.110E-01 PTF=0.000E+00  CJC=2.846E-13 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=1.562E-01 TR =5.832E-10 CJS=5.015E-13
+ VJS=5.723E-01 MJS=4.105E-01  KF =2.000E-12 AF =1.000E+00
+ FC =9.765E-01
*
.MODEL QOUTN2 NPN
+ IS =9.386E-16 BF =3.239E+02 NF =1.000E+00 VAF=8.457E+01
+ IKF=1.089E-01 ISE=1.308E-16 NE =1.197E+00 BR =3.956E+01
+ NR =1.000E+00 VAR=1.696E+00 IKR=7.392E-02 ISC=1.378E-18
+ NC =1.700E+00 RB =65.4      IRB=0.000E+00 RBM=1.683E+00
+ RC =1.857E+01 CJE=7.030E-13 VJE=7.973E-01
+ MJE=4.950E-01 TF =1.875E-11 XTF=1.873E+01 VTF=2.825E+00
+ ITF=2.635E-01 PTF=0.000E+00 CJC=6.172E-13 VJC=8.046E-01
+ MJC=4.931E-01 XCJC=860m     TR =1.069E-09 CJS=1.028E-12
+ VJS=5.723E-01 MJS=4.105E-01 KF =2.000E-12 AF =1.000E+00
+ FC =9.765E-01
*
.MODEL QINP PNP
+ IS =0.166f    BF =7.165E+01 NF =1.000E+00 VAF=2.000E+01
+ IKF=1.882E-02 ISE=6.380E-16 NE =1.366E+00 BR =1.833E+01
+ NR =1.000E+00 VAR=1.805E+00 IKR=1.321E-01 ISC=3.666E-18
+ NC =1.634E+00 RB =78.8      IRB=0.000E+00 RBM=57.6
+ RC =3.739E+01 CJE=1.588E-13 VJE=7.975E-01
+ MJE=5.000E-01 TF =3.156E-11 XTF=5.386E+00 VTF=2.713E+00
+ ITF=5.084E-02 PTF=0.000E+00 CJC=2.725E-13 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=741m     TR =7.500E-11 CJS=515f
+ MJS=0         KF =2.000E-12 AF =1.000E+00 FC =8.803E-01
*
.MODEL QOUTP1 PNP
+ IS =2.399E-16 BF =7.165E+01  NF =1.000E+00 VAF=3.439E+01
+ IKF=3.509E-02 ISE=1.190E-15  NE =1.366E+00 BR =1.900E+01
+ NR =1.000E+00 VAR=1.805E+00  IKR=2.464E-01 ISC=6.745E-18
+ NC =1.634E+00 RB =1.542E+01  IRB=0.000E+00 RBM=4.059E+00
+ RC =4.174E+01 CJE=2.962E-13  VJE=7.975E-01
+ MJE=5.000E-01 TF =3.107E-11  XTF=5.386E+00 VTF=2.713E+00
+ ITF=9.481E-02 PTF=0.000E+00  CJC=4.508E-13 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=1.562E-01 TR =9.500E-11 CJS=1.045E-12
+ VJS=6.691E-01 MJS=3.950E-01  KF =2.000E-12 AF =1.000E+00
+ FC =8.803E-01
*
.MODEL QOUTP2 PNP
+ IS =5.693E-16 BF =7.165E+01 NF =1.000E+00 VAF=3.439E+01
+ IKF=8.328E-02 ISE=5.742E-15 NE =1.366E+00 BR =1.923E+01
+ NR =1.000E+00 VAR=1.805E+00 IKR=5.848E-01 ISC=1.586E-17
+ NC =1.634E+00 RB =56.5      IRB=0.000E+00 RBM=51.7
+ RC =1.767E+00 CJE=7.030E-13 VJE=7.975E-01
+ MJE=5.000E-01 TF =3.073E-11 XTF=5.386E+00 VTF=2.713E+00
+ ITF=2.250E-01 PTF=0.000E+00 CJC=9.776E-13 VJC=7.130E-01
+ MJC=4.200E-01 XCJC=923m     TR =1.450E-10 CJS=1.637E-12
+ VJS=6.691E-01 MJS=3.950E-01 KF =2.000E-12 AF =1.000E+00
+ FC =8.803E-01
*
.ENDS CLC409
* fine clc409

*==================================================================

* (C) National Semiconductor, Inc.
* Models developed and under copyright by:
* National Semiconductor, Inc.  

