kicad/spice/test/OptiMOS2_100V.lib

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*****************************************************************
* INFINEON Power Transistors *
* Level1/3 PSPICE Library for OptiMOS2 n-Channel Transistors *
* *
* This file also contains simplified models that are compatible *
* to standard Spice. *
* *
* Version 10122008 *
* *
*****************************************************************
* *
* The Simulation Model is subject to change without notice. In *
* addition, models can be a useful tool in evaluating device *
* performance, they cannot reflect the accurate device *
* performance under all conditions, nor are they intended to *
* replace bread boarding for final verification. Infineon *
* therefore does not assume any warranty or liability *
* whatsoever arising from their use. Infineon does not assume *
* any warranty or liability for the values and functions of the *
* Simulation Model. *
* The methods and results of the Simulation Model are to the *
* best of our knowledge *
* correct. However, the user is fully responsible to verify and *
* validate these results under the operating conditions and in *
* the environment of its application. Infineon will not bear *
* the responsibility arising out of or in connection with any *
* malfunction of the Simulation Models. *
* Models provided by Infineon are not warranted by Infineon as *
* completely and comprehensively representing all the *
* specifications and operating characteristics of the *
* semiconductor products to which these models relate. The *
* models describe the characteristics of typical devices. In *
* all cases, the current data sheet information for a given *
* device is the conclusive design guideline and the only actual *
* performance specification. *
* *
* This library contains models of the following INFINEON *
* OptiMOS2 transistors: *
* *
* 100V NL *
* IPB04CN10N IPD12CN10N *
* IPB05CN10N IPD16CN10N *
* IPB06CN10N IPD25CN10N *
* IPB08CN10N IPD33CN10N *
* IPB12CN10N IPD49CN10N *
* IPB16CN10N IPD78CN10N *
* IPP04CN10N IPD64CN10N *
* IPP05CN10N BSC079N10NS *
* IPP06CN10N BSC118N10NS *
* IPP08CN10N BSC196N10NS *
* IPP12CN10N BSC100N10NSF *
* IPP16CN10N BSC152N10NSF *
* IPP26CN10N BSC252N10NSF *
* IPP35CN10N BSC750N10ND *
* IPP50CN10N *
* IPP80CN10N *
* *
* 100 V LL *
* IPP05CN10L IPS12CN10L *
* IPP06CN10L BSC082N10LS BSC159N10LSF *
* IPP08CN10L BSC123N10LS BSC265N10LSF *
* IPP12CN10L BSC205N10LS *
* IPP16CN10L BSC105N10LSF *
*****************************************************************
* thermal nodes of level 3 models: *
* *
* .SUBCKT IPB05CN10N drain gate source Tj Tcase *
* Tj : potential=temperature (in <20>C) at junction (typically *
* not connected) *
* Tcase : node where the boundary contition - external heat *
* sinks etc - have to be connected (ideal heat sink *
* can be modeled by using a voltage source stating the *
* ambient temperature in <20>C between Tcase and ground. *
* *
*****************************************************************
.SUBCKT S3_100_a_var dd g s0 Tj PARAMS: a=1 dVth=0 dR=0 dgfs=0 Inn=1 Unn=1 Rmax=1
+gmin=1 Rs=1 Rp=1 dC=0 Rm=1u heat=0
.PARAM Fm=0.065 Fn=0.5 kbq=85.8u
.PARAM c=1.55 muc=0.0 Vth0=4.073 auth=5.5m al=0.001
.PARAM UT=100m ab=78.7m ab2=0 lB=-23 UB=132
.PARAM b0=22.55 p0=6.62 p1=-20.6m p2=39.2u
.PARAM Rd=60m nmu=2.75 Tref=298 T0=273 lnIsj=-25.7
.PARAM ndi=1.17 Rdi=12m nmu2=0.3 ta=30n td=100n
.PARAM Rf=0.34 nmu3=1.8 rpa=150u
.PARAM f3=380p f3a=60p
.PARAM ps1=45p ps2=-62.5m ps3=80p ps4=-2 ps5=1.06p ps6=4p
.PARAM qs1=26p qs2=50p qs3=-2 qs4=175p qs5=-0.0357
.PARAM Vmin=3.073 Vmax=5.073 dCmax=0.33
.PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)}
.PARAM q0={b0*((T0/Tref)**nmu3)*a}
.PARAM q1={(Unn-Inn*Rs-Vth0)*q0}
.PARAM q2={(Fm*SQRT(0.4)-c)*Inn*q0}
.PARAM Rlim={(q1+2*q2*Rmax-SQRT(q1**2+4*q2))/(2*q2)}
.PARAM dRd={Rd/a+if(dVth==0,limit(dR,0,1)*max(Rlim-Rd/a-Rs-Rp,0),0)}
.PARAM bm={c/((1/gmin-Rs)**2*Inn*a*(T0/Tref)**nmu3)}
.PARAM bet={b0+(b0-bm)*if(dR==0,if(dVth==0,limit(dgfs,-1,0),0),0)}
.PARAM dC1={1+dCmax*limit(dC,0,1)}
.PARAM Cox1={ps1*a*dC1}
.PARAM Cox2={ps3*a*dC1}
.PARAM Cox3={(ps5*a+ps6)*dC1}
.PARAM Cds0={qs1*a*dC1}
.PARAM Cds1={qs2*a*dC1}
.PARAM Cds2={qs4*a*dC1}
.PARAM Cgs0={(f3a+f3*a)*dC1}
.PARAM dRdi={Rdi/a}
.FUNC I0(Uee,p,pp,z1,cc) {if(Uee>pp,(Uee-cc*z1)*z1,p*(pp-p)/cc*exp((Uee-pp)/p))}
.FUNC Ig(Uds,T,p,Uee,cc) {bet*(T0/T)**nmu3*I0(Uee,p,min(2*p,p+cc*Uds),min(Uds,Uee/(2*cc)),cc)}
.FUNC J(d,g,T,da,s)
+ {a*s*((Ig(da,T,(p0+(p1+p2*T)*T)*kbq*T,g-Vth+auth*(T-Tref)+Fm*da**Fn,c*(T/Tref)**muc)+exp(min(lB+(d-UB-ab*(T-Tref))/UT,25))))}
.FUNC Idiode(Usd,Tj,Iss) {exp(min(log(Iss)+Usd/(ndi*kbq*Tj),7))-Iss}
.FUNC Idiod(Usd,Tj) {a*Idiode(Usd,Tj,exp(min(lnIsj+(Tj/Tref-1)*1.12/(ndi*kbq*Tj),7))*(Tj/Tref)**3)}
E_Edg1 d ox VALUE {if(V(d,g)>0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/ps2,0)}
C_Cdg1 ox g {Cox1}
E_Edg2 d ox1 VALUE {if(V(d,g)>0,V(d,g)-(exp(ps4*max(V(d,g),0))-1)/ps4,0)}
C_Cdg2 ox1 g {Cox2}
Vx d ox2 0
C_Cdg3 ox2 g {Cox3}
E_Eds d edep VALUE {(V(d,s)-I(V_sense3)/(Cds0+Cds1+Cds2))}
C_Cds edep s {Cds0+Cds1+Cds2}
C_Cgs g s {Cgs0}
G_chan d s VALUE={J(V(d,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*abs(V(d,s)))-1)/2/al,sgn(V(d,s)))}
G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)/(1+rpa*(I(V_sense)/a)**2)}
V_sense dd d1 0
G_diode s d3 VALUE={Idiod(V(s,d3),T0+limit(V(Tj),-200,499))}
G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)}
V_sense2 d2 d3 0
L_L001 a c {td/(ta+td)}
R_R001 a b {1/ta}
V_sense3 c 0 0
E_E001 b 0 VALUE {I(V_sense2)}
E_E002 e 0 VALUE {Cds1/qs3*(exp(qs3*max(V(d1,s),-1))-1)+Cds2/qs5*(exp(qs5*max(V(d1,s),-1))-1)+Cds0*V(d1,s)}
R_R002 e c 1
R_R003 a 0 500Meg
R1 g s 1G
Rd01 d s 500Meg
Rd02 d2 s 500Meg
Rd03 d1 d 1k
Rmet s s0 {Rm}
G_TH 0 Tj VALUE =
+{(LIMIT(I(V_sense2)*V(d1,s)+(V(s,s0)**2)/Rm+(I(V_sense)-I(V_sense2))*V(d1,d)+
+(I(V_sense)-I(V_sense2)-I(E_Edg1)-I(E_Edg2)-I(Vx)-I(E_Eds))*V(d,s),-10k,100k))}
.ENDS
*********
.SUBCKT S3_100_b_var dd g s0 Tj PARAMS: a=1 dVth=0 dR=0 dgfs=0 Inn=1 Unn=1 Rmax=1
+gmin=1 Rs=1 Rp=1 dC=0 Rm=1u heat=0
.PARAM Fm=0.065 Fn=0.5 kbq=85.8u
.PARAM c=1.312 muc=5m Vth0=4.073 auth=4.856m al=0.5
.PARAM UT=100m ab=78.7m ab2=0 lB=-23 UB=132
.PARAM b0=10.91 p0=4.562 p1=-12.6m p2=32u
.PARAM Rd=63m nmu=2.64 Tref=298 T0=273 lnIsj=-25.3
.PARAM ndi=1.2 Rdi=5.7m nmu2=0.3 ta=30n td=100n
.PARAM Rf=0.28 nmu3=1.8 rpa=0u
.PARAM f3=185p f3a=55p
.PARAM ps1=25p ps2=-62.5m ps3=40p ps4=-2 ps5=0.6p ps6=3p
.PARAM qs1=30p qs2=50p qs3=-2 qs4=200p qs5=-0.0357
.PARAM Vmin=3.073 Vmax=5.073 dCmax=0.33
.PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)}
.PARAM q0={b0*((T0/Tref)**nmu3)*a}
.PARAM q1={(Unn-Inn*Rs-Vth0)*q0}
.PARAM q2={(Fm*SQRT(0.4)-c)*Inn*q0}
.PARAM Rlim={(q1+2*q2*Rmax-SQRT(q1**2+4*q2))/(2*q2)}
.PARAM dRd={Rd/a+if(dVth==0,limit(dR,0,1)*max(Rlim-Rd/a-Rs-Rp,0),0)}
.PARAM bm={c/((1/gmin-Rs)**2*Inn*a*(T0/Tref)**nmu3)}
.PARAM bet={b0+(b0-bm)*if(dR==0,if(dVth==0,limit(dgfs,-1,0),0),0)}
.PARAM dC1={1+dCmax*limit(dC,0,1)}
.PARAM Cox1={ps1*a*dC1}
.PARAM Cox2={ps3*a*dC1}
.PARAM Cox3={(ps5*a+ps6)*dC1}
.PARAM Cds0={qs1*a*dC1}
.PARAM Cds1={qs2*a*dC1}
.PARAM Cds2={qs4*a*dC1}
.PARAM Cgs0={(f3a+f3*a)*dC1}
.PARAM dRdi={Rdi/a}
.FUNC I0(Uee,p,pp,z1,cc) {if(Uee>pp,(Uee-cc*z1)*z1,p*(pp-p)/cc*exp((Uee-pp)/p))}
.FUNC Ig(Uds,T,p,Uee,cc) {bet*(T0/T)**nmu3*I0(Uee,p,min(2*p,p+cc*Uds),min(Uds,Uee/(2*cc)),cc)}
.FUNC J(d,g,T,da,s)
+ {a*s*((Ig(da,T,(p0+(p1+p2*T)*T)*kbq*T,g-Vth+auth*(T-Tref)+Fm*da**Fn,c*(T/Tref)**muc)+exp(min(lB+(d-UB-ab*(T-Tref))/UT,25))))}
.FUNC Idiode(Usd,Tj,Iss) {exp(min(log(Iss)+Usd/(ndi*kbq*Tj),7))-Iss}
.FUNC Idiod(Usd,Tj) {a*Idiode(Usd,Tj,exp(min(lnIsj+(Tj/Tref-1)*1.12/(ndi*kbq*Tj),7))*(Tj/Tref)**3)}
E_Edg1 d ox VALUE {if(V(d,g)>0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/ps2,0)}
C_Cdg1 ox g {Cox1}
E_Edg2 d ox1 VALUE {if(V(d,g)>0,V(d,g)-(exp(ps4*max(V(d,g),0))-1)/ps4,0)}
C_Cdg2 ox1 g {Cox2}
Vx d ox2 0
C_Cdg3 ox2 g {Cox3}
E_Eds d edep VALUE {(V(d,s)-I(V_sense3)/(Cds0+Cds1+Cds2))}
C_Cds edep s {Cds0+Cds1+Cds2}
C_Cgs g s {Cgs0}
G_chan d s VALUE={J(V(d,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*abs(V(d,s)))-1)/2/al,sgn(V(d,s)))}
G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)/(1+rpa*(I(V_sense)/a)**2)}
V_sense dd d1 0
G_diode s d3 VALUE={Idiod(V(s,d3),T0+limit(V(Tj),-200,499))}
G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)}
V_sense2 d2 d3 0
L_L001 a c {td/(ta+td)}
R_R001 a b {1/ta}
V_sense3 c 0 0
E_E001 b 0 VALUE {I(V_sense2)}
E_E002 e 0 VALUE {Cds1/qs3*(exp(qs3*max(V(d1,s),-1))-1)+Cds2/qs5*(exp(qs5*max(V(d1,s),-1))-1)+Cds0*V(d1,s)}
R_R002 e c 1
R_R003 a 0 500Meg
R1 g s 1G
Rd01 d s 500Meg
Rd02 d2 s 500Meg
Rd03 d1 d 1k
Rmet s s0 {Rm}
G_TH 0 Tj VALUE =
+{(LIMIT(I(V_sense2)*V(d1,s)+(V(s,s0)**2)/Rm+(I(V_sense)-I(V_sense2))*V(d1,d)+
+(I(V_sense)-I(V_sense2)-I(E_Edg1)-I(E_Edg2)-I(Vx)-I(E_Eds))*V(d,s),-10k,100k))}
.ENDS
*********
.SUBCKT S3_100_c_var dd g s0 Tj PARAMS: a=1 dVth=0 dR=0 dgfs=0 Inn=1 Unn=1 Rmax=1
+gmin=1 Rs=1 Rp=1 dC=0 Rm=1u heat=0
.PARAM Fm=0.085 Fn=0.5 kbq=85.8u
.PARAM c=1.08 muc=0.0 Vth0=2.69 auth=3.3m al=0.5
.PARAM UT=100m ab=78.7m ab2=0 lB=-23 UB=132
.PARAM b0=35 p0=5.022 p1=-14.6m p2=25u
.PARAM Rd=66m nmu=2.75 Tref=298 T0=273 lnIsj=-25.7
.PARAM ndi=1.14 Rdi=12m nmu2=0.7 ta=30n td=100n
.PARAM Rf=0.34 nmu3=1.65 rpa=150u
.PARAM f3=490p f3a=110p
