* ACPL-332J SPICE Macromodel
* Rev. A
* 11/07
* ZFC 
*
* This is the behavioural model for the above-mentioned part number.
* It is valid for functional simulation over the range specified below.
* Temperature = 25C
*
* Macromodels provided by Avago Technologies are not warranted
* as fully representing all of the specifications and operating 
* characteristics of the product. 
*
* Macromodels are useful for evaluating product performance but they
* cannot model exact device performance under all conditions, nor are
* they intended to replace breadboarding for final verification.
*
* Copyright 2007 Avago Technologies Limited. All Rights Reserved
********************************************************************************
* This is       pin1               to              pin16
*                |                                    |                
.subckt ACPL332J 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16  
xicc2 9 13  icc
xldlogic3 9 130 38 57 32 53 or3
xldlogic 9 130 51 52 53 50 and3
xlimitl 9 50 54 limitl
xhlimit 9 40 45 limit
xhdlogic 9 130 41 34 43 44 40 and4
xocplogic2 9 130 35 32 36 or2
xled_drive 9 34 8 6 led
xled_fault 1 22 9 15 led
xinver_clamp 9 130 344 83 inverter
xldlogic4 9 130 34 57 inverter
xldlogic2 9 130 56 52 inverter
xldlogic1 9 130 40 51 inverter
xhdlogic3 9 130 50 44 inverter
xhdlogic2 9 130 32 43 inverter
xhdlogic1 9 130 38 41 inverter
xocplogic3 9 130 34 35 inverter
xclamplogic 9 130 82 83 84 and2
xldlogic5 9 130 11 32 56 and2
xocplogic4 9 130 31 344 390 and2
xrs_clamp 9 130 344 81 82 r_s
xrs_desat 9 130 33 390 32 r_s
xcompa_clamp 9 130 10 80 81 comparator
xfaultreset 9 130 92 91 33 comparator
xocp 9 130 30 14 31 comparator
xuvlo 9 130 13 377 38 comparator
xfault_delay 1 23 212 211 21 comparator
efaultdrive 24 1  21 1 1
efault 210 1  22 1 1
edsatshut 71 9  32 9 1
ehdrive 42 11  45 9 1
eledisolat 344 9  34 9 1
eldrive 55 9  54 9 1
vcc1inside 23 1 DC 5
vclamp 80 9 DC 2
vfaultreset 92 9 DC 1
vcc2internal 130 9 DC 30
vdesat 30 9 DC  7
vuvlo 37 9 DC  11
vfault 212 1 DC 3
idesat 16 14 DC 250e-6
dclamp 9 10 dmod
dmosl 9 11 dmod
ddrive3 47 46 dmod
ddrive2 49 47 dmod
ddrive1 11 49 dmod
qfault 3 25 1  npnmod
qdrive3 13 46 47  NPNMOD
qdrive2 13 47 49  NPNMOD
qdrive1 13 49 48  NPNMOD
giledfault 9 15  32 9 500e-6 
mclamp 10 84 9 9 nmosmod L=1e-6 W=15e-3
mlogic2 14 36 16 9 nmosmod L=1e-6 W=100e-6
mlogic 11 71 9 9 nmosmod L=1e-6 W=27e-6
mdrive 11 555 9 9 nmosmod L=50e-9 W=500e-6
chigh 13 11 30e-12
clgate 555 9 1e-12
cfault 211 1 1e-9
clow 11 9 2e-12
chgate 46 11 120e-12
creset 344 91 1e-9
rfaultbase 25 24 15e3
ricc1 2 1 100e3
rcathode 5 8 1e-6
ruvlo2 38 377 50e3
rgnd2 9 12 1e-6
rfault 210 211 1e3
ranode 7 6 1e-6
rreset 91 9 1e3
rhgate 42 46 1e3
rlgate 55 555 1e3
rgnd 4 1 1e-6
ruvlo 377 37 1e3
rehdrive 48 11 1
rdesatshut2 71 9 1e3
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends ACPL332J

.subckt icc 1 2 
r2 3 1 600
r1 6 4 100
qnpn2 4 3 1  NPNMOD
qnpn1 5 4 3  NPNMOD
qpnp2 5 5 2  PNPMOD
qpnp1 6 5 2  PNPMOD
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends icc

.subckt or3 1 2 3 4 5 6
r2 2 6 10e3
r1 2 7 10e3
m4 6 7 1 1 nmosswitch L=1e-6 W=100e-6
m3 7 5 1 1 nmosswitch L=1e-6 W=100e-6
m2 7 3 1 1 nmosswitch L=1e-6 W=100e-6
m1 7 4 1 1 nmosswitch L=1e-6 W=100e-6
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends or3