*/////////////////////////////////////////////////////////////////////
* Legal Notice: This material is intended for free software support.
* The file may be copied, and distributed; however, reselling the 
*  material is illegal

*////////////////////////////////////////////////////////////////////
* For ordering or technical information on these models, contact:
* National Semiconductor's Customer Response Center
*                 7:00 A.M.--7:00 P.M.  U.S. Central Time
*                                (800) 272-9959
* For Applications support, contact the Internet address:
*  amps-apps@galaxy.nsc.com
* ///////////////////////////////////////////////////////////////////
* User Notes:
*
* 1. Input resistance (Rin) for these JFET op amps is 1TOhm.  Rin is
*    modeled by assuming the option GMIN=1TOhm.  If a different (non-
*    default) GMIN value is needed, users may recalculate as follows:
*    Rin=(R1||GMIN+R2||GMIN), where R1=R2,
*    to maintain a consistent Rin model.

*//////////////////////////////////////////////////////////
*LF356 Monolithic JFET-Input OP-AMP MACRO-MODEL
*//////////////////////////////////////////////////////////
*
* connections:    non-inverting input
*                 |   inverting input
*                 |   |   positive power supply
*                 |   |   |   negative power supply
*                 |   |   |   |   output
*                 |   |   |   |   |
*                 |   |   |   |   |
.SUBCKT LF356/NS  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
*
****************INPUT STAGE************** 
*
IOS 2 1 3P
*^Input offset current
R1 1 3 1E12
R2 3 2 1E12
I1 99 4 100U
J1 5 2 4 JX
J2 6 7 4 JX
R3 5 50 20K
R4 6 50 20K
*Fp2=20 MHz
C4 5 6 1.9894E-13
*
***********COMMON MODE EFFECT***********
*
I2 99 50 4.65MA
*^Quiescent supply current
EOS 7 1 POLY(1) 16 49 3E-3 1
*Input offset voltage.^
R8 99 49 50K
R9 49 50 50K
*
*********OUTPUT VOLTAGE LIMITING********
V2 99 8 2.63
D1 9 8 DX
D2 10 9 DX
V3 10 50 2.63
*
**************SECOND STAGE**************
*
EH 99 98 99 49 1
F1 9 98 POLY(1) VA3 0 0 0 1.5944E7
G1 98 9 5 6 2E-3
R5 98 9 100MEG
VA3 9 11 0
*Fp1=31.96 HZ
C3 98 11 49.9798P
*
*********COMMON-MODE ZERO STAGE*********
*
G4 98 16 3 49 1E-8
L2 98 17 530.52M
R13 17 16 1K
*
**************OUTPUT STAGE**************
*
F6  99 50 VA7 1
F5  99 23 VA8 1
D5  21 23 DX
VA7 99 21 0
D6  23 99 DX
E1  99 26 99 9 1
VA8 26 27 0
R16 27 28 20
V5  28 25 -.25V
D4  25  9 DX
V4  24 28 -.25V
D3   9 24 DX
*
***************MODELS USED**************
*
.MODEL DX D(IS=1E-15)
.MODEL JX PJF(BETA=1.25E-5 VTO=-2.00 IS=30E-12)
*
.ENDS
*$

