***************************************************************** * INFINEON Power Transistors * * SPICE Library for * * OptiMOS 60V / OptiMOS5 60V * * n-channel Transistors * * Version 280225 * * * ***************************************************************** * * * 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 * * transistors: * * * * OptiMOS 60V / OptiMOS5 60V * * * * IPT009N06NM5 IPTC007N06NM5 IPTC012N06NM5 * * IQD009N06NM5 IQD009N06NM5CG IQD009N06NM5CGSC * * IQD009N06NM5SC IQDH88N06LM5 IQDH88N06LM5CG * * IQDH88N06LM5CGSC IQDH88N06LM5SC IQE022N06LM5 * * IQE022N06LM5CG IQE022N06LM5CGSC IQE022N06LM5SC * * IQFH68N06NM5 IQFH86N06NM5 IQFH99N06NM5 * * ISC010N06NM5 BSC012N06NS BSC014N06NS * * BSC014N06NSSC BSC014N06NST BSC016N06NS * * BSC016N06NSSC BSC016N06NST BSC019N06NS * * BSC028N06NS BSC028N06NST BSC028N06NSSC * * BSC034N06NS BSC039N06NS BSZ039N06NS * * BSZ042N06NS BSC066N06NS BSC097N06NS * * BSC097N06NST BSZ068N06NS BSZ100N06NS * * IPD025N06N IPD033N06N IPT007N06N * * IPTG007N06NM5 IPB010N06N IPT012N06N * * IPB014N06N IPI020N06N IPP020N06N * * IPB026N06N IPI029N06N IPP029N06N * * IPP040N06N IPB057N06N IPD053N06N * * IPP060N06N IPA029N06N IPA029N06NM5S * * IPA040N06N IPA040N06NM5S IPA060N06N * * IPA060N06NM5S IQE030N06NM5 IQE030N06NM5CG * * IQE030N06NM5CGSC IQE030N06NM5SC ISC015N06NM5LF2 * * ISG0614N06NM5H ISG0614N06NM5HSC IST011N06NM5 * * IST015N06NM5 BSC027N06LS5 BSC065N06LS5 * * BSC094N06LS5 BSZ037N06LS5 BSZ040N06LS5 * * BSZ065N06LS5 BSZ099N06LS5 IRL60HS118 * * ISC009N06LM5 ISC011N06LM5 ISC0702NLS * * ISC0703NLS ISZ0702NLS ISZ0703NLS * * ISZ034N06LM5 * * * * * ***************************************************************** * thermal nodes of level 3 models: * * * * .SUBCKT BSC016N06NS drain gate source Tj Tcase * * Tj : potential=temperature (in °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 °C between Tcase and ground. * * * ***************************************************************** * thermal nodes of level 3 models with top side cooling: * * * * .SUBCKT BSC014N06NSSC drain gate source Tj Ttop Tbottom * * Tj : potential=temperature (in °C) at junction (typically * * not connected) * * Ttop, Tbottom : nodes where the boundary condition - * * external heat sinks etc - have to be connected * * (ideal heat sink can be modeled by using a voltage * * source stating the ambient temperature in °C between * * the surface node and ground. * * * ***************************************************************** .SUBCKT S5_60_e4_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1m Rp=1 dC=0 Rm=1u .PARAM b0=70.2 p0=7.92 p1=-29.8m p2=53u mubet=1.3 fbet=0 .PARAM Vth0=3.98 c=1.47 Fm=220m Fn=500m al=500m auth=3.5m .PARAM dvx=550m dvgs=100m auth_sub=3.5m .PARAM Rd=8.2m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.08 Rdi=5m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 td=10n ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=465p rc1=80p f3a=90p .PARAM f4=29.27p f5=29.27p sl=1.21p ps1=56.43p ps2=-152.19m ps3=34.74p .PARAM ps4=-956.13m ps5=3.5p ps6=10p ps7=0 pc0=25p .PARAM q83=60p q84=-37.93m qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=6.5p q85=0 qs1=74.03p qs2=4.28p .PARAM qs3=-37.93m f2r=30.04 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2.98 Vmax=4.98 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+rc1)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(ps1*a+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC Ia(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*Ia(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .FUNC Idiode(Usd,Tj,Iss) {exp(min(ln(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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} E_Eds3 d edep3 VALUE {V(d,s)-I(V_sense3)/Cds3} C_Cds3 edep3 s {Cds3} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)+min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} 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 {Cds3*((exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)+min(V(d,s)+1,0)*exp(-q84))} 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 Rd07 d3 s 1G Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT S5_60_e_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=70.2 p0=7.92 p1=-29.8m p2=53u mubet=1.3 fbet=0 .PARAM Vth0=3.98 c=1.47 Fm=220m Fn=500m al=500m auth=3.5m .PARAM dvx=550m dvgs=100m auth_sub=3.5m .PARAM Rd=7.7m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.08 Rdi=5m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=450p f3a=90p .PARAM f4=29.27p f5=29.27p sl=1.21p ps1=50.33p ps2=-117.07m ps3=34.74p .PARAM ps4=-956.13m ps5=2.92p ps6=6p ps7=0 .PARAM q83=60p q84=-37.93m qs6=1p qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=6.5p qs1=73.03p qs2=4.28p qs3=-37.93m .PARAM f2r=30.04 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2.98 Vmax=4.98 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={f3*a*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds1={qs6*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={a*ps1*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC I0(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*I0(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} C_Cds1 d s {Cds1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********************** .SUBCKT S5_60_e1_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=70.2 p0=7.92 p1=-29.8m p2=53u mubet=1.3 fbet=0 .PARAM Vth0=3.98 c=1.47 Fm=220m Fn=500m al=500m auth=3.5m .PARAM dvx=550m dvgs=100m auth_sub=3.5m .PARAM Rd=7.7m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.08 Rdi=5m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=465p rc1=80p