.PARAM ps1=45p ps2=-62.5m ps3=80p ps4=-2 ps5=1.06p ps6=4p
.PARAM qs1=26p qs2=50p qs3=-2 qs4=180p qs5=-0.0333
.PARAM Vmin=2.04 Vmax=2.84 dCmax=0.33
.PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)}
.PARAM q0={b0*((T0/Tref)**nmu3)*a}
.PARAM q1={(Unn-Inn*Rs-Vth0)*q0}
.PARAM q2={(Fm*SQRT(0.4)-c)*Inn*q0}
.PARAM Rlim={(q1+2*q2*Rmax-SQRT(q1**2+4*q2))/(2*q2)}
.PARAM dRd={Rd/a+if(dVth==0,limit(dR,0,1)*max(Rlim-Rd/a-Rs-Rp,0),0)}
.PARAM bm={c/((1/gmin-Rs)**2*Inn*a*(T0/Tref)**nmu3)}
.PARAM bet={b0+(b0-bm)*if(dR==0,if(dVth==0,limit(dgfs,-1,0),0),0)}
.PARAM dC1={1+dCmax*limit(dC,0,1)}
.PARAM Cox1={ps1*a*dC1}
.PARAM Cox2={ps3*a*dC1}
.PARAM Cox3={(ps5*a+ps6)*dC1}
.PARAM Cds0={qs1*a*dC1}
.PARAM Cds1={qs2*a*dC1}
.PARAM Cds2={qs4*a*dC1}
.PARAM Cgs0={(f3a+f3*a)*dC1}
.PARAM dRdi={Rdi/a}
.FUNC I0(Uee,p,pp,z1,cc) {if(Uee>pp,(Uee-cc*z1)*z1,p*(pp-p)/cc*exp((Uee-pp)/p))}
.FUNC Ig(Uds,T,p,Uee,cc) {bet*(T0/T)**nmu3*I0(Uee,p,min(2*p,p+cc*Uds),min(Uds,Uee/(2*cc)),cc)}
.FUNC J(d,g,T,da,s)
+ {a*s*((Ig(da,T,(p0+(p1+p2*T)*T)*kbq*T,g-Vth+auth*(T-Tref)+Fm*da**Fn,c*(T/Tref)**muc)+exp(min(lB+(d-UB-ab*(T-Tref))/UT,25))))}
.FUNC Idiode(Usd,Tj,Iss) {exp(min(log(Iss)+Usd/(ndi*kbq*Tj),7))-Iss}
.FUNC Idiod(Usd,Tj) {a*Idiode(Usd,Tj,exp(min(lnIsj+(Tj/Tref-1)*1.12/(ndi*kbq*Tj),7))*(Tj/Tref)**3)}
E_Edg1 d ox VALUE {if(V(d,g)>0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/ps2,0)}
C_Cdg1 ox g {Cox1}
E_Edg2 d ox1 VALUE {if(V(d,g)>0,V(d,g)-(exp(ps4*max(V(d,g),0))-1)/ps4,0)}
C_Cdg2 ox1 g {Cox2}
Vx d ox2 0
C_Cdg3 ox2 g {Cox3}
E_Eds d edep VALUE {(V(d,s)-I(V_sense3)/(Cds0+Cds1+Cds2))}
C_Cds edep s {Cds0+Cds1+Cds2}
C_Cgs g s {Cgs0}
G_chan d s VALUE={J(V(d,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*abs(V(d,s)))-1)/2/al,sgn(V(d,s)))}
G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)/(1+rpa*(I(V_sense)/a)**2)}
V_sense dd d1 0
G_diode s d3 VALUE={Idiod(V(s,d3),T0+limit(V(Tj),-200,499))}
G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)}
V_sense2 d2 d3 0
L_L001 a c {td/(ta+td)}
R_R001 a b {1/ta}
V_sense3 c 0 0
E_E001 b 0 VALUE {I(V_sense2)}
E_E002 e 0 VALUE {Cds1/qs3*(exp(qs3*max(V(d1,s),-1))-1)+Cds2/qs5*(exp(qs5*max(V(d1,s),-1))-1)+Cds0*V(d1,s)}
R_R002 e c 1
R_R003 a 0 500Meg
R1 g s 1G
Rd01 d s 500Meg
Rd02 d2 s 500Meg
Rd03 d1 d 1k
Rmet s s0 {Rm}
G_TH 0 Tj VALUE =
+{(LIMIT(I(V_sense2)*V(d1,s)+(V(s,s0)**2)/Rm+(I(V_sense)-I(V_sense2))*V(d1,d)+
+(I(V_sense)-I(V_sense2)-I(E_Edg1)-I(E_Edg2)-I(Vx)-I(E_Eds))*V(d,s),-10k,100k))}
.ENDS
*********
.SUBCKT S3_100_d_var dd g s0 Tj PARAMS: a=1 dVth=0 dR=0 dgfs=0 Inn=1 Unn=1 Rmax=1
+gmin=1 Rs=1 Rp=1 dC=0 Rm=1u heat=0
.PARAM Fm=0.085 Fn=0.5 kbq=85.8u
.PARAM c=1.4 muc=0.0 Vth0=2.69 auth=3.3m al=0.5
.PARAM UT=100m ab=78.7m ab2=0 lB=-23 UB=132
.PARAM b0=16 p0=6.445 p1=-22.5m p2=39u
.PARAM Rd=66m nmu=2.75 Tref=298 T0=273 lnIsj=-25.7
.PARAM ndi=1.14 Rdi=12m nmu2=0.7 ta=30n td=100n
.PARAM Rf=0.34 nmu3=1.65 rpa=300u
.PARAM f3=245p f3a=100p
.PARAM ps1=25p ps2=-77m ps3=43p ps4=-2 ps5=0.4p ps6=4p
.PARAM qs1=30p qs2=50p qs3=-2 qs4=180p qs5=-0.0333
.PARAM Vmin=2.04 Vmax=2.84 dCmax=0.33
.PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)}
.PARAM q0={b0*((T0/Tref)**nmu3)*a}
.PARAM q1={(Unn-Inn*Rs-Vth0)*q0}
.PARAM q2={(Fm*SQRT(0.4)-c)*Inn*q0}
.PARAM Rlim={(q1+2*q2*Rmax-SQRT(q1**2+4*q2))/(2*q2)}
.PARAM dRd={Rd/a+if(dVth==0,limit(dR,0,1)*max(Rlim-Rd/a-Rs-Rp,0),0)}
.PARAM bm={c/((1/gmin-Rs)**2*Inn*a*(T0/Tref)**nmu3)}
.PARAM bet={b0+(b0-bm)*if(dR==0,if(dVth==0,limit(dgfs,-1,0),0),0)}
.PARAM dC1={1+dCmax*limit(dC,0,1)}
.PARAM Cox1={ps1*a*dC1}
.PARAM Cox2={ps3*a*dC1}
.PARAM Cox3={(ps5*a+ps6)*dC1}
.PARAM Cds0={qs1*a*dC1}
.PARAM Cds1={qs2*a*dC1}
.PARAM Cds2={qs4*a*dC1}
.PARAM Cgs0={(f3a+f3*a)*dC1}
.PARAM dRdi={Rdi/a}
.FUNC I0(Uee,p,pp,z1,cc) {if(Uee>pp,(Uee-cc*z1)*z1,p*(pp-p)/cc*exp((Uee-pp)/p))}
.FUNC Ig(Uds,T,p,Uee,cc) {bet*(T0/T)**nmu3*I0(Uee,p,min(2*p,p+cc*Uds),min(Uds,Uee/(2*cc)),cc)}
.FUNC J(d,g,T,da,s)
+ {a*s*((Ig(da,T,(p0+(p1+p2*T)*T)*kbq*T,g-Vth+auth*(T-Tref)+Fm*da**Fn,c*(T/Tref)**muc)+exp(min(lB+(d-UB-ab*(T-Tref))/UT,25))))}
.FUNC Idiode(Usd,Tj,Iss) {exp(min(log(Iss)+Usd/(ndi*kbq*Tj),7))-Iss}
.FUNC Idiod(Usd,Tj) {a*Idiode(Usd,Tj,exp(min(lnIsj+(Tj/Tref-1)*1.12/(ndi*kbq*Tj),7))*(Tj/Tref)**3)}
E_Edg1 d ox VALUE {if(V(d,g)>0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/ps2,0)}
C_Cdg1 ox g {Cox1}
E_Edg2 d ox1 VALUE {if(V(d,g)>0,V(d,g)-(exp(ps4*max(V(d,g),0))-1)/ps4,0)}
C_Cdg2 ox1 g {Cox2}
Vx d ox2 0
C_Cdg3 ox2 g {Cox3}
E_Eds d edep VALUE {(V(d,s)-I(V_sense3)/(Cds0+Cds1+Cds2))}
C_Cds edep s {Cds0+Cds1+Cds2}
C_Cgs g s {Cgs0}
G_chan d s VALUE={J(V(d,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*abs(V(d,s)))-1)/2/al,sgn(V(d,s)))}
G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)/(1+rpa*(I(V_sense)/a)**2)}
V_sense dd d1 0
G_diode s d3 VALUE={Idiod(V(s,d3),T0+limit(V(Tj),-200,499))}
G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)}
V_sense2 d2 d3 0
L_L001 a c {td/(ta+td)}
R_R001 a b {1/ta}
V_sense3 c 0 0
E_E001 b 0 VALUE {I(V_sense2)}
E_E002 e 0 VALUE {Cds1/qs3*(exp(qs3*max(V(d1,s),-1))-1)+Cds2/qs5*(exp(qs5*max(V(d1,s),-1))-1)+Cds0*V(d1,s)}
R_R002 e c 1
R_R003 a 0 500Meg
R1 g s 1G
Rd01 d s 500Meg
Rd02 d2 s 500Meg
Rd03 d1 d 1k
Rmet s s0 {Rm}
G_TH 0 Tj VALUE =
+{(LIMIT(I(V_sense2)*V(d1,s)+(V(s,s0)**2)/Rm+(I(V_sense)-I(V_sense2))*V(d1,d)+
+(I(V_sense)-I(V_sense2)-I(E_Edg1)-I(E_Edg2)-I(Vx)-I(E_Eds))*V(d,s),-10k,100k))}
.ENDS
*********
.SUBCKT IPB04CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=623u Rg=1.9 Rd=50u Rm=156u
.PARAM Inn=100 Unn=10 Rmax=4.1m gmin=87
.PARAM RRf=181m Rrbond=10m Rtb=5 g2=572m
.PARAM act=27.1
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 7.61m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.21m+limit(Zthtype,0,1)*449.24u}
Rth2 t1 t2 {13.31m+limit(Zthtype,0,1)*4.92m}
Rth3 t2 t3 {75.74m+limit(Zthtype,0,1)*25.08m}
Rth4 t3 t4 {65.33m+limit(Zthtype,0,1)*38.48m}
Rth5 t4 Tcase {173.36m+limit(Zthtype,0,1)*102.12m}
Cth1 Tj 0 377.292u
Cth2 t1 0 856.511u
Cth3 t2 0 9.103m
Cth4 t3 0 4.607m
Cth5 t4 0 136.409m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPB05CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=805u Rg=1.9 Rd=50u Rm=300u
.PARAM Inn=100 Unn=10 Rmax=5.1m gmin=81
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=23.47
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.4m+limit(Zthtype,0,1)*515.4u}
Rth2 t1 t2 {15.33m+limit(Zthtype,0,1)*5.68m}
Rth3 t2 t3 {87.39m+limit(Zthtype,0,1)*28.98m}
Rth4 t3 t4 {75.43m+limit(Zthtype,0,1)*29.02m}
Rth5 t4 Tcase {185.07m+limit(Zthtype,0,1)*71.19m}
Cth1 Tj 0 326.755u
Cth2 t1 0 743.512u
Cth3 t2 0 7.891m
Cth4 t3 0 3.99m
Cth5 t4 0 121.993m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPB06CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=745u Rg=1.6 Rd=50u Rm=240u
.PARAM Inn=100 Unn=10 Rmax=6.2m gmin=77
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=17.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.83m+limit(Zthtype,0,1)*681.8u}
Rth2 t1 t2 {20m+limit(Zthtype,0,1)*7.41m}
Rth3 t2 t3 {113.28m+limit(Zthtype,0,1)*38.04m}
Rth4 t3 t4 {98.91m+limit(Zthtype,0,1)*67.42m}
Rth5 t4 Tcase {209.58m+limit(Zthtype,0,1)*142.85m}
Cth1 Tj 0 249.208u
Cth2 t1 0 569.82u
Cth3 t2 0 6.105m
Cth4 t3 0 3.043m
Cth5 t4 0 100.531m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPB08CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=705u Rg=1.5 Rd=50u Rm=200u
.PARAM Inn=95 Unn=10 Rmax=8.2m gmin=57
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=12.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {2.54m+limit(Zthtype,0,1)*945.06u}
Rth2 t1 t2 {27.57m+limit(Zthtype,0,1)*10.21m}
Rth3 t2 t3 {154.04m+limit(Zthtype,0,1)*52.84m}
Rth4 t3 t4 {137.24m+limit(Zthtype,0,1)*97.36m}
Rth5 t4 Tcase {244.09m+limit(Zthtype,0,1)*173.16m}
Cth1 Tj 0 179.597u
Cth2 t1 0 413.456u
Cth3 t2 0 4.512m
Cth4 t3 0 2.193m
Cth5 t4 0 81.53m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPB12CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=4n Ld=1n Lg=4n
.PARAM Rs=958u Rg=1.5 Rd=50u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.6m gmin=38
.PARAM RRf=393m Rrbond=31m Rtb=8.7 g2=698m
.PARAM act=8.31
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 5.85m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {3.95m+limit(Zthtype,0,1)*1.46m}
Rth2 t1 t2 {42.33m+limit(Zthtype,0,1)*15.67m}
Rth3 t2 t3 {234.29m+limit(Zthtype,0,1)*82.2m}
Rth4 t3 t4 {213.05m+limit(Zthtype,0,1)*127.18m}
Rth5 t4 Tcase {300.49m+limit(Zthtype,0,1)*179.38m}
Cth1 Tj 0 115.694u
Cth2 t1 0 269.296u
Cth3 t2 0 2.983m
Cth4 t3 0 1.413m
Cth5 t4 0 63.737m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPB16CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=4n Ld=1n Lg=4n
.PARAM Rs=908u Rg=1.2 Rd=50u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16.2m gmin=30
.PARAM RRf=393m Rrbond=31m Rtb=8.7 g2=698m
.PARAM act=6.16
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 5.85m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {5.33m+limit(Zthtype,0,1)*1.97m}
Rth2 t1 t2 {56.59m+limit(Zthtype,0,1)*20.95m}
Rth3 t2 t3 {306.84m+limit(Zthtype,0,1)*111.08m}
Rth4 t3 t4 {287.41m+limit(Zthtype,0,1)*164.5m}
Rth5 t4 Tcase {346.82m+limit(Zthtype,0,1)*198.51m}
Cth1 Tj 0 85.761u
Cth2 t1 0 201.422u
Cth3 t2 0 2.296m
Cth4 t3 0 1.047m
Cth5 t4 0 55.041m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP04CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=623u Rg=1.9 Rd=350u Rm=156u
.PARAM Inn=100 Unn=10 Rmax=4.4m gmin=87