*==================================================================

* OPA657  Non-Unity Gain Stable, FET Voltage Limiting Amplifier
* REV. A - Created 1/21/02 Rea Schmid
* REV. B - Created 2/26/02 Rea Schmid - Purpose to adjust voltage and noise curves
*
*
* NOTES:
*   1- This macromodel predicts well: DC, small-signal AC,
*      noise, and transient performance under a wide range
*      of conditions
*   2- This macromodel does not predict well: distortion
*      (harmonic, intermod, diff. gain & phase, ...),
*      temperature effects, board parasitics, differences
*      between package styles, and process changes
*
* |-------------------------------------------------------------|
* |  This macro model is being supplied as an aid to            |
* |  circuit designs.  While it reflects reasonably close       |
* |  similarity to the actual device in terms of performance,   |
* |  it is not suggested as a replacement for breadboarding.    |
* |  Simulation should be used as a forerunner or a supplement  |
* |  to traditional lab testing.                                |
* |                                                             |
* |  Neither this library nor any part may be copied without    |
* |  the express written consent of Texas Instruments Corp.     |
* |-------------------------------------------------------------|
*
* CONNECTIONS:
*              Non-Inverting Input
*              | Inverting Input
*              | | Output
*              | | |  Positive Supply
*              | | |   |  Negative Supply
*              | | |   |  | 
*              | | |   |  |  
*              | | |   |  |  
.SUBCKT OPA657 + - Out V+ V- 
C_C4         V- 0  1P  
C_C2         0 V+  1P  
D_D12         14 12 DX 1
V_V12         14 V- DC 4.54  
R_R51         V- 23  9.0  
R_R50         19 V+  5  
D_D51         Out 22 DX 1
D_D50         20 Out DX 1
D_D32         18 40 DX 1
D_D31         40 17 DX 1
R_R30         15 0  39.85K  
C_C10         10 11  950F  
E_E50         19 20 POLY(2) 0 40  V+ V- -765M 1 0.5
E_E51         22 23 POLY(2) 40 0  V+ V- -765M 1 0.5
J_J2         11 - 12 JX .5
E_E32         18 0 POLY(1) V- V+ 1.95 0.5 0 0
C_C6         Out 0  1P  
I_I12         12 V- DC 9.8M  
R_R10         10 V+  750  
R_R11         11 V+  750  
J_J1         10 + 12 JX .5
E_E31         17 0 POLY(1) V+ V- -1.95 0.5 0 0
G_G40         0 40 POLY(1) 15 0 0 1U 0 0
R_R40         40 0  1MEG  
G_G1         0 15 POLY(1) 11 10 0 245.84M 0 0
C_C30         0 15  8.55P  
C_C40         40 0  .195F  
*
.model DX D(IS=1E-15) 
*
.MODEL JX NJF(BETA=10.000E-3 LAMBDA=35.000E-6 IS=2.5000E-12
+ALPHA=1.0000E-6 VK=1 RD=1 RS=30 CGD=500.00E-15 CGS=100.00E-15
+KF=69.500E-18 BETATCE=-.5 VTOTC=-2.5000E-3)
*
.ENDS    OPA657

*==================================================================

*
* This version of the AD8001 model simulates the worst case 
* parameters of the 'A' grade in the N package (PDIP).  The worst case
* parameters used correspond to those in the data sheet.
* This model was developed using the +-5V specifications.
*
* Copyright 1994 by Analog Devices, Inc.
*
* Refer to the "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 AD8001AN 3 2 7 4 6
*
* INPUT STAGE
*
CIN 3 4 1.5E-12
GB1 7 3 POLY(1) 3 100 (6E-6,0.3E-6)
EOS 9 3 POLY(1) 23 100 (5E-3,1)
Q1 7 9 10 QN
I1 10 4 DC 2.568E-4
I2 7 11 DC 2.568E-4
Q2 4 9 11 QP
R1 7 14 1E3
V1 7 17 DC -6.34541E-2
D1 17 14 DX
Q3 14 11 15 QN
Q4 16 10 15 QP
R2 16 4 1E3
D2 16 18 DX
V2 18 4 DC -6.34541E-2
LIN- 15 2 0.1E-9
GB2 7 2 POLY(1) 3 100 (25E-6,1E-6)
CS1 7 2 0.03E-12
CS2 2 4 0.03E-12
*
* GAIN STAGE AND DOMINANT POLE AT 891 kHz
*
EREF 100 0 POLY(2) (7,0) (4,0) (0,0.5,0.5)
G1 100 19 7 14 1E-3
G2 19 100 16 4 1E-3
R3 19 100 3.196E5
C1 19 100 5.58902E-13
V3 7 20 DC 2.8108
D3 19 20 DX
D4 21 19 DX
V4 21 4 DC 2.8108
*
* COMMON-MODE REJECTION NETWORK WITH ZERO AT 34.87 MHz
*
ECM 100 22 3 100 31.668
RCM1 22 23 1E4
CCM 22 23 4.56424E-13
RCM2 23 100 1
*
* POLE AT 800 MHz
*
G4 100 24 19 100 1E-6
R5 24 100 1E6
C3 24 100 1.9894368E-16
*
* POLE AT 4 GHz
*
G5 100 25 24 100 1E-6
R6 25 100 1E6
C4 25 100 3.9788736E-17
*
* OUTPUT STAGE
*
VW 25 30 DC 0
*
FSY 7 4 POLY(2) VSY1 VSY2 (4.7326E-3,1,1)
GSY 100 35 33 30 4.6728972E-2
DSY1 35 36 DX
VSY1 36 100 DC 0
DSY2 37 35 DX
VSY2 100 37 DC 0
DSC1 30 31 DX
VSC1 31 33 DC 0.3615
DSC2 32 30 DX
VSC2 33 32 DC 0.3615
GO1 33 7 7 30 4.6728972E-2
RO1 7 33 21.4
GO2 4 33 30 4 4.6728972E-2
RO2 33 4 21.4
LO 33 6 7E-9
*
.MODEL QN NPN(BF=100 IS=1E-15)
.MODEL QP PNP(BF=100 IS=1E-15)
.MODEL DX D(IS=1E-15)
*
.ENDS AD8001AN