f3a=90p .PARAM f4=29.27p f5=29.27p sl=1.21p ps1=56.43p ps2=-152.19m ps3=34.74p .PARAM ps4=-956.13m ps5=3.5p ps6=10p ps7=0 pc0=25p .PARAM q83=60p q84=-37.93m qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=6.5p qs1=74.03p qs2=4.28p qs3=-37.93m .PARAM f2r=30.04 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2.98 Vmax=4.98 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+rc1)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(a*ps1+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC I0(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*I0(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS **************** .SUBCKT S5_60_e3_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=70.2 p0=7.92 p1=-29.8m p2=53u bs1=0 bs2=0 .PARAM mubet=1.3 fbet=0 Vth0=3.98 c=1.47 Fm=220m Fn=500m .PARAM al=500m auth=3.5m dvx=550m dvgs=100m auth_sub=3.5m .PARAM Rd=7.8m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.08 Rdi=5m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=450p f3b=80p f3a=90p .PARAM f4=29.27p f5=29.27p sl=1.3p ps1=30p ps2=-117.07m ps3=38p .PARAM ps4=-956.13m ps5=6p ps7=0 pc0=39p .PARAM q83=60p q84=-37.93m qs6=1p qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=7.2p q85=0 qs1=77p qs2=4.28p .PARAM qs3=-37.93m f2r=25 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2.98 Vmax=4.98 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+sqrt(a)*f3b)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds1={qs6*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(ps1*a+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC Ia(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*Ia(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .FUNC Idiode(Usd,Tj,Iss) {exp(min(ln(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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} C_Cds1 d s {Cds1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rd07 d3 s 1G Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT S5_60_f_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=70.2 p0=7.92 p1=-29.8m p2=53u mubet=1.3 fbet=0 .PARAM Vth0=3.98 c=1.47 Fm=220m Fn=500m al=500m auth=3.5m .PARAM dvx=550m dvgs=100m auth_sub=3.5m .PARAM Rd=8.7m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.08 Rdi=5m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=450p f3a=90p .PARAM f4=29.27p f5=29.27p sl=1.21p ps1=50.33p ps2=-117.07m ps3=34.74p .PARAM ps4=-956.13m ps5=2.92p ps6=6p ps7=0 .PARAM q83=60p q84=-37.93m qs6=1p qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=6.5p qs1=73.03p qs2=4.28p qs3=-37.93m .PARAM f2r=30.04 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2.98 Vmax=4.98 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={f3*a*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds1={qs6*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={a*ps1*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC I0(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*I0(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} C_Cds1 d s {Cds1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT S5_60_f1_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=70.2 p0=7.92 p1=-29.8m p2=53u mubet=1.3 fbet=0 .PARAM Vth0=3.98 c=1.47 Fm=220m Fn=500m al=500m auth=3.5m .PARAM dvx=550m dvgs=100m auth_sub=3.5m .PARAM Rd=8.7m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.08 Rdi=5m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=465p rc1=80p f3a=90p .PARAM f4=29.27p f5=29.27p sl=1.21p ps1=56.43p ps2=-152.19m ps3=34.74p .PARAM ps4=-956.13m ps5=3.5p ps6=10p ps7=0 pc0=25p .PARAM q83=60p q84=-37.93m qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=6.5p qs1=74.03p qs2=4.28p qs3=-37.93m .PARAM f2r=30.04 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2.98 Vmax=4.98 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+rc1)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(a*ps1+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC I0(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*I0(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT S5_60_f4_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=70.2 p0=7.92 p1=-29.8m p2=53u mubet=1.3 fbet=0 .PARAM Vth0=3.98 c=1.47 Fm=220m Fn=500m al=500m auth=3.5m .PARAM dvx=550m dvgs=100m auth_sub=3.5m .PARAM Rd=8.7m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.08 Rdi=5m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 td=10n ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=450p f3b=80p f3a=90p .PARAM f4=29.27p f5=29.27p sl=1.3p ps1=30p ps2=-117.07m ps3=38p .PARAM ps4=-956.13m ps5=6p ps7=0 pc0=39p .PARAM q83=60p q84=-37.93m qs6=1p qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=7.2p qs1=77p qs2=4.28p qs3=-37.93m .PARAM f2r=25 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2.98 Vmax=4.98 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+sqrt(a)*f3b)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds1={qs6*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(ps1*a+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC I0(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*I0(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .FUNC Idiode(Usd,Tj,Iss) {exp(min(ln(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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} C_Cds1 d s {Cds1} E_Eds3 d edep3 VALUE {V(d,s)-I(V_sense3)/Cds3} C_Cds3 edep3 s {Cds3} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} 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 {Cds3*((exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} 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 Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ******************* .SUBCKT S5_60_j1_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=102 p0=5.13 p1=-15.4m p2=25u mubet=1.3 fbet=0 .PARAM Vth0=2.4 c=1.47 Fm=220m Fn=500m al=500m auth=2.3m .PARAM dvx=550m dvgs=0 auth_sub=2.3m .PARAM Rd=8.6m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.03 Rdi=4m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=570p rc1=50p f3a=90p .PARAM f4=26.3p f5=26.3p sl=1.26p ps1=50.1p ps2=-116m ps3=120p .PARAM ps4=-1.16 ps5=4.04p ps6=3.95p ps7=0 pc0=20p .PARAM q83=60p q84=-37.93m qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=6.5p qs1=74.03p qs2=4.28p qs3=-37.93m .PARAM f2r=30.04 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=2 Vmax=2.8 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+rc1)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(a*ps1+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC I0(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*I0(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT S5_60_j2_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=102 p0=5.13 p1=-15.4m p2=25u mubet=1.3 fbet=0 .PARAM Vth0=2.52 c=1.47 Fm=220m Fn=500m al=500m auth=2.3m .PARAM dvx=550m dvgs=0 auth_sub=2.3m .PARAM Rd=8.6m nmu=3.15 Rf=600m .PARAM lnIsj=-27.24 ndi=1.03 Rdi=4m nmu2=0 n_Isj=0 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=1n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=570p rc1=50p f3a=90p .PARAM f4=26.3p f5=26.3p sl=1.26p ps1=50.1p ps2=-116m ps3=120p .PARAM ps4=-1.16 ps5=4.04p ps6=3.95p ps7=0 pc0=20p .PARAM q83=60p q84=-37.93m qs7=59.67p qs8=-841.35m .PARAM q80=210p q81=210p q82=6.5p qs1=74.03p qs2=4.28p qs3=-37.93m .PARAM f2r=30.04 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin={Vth0} Vmax={Vth0} dCmax=0 .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+rc1)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(a*ps1+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC I0(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*I0(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT S5_60_j3_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=155 p0=5.13 p1=-15.4m p2=25u bs1=0 bs2=0 .PARAM mubet=1.4 fbet=0 Vth0=2.35 c=1.47 Fm=220m Fn=500m .PARAM al=500m auth=2.4m dvx=550m dvgs=-100m auth_sub=2.4m .PARAM Rd=7m nmu=3 Rf=560m .PARAM lnIsj=-27.7 ndi=1.03 Rdi=2.5m nmu2=500m n_Isj=1.7 UB=65 .PARAM ab=30m ab2=0 UT=100m lB=-23 ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=610p rc1=60p f3a=90p .PARAM f4=29p f5=26p sl=1.26p ps1=41p ps2=-116m ps3=190p .PARAM ps4=-3 ps5=3.5p ps6=4.1p ps7=300m pc0=70p .PARAM q83=70p q84=-37.93m qs7=5p qs8=-841.35m .PARAM q80=210.85p q81=213.58p q82=6.61p q85=0 qs1=79.82p qs2=5.91p .PARAM qs3=-27.5m f2r=21 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=1.85 Vmax=3.05 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+rc1)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(ps1*a+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC Ia(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*Ia(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .FUNC Idiode(Usd,Tj,Iss) {exp(min(ln(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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} V_sense dd d1 0 G_Rdio d2 d1 VALUE={V(d2,d1)/(dRdi*((limit(V(Tj),-200,999)+T0)/Tref)**nmu2)} V_sense2 d2 d3 0 Dbody s d3 dbody .model dbody D (BV= {UB*10},CJO ={Cds3/1000},TT ={ta},IS ={a*exp(lnIsj)} m={0.3} RS={dRdi*1m} n={ndi}) R1 g s 1G Rd01 d s 500Meg Rd02 d2 s 500Meg Rd03 d1 d 1k Rd07 d3 s 1G Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ************************************************************************************************* .SUBCKT S5_60_j4_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 dgfs=0 Inn=1 +Unn=1 Rmax=1 gmin=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=145 p0=5.13 p1=-15.4m p2=25u mubet=1.4 fbet=0 .PARAM Vth0=2.35 c=1.47 Fm=220m Fn=500m al=500m auth=2.4m .PARAM dvx=550m dvgs=-100m auth_sub=2.4m .PARAM Rd=7.6m nmu=3 Rf=560m .PARAM lnIsj=-27.7 ndi=1.03 Rdi=2.5m nmu2=500m n_Isj=1.7 UB=65 .PARAM ab=30m ab2=0 UT=100m lB=-23 td=10n ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=610p rc1=60p f3a=90p .PARAM f4=29p f5=26p sl=1.26p ps1=41p ps2=-116m ps3=190p .PARAM ps4=-3 ps5=3.5p ps6=7p ps7=300m pc0=70p .PARAM q83=70p q84=-37.93m qs7=5p qs8=-841.35m .PARAM q80=210.85p q81=213.58p q82=6.61p q85=0 qs1=79.82p qs2=5.91p .PARAM qs3=-27.5m f2r=21 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=1.85 Vmax=3.05 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*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*((1-fbet)*(T0/Tref)**mubet+fbet))} .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 dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+rc1)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(ps1*a+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC Ia(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*Ia(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) {a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,Ue1(g,y,w))+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .FUNC Idiode(Usd,Tj,Iss) {exp(min(ln(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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} E_Eds3 d edep3 VALUE {V(d,s)-I(V_sense3)/Cds3} C_Cds3 edep3 s {Cds3} E_Eds2 d edep2 VALUE {if(qs8==0,0,V(d,s)-(exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)-min(V(d,s)+1,0)*exp(-qs8))} C_Cds2 edep2 s {Cds2} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE={Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} 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 {Cds3*((exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)-min(V(d,s)+1,0)*exp(-q84))} 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 Rd07 d3 s 1G Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT S5_60_lf2_var dd g s0 sp Tj PARAMS: a=1 Rsp=1 dVth=0 dR=0 Inn=1 +Unn=1 Rmax=1 Rs=1 Rp=1 dC=0 Rm=1u .PARAM b0=40 p0=7.92 p1=-29.8m p2=53u mubet=1 fbet=0 .PARAM Vth0=4.05 c=1.3 Fm=220m Fn=500m al=500m auth=4.1m .PARAM dvx=550m dvgs=100m eta=150m auth_sub=3.4m dvtha=1.2 arela=150m .PARAM dvthb=2.4 arelb=750m .PARAM Rd=5.4m nmu=3.2 Rf=380m .PARAM lnIsj=-27.7 ndi=1.07 Rdi=2m nmu2=0 n_Isj=3 UB=66 .PARAM ab=30m ab2=0 UT=100m lB=-23 td=10n ta=10n .PARAM kbq=85.8u Tref=298 T0=273 .PARAM f3=510p f3b=30p f3a=70p .PARAM f4=12.99p f5=4.99p sl=0.533p ps1=11.96p ps2=-1.38 ps3=87p .PARAM ps4=-140m ps5=2.7p ps6=9.08p ps7=500m pc0=35.09p .PARAM q83=61.34p q84=-716.28m qs6=5.39p qs7=74.81p qs8=-44.94m .PARAM q80=87.11p q81=44.04p q82=2.97p q85=0 qs1=57.9p qs2=166.7p .PARAM qs3=-68.93m f2r=1.21 .PARAM x1={(q80-q81)/q82} x2={q80/q82} .PARAM y1={(f4-f5)/sl} y2={f4/sl} .PARAM Vmin=3.25 Vmax=4.4 dCmax=330m .PARAM Vth={Vth0+(Vmax-Vth0)*limit(dVth,0,1)-(Vmin-Vth0)*limit(dVth,-1,0)} .PARAM q0={b0*((1-fbet)*(T0/Tref)**mubet+fbet)*a} .PARAM q1={tanh((Unn-Inn*Rs-Vth0-dvtha*arela-dvthb*arelb)*eta)/eta*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 bet={b0} .PARAM dC1={1+dCmax*limit(dC,0,1)} .PARAM dC2={1+dCmax*limit(dC,0,1)} .PARAM Cgs0={(f3*a+sqrt(a)*f3b)*dC1} .PARAM Cgs1={f3a*a*dC1} .PARAM Cds1={qs6*a*dC1} .PARAM Cds2={qs7*a*dC1} .PARAM Cds3={q83*a*dC1} .PARAM Cds5={qs1*a*dC1} .PARAM Cds6={(a*qs2*(1+f2r/sqrt(a)))*dC1} .PARAM Cds8={q80*a*dC1} .PARAM Cdg1={(ps1*a+pc0*sqrt(a))*dC2} .PARAM Cdg2={ps3*a*dC2} .PARAM Cdg3={(ps5*a+ps6)*dC2} .PARAM Cdg4={f4*a*dC2} .PARAM dRdi={Rdi/a} .FUNC Ue(g,y,w) {(g-Vth+auth*(w-Tref)+Fm*y**Fn)} .FUNC Ue1(g,y,w) {Ue(g,y,w)+(1+limit(Ue(g,y,w)+dvx,0,1)**2*(2*limit(Ue(g,y,w)+dvx,0,1)-3))*(dvgs+(auth_sub-auth)*(w-Tref))} .FUNC Ia(Uee,p,pp,z1) {if(Uee>pp,(Uee-c*z1)*z1,p*(pp-p)/c*exp((Uee-pp)/p))} .FUNC Ih(Uds,T,p,Uee) {bet*((1-fbet)*(T0/T)**mubet+fbet)*Ia(Uee,p,min(2*p,p+c*Uds),min(Uds,Uee/(2*c)))} .FUNC Jh(d,g,w,y,s,x) +{a*((Ih(s*y+min(d,0),w,(p0+(p1+p2*w)*w)*kbq*w,tanh(eta*Ue1(g,y,w))/eta)+exp(min(lB+(d-UB-ab*(w-Tref))/UT,24))))} .FUNC Idiode(Usd,Tj,Iss) {exp(min(ln(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)**n_Isj)} .FUNC Pr(Vss0,Vssp) {Vss0*Vss0/Rm+Vssp*Vssp/Rsp} .FUNC Q01(Uds) {a*(limit(Uds,x1,x2)*(q80-q82/2*limit(Uds,x1,x2))+min(Uds-x1,0)*q81-max(x1,0)*(q80-q81)/2)} .FUNC Q02(Udg) {a*(limit(Udg,y1,y2)*(f4-sl/2*limit(Udg,y1,y2))+min(Udg-y1,0)*f5-max(y1,0)*(f4-f5)/2)} C_Cgs g s {Cgs0} C_Cgs1 g sp {Cgs1} C_Cds1 d s {Cds1} E_Eds2 d edep2 VALUE {V(d,s)-I(V_sense3)/Cds2} C_Cds2 edep2 s {Cds2} E_Eds3 d edep3 VALUE {if(q84==0,0,V(d,s)-(exp(q84*max(V(d,s),-1))-1)/min(q84,-1u)+min(V(d,s)+1,0)*exp(-q84))} C_Cds3 edep3 s {Cds3} C_Cds5 d sp {Cds5} E_Eds6 d edep6 VALUE {if(qs3==0,0,V(d,sp)-(exp(qs3*max(V(d,sp),0))-1)/min(qs3,-1u)-min(V(d,sp),0))} C_Cds6 edep6 sp {Cds6} E_Eds8 d edep8 VALUE {V(d,sp)-Q01(V(d,sp))/Cds8} C_Cds8 edep8 sp {Cds8} E_Edg1 d ox1 VALUE {if(ps2==0,0,V(d,g)-(exp(ps2*max(V(d,g),0))-1)/min(ps2,-1u)-min(V(d,g),0))} C_Cdg1 ox1 g {Cdg1} E_Edg2 d ox2 VALUE = +{if(ps4==0,0,V(d,g)-((exp(ps4*(max(V(d,g)+ps7,0)))-exp(ps4*max(ps7,0)))/min(ps4,-1u)+min(V(d,g)+max(ps7,0),max(0,-ps7))))} C_Cdg2 ox2 g {Cdg2} C_Cdg3 d g {Cdg3} E_Edg4 d ox4 VALUE {V(d,g)-Q02(V(d,g))/Cdg4} C_Cdg4 ox4 g {Cdg4} Rfp s sp {Rsp} G_chan d5a s VALUE= +{(1-arela-arelb)*Jh(V(d5a,s),V(g,s),T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)+ +arela*Jh(V(d5a,s),V(g,s)-dvtha,T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)+ +arelb*Jh(V(d5a,s),V(g,s)-dvthb,T0+limit(V(Tj),-200,300),(SQRT(1+4*al*max(V(d5a,s),0))-1)/2/al,sgn(V(d5a,s)),0)} Rd06 d5a d5 1u V_sm d d5 0 G_RMos d1 d VALUE={V(d1,d)/(Rf*dRd+(1-Rf)*dRd*((limit(V(Tj),-200,999)+T0)/Tref)**nmu)} 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 {Cds2*((exp(qs8*max(V(d,s),-1))-1)/min(qs8,-1u)+min(V(d,s)+1,0)*exp(-qs8))} 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 Rd07 d3 s 1G Rssp g sp 100Meg Rmet s s0 {Rm} G_TH 0 Tj VALUE = +{(I(V_sense)-I(V_sense2))*V(d1,d)+I(V_sm)*V(d,s)+I(V_sense2)*V(d1,s)+Pr(V(s,s0),V(s,sp))} .ENDS ********** .SUBCKT IPT009N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.5n Ld=0.1n Lg=2.7n .PARAM Rs=234u Rg=1.8 Rd=20u Rm=96u .PARAM Inn=150 Unn=10 Rmax=900u gmin=175.04 .PARAM RRf=500m Rrbond=0.003 Rtb=2.6 g2=999m .PARAM act=22.06 Rsp=0.8 .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 sp Tj S5_60_f1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 10.974m Rthb Tb Tj {Rtb} Rth1 Tj t1 {1.34m+limit(Zthtype,0,1)*496.52u} Rth2 t1 t2 {16.29m+limit(Zthtype,0,1)*6.04m} Rth3 t2 t3 {59.3m+limit(Zthtype,0,1)*8.45m} Rth4 t3 t4 {64.79m+limit(Zthtype,0,1)*58.38m} Rth5 t4 Tcase {149.88m+limit(Zthtype,0,1)*135.05m} Cth1 Tj 0 230.34u Cth2 t1 0 779.09u Cth3 t2 0 5.04m Cth4 t3 0 3.89m Cth5 t4 0 80m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT IPTC007N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.9n Ld=0.6n Lg=4.4n .PARAM Rs=224u Rg=1.8 Rd=30u Rm=86u .PARAM Inn=150 Unn=10 Rmax=750u gmin=197 .PARAM RRf=500m Rrbond=0.003 Rtb=2.6 g2=999m .PARAM act=27.96 Rsp=0.8 .