.PARAM RRf=181m Rrbond=10m Rtb=5 g2=572m
.PARAM act=27.1
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 7.61m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.21m+limit(Zthtype,0,1)*449.24u}
Rth2 t1 t2 {13.31m+limit(Zthtype,0,1)*4.92m}
Rth3 t2 t3 {75.74m+limit(Zthtype,0,1)*25.08m}
Rth4 t3 t4 {65.33m+limit(Zthtype,0,1)*38.48m}
Rth5 t4 Tcase {173.36m+limit(Zthtype,0,1)*102.12m}
Cth1 Tj 0 377.292u
Cth2 t1 0 856.511u
Cth3 t2 0 9.103m
Cth4 t3 0 4.607m
Cth5 t4 0 136.409m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPP05CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=805u Rg=1.9 Rd=350u Rm=300u
.PARAM Inn=100 Unn=10 Rmax=5.4m gmin=81
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=23.47
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.4m+limit(Zthtype,0,1)*515.4u}
Rth2 t1 t2 {15.33m+limit(Zthtype,0,1)*5.68m}
Rth3 t2 t3 {87.39m+limit(Zthtype,0,1)*28.98m}
Rth4 t3 t4 {75.43m+limit(Zthtype,0,1)*29.02m}
Rth5 t4 Tcase {185.07m+limit(Zthtype,0,1)*71.19m}
Cth1 Tj 0 326.755u
Cth2 t1 0 743.512u
Cth3 t2 0 7.891m
Cth4 t3 0 3.99m
Cth5 t4 0 121.993m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPP06CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=745u Rg=1.6 Rd=350u Rm=240u
.PARAM Inn=100 Unn=10 Rmax=6.5m gmin=77
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=17.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.83m+limit(Zthtype,0,1)*681.8u}
Rth2 t1 t2 {20m+limit(Zthtype,0,1)*7.41m}
Rth3 t2 t3 {113.28m+limit(Zthtype,0,1)*38.04m}
Rth4 t3 t4 {98.91m+limit(Zthtype,0,1)*67.42m}
Rth5 t4 Tcase {209.58m+limit(Zthtype,0,1)*142.85m}
Cth1 Tj 0 249.208u
Cth2 t1 0 569.82u
Cth3 t2 0 6.105m
Cth4 t3 0 3.043m
Cth5 t4 0 100.531m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPP08CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=705u Rg=1.5 Rd=350u Rm=200u
.PARAM Inn=95 Unn=10 Rmax=8.5m gmin=57
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=12.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {2.54m+limit(Zthtype,0,1)*945.06u}
Rth2 t1 t2 {27.57m+limit(Zthtype,0,1)*10.21m}
Rth3 t2 t3 {154.04m+limit(Zthtype,0,1)*52.84m}
Rth4 t3 t4 {137.24m+limit(Zthtype,0,1)*97.36m}
Rth5 t4 Tcase {244.09m+limit(Zthtype,0,1)*173.16m}
Cth1 Tj 0 179.597u
Cth2 t1 0 413.456u
Cth3 t2 0 4.512m
Cth4 t3 0 2.193m
Cth5 t4 0 81.53m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP12CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=958u Rg=1.5 Rd=350u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.9m gmin=38
.PARAM RRf=393m Rrbond=31m Rtb=8.7 g2=698m
.PARAM act=8.31
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 5.85m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {3.95m+limit(Zthtype,0,1)*1.46m}
Rth2 t1 t2 {42.33m+limit(Zthtype,0,1)*15.67m}
Rth3 t2 t3 {234.29m+limit(Zthtype,0,1)*82.2m}
Rth4 t3 t4 {213.05m+limit(Zthtype,0,1)*127.18m}
Rth5 t4 Tcase {300.49m+limit(Zthtype,0,1)*179.38m}
Cth1 Tj 0 115.694u
Cth2 t1 0 269.296u
Cth3 t2 0 2.983m
Cth4 t3 0 1.413m
Cth5 t4 0 63.737m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP16CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=908u Rg=1.2 Rd=350u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16.5m gmin=30
.PARAM RRf=393m Rrbond=31m Rtb=8.7 g2=698m
.PARAM act=6.16
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 5.85m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {5.33m+limit(Zthtype,0,1)*1.97m}
Rth2 t1 t2 {56.59m+limit(Zthtype,0,1)*20.95m}
Rth3 t2 t3 {306.84m+limit(Zthtype,0,1)*111.08m}
Rth4 t3 t4 {287.41m+limit(Zthtype,0,1)*164.5m}
Rth5 t4 Tcase {346.82m+limit(Zthtype,0,1)*198.51m}
Cth1 Tj 0 85.761u
Cth2 t1 0 201.422u
Cth3 t2 0 2.296m
Cth4 t3 0 1.047m
Cth5 t4 0 55.041m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP26CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=1.72m Rg=1.1 Rd=350u Rm=640u
.PARAM Inn=35 Unn=10 Rmax=26m gmin=19
.PARAM RRf=473m Rrbond=124m Rtb=17.4 g2=822m
.PARAM act=3.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 2.93m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {8.42m+limit(Zthtype,0,1)*3.11m}
Rth2 t1 t2 {87.93m+limit(Zthtype,0,1)*32.54m}
Rth3 t2 t3 {463.44m+limit(Zthtype,0,1)*175.99m}
Rth4 t3 t4 {457.12m+limit(Zthtype,0,1)*225.29m}
Rth5 t4 Tcase {432.84m+limit(Zthtype,0,1)*213.32m}
Cth1 Tj 0 54.297u
Cth2 t1 0 129.642u
Cth3 t2 0 1.539m
Cth4 t3 0 662.942u
Cth5 t4 0 45.488m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP35CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=1.53m Rg=1 Rd=350u Rm=450u
.PARAM Inn=27 Unn=10 Rmax=35m gmin=15
.PARAM RRf=473m Rrbond=124m Rtb=17.4 g2=822m
.PARAM act=2.92
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 2.93m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {11.24m+limit(Zthtype,0,1)*4.16m}
Rth2 t1 t2 {115.99m+limit(Zthtype,0,1)*42.92m}
Rth3 t2 t3 {603.94m+limit(Zthtype,0,1)*235.6m}
Rth4 t3 t4 {614.86m+limit(Zthtype,0,1)*260.87m}
Rth5 t4 Tcase {498.79m+limit(Zthtype,0,1)*211.63m}
Cth1 Tj 0 40.653u
Cth2 t1 0 98.282u
Cth3 t2 0 1.19m
Cth4 t3 0 496.356u
Cth5 t4 0 41.277m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP50CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=2.62m Rg=0.9 Rd=350u Rm=650u
.PARAM Inn=20 Unn=10 Rmax=50m gmin=10.5
.PARAM RRf=494m Rrbond=518m Rtb=35.4 g2=904m
.PARAM act=1.98
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 1.43m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {16.58m+limit(Zthtype,0,1)*6.13m}
Rth2 t1 t2 {167.72m+limit(Zthtype,0,1)*62.07m}
Rth3 t2 t3 {841.93m+limit(Zthtype,0,1)*348.69m}
Rth4 t3 t4 {920.39m+limit(Zthtype,0,1)*260.77m}
Rth5 t4 Tcase {604.46m+limit(Zthtype,0,1)*171.26m}
Cth1 Tj 0 27.566u
Cth2 t1 0 67.968u
Cth3 t2 0 868.439u
Cth4 t3 0 336.57u
Cth5 t4 0 37.577m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP80CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=4.3m Rg=0.8 Rd=350u Rm=660u
.PARAM Inn=13 Unn=10 Rmax=80m gmin=6.5
.PARAM RRf=498m Rrbond=2 Rtb=69.4 g2=949m
.PARAM act=1.238
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 731.6u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {26.51m+limit(Zthtype,0,1)*9.81m}
Rth2 t1 t2 {260.54m+limit(Zthtype,0,1)*96.42m}
Rth3 t2 t3 {1.23+limit(Zthtype,0,1)*565.19m}
Rth4 t3 t4 {1.5+limit(Zthtype,0,1)*296.12m}
Rth5 t4 Tcase {764.49m+limit(Zthtype,0,1)*150.92m}
Cth1 Tj 0 17.236u
Cth2 t1 0 43.753u
Cth3 t2 0 609.936u
Cth4 t3 0 210.441u
Cth5 t4 0 36.415m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPD12CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=1n Lg=3n
.PARAM Rs=791u Rg=1.5 Rd=50u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.4m gmin=38
.PARAM RRf=301m Rrbond=14m Rtb=5.8 g2=623m
.PARAM act=8.31
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 3.9m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {3.95m+limit(Zthtype,0,1)*1.46m}
Rth2 t1 t2 {42.33m+limit(Zthtype,0,1)*15.67m}
Rth3 t2 t3 {234.29m+limit(Zthtype,0,1)*82.2m}
Rth4 t3 t4 {172m+limit(Zthtype,0,1)*138.86m}
Rth5 t4 Tcase {281.76m+limit(Zthtype,0,1)*227.48m}
Cth1 Tj 0 115.694u
Cth2 t1 0 269.296u
Cth3 t2 0 2.983m
Cth4 t3 0 1.464m
Cth5 t4 0 34.87m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPD16CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=1n Lg=3n
.PARAM Rs=741u Rg=1.2 Rd=50u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16m gmin=30
.PARAM RRf=301m Rrbond=14m Rtb=5.8 g2=623m
.PARAM act=6.16
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 3.9m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {5.33m+limit(Zthtype,0,1)*1.97m}
Rth2 t1 t2 {56.59m+limit(Zthtype,0,1)*20.95m}
Rth3 t2 t3 {306.84m+limit(Zthtype,0,1)*111.08m}
Rth4 t3 t4 {232.04m+limit(Zthtype,0,1)*180.69m}
Rth5 t4 Tcase {328.61m+limit(Zthtype,0,1)*255.9m}
Cth1 Tj 0 85.761u
Cth2 t1 0 201.422u
Cth3 t2 0 2.296m
Cth4 t3 0 1.086m
Cth5 t4 0 29.486m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPD25CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=1.41m Rg=1.1 Rd=50u Rm=640u
.PARAM Inn=35 Unn=10 Rmax=25m gmin=19
.PARAM RRf=450m Rrbond=55m Rtb=11.6 g2=767m
.PARAM act=3.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 1.95m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {8.42m+limit(Zthtype,0,1)*3.11m}
Rth2 t1 t2 {87.93m+limit(Zthtype,0,1)*32.54m}
Rth3 t2 t3 {463.44m+limit(Zthtype,0,1)*175.99m}
Rth4 t3 t4 {369.67m+limit(Zthtype,0,1)*266.53m}
Rth5 t4 Tcase {402.31m+limit(Zthtype,0,1)*290.06m}
Cth1 Tj 0 54.297u
Cth2 t1 0 129.642u
Cth3 t2 0 1.539m
Cth4 t3 0 687.254u
Cth5 t4 0 25.436m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPD33CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=1.22m Rg=1 Rd=50u Rm=450u
.PARAM Inn=27 Unn=10 Rmax=33m gmin=15
.PARAM RRf=450m Rrbond=55m Rtb=11.6 g2=767m
.PARAM act=2.92
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 1.95m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {11.24m+limit(Zthtype,0,1)*4.16m}
Rth2 t1 t2 {115.99m+limit(Zthtype,0,1)*42.92m}
Rth3 t2 t3 {603.94m+limit(Zthtype,0,1)*235.6m}
Rth4 t3 t4 {498.05m+limit(Zthtype,0,1)*337.62m}
Rth5 t4 Tcase {447.28m+limit(Zthtype,0,1)*303.2m}
Cth1 Tj 0 40.653u
Cth2 t1 0 98.282u
Cth3 t2 0 1.19m
Cth4 t3 0 514.559u
Cth5 t4 0 25.184m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPD49CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=2.01m Rg=0.9 Rd=50u Rm=650u
.PARAM Inn=20 Unn=10 Rmax=49m gmin=10.5
.PARAM RRf=488m Rrbond=230m Rtb=23.6 g2=871m
.PARAM act=1.98