*==================================================================
* invertitore fatto con LEDIT

* Circuit Extracted by Tanner Research's L-Edit V7.12 / Extract V4.00 ;
* TDB File:  C:\sc\didatt\disp_el\ledit_win\sc_files\cmos20_subcircuit, Cell:  Cell0
* Extract Definition File:  C:\programs\ledit712\MOSIS\morbn20.ext
* Extract Date and Time:  02/04/2008 - 12:05

* WARNING:  Layers with Unassigned AREA Capacitance.
*   <Poly Resistor>
*   <Poly2 Resistor>
*   <N Diff Resistor>
*   <P Diff Resistor>
*   <N Well Resistor>
*   <P Base Resistor>
* WARNING:  Layers with Unassigned FRINGE Capacitance.
*   <Poly Resistor>
*   <Poly2 Resistor>
*   <N Diff Resistor>
*   <P Diff Resistor>
*   <N Well Resistor>
*   <P Base Resistor>
*   <Poly1-Poly2 Capacitor>
*   <Pad Comment>
* WARNING:  Layers with Zero Resistance.
*   <Poly1-Poly2 Capacitor>
*   <NMOS Capacitor>
*   <PMOS Capacitor>
*   <Pad Comment>

* 44 in, 41 gnd, 42 Vdd, 43 out 
*.SUBCKT Cell0 41 42 43 44 
* linea originale; aggiunto un piedino, 50, ed una resist. da li' a massa
.SUBCKT Cell0 41 42 43 44 50
R1 50 41 1g

M1 42 44 43 42 PMOS L=2u W=11u AD=55p PD=32u AS=66p PS=34u 
* M1 DRAIN GATE SOURCE BULK (39 2 41 13) 
M2 43 44 41 41 NMOS L=2u W=11u AD=66p PD=34u AS=55p PS=32u 
* M2 DRAIN GATE SOURCE BULK (14 2 16 13) 
* Pins of element D3 are shorted:
* D3 42 42 D_lateral AREA=11p
* D3 PLUS MINUS (46 2 47 13) 
* Pins of element D4 are shorted:
* D4 41 41 D_lateral AREA=11p
* D4 PLUS MINUS (9 2 10 13) 