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 sp Tj S5_60_f4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 10.974m Rthb Tb Tj {Rtb} Rth1 Tj t1 {1.06m+limit(Zthtype,0,1)*388.99u} Rth2 t1 t2 {12.91m+limit(Zthtype,0,1)*4.77m} Rth3 t2 t3 {47.04m+limit(Zthtype,0,1)*6.64m} Rth4 t3 t4 {51.12m+limit(Zthtype,0,1)*44.65m} Rth5 t4 Tcase {123.53m+limit(Zthtype,0,1)*107.89m} Cth1 Tj 0 291.949u Cth2 t1 0 983.645u Cth3 t2 0 6.351m Cth4 t3 0 4.927m Cth5 t4 0 115m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT IPTC012N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1n Ld=0.6n Lg=4.4n .PARAM Rs=246u Rg=1.6 Rd=30u Rm=53u .PARAM Inn=100 Unn=10 Rmax=1.2m gmin=117 .PARAM RRf=500m Rrbond=0.004 Rtb=3 g2=1 .PARAM act=14.25 Rsp=0.9 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 8.194m Rthb Tb Tj {Rtb} Rth1 Tj t1 {2.08m+limit(Zthtype,0,1)*763.07u} Rth2 t1 t2 {25.01m+limit(Zthtype,0,1)*9.26m} Rth3 t2 t3 {89.99m+limit(Zthtype,0,1)*13.15m} Rth4 t3 t4 {100.3m+limit(Zthtype,0,1)*83.97m} Rth5 t4 Tcase {204.37m+limit(Zthtype,0,1)*171.1m} Cth1 Tj 0 148.79u Cth2 t1 0 507.52u Cth3 t2 0 3.33m Cth4 t3 0 2.51m Cth5 t4 0 55.3m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT IQD009N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.86m+limit(Zthtype,0,1)*683.23u} Rth2 t1 t2 {22.43m+limit(Zthtype,0,1)*8.3m} Rth3 t2 t3 {79.87m+limit(Zthtype,0,1)*6.98m} Rth4 t3 t4 {44.86m+limit(Zthtype,0,1)*16.71m} Rth5 t4 Tcase {195.48m+limit(Zthtype,0,1)*72.83m} Cth1 Tj 0 166.34u Cth2 t1 0 566.04u Cth3 t2 0 3.62m Cth4 t3 0 2.81m Cth5 t4 0 15.97m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQD009N06NM5CG drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.86m+limit(Zthtype,0,1)*683.23u} Rth2 t1 t2 {22.43m+limit(Zthtype,0,1)*8.3m} Rth3 t2 t3 {79.87m+limit(Zthtype,0,1)*6.98m} Rth4 t3 t4 {44.86m+limit(Zthtype,0,1)*16.71m} Rth5 t4 Tcase {195.48m+limit(Zthtype,0,1)*72.83m} Cth1 Tj 0 166.34u Cth2 t1 0 566.04u Cth3 t2 0 3.62m Cth4 t3 0 2.81m Cth5 t4 0 15.97m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQD009N06NM5CGSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.56m+limit(Zthtype,0,1)*570.59u} Rth2 t1 t2 {22.21m+limit(Zthtype,0,1)*8.22m} Rth3 t2 t3 {79.17m+limit(Zthtype,0,1)*7m} Rth4 t3 t4 {44.42m+limit(Zthtype,0,1)*17.05m} Rth5 t4 Tbottom {194.97m+limit(Zthtype,0,1)*74.83m} Cth1 Tj 0 89.6u Cth2 t1 0 653.27u Cth3 t2 0 3.66m Cth4 t3 0 2.84m Cth5 t4 0 16.17m Cth6 Tbottom 0 10m Rth1t Tj tt1 {137.36m+limit(Zthtype,0,1)*86.63m} Rth2t tt1 tt2 {52.7m+limit(Zthtype,0,1)*86.63m} Rth3t tt2 Ttop {47.43m+limit(Zthtype,0,1)*86.63m} Cth1t tt1 0 2.01m Cth2t tt2 0 4.33m Cth3t Ttop 0 5.34m .ENDS ********** .SUBCKT IQD009N06NM5SC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.56m+limit(Zthtype,0,1)*570.59u} Rth2 t1 t2 {22.21m+limit(Zthtype,0,1)*8.22m} Rth3 t2 t3 {79.17m+limit(Zthtype,0,1)*7m} Rth4 t3 t4 {44.42m+limit(Zthtype,0,1)*17.05m} Rth5 t4 Tbottom {194.97m+limit(Zthtype,0,1)*74.83m} Cth1 Tj 0 89.6u Cth2 t1 0 653.27u Cth3 t2 0 3.66m Cth4 t3 0 2.84m Cth5 t4 0 16.17m Cth6 Tbottom 0 10m Rth1t Tj tt1 {137.36m+limit(Zthtype,0,1)*86.63m} Rth2t tt1 tt2 {52.7m+limit(Zthtype,0,1)*86.63m} Rth3t tt2 Ttop {47.43m+limit(Zthtype,0,1)*86.63m} Cth1t tt1 0 2.01m Cth2t tt2 0 4.33m Cth3t Ttop 0 5.34m .ENDS ********** .SUBCKT IQDH88N06LM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=880u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.86m+limit(Zthtype,0,1)*683.23u} Rth2 t1 t2 {22.43m+limit(Zthtype,0,1)*8.3m} Rth3 t2 t3 {79.16m+limit(Zthtype,0,1)*3.45m} Rth4 t3 t4 {44.86m+limit(Zthtype,0,1)*17.5m} Rth5 t4 Tcase {195.48m+limit(Zthtype,0,1)*76.27m} Cth1 Tj 0 166.34u Cth2 t1 0 566.04u Cth3 t2 0 3.56m Cth4 t3 0 2.81m Cth5 t4 0 15.97m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQDH88N06LM5CG drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=860u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.86m+limit(Zthtype,0,1)*683.23u} Rth2 t1 t2 {22.43m+limit(Zthtype,0,1)*8.3m} Rth3 t2 t3 {79.16m+limit(Zthtype,0,1)*3.45m} Rth4 t3 t4 {44.86m+limit(Zthtype,0,1)*17.5m} Rth5 t4 Tcase {195.48m+limit(Zthtype,0,1)*76.27m} Cth1 Tj 0 166.34u Cth2 t1 0 566.04u Cth3 t2 0 3.56m Cth4 t3 0 2.81m Cth5 t4 0 15.97m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQDH88N06LM5CGSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=860u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.56m+limit(Zthtype,0,1)*570.59u} Rth2 t1 t2 {22.21m+limit(Zthtype,0,1)*8.22m} Rth3 t2 t3 {79.17m+limit(Zthtype,0,1)*7m} Rth4 t3 t4 {44.42m+limit(Zthtype,0,1)*17.05m} Rth5 t4 Tbottom {194.97m+limit(Zthtype,0,1)*74.83m} Cth1 Tj 0 89.6u Cth2 t1 0 653.27u Cth3 t2 0 3.66m Cth4 t3 0 2.84m Cth5 t4 0 16.17m Cth6 Tbottom 0 10m Rth1t Tj tt1 {137.36m+limit(Zthtype,0,1)*86.63m} Rth2t tt1 tt2 {52.7m+limit(Zthtype,0,1)*86.63m} Rth3t tt2 Ttop {47.43m+limit(Zthtype,0,1)*86.63m} Cth1t tt1 0 2.01m Cth2t tt2 0 4.33m Cth3t Ttop 0 5.34m .ENDS ********** .SUBCKT IQDH88N06LM5SC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=860u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.56m+limit(Zthtype,0,1)*570.59u} Rth2 t1 t2 {22.21m+limit(Zthtype,0,1)*8.22m} Rth3 t2 t3 {79.17m+limit(Zthtype,0,1)*7m} Rth4 t3 t4 {44.42m+limit(Zthtype,0,1)*17.05m} Rth5 t4 Tbottom {194.97m+limit(Zthtype,0,1)*74.83m} Cth1 Tj 0 89.6u Cth2 t1 0 653.27u Cth3 t2 0 3.66m Cth4 t3 0 2.84m Cth5 t4 0 16.17m Cth6 Tbottom 0 10m Rth1t Tj tt1 {137.36m+limit(Zthtype,0,1)*86.63m} Rth2t tt1 tt2 {52.7m+limit(Zthtype,0,1)*86.63m} Rth3t tt2 Ttop {47.43m+limit(Zthtype,0,1)*86.63m} Cth1t tt1 0 2.01m Cth2t tt2 0 4.33m Cth3t Ttop 0 5.34m .ENDS ********** .SUBCKT IQE022N06LM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {6.17m+limit(Zthtype,0,1)*2.29m} Rth2 t1 t2 {72.16m+limit(Zthtype,0,1)*26.7m} Rth3 t2 t3 {252.4m+limit(Zthtype,0,1)*12.37m} Rth4 t3 t4 {149.2m+limit(Zthtype,0,1)*244.26m} Rth5 t4 Tcase {278.5m+limit(Zthtype,0,1)*455.95m} Cth1 Tj 0 50.02u Cth2 t1 0 175.93u Cth3 t2 0 1.12m Cth4 t3 0 844.09u Cth5 t4 0 6.18m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQE022N06LM5CG drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {6.17m+limit(Zthtype,0,1)*2.29m} Rth2 t1 t2 {72.16m+limit(Zthtype,0,1)*26.7m} Rth3 t2 t3 {252.4m+limit(Zthtype,0,1)*12.37m} Rth4 t3 t4 {149.2m+limit(Zthtype,0,1)*244.26m} Rth5 t4 Tcase {278.5m+limit(Zthtype,0,1)*455.95m} Cth1 Tj 0 50.02u Cth2 t1 0 175.93u Cth3 t2 0 1.12m Cth4 t3 0 844.09u Cth5 t4 0 6.18m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQE022N06LM5CGSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {6.17m+limit(Zthtype,0,1)*2.29m} Rth2 t1 t2 {72.16m+limit(Zthtype,0,1)*26.7m} Rth3 t2 t3 {252.4m+limit(Zthtype,0,1)*12.37m} Rth4 t3 t4 {149.2m+limit(Zthtype,0,1)*244.26m} Rth5 t4 Tbottom {278.5m+limit(Zthtype,0,1)*455.95m} Cth1 Tj 0 50.02u Cth2 t1 0 175.93u Cth3 t2 0 1.12m Cth4 t3 0 844.09u Cth5 t4 0 6.18m Cth6 Tbottom 0 10m Rth1t Tj tt1 {406.25m+limit(Zthtype,0,1)*222.2m} Rth2t tt1 tt2 {150.94m+limit(Zthtype,0,1)*222.2m} Rth3t tt2 Ttop {169.48m+limit(Zthtype,0,1)*228.93m} Cth1t tt1 0 176.8u Cth2t tt2 0 603.63u Cth3t Ttop 0 1.67m .ENDS ********** .SUBCKT IQE022N06LM5SC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {6.17m+limit(Zthtype,0,1)*2.29m} Rth2 t1 t2 {72.16m+limit(Zthtype,0,1)*26.7m} Rth3 t2 t3 {252.4m+limit(Zthtype,0,1)*12.37m} Rth4 t3 t4 {149.2m+limit(Zthtype,0,1)*244.26m} Rth5 t4 Tbottom {278.5m+limit(Zthtype,0,1)*455.95m} Cth1 Tj 0 50.02u Cth2 t1 0 175.93u Cth3 t2 0 1.12m Cth4 t3 0 844.09u Cth5 t4 0 6.18m Cth6 Tbottom 0 10m Rth1t Tj tt1 {406.25m+limit(Zthtype,0,1)*222.2m} Rth2t tt1 tt2 {150.94m+limit(Zthtype,0,1)*222.2m} Rth3t tt2 Ttop {169.48m+limit(Zthtype,0,1)*228.93m} Cth1t tt1 0 176.8u Cth2t tt2 0 603.63u Cth3t Ttop 0 1.67m .ENDS ********** .SUBCKT IQFH68N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=57u Rg=0.6 Rd=3u Rm=8u .PARAM Inn=100 Unn=10 Rmax=680u gmin=150 .PARAM act=21.734 Rsp=0.18 X1 d1 g s sp Tj S5_60_e4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.36m+limit(Zthtype,0,1)*504.07u} Rth2 t1 t2 {16.53m+limit(Zthtype,0,1)*6.12m} Rth3 t2 t3 {59.1m+limit(Zthtype,0,1)*5.08m} Rth4 t3 t4 {32.88m+limit(Zthtype,0,1)*38.14m} Rth5 t4 Tcase {180.68m+limit(Zthtype,0,1)*209.6m} Cth1 Tj 0 226.94u Cth2 t1 0 767.77u Cth3 t2 0 4.89m Cth4 t3 0 3.83m Cth5 t4 0 41.99m Cth6 Tcase 0 50m .ENDS ********** .SUBCKT IQFH86N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=125u Rg=0.6 Rd=5u Rm=36u .PARAM Inn=100 Unn=10 Rmax=860u gmin=135 .PARAM act=17.595 Rsp=0.23 X1 d1 g s sp Tj S5_60_e4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {1.68m+limit(Zthtype,0,1)*622.57u} Rth2 t1 t2 {20.35m+limit(Zthtype,0,1)*7.53m} Rth3 t2 t3 {72.55m+limit(Zthtype,0,1)*6.3m} Rth4 t3 t4 {40.62m+limit(Zthtype,0,1)*45.67m} Rth5 t4 Tcase {190.5m+limit(Zthtype,0,1)*214.19m} Cth1 Tj 0 183.72u Cth2 t1 0 623.97u Cth3 t2 0 3.99m Cth4 t3 0 3.1m Cth5 t4 0 30.74m Cth6 Tcase 0 50m .ENDS ********** .SUBCKT IQFH99N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=125u Rg=0.6 Rd=5u Rm=36u .PARAM Inn=100 Unn=10 Rmax=990u gmin=124 .PARAM act=14.733 Rsp=2.57 X1 d1 g s sp Tj S5_60_e4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.01m+limit(Zthtype,0,1)*740.37u} Rth2 t1 t2 {24.22m+limit(Zthtype,0,1)*8.96m} Rth3 t2 t3 {86.16m+limit(Zthtype,0,1)*7.55m} Rth4 t3 t4 {97.04m+limit(Zthtype,0,1)*89.3m} Rth5 t4 Tcase {199.98m+limit(Zthtype,0,1)*184.04m} Cth1 Tj 0 153.806u Cth2 t1 0 524.247u Cth3 t2 0 3.358m Cth4 t3 0 2.596m Cth5 t4 0 57.39m Cth6 Tcase 0 50m .ENDS ********** .SUBCKT ISC010N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=300p Ld=100p Lg=2.2n .PARAM Rs=159u Rg=2.2 Rd=10u Rm=35u .PARAM Inn=50 Unn=10 Rmax=1.05m gmin=87 .PARAM act=14.73 Rsp=1.6 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.01m+limit(Zthtype,0,1)*740.37u} Rth2 t1 t2 {24.22m+limit(Zthtype,0,1)*8.96m} Rth3 t2 t3 {86.16m+limit(Zthtype,0,1)*7.55m} Rth4 t3 t4 {97.04m+limit(Zthtype,0,1)*89.3m} Rth5 t4 Tcase {199.98m+limit(Zthtype,0,1)*184.04m} Cth1 Tj 0 153.806u Cth2 t1 0 524.247u Cth3 t2 0 3.358m Cth4 t3 0 2.596m Cth5 t4 0 57.39m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC012N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=158u Rg=2.2 Rd=20u Rm=35u .PARAM Inn=50 Unn=10 Rmax=1.2m gmin=122 .PARAM act=14.73 Rsp=1.6 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.01m+limit(Zthtype,0,1)*740.37u} Rth2 t1 t2 {24.22m+limit(Zthtype,0,1)*8.96m} Rth3 t2 t3 {86.16m+limit(Zthtype,0,1)*7.55m} Rth4 t3 t4 {97.04m+limit(Zthtype,0,1)*89.3m} Rth5 t4 Tcase {199.98m+limit(Zthtype,0,1)*184.04m} Cth1 Tj 0 153.806u Cth2 t1 0 524.247u Cth3 t2 0 3.358m Cth4 t3 0 2.596m Cth5 t4 0 57.39m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC014N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.3n Ld=100p Lg=2.2n .PARAM Rs=297u Rg=2 Rd=20u Rm=126u .PARAM Inn=50 Unn=10 Rmax=1.45m gmin=107 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.48m+limit(Zthtype,0,1)*918.63u} Rth2 t1 t2 {29.78m+limit(Zthtype,0,1)*11.03m} Rth3 t2 t3 {104.94m+limit(Zthtype,0,1)*4.68m} Rth4 t3 t4 {119.91m+limit(Zthtype,0,1)*102.27m} Rth5 t4 Tcase {228.82m+limit(Zthtype,0,1)*195.17m} Cth1 Tj 0 124.465u Cth2 t1 0 426.236u Cth3 t2 0 2.689m Cth4 t3 0 2.101m Cth5 t4 0 46.196m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC014N06NSSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=127u Rg=2 Rd=10u Rm=19u .PARAM Inn=50 Unn=10 Rmax=1.4m gmin=108.11 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.48m+limit(Zthtype,0,1)*918.8u} Rth2 t1 t2 {29.78m+limit(Zthtype,0,1)*11.03m} Rth3 t2 t3 {104.94m+limit(Zthtype,0,1)*4.68m} Rth4 t3 t4 {119.91m+limit(Zthtype,0,1)*102.27m} Rth5 t4 Tbottom {228.82m+limit(Zthtype,0,1)*195.17m} Cth1 Tj 0 124.46u Cth2 t1 0 426.24u Cth3 t2 0 2.69m Cth4 t3 0 2.1m Cth5 t4 0 