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 955.96u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {16.58m+limit(Zthtype,0,1)*6.13m}
Rth2 t1 t2 {167.72m+limit(Zthtype,0,1)*62.07m}
Rth3 t2 t3 {841.93m+limit(Zthtype,0,1)*348.69m}
Rth4 t3 t4 {748.13m+limit(Zthtype,0,1)*425.86m}
Rth5 t4 Tcase {498.9m+limit(Zthtype,0,1)*283.99m}
Cth1 Tj 0 27.566u
Cth2 t1 0 67.968u
Cth3 t2 0 868.439u
Cth4 t3 0 348.914u
Cth5 t4 0 29.676m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPD78CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=3.14m Rg=0.8 Rd=50u Rm=660u
.PARAM Inn=13 Unn=10 Rmax=78m gmin=6.5
.PARAM RRf=497m Rrbond=884m Rtb=46.3 g2=930m
.PARAM act=1.238
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 487.73u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {26.51m+limit(Zthtype,0,1)*9.81m}
Rth2 t1 t2 {260.54m+limit(Zthtype,0,1)*96.42m}
Rth3 t2 t3 {1.23+limit(Zthtype,0,1)*565.19m}
Rth4 t3 t4 {1.23+limit(Zthtype,0,1)*664.58m}
Rth5 t4 Tcase {530.38m+limit(Zthtype,0,1)*286.57m}
Cth1 Tj 0 17.236u
Cth2 t1 0 43.753u
Cth3 t2 0 609.936u
Cth4 t3 0 218.159u
Cth5 t4 0 106.171m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPD64CN10N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=3.14m Rg=0.9 Rd=50u Rm=660u
.PARAM Inn=17 Unn=10 Rmax=64m gmin=4.86
.PARAM RRf=497m Rrbond=884m Rtb=46.3 g2=930m
.PARAM act=1.98
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 487.73u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {16.58m+limit(Zthtype,0,1)*6.13m}
Rth2 t1 t2 {167.72m+limit(Zthtype,0,1)*62.07m}
Rth3 t2 t3 {841.93m+limit(Zthtype,0,1)*348.69m}
Rth4 t3 t4 {748.13m+limit(Zthtype,0,1)*425.86m}
Rth5 t4 Tcase {498.9m+limit(Zthtype,0,1)*283.99m}
Cth1 Tj 0 27.566u
Cth2 t1 0 67.968u
Cth3 t2 0 868.439u
Cth4 t3 0 348.914u
Cth5 t4 0 29.676m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT BSC079N10NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=7.9m gmin=40
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=11.21
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {2.93m+limit(Zthtype,0,1)*1.08m}
Rth2 t1 t2 {31.62m+limit(Zthtype,0,1)*11.71m}
Rth3 t2 t3 {174.06m+limit(Zthtype,0,1)*60.85m}
Rth4 t3 t4 {127.51m+limit(Zthtype,0,1)*53.35m}
Rth5 t4 Tcase {237.51m+limit(Zthtype,0,1)*99.38m}
Cth1 Tj 0 156.068u
Cth2 t1 0 360.466u
Cth3 t2 0 4.012m
Cth4 t3 0 1.975m
Cth5 t4 0 43.728m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC118N10NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=0.8 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=11.8m gmin=33
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=7.207
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {4.55m+limit(Zthtype,0,1)*1.69m}
Rth2 t1 t2 {48.61m+limit(Zthtype,0,1)*17.99m}
Rth3 t2 t3 {259.98m+limit(Zthtype,0,1)*94.86m}
Rth4 t3 t4 {198.33m+limit(Zthtype,0,1)*67.23m}
Rth5 t4 Tcase {303.78m+limit(Zthtype,0,1)*102.98m}
Cth1 Tj 0 100.337u
Cth2 t1 0 234.513u
Cth3 t2 0 2.715m
Cth4 t3 0 1.27m
Cth5 t4 0 31.977m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC196N10NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1 Rd=10u Rm=106u
.PARAM Inn=45 Unn=10 Rmax=19.6m gmin=24
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=4.269
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {7.69m+limit(Zthtype,0,1)*2.84m}
Rth2 t1 t2 {80.62m+limit(Zthtype,0,1)*29.83m}
Rth3 t2 t3 {427.48m+limit(Zthtype,0,1)*160.67m}
Rth4 t3 t4 {336.57m+limit(Zthtype,0,1)*77.37m}
Rth5 t4 Tcase {387.78m+limit(Zthtype,0,1)*89.15m}
Cth1 Tj 0 59.434u
Cth2 t1 0 141.405u
Cth3 t2 0 1.664m
Cth4 t3 0 752.279u
Cth5 t4 0 25.896m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC100N10NSF drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=10m gmin=20
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=11.21
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {2.93m+limit(Zthtype,0,1)*1.08m}
Rth2 t1 t2 {31.62m+limit(Zthtype,0,1)*11.71m}
Rth3 t2 t3 {174.06m+limit(Zthtype,0,1)*60.85m}
Rth4 t3 t4 {127.51m+limit(Zthtype,0,1)*53.35m}
Rth5 t4 Tcase {237.51m+limit(Zthtype,0,1)*99.38m}
Cth1 Tj 0 156.068u
Cth2 t1 0 360.466u
Cth3 t2 0 4.012m
Cth4 t3 0 1.975m
Cth5 t4 0 43.728m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC152N10NSF drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=0.8 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=15.2m gmin=16
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=7.207
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {4.55m+limit(Zthtype,0,1)*1.69m}
Rth2 t1 t2 {48.61m+limit(Zthtype,0,1)*17.99m}
Rth3 t2 t3 {259.98m+limit(Zthtype,0,1)*94.86m}
Rth4 t3 t4 {198.33m+limit(Zthtype,0,1)*67.23m}
Rth5 t4 Tcase {303.78m+limit(Zthtype,0,1)*102.98m}
Cth1 Tj 0 100.337u
Cth2 t1 0 234.513u
Cth3 t2 0 2.715m
Cth4 t3 0 1.27m
Cth5 t4 0 31.977m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC252N10NSF drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1 Rd=10u Rm=106u
.PARAM Inn=39 Unn=10 Rmax=25.2m gmin=17
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=4.269
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {7.69m+limit(Zthtype,0,1)*2.84m}
Rth2 t1 t2 {80.62m+limit(Zthtype,0,1)*29.83m}
Rth3 t2 t3 {427.48m+limit(Zthtype,0,1)*160.67m}
Rth4 t3 t4 {336.57m+limit(Zthtype,0,1)*77.37m}
Rth5 t4 Tcase {387.78m+limit(Zthtype,0,1)*89.15m}
Cth1 Tj 0 59.434u
Cth2 t1 0 141.405u
Cth3 t2 0 1.664m
Cth4 t3 0 752.279u
Cth5 t4 0 25.896m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC750N10ND drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=5.06m Rg=0.8 Rd=10u Rm=2m
.PARAM Inn=12 Unn=10 Rmax=75m gmin=7.1
.PARAM RRf=500m Rrbond=2 Rtb=67.5 g2=995m
.PARAM act=1.238
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 92.18u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {26.51m+limit(Zthtype,0,1)*9.81m}
Rth2 t1 t2 {260.54m+limit(Zthtype,0,1)*96.42m}
Rth3 t2 t3 {1.23+limit(Zthtype,0,1)*565.19m}
Rth4 t3 t4 {1.23+limit(Zthtype,0,1)*664.58m}
Rth5 t4 Tcase {530.38m+limit(Zthtype,0,1)*286.57m}
Cth1 Tj 0 17.236u
Cth2 t1 0 43.753u
Cth3 t2 0 609.936u
Cth4 t3 0 218.159u
Cth5 t4 0 106.171m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT IPP05CN10L drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=805u Rg=1.9 Rd=350u Rm=300u
.PARAM Inn=100 Unn=10 Rmax=5.4m gmin=81
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=23.47
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.4m+limit(Zthtype,0,1)*515.4u}
Rth2 t1 t2 {15.33m+limit(Zthtype,0,1)*5.68m}
Rth3 t2 t3 {87.39m+limit(Zthtype,0,1)*28.98m}
Rth4 t3 t4 {75.43m+limit(Zthtype,0,1)*29.02m}
Rth5 t4 Tcase {185.07m+limit(Zthtype,0,1)*71.19m}
Cth1 Tj 0 326.755u
Cth2 t1 0 743.512u
Cth3 t2 0 7.891m
Cth4 t3 0 3.99m
Cth5 t4 0 121.993m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP06CN10L drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=745u Rg=1.6 Rd=350u Rm=240u
.PARAM Inn=100 Unn=10 Rmax=6.5m gmin=77
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=17.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {1.83m+limit(Zthtype,0,1)*681.8u}
Rth2 t1 t2 {20m+limit(Zthtype,0,1)*7.41m}
Rth3 t2 t3 {113.28m+limit(Zthtype,0,1)*38.04m}
Rth4 t3 t4 {98.91m+limit(Zthtype,0,1)*67.42m}
Rth5 t4 Tcase {209.58m+limit(Zthtype,0,1)*142.85m}
Cth1 Tj 0 249.208u
Cth2 t1 0 569.82u
Cth3 t2 0 6.105m
Cth4 t3 0 3.043m
Cth5 t4 0 100.531m
Cth6 Tcase 0 190m
.ENDS
**********
.SUBCKT IPP08CN10L drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=705u Rg=1.5 Rd=350u Rm=200u
.PARAM Inn=95 Unn=10 Rmax=8.5m gmin=57
.PARAM RRf=260m Rrbond=14m Rtb=5.8 g2=606m
.PARAM act=12.9
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 8.78m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {2.54m+limit(Zthtype,0,1)*945.06u}
Rth2 t1 t2 {27.57m+limit(Zthtype,0,1)*10.21m}
Rth3 t2 t3 {154.04m+limit(Zthtype,0,1)*52.84m}
Rth4 t3 t4 {137.24m+limit(Zthtype,0,1)*97.36m}
Rth5 t4 Tcase {244.09m+limit(Zthtype,0,1)*173.16m}
Cth1 Tj 0 179.597u
Cth2 t1 0 413.456u
Cth3 t2 0 4.512m
Cth4 t3 0 2.193m
Cth5 t4 0 81.53m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP12CN10L drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=958u Rg=1.5 Rd=350u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.9m gmin=38
.PARAM RRf=393m Rrbond=31m Rtb=8.7 g2=698m
.PARAM act=8.31
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 5.85m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {3.95m+limit(Zthtype,0,1)*1.46m}
Rth2 t1 t2 {42.33m+limit(Zthtype,0,1)*15.67m}
Rth3 t2 t3 {234.29m+limit(Zthtype,0,1)*82.2m}
Rth4 t3 t4 {213.05m+limit(Zthtype,0,1)*127.18m}
Rth5 t4 Tcase {300.49m+limit(Zthtype,0,1)*179.38m}
Cth1 Tj 0 115.694u
Cth2 t1 0 269.296u
Cth3 t2 0 2.983m
Cth4 t3 0 1.413m
Cth5 t4 0 63.737m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPP16CN10L drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=908u Rg=1.2 Rd=350u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16m gmin=30
.PARAM RRf=393m Rrbond=31m Rtb=8.7 g2=698m
.PARAM act=6.16
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 5.85m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {5.33m+limit(Zthtype,0,1)*1.97m}
Rth2 t1 t2 {56.59m+limit(Zthtype,0,1)*20.95m}
Rth3 t2 t3 {306.84m+limit(Zthtype,0,1)*111.08m}
Rth4 t3 t4 {287.41m+limit(Zthtype,0,1)*164.5m}
Rth5 t4 Tcase {346.82m+limit(Zthtype,0,1)*198.51m}
Cth1 Tj 0 85.761u
Cth2 t1 0 201.422u
Cth3 t2 0 2.296m
Cth4 t3 0 1.047m
Cth5 t4 0 55.041m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT IPS12CN10L drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=2n Lg=3n