* Total Nodes: 4
* Total Elements: 4
* Extract Elapsed Time: 0 seconds
.ENDS
*$


*==================================================================

*//////////////////////////////////////////////////////////////////////
* (C) National Semiconductor, Corporation.
* Models developed and under copyright by:
* National Semiconductor, Corporation.  
*/////////////////////////////////////////////////////////////////////
* Legal Notice:  
* The model may be copied, and distributed without any modifications;
* however, reselling or licensing the material is illegal.
* We reserve the right to make changes to the model without prior notice. 
* Pspice Models are provided "AS IS, WITH NO WARRANTY OF ANY KIND" 
*////////////////////////////////////////////////////////////////////
* For more information, and our latest models,
* please visit the models section of our website at
*       http://www.national.com/models/
*////////////////////////////////////////////////////////////////////
* PINOUT ORDER +IN -IN +V -V OUT
* PINOUT ORDER  3   4   5  2  1
.SUBCKT LMH6723 3 4 5 2 1
* BEGIN MODEL PROGRAMMING
*########### IMPORTANT - PLEASE READ! ###############
* TO SET THE MODEL UP FOR EITHER +-2.5 VOLT SUPPLY
* OR +- 5 VOLT SUPPLY KEEP ONE OF THE FOLLOWING
* SETS OF VALUES AND COMMENT THE OTHER. THE LINES
* IN PLACE NOW ARE FOR +- 5 VOLTS. FOR POWER SUPPLY
* VOLTAGES BETWEEN +-2.5 AND +-5 THE COMPONENT
* VALUES SHOULD BE LINEARLY INTERPOLATED.
* C11 AND F1 MODIFY BANDWITH
* C11 AND F1 AND R40 MODIFY SLEW
* C12 SLIGHTLY MODIFIES BANDWIDTH
* BEGIN +-5 VOLT VALUES
C11 31 0 3.33E-12
R40 39 31 334
C12 43 0 0.5E-12
F1 39 0 V14 -6.6
* END +- 5 VOLT VALUES
* END MODEL PROGRAMMING
Q17 2 6 7 QOP
Q21 5 8 7 QON
D5 1 5 DD
D6 2 1 DD
D7 9 0 DIN
D8 10 0 DIN
I8 0 9 0.1E-3
I9 0 10 0.1E-3
E2 11 0 2 0 1
E3 12 0 5 0 1
D9 13 0 DVN
D10 14 0 DVN
I10 0 13 0.1E-3
I11 0 14 0.1E-3
E4 15 4 13 14 0.4
G2 3 15 9 10 2.9E-3
R22 2 5 1E6
E5 16 0 12 0 1
E6 17 0 11 0 1
E7 18 0 19 0 1
R30 16 20 3E5
R31 17 21 3E5
R32 18 22 1E6
R33 0 20 30
R34 0 21 30
R35 0 22 100
R36 19 23 1E3
R37 19 24 1E3
C6 16 20 1E-12
C7 17 21 1E-12
C8 18 22 0.5E-12
E11 25 26 21 0 4.5
E12 27 25 20 0 2.3
Q22 11 28 8 QDP
Q23 12 28 6 QDN
I12 5 2 20E-6
I13 12 8 1E-3
I14 6 11 1E-3
R38 0 29 10
R39 0 28 10
C9 29 0 30E-12
C10 28 0 10E-12
E15 30 31 32 0 1
E16 31 33 32 0 1
E17 34 0 31 0 1
D11 35 12 DD
D12 11 36 DD
V11 33 36 1.85
V12 35 30 1.6
I15 0 37 1M
D13 37 0 DD
V13 32 37 -0.71465
D14 38 39 DD
D15 39 40 DD
R41 0 39 320E3
E18 41 0 27 0 0.999
R42 41 42 300
C13 27 0 1.5E-12
V14 42 44 0
R43 7 45 7
G3 29 0 31 0 0.1
G4 28 0 29 0 0.1
C14 7 0 2P
L1 45 1 4E-9
R45 45 1 40
E20 38 34 32 0 1
E21 40 34 32 0 -1
L2 43 44 5E-9
R47 43 44 400
E10 26 3 22 0 0.005
C26 15 27 0.4E-12
V15 12 46 1.13
V16 47 11 1.13
D16 15 46 DV
D17 47 15 DV
D18 3 46 DV
D19 47 3 DV
I16 0 3 2E-6
R76 0 32 1E9
R77 25 27 1E9
R78 26 25 1E9
R79 3 26 1E9
R80 4 15 1E9
R81 33 31 1E9
R82 31 30 1E9
E22 23 0 3 0 1
E23 24 0 15 0 1
I17 0 15 -0.4E-6
V18 43 15 0.5E-3
.MODEL QON NPN VAF=150 BF=110 IKF=0.5 RE=1 RC=1