46.2m Cth6 Tbottom 0 30m Rth1t Tj tt1 {181.16m+limit(Zthtype,0,1)*136.1m} Rth2t tt1 tt2 {68.76m+limit(Zthtype,0,1)*136.1m} Rth3t tt2 Ttop {57.67m+limit(Zthtype,0,1)*140.22m} Cth1t tt1 0 1.52m Cth2t tt2 0 3.33m Cth3t Ttop 0 4.48m .ENDS ********** .SUBCKT BSC014N06NST drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=300p Ld=100p Lg=2.2n .PARAM Rs=297u Rg=2 Rd=20u Rm=126u .PARAM Inn=50 Unn=10 Rmax=1.45m gmin=107 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.48m+limit(Zthtype,0,1)*918.63u} Rth2 t1 t2 {29.78m+limit(Zthtype,0,1)*11.03m} Rth3 t2 t3 {104.94m+limit(Zthtype,0,1)*4.68m} Rth4 t3 t4 {119.91m+limit(Zthtype,0,1)*102.27m} Rth5 t4 Tcase {228.82m+limit(Zthtype,0,1)*195.17m} Cth1 Tj 0 124.465u Cth2 t1 0 426.236u Cth3 t2 0 2.689m Cth4 t3 0 2.101m Cth5 t4 0 46.196m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC016N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=273u Rg=1.8 Rd=20u Rm=102u .PARAM Inn=50 Unn=10 Rmax=1.6m gmin=97 .PARAM act=9.5 Rsp=1 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {3.11m+limit(Zthtype,0,1)*1.15m} Rth2 t1 t2 {37.16m+limit(Zthtype,0,1)*13.76m} Rth3 t2 t3 {130.74m+limit(Zthtype,0,1)*5.95m} Rth4 t3 t4 {150.46m+limit(Zthtype,0,1)*108.1m} Rth5 t4 Tcase {261.61m+limit(Zthtype,0,1)*187.96m} Cth1 Tj 0 99.196u Cth2 t1 0 341.611u Cth3 t2 0 2.159m Cth4 t3 0 1.674m Cth5 t4 0 38.28m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC016N06NST drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=273u Rg=1.8 Rd=20u Rm=102u .PARAM Inn=50 Unn=10 Rmax=1.6m gmin=97 .PARAM act=9.5 Rsp=1 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {3.11m+limit(Zthtype,0,1)*1.15m} Rth2 t1 t2 {37.16m+limit(Zthtype,0,1)*13.76m} Rth3 t2 t3 {130.74m+limit(Zthtype,0,1)*5.95m} Rth4 t3 t4 {150.46m+limit(Zthtype,0,1)*108.1m} Rth5 t4 Tcase {261.61m+limit(Zthtype,0,1)*187.96m} Cth1 Tj 0 99.196u Cth2 t1 0 341.611u Cth3 t2 0 2.159m Cth4 t3 0 1.674m Cth5 t4 0 38.28m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC028N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=213u Rg=1.3 Rd=20u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.8m gmin=71 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.99m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {70.04m+limit(Zthtype,0,1)*25.93m} Rth3 t2 t3 {245.08m+limit(Zthtype,0,1)*11.97m} Rth4 t3 t4 {289.34m+limit(Zthtype,0,1)*214.85m} Rth5 t4 Tcase {364.17m+limit(Zthtype,0,1)*270.42m} Cth1 Tj 0 51.582u Cth2 t1 0 181.242u Cth3 t2 0 1.154m Cth4 t3 0 870.522u Cth5 t4 0 26.987m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC028N06NST drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=213u Rg=1.3 Rd=20u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.8m gmin=71 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.99m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {70.04m+limit(Zthtype,0,1)*25.93m} Rth3 t2 t3 {245.08m+limit(Zthtype,0,1)*11.97m} Rth4 t3 t4 {289.34m+limit(Zthtype,0,1)*214.85m} Rth5 t4 Tcase {364.17m+limit(Zthtype,0,1)*270.42m} Cth1 Tj 0 51.582u Cth2 t1 0 181.242u Cth3 t2 0 1.154m Cth4 t3 0 870.522u Cth5 t4 0 26.987m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC028N06NSSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=140u Rg=1.3 Rd=10u Rm=32u .PARAM Inn=30 Unn=10 Rmax=2.8m gmin=56 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.99m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {70.04m+limit(Zthtype,0,1)*25.93m} Rth3 t2 t3 {245.08m+limit(Zthtype,0,1)*11.97m} Rth4 t3 t4 {289.34m+limit(Zthtype,0,1)*214.86m} Rth5 t4 Tbottom {364.16m+limit(Zthtype,0,1)*270.42m} Cth1 Tj 0 51.58u Cth2 t1 0 181.24u Cth3 t2 0 1.15m Cth4 t3 0 870.52u Cth5 t4 0 26.99m Cth6 Tbottom 0 30m Rth1t Tj tt1 {462.96m+limit(Zthtype,0,1)*216.41m} Rth2t tt1 tt2 {169.4m+limit(Zthtype,0,1)*216.41m} Rth3t tt2 Ttop {111.84m+limit(Zthtype,0,1)*222.97m} Cth1t tt1 0 596.7u Cth2t tt2 0 1.42m Cth3t Ttop 0 2.83m .ENDS ********** .SUBCKT BSC019N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=251u Rg=1.7 Rd=20u Rm=80u .PARAM Inn=50 Unn=10 Rmax=1.95m gmin=86 .PARAM act=7.35 Rsp=0.9 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {4.02m+limit(Zthtype,0,1)*1.49m} Rth2 t1 t2 {47.69m+limit(Zthtype,0,1)*17.65m} Rth3 t2 t3 {167.45m+limit(Zthtype,0,1)*7.82m} Rth4 t3 t4 {194.47m+limit(Zthtype,0,1)*140.87m} Rth5 t4 Tcase {300.71m+limit(Zthtype,0,1)*217.83m} Cth1 Tj 0 76.746u Cth2 t1 0 266.191u Cth3 t2 0 1.687m Cth4 t3 0 1.295m Cth5 t4 0 32.337m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC034N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=216u Rg=1.3 Rd=20u Rm=45u .PARAM Inn=50 Unn=10 Rmax=3.4m gmin=65 .PARAM act=4.13 Rsp=0.7 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {7.16m+limit(Zthtype,0,1)*2.65m} Rth2 t1 t2 {83.22m+limit(Zthtype,0,1)*30.8m} Rth3 t2 t3 {290.67m+limit(Zthtype,0,1)*14.52m} Rth4 t3 t4 {346.09m+limit(Zthtype,0,1)*248.98m} Rth5 t4 Tcase {393.11m+limit(Zthtype,0,1)*282.8m} Cth1 Tj 0 43.124u Cth2 t1 0 152.543u Cth3 t2 0 973.696u Cth4 t3 0 727.784u Cth5 t4 0 25.709m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC039N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=365u Rg=1.6 Rd=20u Rm=173u .PARAM Inn=50 Unn=10 Rmax=3.9m gmin=60 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {398.15m+limit(Zthtype,0,1)*242.6m} Rth5 t4 Tcase {415.48m+limit(Zthtype,0,1)*253.15m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 632.626u Cth5 t4 0 25.164m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSZ039N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=268u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=3.9m gmin=39 .PARAM RRf=471m Rrbond=1m Rtb=1.7 g2=859m .PARAM act=3.59 