.PARAM Rs=791u Rg=1.5 Rd=250u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.4m gmin=38
.PARAM RRf=301m Rrbond=14m Rtb=5.8 g2=623m
.PARAM act=8.31
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 3.9m
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {3.95m+limit(Zthtype,0,1)*1.46m}
Rth2 t1 t2 {42.33m+limit(Zthtype,0,1)*15.67m}
Rth3 t2 t3 {234.29m+limit(Zthtype,0,1)*82.2m}
Rth4 t3 t4 {0p+limit(Zthtype,0,1)*0p}
Rth5 t4 Tcase {140.17m+limit(Zthtype,0,1)*679.93m}
Cth1 Tj 0 115.694u
Cth2 t1 0 269.296u
Cth3 t2 0 2.983m
Cth4 t3 0 1.413m
Cth5 t4 0 63.737m
Cth6 Tcase 0 70m
.ENDS
**********
.SUBCKT BSC082N10LS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=8.2m gmin=60
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=11.21
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {2.93m+limit(Zthtype,0,1)*1.08m}
Rth2 t1 t2 {31.62m+limit(Zthtype,0,1)*11.71m}
Rth3 t2 t3 {174.06m+limit(Zthtype,0,1)*60.85m}
Rth4 t3 t4 {127.51m+limit(Zthtype,0,1)*53.35m}
Rth5 t4 Tcase {237.51m+limit(Zthtype,0,1)*99.38m}
Cth1 Tj 0 156.068u
Cth2 t1 0 360.466u
Cth3 t2 0 4.012m
Cth4 t3 0 1.975m
Cth5 t4 0 43.728m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC123N10LS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=0.8 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=12.3m gmin=49
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=7.207
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {4.55m+limit(Zthtype,0,1)*1.69m}
Rth2 t1 t2 {48.61m+limit(Zthtype,0,1)*17.99m}
Rth3 t2 t3 {259.98m+limit(Zthtype,0,1)*94.86m}
Rth4 t3 t4 {198.33m+limit(Zthtype,0,1)*67.23m}
Rth5 t4 Tcase {303.78m+limit(Zthtype,0,1)*102.98m}
Cth1 Tj 0 100.337u
Cth2 t1 0 234.513u
Cth3 t2 0 2.715m
Cth4 t3 0 1.27m
Cth5 t4 0 31.977m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC205N10LS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1 Rd=10u Rm=106u
.PARAM Inn=45 Unn=10 Rmax=20.5m gmin=36
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=4.269
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {7.69m+limit(Zthtype,0,1)*2.84m}
Rth2 t1 t2 {80.62m+limit(Zthtype,0,1)*29.83m}
Rth3 t2 t3 {427.48m+limit(Zthtype,0,1)*160.67m}
Rth4 t3 t4 {336.57m+limit(Zthtype,0,1)*77.37m}
Rth5 t4 Tcase {387.78m+limit(Zthtype,0,1)*89.15m}
Cth1 Tj 0 59.434u
Cth2 t1 0 141.405u
Cth3 t2 0 1.664m
Cth4 t3 0 752.279u
Cth5 t4 0 25.896m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC105N10LSF drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1.3 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=10.5m gmin=40
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=11.21
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_d_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {2.93m+limit(Zthtype,0,1)*1.08m}
Rth2 t1 t2 {31.62m+limit(Zthtype,0,1)*11.71m}
Rth3 t2 t3 {174.06m+limit(Zthtype,0,1)*60.85m}
Rth4 t3 t4 {127.51m+limit(Zthtype,0,1)*53.35m}
Rth5 t4 Tcase {237.51m+limit(Zthtype,0,1)*99.38m}
Cth1 Tj 0 156.068u
Cth2 t1 0 360.466u
Cth3 t2 0 4.012m
Cth4 t3 0 1.975m
Cth5 t4 0 43.728m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC159N10LSF drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=1.0 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=15.9m gmin=32
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=7.207
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_d_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {4.55m+limit(Zthtype,0,1)*1.69m}
Rth2 t1 t2 {48.61m+limit(Zthtype,0,1)*17.99m}
Rth3 t2 t3 {259.98m+limit(Zthtype,0,1)*94.86m}
Rth4 t3 t4 {198.33m+limit(Zthtype,0,1)*67.23m}
Rth5 t4 Tcase {303.78m+limit(Zthtype,0,1)*102.98m}
Cth1 Tj 0 100.337u
Cth2 t1 0 234.513u
Cth3 t2 0 2.715m
Cth4 t3 0 1.27m
Cth5 t4 0 31.977m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT BSC265N10LSF drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1.5 Rd=10u Rm=106u
.PARAM Inn=50 Unn=10 Rmax=26.5m gmin=24
.PARAM RRf=411m Rrbond=1m Rtb=1.7 g2=841m
.PARAM act=4.269
.FUNC Pb(I,dT,Rb) {Rb/(2*Rtb)*(I-limit(dT/(max(I,1n)*Rb)+RRf*I*g2,0,I))**2}
X1 d1 g s Tj S3_100_d_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=1
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
RLs source s1 10
RLg gate g1 10
RLd drain d2 10
G_TH 0 Tb VALUE = {Pb(abs(I(Ls)),V(Tj,Tcase),Rrbond*(1+(limit((V(Tb)+V(Tj))/2,-200,999)-25)*4m))}
Cthb Tb 0 18.29u
Rthb Tb Tj {Rtb}
Rth1 Tj t1 {7.69m+limit(Zthtype,0,1)*2.84m}
Rth2 t1 t2 {80.62m+limit(Zthtype,0,1)*29.83m}
Rth3 t2 t3 {427.48m+limit(Zthtype,0,1)*160.67m}
Rth4 t3 t4 {336.57m+limit(Zthtype,0,1)*77.37m}
Rth5 t4 Tcase {387.78m+limit(Zthtype,0,1)*89.15m}
Cth1 Tj 0 59.434u
Cth2 t1 0 141.405u
Cth3 t2 0 1.664m
Cth4 t3 0 752.279u
Cth5 t4 0 25.896m
Cth6 Tcase 0 30m
.ENDS
**********
.SUBCKT IPB04CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=623u Rg=1.9 Rd=50u Rm=156u
.PARAM Inn=100 Unn=10 Rmax=4.1m gmin=87
.PARAM act=27.1
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPB05CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=805u Rg=1.9 Rd=50u Rm=300u
.PARAM Inn=100 Unn=10 Rmax=5.1m gmin=81
.PARAM act=23.47
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPB06CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=745u Rg=1.6 Rd=50u Rm=240u
.PARAM Inn=100 Unn=10 Rmax=6.2m gmin=77
.PARAM act=17.9
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPB08CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=1n Lg=4n
.PARAM Rs=705u Rg=1.5 Rd=50u Rm=200u
.PARAM Inn=95 Unn=10 Rmax=8.2m gmin=57
.PARAM act=12.9
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPB12CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=4n Ld=1n Lg=4n
.PARAM Rs=958u Rg=1.5 Rd=50u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.6m gmin=38
.PARAM act=8.31
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPB16CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=4n Ld=1n Lg=4n
.PARAM Rs=908u Rg=1.2 Rd=50u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16.2m gmin=30
.PARAM act=6.16
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP04CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=623u Rg=1.9 Rd=350u Rm=156u
.PARAM Inn=100 Unn=10 Rmax=4.4m gmin=87
.PARAM act=27.1
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP05CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=805u Rg=1.9 Rd=350u Rm=300u
.PARAM Inn=100 Unn=10 Rmax=5.4m gmin=81
.PARAM act=23.47
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP06CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=745u Rg=1.6 Rd=350u Rm=240u
.PARAM Inn=100 Unn=10 Rmax=6.5m gmin=77
.PARAM act=17.9
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP08CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=705u Rg=1.5 Rd=350u Rm=200u
.PARAM Inn=95 Unn=10 Rmax=8.5m gmin=57
.PARAM act=12.9
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP12CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=958u Rg=1.5 Rd=350u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.9m gmin=38
.PARAM act=8.31
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP16CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=908u Rg=1.2 Rd=350u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16.5m gmin=30
.PARAM act=6.16
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP26CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=1.72m Rg=1.1 Rd=350u Rm=640u
.PARAM Inn=35 Unn=10 Rmax=26m gmin=19
.PARAM act=3.9
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP35CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=1.53m Rg=1 Rd=350u Rm=450u
.PARAM Inn=27 Unn=10 Rmax=35m gmin=15
.PARAM act=2.92
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP50CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=2.62m Rg=0.9 Rd=350u Rm=650u
.PARAM Inn=20 Unn=10 Rmax=50m gmin=10.5
.PARAM act=1.98
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP80CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=5n Ld=2n Lg=4n
.PARAM Rs=4.3m Rg=0.8 Rd=350u Rm=660u
.PARAM Inn=13 Unn=10 Rmax=80m gmin=6.5
.PARAM act=1.238
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPD12CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=1n Lg=3n
.PARAM Rs=791u Rg=1.5 Rd=50u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.4m gmin=38
.PARAM act=8.31
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPD16CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=1n Lg=3n
.PARAM Rs=741u Rg=1.2 Rd=50u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16m gmin=30
.PARAM act=6.16
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPD25CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=1.41m Rg=1.1 Rd=50u Rm=640u
.PARAM Inn=35 Unn=10 Rmax=25m gmin=19
.PARAM act=3.9
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPD33CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=1.22m Rg=1 Rd=50u Rm=450u
.PARAM Inn=27 Unn=10 Rmax=33m gmin=15
.PARAM act=2.92
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPD49CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=2.01m Rg=0.9 Rd=50u Rm=650u
.PARAM Inn=20 Unn=10 Rmax=49m gmin=10.5
.PARAM act=1.98
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPD78CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=3.14m Rg=0.8 Rd=50u Rm=660u
.PARAM Inn=13 Unn=10 Rmax=78m gmin=6.5
.PARAM act=1.238
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC079N10NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=7.9m gmin=40
.PARAM act=11.21