.MODEL QOP PNP VAF=150 BF=110 IKF=0.5 RE=1 RC=1
.MODEL QDP PNP
.MODEL QDN NPN
.MODEL DD D
.MODEL DV D RS=10E3
.MODEL DVN D KF=2.5E-16
.MODEL DIN D KF=8E-17
.ENDS
* END MODEL LMH6723
*==================================================================
* Linear Technology OP07 op amp model
* Written: 08-24-1989 12:35:59 Type: Bipolar npn input, internal comp.
* Typical specs: 
* Vos=3.0E-05, Ib=1.0E-09, Ios=4.0E-10, GBP=6.0E+05Hz, Phase mar.= 70 deg, 
* SR(+)=2.5E-01V/us, SR(-)=2.4E-01V/us, Av= 114 dB, CMMR= 126 dB, 
* Vsat(+)=2.00V, Vsat(-)=2.00V, Isc=+/-25.0mA, Iq=2500uA
* (input differential mode clamp active)
*
* nb scaricato sept09 da un altro sito, sul sito LT non c'e' piu'
* 
* Connections: + - V+V-O 
.subckt OP07 3 2 7 4 6
* input
rc1 7  80 8.842E+03
rc2 7  90 8.842E+03
q1  80 102 10 qm1 
q2  90 103 11 qm2 
rb1  2   102 5.000E+02
rb2  3   103 5.000E+02
ddm1 102 104 dm2 
ddm3 104 103 dm2 
ddm2 103 105 dm2 
ddm4 105 102 dm2 
c1  80 90 5.460E-12
re1 10 12 1.948E+03
re2 11 12 1.948E+03
iee 12 4  7.502E-06
re  12 0  2.666E+07
ce  12 0  1.579E-12
* intermediate 
gcm 0  8  12 0  5.668E-11
ga  8  0  80 90 1.131E-04
r2  8  0  1.000E+05
c2  1  8  3.000E-11
gb  1  0  8  0  1.294E+03
* output 
ro1 1  6  2.575E+01
ro2 1  0  3.425E+01
rc  17 0  6.634E-06
gc  0  17 6  0  1.507E+05
d1  1  17 dm1 
d2  17 1  dm1 
d3  6  13 dm2 
d4  14 6  dm2 
vc  7  13 2.803E+00
ve  14 4  2.803E+00
ip  7  4  2.492E-03
dsub 4  7  dm2 
* models 
.model qm1 npn (is=8.000E-16 bf=3.125E+03)
.model qm2 npn (is=8.009E-16 bf=4.688E+03)
.model dm1 d   (is=1.486E-08)
.model dm2 d   (is=8.000E-16)
.ends OP07
* 
* - - - - - * fini OP07 * - - - - - * [oamm vn1 8/89]
*=====================================================
* SPICE MODEL OCTOBER 1993 PHILIPS SEMICONDUCTORS
.MODEL QBC847C NPN(
+ IS = 2.375E-14
+ NF = 0.9925
+ ISE = 5.16E-16
+ NE = 1.3
+ BF = 524.9
+ IKF = 0.09
+ VAF = 49.77
+ NR = 0.9931
+ ISC = 7.064E-12
+ NC = 1.78
+ BR = 10.04
+ IKR = 0.132
+ VAR = 16
+ RB = 10
+ IRB = 5E-06
+ RBM = 5
+ RE = 0.653
+ RC = 0.78
+ XTI = 3
+ CJE = 1.132E-11
+ VJE = 0.7685
+ MJE = 0.3733
+ TF = 4.258E-10
+ XTF = 6.319
+ VTF = 6.4
+ ITF = 0.1845
+ PTF = 0
+ CJC = 3.379E-12
+ VJC = 0.5444
+ MJC = 0.3968
+ XCJC = 0.6193
+ TR = 9.5E-08
+ CJS = 0
+ VJS = 0.75
+ MJS = 0.333
+ XTB = 0
+ EG = 1.11
+ FC = 0.999)
*=====================================================
.MODEL QBC847A NPN (
+     IS = 9.677E-15
+     NF = 0.9922
+     ISE = 5.44E-15
+     NE = 2
+     BF = 182.1
+     IKF = 0.14
+     VAF = 143.8
+     NR = 0.9935
+     ISC = 5.236E-12
+     NC = 1.53
+     BR = 7.004
+     IKR = 0.06
+     VAR = 31.15
+     RB = 10
+     IRB = 5E-06
+     RBM = 4
+     RE = 0.78
+     RC = 0.656
+     XTB = 0
+     EG = 1.11
+     XTI = 3
+     CJE = 1.443E-11
+     VJE = 0.733
+     MJE = 0.3514
+     TF = 6.04E-10
+     XTF = 8.94
+     VTF = 3.78
+     ITF = 0.2711
+     PTF = 0
+     CJC = 3.287E-12
+     VJC = 0.5444
+     MJC = 0.3954
+     XCJC = 0.6193
+     TR = 1.1E-07
+     CJS = 0
+     VJS = 0.75
+     MJS = 0.333
+     FC = 0.789)