.subckt and3 1 2 3 4 5 6
r2 2 6 10e3
r1 2 7 10e3
m4 6 7 1 1 nmosswitch L=1e-6 W=100e-6
m3 9 5 1 1 nmosswitch L=1e-6 W=100e-6
m2 8 4 9 1 nmosswitch L=1e-6 W=100e-6
m1 7 3 8 1 nmosswitch L=1e-6 W=100e-6
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends and3

.subckt limitl 1 2 3
elimit 4 1  2 7 10
vnegativ 6 1 DC -10
vthreshold 7 1 DC  8
vpositive 5 1 DC 10
dnega 6 3 dmod
dposi 3 5 dmod
r2 4 3 1e3
r1 2 7 10e6
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends limitl

.subckt limit 1 2 3
elimit 4 1  2  7 10
vnegativ 6 1 DC -10
vthreshold 7 1 DC 8
vpositive 5 1 DC 10
dnega 6 3 dmod
dposi 3 5 dmod
r2 4 3 1e3
r1 2 7 1e6
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends limit

.subckt and4 1 2 3 4 5 6 7
r2 2 7 10e3
r1 2 8 10e3
m1m4 7 8 1 1 nmosswitch L=1e-6 W=100e-6
m4 11 6 1 1 nmosswitch L=1e-6 W=100e-6
m3 10 5 11 1 nmosswitch L=1e-6 W=100e-6
m2 9 4 10 1 nmosswitch L=1e-6 W=100e-6
m1 8 3 9 1 nmosswitch L=1e-6 W=100e-6
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends and4

.subckt or2 1 2 3 4 5
m3 5 6 1 1 nmosswitch L=1e-6 W=100e-6
m2 6 3 1 1 nmosswitch L=1e-6 W=100e-6
m1 6 4 1 1 nmosswitch L=1e-6 W=100e-6
r2 2 5 10e3
r1 2 6 10e3
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends or2

.subckt led 1 3 4 5
gband 1 3  9 1 1 
fphoto 1 9  vsense  1 
egain 7 4  6 4 1
cdelay 9 1 70e-9
cband 3 1 10e-12
ithre 3 1 DC  1e-3
vsense 8 4 DC  0
dled 6 4 lednor
doptic 7 8 lednorc
rband 3 1 2e3 
rthermo 9 1 1 
rled 5 6 1
.MODEL  LEDNOR D IS=5E-16 N=2 XTI=3 EG=2.1 BV=5 IBV=10u
+  CJO=60p VJ=.75 M=.3333 FC=.5 TT=20n
.MODEL LEDNORC D IS=5E-16 N=2 XTI=3 EG=2.1 BV=5 IBV=10u
+  VJ=.75 M=.3333 FC=.5
.ends led

.subckt inverter 1 2 3 4
m0 4 3 1 1 nmosswitch L=1e-6 W=100e-6
r1 2 4 10e3
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends inverter

.subckt and2 1 2 3 4 5
m3 5 6 1 1 nmosswitch L=1e-6 W=100e-6
m2 7 4 1 1 nmosswitch L=1e-6 W=100e-6
m1 6 3 7 1 nmosswitch L=1e-6 W=100e-6
r2 2 5 10e3
r1 2 6 10e3
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends and2

.subckt r_s 1 2 3 4 5
m4 5 3 1 1 nmosswitch L=1e-6 W=100e-6
m3 5 6 1 1 nmosswitch L=1e-6 W=100e-6
m2 6 5 1 1 nmosswitch L=1e-6 W=100e-6
m1 6 4 1 1 nmosswitch L=1e-6 W=100e-6
rl 5 1 50e3
r1 2 6 10e3
r2 2 5 10e3
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends r_s

.subckt comparator 1 2 3 4 5
mcopa 5 6 1 1 nmosswitch L=1e-6 W=100e-6
egain 6 1  3 4 1e3
ro 5 2 10e3
rgate 6 1 10e3
r1n 3 4 1e6
.MODEL nmosswitch nmos (vto=+0.7)
.MODEL nmosmod nmos (vto=+1.2   RS=0.5  LAMBDA=0)
.MODEL pmosmod pmos (vto=-0.2 )
.MODEL npnmod  npn bf=11
.MODEL pnpmod  pnp bf=100
.MODEL dmod D IS=2.22P CJO=1P VJ=.376 M=.139 N=1.07
.ends comparator