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC118N10NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=0.8 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=11.8m gmin=33
.PARAM act=7.207
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC196N10NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1 Rd=10u Rm=106u
.PARAM Inn=45 Unn=10 Rmax=19.6m gmin=24
.PARAM act=4.269
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPD64CN10N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=1n Lg=3n
.PARAM Rs=3.14m Rg=0.9 Rd=50u Rm=660u
.PARAM Inn=17 Unn=10 Rmax=64m gmin=4.86
.PARAM act=1.98
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC100N10NSF_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=10m gmin=20
.PARAM act=11.21
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC152N10NSF_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=0.8 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=15.2m gmin=16
.PARAM act=7.207
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC252N10NSF_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1 Rd=10u Rm=106u
.PARAM Inn=39 Unn=10 Rmax=25.2m gmin=17
.PARAM act=4.269
X1 d1 g s Tj S3_100_b_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC750N10ND_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=5.06m Rg=0.8 Rd=10u Rm=2m
.PARAM Inn=12 Unn=10 Rmax=75m gmin=7.1
.PARAM act=1.238
X1 d1 g s Tj S3_100_a_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP05CN10L_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=805u Rg=1.9 Rd=350u Rm=300u
.PARAM Inn=100 Unn=10 Rmax=5.4m gmin=81
.PARAM act=23.47
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP06CN10L_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=745u Rg=1.6 Rd=350u Rm=240u
.PARAM Inn=100 Unn=10 Rmax=6.5m gmin=77
.PARAM act=17.9
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP08CN10L_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3n Ld=2n Lg=4n
.PARAM Rs=705u Rg=1.5 Rd=350u Rm=200u
.PARAM Inn=95 Unn=10 Rmax=8.5m gmin=57
.PARAM act=12.9
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP12CN10L_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=958u Rg=1.5 Rd=350u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.9m gmin=38
.PARAM act=8.31
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPP16CN10L_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=4n Ld=2n Lg=4n
.PARAM Rs=908u Rg=1.2 Rd=350u Rm=260u
.PARAM Inn=53 Unn=10 Rmax=16m gmin=30
.PARAM act=6.16
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPS12CN10L_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=2n Lg=3n
.PARAM Rs=791u Rg=1.5 Rd=250u Rm=310u
.PARAM Inn=67 Unn=10 Rmax=12.4m gmin=38
.PARAM act=8.31
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC082N10LS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=8.2m gmin=60
.PARAM act=11.21
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC123N10LS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=0.8 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=12.3m gmin=49
.PARAM act=7.207
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC205N10LS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1 Rd=10u Rm=106u
.PARAM Inn=45 Unn=10 Rmax=20.5m gmin=36
.PARAM act=4.269
X1 d1 g s Tj S3_100_c_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC105N10LSF_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=450u Rg=1.3 Rd=10u Rm=280u
.PARAM Inn=50 Unn=10 Rmax=10.5m gmin=40
.PARAM act=11.21
X1 d1 g s Tj S3_100_d_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC159N10LSF_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=349u Rg=1.0 Rd=10u Rm=179u
.PARAM Inn=50 Unn=10 Rmax=15.9m gmin=32
.PARAM act=7.207
X1 d1 g s Tj S3_100_d_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT BSC265N10LSF_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.5n Lg=2n
.PARAM Rs=276u Rg=1.5 Rd=10u Rm=106u
.PARAM Inn=50 Unn=10 Rmax=26.5m gmin=24
.PARAM act=4.269
X1 d1 g s Tj S3_100_d_var PARAMS: a={act} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn}
+Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} heat=0
Rg g1 g {Rg}
Lg gate g1 {Lg*if(dgfs==99,0,1)}
Gs s1 s VALUE={V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)}
Rsa s1 s 1Meg
Ls source s1 {Ls*if(dgfs==99,0,1)}
Rda d1 d2 {Rd}
Ld drain d2 {Ld*if(dgfs==99,0,1)}
E1 Tj w VALUE={TEMP}
R1 w 0 1u
.ENDS
**********
.SUBCKT IPB04CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 1n
Ls source s1 3n
Rs s1 s2 623u
Rg g1 g2 1.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 372.6 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 2.3m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=7.7n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=51.5p N=1.11 RS=0.74u EG=1.12 TT=90n)
Rdiode d1 21 0.53m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 3.39n
.MODEL DGD D(M=2.4 CJO=3.39n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 10.36n
.ENDS IPB04CN10N_L0
******
.SUBCKT IPP04CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 3n
Rs s1 s2 623u
Rg g1 g2 1.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 372.6 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 2.6m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=7.7n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=51.5p N=1.11 RS=0.74u EG=1.12 TT=90n)
Rdiode d1 21 0.53m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 3.39n
.MODEL DGD D(M=2.4 CJO=3.39n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 10.36n
.ENDS IPP04CN10N_L0
******
.SUBCKT IPB05CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 1n
Ls source s1 3n
Rs s1 s2 805u
Rg g1 g2 1.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 322.7 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 2.65m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=6.67n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=44.6p N=1.11 RS=0.85u EG=1.12 TT=90n)
Rdiode d1 21 0.61m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 2.94n
.MODEL DGD D(M=2.4 CJO=2.94n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 8.98n
.ENDS IPB05CN10N_L0
******
.SUBCKT IPP05CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 3n
Rs s1 s2 805u
Rg g1 g2 1.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 322.7 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 2.95m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=6.67n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=44.6p N=1.11 RS=0.85u EG=1.12 TT=90n)
Rdiode d1 21 0.61m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 2.94n
.MODEL DGD D(M=2.4 CJO=2.94n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 8.98n
.ENDS IPP05CN10N_L0
******
.SUBCKT IPB06CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 1n
Ls source s1 3n
Rs s1 s2 745u
Rg g1 g2 1.6
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 246.1 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 3.46m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=5.08n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=34p N=1.11 RS=1.12u EG=1.12 TT=90n)
Rdiode d1 21 0.8m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 2.24n
.MODEL DGD D(M=2.4 CJO=2.24n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 6.86n
.ENDS IPB06CN10N_L0
******
.SUBCKT IPP06CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 3n
Rs s1 s2 745u
Rg g1 g2 1.6
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 246.1 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 3.76m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=5.08n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=34p N=1.11 RS=1.12u EG=1.12 TT=90n)
Rdiode d1 21 0.8m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 2.24n
.MODEL DGD D(M=2.4 CJO=2.24n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 6.86n
.ENDS IPP06CN10N_L0
******
.SUBCKT IPB08CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 1n
Ls source s1 3n
Rs s1 s2 705u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 177.4 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 4.78m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=3.66n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=24.5p N=1.11 RS=1.55u EG=1.12 TT=90n)
Rdiode d1 21 1.12m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.62n
.MODEL DGD D(M=2.4 CJO=1.62n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 4.96n
.ENDS IPB08CN10N_L0
******
.SUBCKT IPP08CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 3n
Rs s1 s2 705u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 177.4 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 5.08m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=3.66n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=24.5p N=1.11 RS=1.55u EG=1.12 TT=90n)
Rdiode d1 21 1.12m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.62n
.MODEL DGD D(M=2.4 CJO=1.62n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 4.96n
.ENDS IPP08CN10N_L0
******
.SUBCKT IPB12CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 1n
Ls source s1 4n
Rs s1 s2 958u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 114.3 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 7.39m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.36n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=15.8p N=1.11 RS=2.41u EG=1.12 TT=90n)
Rdiode d1 21 1.73m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.04n