*=====================================================

*//////////////////////////////////////////////////////////////////////
* (C) National Semiconductor, Inc.
* Models developed and under copyright by:
* National Semiconductor, Inc.  

*/////////////////////////////////////////////////////////////////////
* Legal Notice: This material is intended for free software support.
* The file may be copied, and distributed; however, reselling the 
*  material is illegal

*////////////////////////////////////////////////////////////////////
* For ordering or technical information on these models, contact:
* National Semiconductor's Customer Response Center
*                 7:00 A.M.--7:00 P.M.  U.S. Central Time
*                                (800) 272-9959
* For Applications support, contact the Internet address:
*  amps-apps@galaxy.nsc.com

* \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\            
* LM13700 Dual Operational Transconductance Amplifier                 
* \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\                 
*
*                   Amplifier Bias Input
*                   | Diode Bias
*                   | | Positive Input
*                   | | | Negative Input
*                   | | | | Output
*                   | | | | | Negative power supply
*                   | | | | | | Buffer Input
*                   | | | | | | | Buffer Output
*                   | | | | | | | | Positive power supply
*                   | | | | | | | | |
.SUBCKT LM13700/NS  1 2 3 4 5 6 7 8 9
*
* Features:
* gm adjustable over 6 decades.
* Excellent gm linearity.
* Linearizing diodes.
* Wide supply range of +/-2V to +/-22V.
*
* Note:  This model is single-pole in nature and over-estimates
*       AC bandwidth and phase margin (stability) by over 2X.   
*       Although refinement may be possible in the future, please
*       use benchtesting to finalize AC circuit design.
* 
* Note: Model is for single device only and simulated
*       supply current is 1/2 of total device current.
*
******************************************************
* 
C1  6  4  4.8P
C2  3  6  4.8P
* Output capacitor  
C3  5  6  6.26P                                       
D1  2  4  DX
D2  2  3  DX
D3  9 21 DX
D4  21 22 DX
D5  1  26 DX
D6  26 27 DX
D7  5  29 DX
D8  28 5  DX
D10 31 25 DX
* Clamp for -CMR  
D11 28 25 DX                                        
* Ios source 
F1  4  3  POLY(1)   V6 1E-10 5.129E-2 -1.189E4 1.123E9 
F2  9 5  V2        1.022
F3  25 6  V3        1.0
F4  5  6  V1        1.022
* Output impedance 
F5  5  0  POLY(2)   V3 V7 0 0 0 0 1                  
G1  0  33 5         0 .55E-3
I1  9 6  300U
Q1  24 32 31        QX1
Q2  23 3  31        QX2
Q3  9 7  30        QZ
Q4  9 30 8         QY
V1  22 24 0V
V2  22 23 0V
V3  27 6  0V
V4  9 29 1.4
V5  28 6  1.2
V6  4  32 0V
V7  33 0  0V
.MODEL QX1 NPN (IS=5E-16     BF=200 NE=1.15 ISE=.63E-16 IKF=1E-2)
.MODEL QX2 NPN (IS=5.125E-16 BF=200 NE=1.15 ISE=.63E-16 IKF=1E-2)
.MODEL QY  NPN (IS=6E-15     BF=50)
.MODEL QZ  NPN (IS=5E-16     BF=266)  
.MODEL DX  D   (IS=5E-16)
.ENDS

*=====================================================
* zener
* 		fatto con i piedi
.SUBCKT 1N4728  1 2
D1 1 2
.model D1	D(Bv=3.3 )
.ENDS
*=====================================================