.MODEL DGD D(M=2.4 CJO=1.04n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 3.22n
.ENDS IPB12CN10N_L0
******
.SUBCKT IPP12CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 4n
Rs s1 s2 958u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 114.3 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 7.69m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.36n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=15.8p N=1.11 RS=2.41u EG=1.12 TT=90n)
Rdiode d1 21 1.73m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.04n
.MODEL DGD D(M=2.4 CJO=1.04n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 3.22n
.ENDS IPP12CN10N_L0
******
.SUBCKT IPD12CN10N_L0 drain gate source
Lg gate g1 3n
Ld drain d1 1n
Ls source s1 2n
Rs s1 s2 791u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 114.3 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 7.39m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.36n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=15.8p N=1.11 RS=2.41u EG=1.12 TT=90n)
Rdiode d1 21 1.73m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.04n
.MODEL DGD D(M=2.4 CJO=1.04n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 3.22n
.ENDS IPD12CN10N_L0
******
.SUBCKT IPB16CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 1n
Ls source s1 4n
Rs s1 s2 908u
Rg g1 g2 1.2
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 84.7 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 9.95m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.75n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=11.7p N=1.11 RS=3.25u EG=1.12 TT=90n)
Rdiode d1 21 2.34m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.77n
.MODEL DGD D(M=2.4 CJO=0.77n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 2.4n
.ENDS IPB16CN10N_L0
******
.SUBCKT IPP16CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 4n
Rs s1 s2 908u
Rg g1 g2 1.2
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 84.7 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 10.25m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.75n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=11.7p N=1.11 RS=3.25u EG=1.12 TT=90n)
Rdiode d1 21 2.34m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.77n
.MODEL DGD D(M=2.4 CJO=0.77n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 2.4n
.ENDS IPP16CN10N_L0
******
.SUBCKT IPD16CN10N_L0 drain gate source
Lg gate g1 3n
Ld drain d1 1n
Ls source s1 2n
Rs s1 s2 741u
Rg g1 g2 1.2
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 84.7 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 9.95m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.75n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=11.7p N=1.11 RS=3.25u EG=1.12 TT=90n)
Rdiode d1 21 2.34m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.77n
.MODEL DGD D(M=2.4 CJO=0.77n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 2.4n
.ENDS IPD16CN10N_L0
******
.SUBCKT IPP26CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 5n
Rs s1 s2 1.72m
Rg g1 g2 1.1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 53.6 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 15.99m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.11n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=7.4p N=1.11 RS=5.13u EG=1.12 TT=90n)
Rdiode d1 21 3.69m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.49n
.MODEL DGD D(M=2.4 CJO=0.49n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.54n
.ENDS IPP26CN10N_L0
******
.SUBCKT IPD25CN10N_L0 drain gate source
Lg gate g1 3n
Ld drain d1 1n
Ls source s1 2.5n
Rs s1 s2 1.41m
Rg g1 g2 1.1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 53.6 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 15.69m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.11n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=7.4p N=1.11 RS=5.13u EG=1.12 TT=90n)
Rdiode d1 21 3.69m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.49n
.MODEL DGD D(M=2.4 CJO=0.49n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.54n
.ENDS IPD25CN10N_L0
******
.SUBCKT IPP35CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 5n
Rs s1 s2 1.53m
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 40.2 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 21.24m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.83n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=5.5p N=1.11 RS=6.85u EG=1.12 TT=90n)
Rdiode d1 21 4.93m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.37n
.MODEL DGD D(M=2.4 CJO=0.37n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.17n
.ENDS IPP35CN10N_L0
******
.SUBCKT IPD33CN10N_L0 drain gate source
Lg gate g1 3n
Ld drain d1 1n
Ls source s1 2.5n
Rs s1 s2 1.22m
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 40.2 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 20.94m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.83n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=5.5p N=1.11 RS=6.85u EG=1.12 TT=90n)
Rdiode d1 21 4.93m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.37n
.MODEL DGD D(M=2.4 CJO=0.37n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.17n
.ENDS IPD33CN10N_L0
******
.SUBCKT IPP50CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 5n
Rs s1 s2 2.62m
Rg g1 g2 0.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 27.2 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 31.16m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.56n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=3.8p N=1.11 RS=10.1u EG=1.12 TT=90n)
Rdiode d1 21 7.27m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.25n
.MODEL DGD D(M=2.4 CJO=0.25n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 0.81n
.ENDS IPP50CN10N_L0
******
.SUBCKT IPD49CN10N_L0 drain gate source
Lg gate g1 3n
Ld drain d1 1n
Ls source s1 2.5n
Rs s1 s2 2.01m
Rg g1 g2 0.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 27.2 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 30.86m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.56n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=3.8p N=1.11 RS=10.1u EG=1.12 TT=90n)
Rdiode d1 21 7.27m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.25n
.MODEL DGD D(M=2.4 CJO=0.25n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 0.81n
.ENDS IPD49CN10N_L0
******
.SUBCKT IPP80CN10N_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 5n
Rs s1 s2 4.3m
Rg g1 g2 0.8
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 17 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 49.62m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.35n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=2.4p N=1.11 RS=16.16u EG=1.12 TT=90n)
Rdiode d1 21 11.63m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.16n
.MODEL DGD D(M=2.4 CJO=0.16n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 0.53n
.ENDS IPP80CN10N_L0
******
.SUBCKT IPD78CN10N_L0 drain gate source
Lg gate g1 3n
Ld drain d1 1n
Ls source s1 2.5n
Rs s1 s2 3.14m
Rg g1 g2 0.8
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 17 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 49.32m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.35n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=2.4p N=1.11 RS=16.16u EG=1.12 TT=90n)
Rdiode d1 21 11.63m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.16n
.MODEL DGD D(M=2.4 CJO=0.16n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 0.53n
.ENDS IPD78CN10N_L0
******
.SUBCKT BSC079N10NS_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 450u
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 154.1 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 5.45m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=3.18n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=21.3p N=1.11 RS=1.78u EG=1.12 TT=90n)
Rdiode d1 21 1.28m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.405n
.MODEL DGD D(M=2.4 CJO=1.405n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 4.32n
.ENDS BSC079N10NS_L0
******
.SUBCKT BSC118N10NS_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 349u
Rg g1 g2 0.8
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 99.1 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 8.47m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.05n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=13.7p N=1.11 RS=2.78u EG=1.12 TT=90n)
Rdiode d1 21 2m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.905n
.MODEL DGD D(M=2.4 CJO=0.905n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 2.8n
.ENDS BSC118N10NS_L0
******
.SUBCKT BSC196N10NS_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 276u
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 58.7 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 14.3m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.21n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=8.1p N=1.11 RS=4.68u EG=1.12 TT=90n)
Rdiode d1 21 3.37m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.538n
.MODEL DGD D(M=2.4 CJO=0.538n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.68n
.ENDS BSC196N10NS_L0
******
.SUBCKT IPD64CN10N_L0 drain gate source
Lg gate g1 3n
Ld drain d1 1n
Ls source s1 2.5n
Rs s1 s2 3.14m
Rg g1 g2 0.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 16.7 VTO=4.3 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 30.05m TC=10.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.4n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=3.8p N=1.11 RS=10.1u EG=1.12 TT=90n)