*=====================================================


* OPA548
*****************************************************************************
* (C) Copyright 2022 Texas Instruments Incorporated. All rights reserved.                                            
*****************************************************************************
** This model is designed as an aid for customers of Texas Instruments.
** TI and its licensors and suppliers make no warranties, either expressed
** or implied, with respect to this model, including the warranties of 
** merchantability or fitness for a particular purpose.  The model is
** provided solely on an "as is" basis.  The entire risk as to its quality
** and performance is with the customer
*****************************************************************************
*
* This model is subject to change without notice. Texas Instruments
* Incorporated is not responsible for updating this model.
*
*****************************************************************************
*
** Released by: Online Design Tools, Texas Instruments Inc.
* Part: OPA548
* Date: 07OCT2022
* Model Type: ALL IN ONE
* EVM Order Number: OPA548EVM
* EVM Users Guide: SBOU132-November 2015
* Datasheet: SBOS070D - OCTOBER 1997-REVISED DECEMBER 2019
*
* Model Version: Final 1.2
*
*****************************************************************************
* 
* Updates:
*
* Final 1.2
* Updated PSpice symbol
* Moved all .MODEL inside main SUBCKT
* Added .ENDS name as OPA548
*
* Final 1.1 :
* Modified June 25, 2013 by Tim Green to add 1MHz Pole in Aol
* Modified CPOLE2 4/27/2016 to match Collin Wells Lab Data for Aol Gain/Phase
*
* Final 1.0 : 
* Release to Web
*
*****************************************************************************
* 1 = NON-INVERTING INPUT
* 2 = INVERTING INPUT
* 3 = CURRENT LIMIT
* 4 = NEGATIVE RAIL
* 5 = POSITIVE RAIL
* 6 = OUTPUT
* 7 = ENABLE/STATUS
.SUBCKT OPA548 1   2   3   4   5   6   7
*****************************************************************************
R1       17  13    13K
R2       17  14    13K
RIN2     12  2     1K
RIN5     15  4     1K
RIN6     16  4     1K
RBLEED   26  4     10MEG 
GAIN     26  4   260  0   1.6M
EPOLE    160 0   16  15   1
Rpole2   160 260 1K
CPOLE2   260 0  400P 
IBIAS    19  30   300UA
R3       5   20    2K
R4       5   23    6K
QGAIN    25  26  4    NMAX 1
CCOMP    27  25    15P
R5       5   24    667
EBUF     22  5   21  5    1
R7       7   4     250K
QHIGH    5   48  49   NMIN 960
QHDRV    5   45  47   NMIN 60
R47      47  48    14
R49      49  40    0.4
QLDRV    5   35  37   NMIN 60
R37      37  38    35
R39      39  4     0.4
GLOWER   4   31  30  25   0.5M
CCOUT    35  36    11P
RCOUT    36  40    1680
RCOMP    26  27    1000
D34      31  34   DIODE 100
RBL      35  4     10K
Q33      33  33  40   NMIN 5
Q30      30  30  33   NMIN 5
E32      32  4   30  40   1.55
D32      32  31   DIODE 100
Q3       19  19  20   LAT5 3
RB45     25  45    100
V475     28  4    DC 4.75
RCL      3   28    13750
RB35     34  35    100
GLCL     42  4   39  41   .05
D42      35  42   DIODE 100
D43      42  43   DIODE 100
GHCL     52  4   49  51   .05
D52      45  52   DIODE 100
D53      52  53   DIODE 100
D25      6   25   DIODE 100
DIN2     2   10   ZENERD 1
DIN1     1   10   ZENERD 1
HLREF    41  4    V475 -6000
HHREF    51  40   V475 -6000
SW2      6   40  7   4    VSM
D7       54  7    DIODE 100
VES      55  4    DC 3.5
D55      54  55   DIODE 100
SW1      21  19  7   4    VSM
R21      5   21    100K
C40      30  40    150P
ELCL     43  4   37  4    1
EHCL     53  4   47  4    1
VCM      18  17   DC 1.3
VCLMP    29  4    DC 1
RIN1     1   11    1K
QIN2     16  12  14   PSUB 1
RSHTDWN  6   25    25K
R48      48  40    2400
R38      38  4     1200
CIN1     4   1     3P
CIN2     2   4     3P
CIN3     2   1     2.5P
DP       4   5    DIODE 100
DPU1     1   5    DIODE 100
DPL1     4   1    DIODE 100
DPL2     4   2    DIODE 100
DPU2     2   5    DIODE 100
DPU3     3   5    DIODE 100
DPL3     4   3    DIODE 100
DPL6     4   6    DIODE 100
DPU6     6   5    DIODE 100
DPU7     7   5    DIODE 100
DPL7     4   7    DIODE 100
QIN1     15  11  13   PSUB 1
Q4       18  22  23   LAT5 1
Q5       25  22  24   LAT5 9
DC6      29  6    DIODE 100
DC26     29  26   DIODE 100
QLOW     40  38  39   NMIN 960
IEO      5   54   70UA
ILEAK    6   4    3M
.MODEL  NMIN NPN IS=6E-16 BF=150 VAF=140 CJE=5E-13 CJC=2.5E-13 TF=2.5E-10 
+ RC=600
.MODEL  NMAX NPN IS=6E-16 BF=3000 VAF=140 CJE=5E-13 CJC=2.5E-13 TF=2.5E-10 
+ RC=1000
.MODEL  ZENERD D IS=6E-16 CJO=1E-18 RS=1 BV=5.2
.MODEL  DIODE D IS=6E-16 CJO=1E-18 RS=1 BV=80
.MODEL  LAT5 PNP IS=4E-15 BF=80 VAF=80 CJE=1E-13 CJC=6E-13 TF=3.5E-8 RC=1200
.MODEL  PSUB PNP IS=6E-16 BF=360 VAF=140 CJE=5E-13 CJC=2.5E-13 TF=2.5E-10 
+ RC=1200
.MODEL  VSM VSWITCH(RON=.02 ROFF=5E5 VON=2.3  VOFF=1.5)
.ENDS OPA548
*