Rdiode d1 21 4.04m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.127n
.MODEL DGD D(M=2.1 CJO=0.127n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 0.43n
.ENDS IPD64CN10N_L0
******
.SUBCKT BSC100N10NSF_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 450u
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 94.7 VTO=4.3 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 5.31m TC=10.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.24n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=21.3p N=1.11 RS=1.78u EG=1.12 TT=90n)
Rdiode d1 21 0.71m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.699n
.MODEL DGD D(M=2.1 CJO=0.699n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 2.18n
.ENDS BSC100N10NSF_L0
******
.SUBCKT BSC152N10NSF_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 349u
Rg g1 g2 0.8
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 60.9 VTO=4.3 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 8.25m TC=10.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.44n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=13.7p N=1.11 RS=2.78u EG=1.12 TT=90n)
Rdiode d1 21 1.11m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.451n
.MODEL DGD D(M=2.1 CJO=0.451n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.42n
.ENDS BSC152N10NSF_L0
******
.SUBCKT BSC252N10NSF_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 276u
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 36.1 VTO=4.3 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 13.92m TC=10.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.85n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=8.1p N=1.11 RS=4.68u EG=1.12 TT=90n)
Rdiode d1 21 1.87m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.269n
.MODEL DGD D(M=2.1 CJO=0.269n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 0.87n
.ENDS BSC252N10NSF_L0
******
.SUBCKT BSC750N10ND_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 5.06m
Rg g1 g2 0.8
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 17 VTO=4.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 49.28m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=0.35n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=2.4p N=1.11 RS=16.16u EG=1.12 TT=90n)
Rdiode d1 21 11.63m TC=2m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.16n
.MODEL DGD D(M=2.4 CJO=0.16n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 0.53n
.ENDS BSC750N10ND_L0
******
.SUBCKT IPP05CN10L_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 3n
Rs s1 s2 805u
Rg g1 g2 1.9
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 535.1 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 3.09m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=6.67n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=44.6p N=1.07 RS=0.85u EG=1.12 TT=90n)
Rdiode d1 21 0.7m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 2.94n
.MODEL DGD D(M=2.4 CJO=2.94n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 11.56n
.ENDS IPP05CN10L_L0
******
.SUBCKT IPP06CN10L_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 3n
Rs s1 s2 745u
Rg g1 g2 1.6
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 408.1 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 3.95m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=5.08n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=34p N=1.07 RS=1.12u EG=1.12 TT=90n)
Rdiode d1 21 0.92m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 2.24n
.MODEL DGD D(M=2.4 CJO=2.24n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 8.83n
.ENDS IPP06CN10L_L0
******
.SUBCKT IPP08CN10L_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 3n
Rs s1 s2 705u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 294.1 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 5.34m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=3.66n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=24.5p N=1.07 RS=1.55u EG=1.12 TT=90n)
Rdiode d1 21 1.28m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.62n
.MODEL DGD D(M=2.4 CJO=1.62n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 6.38n
.ENDS IPP08CN10L_L0
******
.SUBCKT IPP12CN10L_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 4n
Rs s1 s2 958u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 189.5 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 8.1m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.36n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=15.8p N=1.07 RS=2.41u EG=1.12 TT=90n)
Rdiode d1 21 1.99m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.04n
.MODEL DGD D(M=2.4 CJO=1.04n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 4.13n
.ENDS IPP12CN10L_L0
******
.SUBCKT IPS12CN10L_L0 drain gate source
Lg gate g1 3n
Ld drain d1 2n
Ls source s1 2n
Rs s1 s2 791u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 189.5 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 8m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.36n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=15.8p N=1.07 RS=2.41u EG=1.12 TT=90n)
Rdiode d1 21 1.99m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.04n
.MODEL DGD D(M=2.4 CJO=1.04n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 4.13n
.ENDS IPS12CN10L_L0
******
.SUBCKT IPP16CN10L_L0 drain gate source
Lg gate g1 4n
Ld drain d1 2n
Ls source s1 4n
Rs s1 s2 908u
Rg g1 g2 1.2
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 140.4 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 10.8m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.75n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=11.7p N=1.07 RS=3.25u EG=1.12 TT=90n)
Rdiode d1 21 2.68m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.77n
.MODEL DGD D(M=2.4 CJO=0.77n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 3.08n
.ENDS IPP16CN10L_L0
******
.SUBCKT BSC082N10LS_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 450u
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 255.6 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 5.75m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=3.18n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=21.3p N=1.07 RS=1.78u EG=1.12 TT=90n)
Rdiode d1 21 1.47m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 1.405n
.MODEL DGD D(M=2.4 CJO=1.405n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 5.55n
.ENDS BSC082N10LS_L0
******
.SUBCKT BSC123N10LS_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 349u
Rg g1 g2 0.8
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 164.3 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 8.95m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.05n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=13.7p N=1.07 RS=2.78u EG=1.12 TT=90n)
Rdiode d1 21 2.29m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.905n
.MODEL DGD D(M=2.4 CJO=0.905n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 3.59n
.ENDS BSC123N10LS_L0
******
.SUBCKT BSC205N10LS_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 276u
Rg g1 g2 1
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 97.3 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 15.1m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.21n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=8.1p N=1.07 RS=4.68u EG=1.12 TT=90n)
Rdiode d1 21 3.87m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.538n
.MODEL DGD D(M=2.4 CJO=0.538n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 2.15n
.ENDS BSC205N10LS_L0
******
.SUBCKT BSC105N10LSF_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 450u
Rg g1 g2 1.3
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 125.6 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 5.54m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=3.25n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=21.3p N=1.07 RS=1.78u EG=1.12 TT=90n)
Rdiode d1 21 1.47m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.699n
.MODEL DGD D(M=2.4 CJO=0.699n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 2.85n
.ENDS BSC105N10LSF_L0
******
.SUBCKT BSC159N10LSF_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 349u
Rg g1 g2 1.0
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 80.7 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 8.61m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=2.09n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=13.7p N=1.07 RS=2.78u EG=1.12 TT=90n)
Rdiode d1 21 2.29m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.451n
.MODEL DGD D(M=2.4 CJO=0.451n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.87n
.ENDS BSC159N10LSF_L0
******
.SUBCKT BSC265N10LSF_L0 drain gate source
Lg gate g1 2n
Ld drain d1 0.5n
Ls source s1 1n
Rs s1 s2 276u
Rg g1 g2 1.5
M1 d2 g2 s2 s2 DMOS L=1u W=1u
.MODEL DMOS NMOS ( KP= 47.8 VTO=2.7 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3)
Rd d1 d2 14.53m TC=9.5m
Dbd s2 d2 Dbt
.MODEL Dbt D(BV=131 M=0.35 CJO=1.24n VJ=0.8V)
Dbody s2 21 DBODY
.MODEL DBODY D(IS=8.1p N=1.07 RS=4.68u EG=1.12 TT=90n)
Rdiode d1 21 3.87m TC=4m
.MODEL sw NMOS(VTO=0 KP=10 LEVEL=1)
Maux g2 c a a sw
Maux2 b d g2 g2 sw
Eaux c a d2 g2 1
Eaux2 d g2 d2 g2 -1
Cox b d2 0.269n
.MODEL DGD D(M=2.4 CJO=0.269n VJ=10)
Rpar b d2 1Meg
Dgd a d2 DGD
Rpar2 d2 a 10Meg
Cgs g2 s2 1.15n
.ENDS BSC265N10LSF_L0
******