Rsp=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 sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 7.47m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {398.15m+limit(Zthtype,0,1)*242.6m} Rth5 t4 Tcase {415.48m+limit(Zthtype,0,1)*253.15m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 632.626u Cth5 t4 0 25.164m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSZ042N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=513u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=4.2m gmin=38 .PARAM RRf=498m Rrbond=17m Rtb=6.5 g2=958m .PARAM act=3.59 Rsp=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 sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 1.97m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {398.15m+limit(Zthtype,0,1)*242.6m} Rth5 t4 Tcase {415.48m+limit(Zthtype,0,1)*253.15m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 632.626u Cth5 t4 0 25.164m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSC066N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=332u Rg=1.2 Rd=20u Rm=140u .PARAM Inn=50 Unn=10 Rmax=6.6m gmin=46 .PARAM act=2.04 Rsp=0.7 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {14.49m+limit(Zthtype,0,1)*5.37m} Rth2 t1 t2 {163.05m+limit(Zthtype,0,1)*60.35m} Rth3 t2 t3 {564.7m+limit(Zthtype,0,1)*31.4m} Rth4 t3 t4 {700.66m+limit(Zthtype,0,1)*389.22m} Rth5 t4 Tcase {495.51m+limit(Zthtype,0,1)*275.25m} Cth1 Tj 0 21.301u Cth2 t1 0 77.858u Cth3 t2 0 502.837u Cth4 t3 0 359.487u Cth5 t4 0 28.973m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSZ068N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=465u Rg=1.2 Rd=20u Rm=102u .PARAM Inn=20 Unn=10 Rmax=6.8m gmin=29 .PARAM RRf=498m Rrbond=17m Rtb=6.5 g2=958m .PARAM act=2.04 Rsp=0.7 .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 sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 1.97m Rthb Tb Tj {Rtb} Rth1 Tj t1 {14.49m+limit(Zthtype,0,1)*5.37m} Rth2 t1 t2 {163.05m+limit(Zthtype,0,1)*60.35m} Rth3 t2 t3 {564.7m+limit(Zthtype,0,1)*31.4m} Rth4 t3 t4 {700.66m+limit(Zthtype,0,1)*389.22m} Rth5 t4 Tcase {495.51m+limit(Zthtype,0,1)*275.25m} Cth1 Tj 0 21.301u Cth2 t1 0 77.858u Cth3 t2 0 502.837u Cth4 t3 0 359.487u Cth5 t4 0 28.973m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSC097N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=323u Rg=1.1 Rd=20u Rm=131u .PARAM Inn=40 Unn=10 Rmax=9.7m gmin=34.03 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {21.58m+limit(Zthtype,0,1)*7.99m} Rth2 t1 t2 {237.05m+limit(Zthtype,0,1)*87.73m} Rth3 t2 t3 {816.13m+limit(Zthtype,0,1)*48.88m} Rth4 t3 t4 {1.04+limit(Zthtype,0,1)*472.76m} Rth5 t4 Tcase {527.91m+limit(Zthtype,0,1)*239.97m} Cth1 Tj 0 14.305u Cth2 t1 0 53.554u Cth3 t2 0 348.793u Cth4 t3 0 241.42u Cth5 t4 0 59.521m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC097N06NST drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=323u Rg=1.1 Rd=20u Rm=131u .PARAM Inn=40 Unn=10 Rmax=9.7m gmin=34.03 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {21.58m+limit(Zthtype,0,1)*7.99m} Rth2 t1 t2 {237.05m+limit(Zthtype,0,1)*87.73m} Rth3 t2 t3 {816.13m+limit(Zthtype,0,1)*48.88m} Rth4 t3 t4 {1.04+limit(Zthtype,0,1)*472.76m} Rth5 t4 Tcase {527.91m+limit(Zthtype,0,1)*239.97m} Cth1 Tj 0 14.305u Cth2 t1 0 53.554u Cth3 t2 0 348.793u Cth4 t3 0 241.42u Cth5 t4 0 59.521m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSZ100N06NS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=860u Rg=1.1 Rd=20u Rm=363u .PARAM Inn=20 Unn=10 Rmax=10m gmin=24 .PARAM RRf=499m Rrbond=34m Rtb=9 g2=970m .PARAM act=1.37 Rsp=0.6 .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 sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 1.41m Rthb Tb Tj {Rtb} Rth1 Tj t1 {21.58m+limit(Zthtype,0,1)*7.99m} Rth2 t1 t2 {237.05m+limit(Zthtype,0,1)*87.73m} Rth3 t2 t3 {816.13m+limit(Zthtype,0,1)*48.88m} Rth4 t3 t4 {1.04+limit(Zthtype,0,1)*472.76m} Rth5 t4 Tcase {527.91m+limit(Zthtype,0,1)*239.97m} Cth1 Tj 0 14.305u Cth2 t1 0 53.554u Cth3 t2 0 348.793u Cth4 t3 0 241.42u Cth5 t4 0 59.521m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IPD025N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.5n Ld=1n Lg=3n .PARAM Rs=878u Rg=1.8 Rd=20u Rm=399u .PARAM Inn=90 Unn=10 Rmax=2.5m gmin=114.44 .PARAM RRf=390m Rrbond=12m Rtb=5.5 g2=758m .PARAM act=9.5 Rsp=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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 3.71m Rthb Tb Tj {Rtb} Rth1 Tj t1 {3.11m+limit(Zthtype,0,1)*1.15m} Rth2 t1 t2 {37.16m+limit(Zthtype,0,1)*13.76m} Rth3 t2 t3 {132.38m+limit(Zthtype,0,1)*19.85m} Rth4 t3 t4 {150.46m+limit(Zthtype,0,1)*102.43m} Rth5 t4 Tcase {261.61m+limit(Zthtype,0,1)*178.09m} Cth1 Tj 0 99.196u Cth2 t1 0 341.611u Cth3 t2 0 2.269m Cth4 t3 0 1.674m Cth5 t4 0 38.28m Cth6 Tcase 0 70m .ENDS ********** .SUBCKT IPT007N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.5n Ld=0.1n Lg=2.7n .PARAM Rs=234u Rg=1.8 Rd=20u Rm=96u .PARAM Inn=150 Unn=10 Rmax=0.75m gmin=276 .PARAM RRf=500m Rrbond=3m Rtb=2.6 g2=999m .PARAM act=27.96 Rsp=0.8 .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 sp Tj S5_60_f1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 10.97m Rthb Tb Tj {Rtb} Rth1 Tj t1 {1.06m+limit(Zthtype,0,1)*388.99u} Rth2 t1 t2 {12.91m+limit(Zthtype,0,1)*4.77m} Rth3 t2 t3 {47.04m+limit(Zthtype,0,1)*6.64m} Rth4 t3 t4 {51.12m+limit(Zthtype,0,1)*44.65m} Rth5 t4 Tcase {123.53m+limit(Zthtype,0,1)*107.89m} Cth1 Tj 0 291.949u Cth2 t1 0 983.645u Cth3 t2 0 6.351m Cth4 t3 0 4.927m Cth5 t4 0 115m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT IPB010N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.9n Ld=0.1n Lg=6.5n .PARAM Rs=395u Rg=1.8 Rd=20u Rm=121u .PARAM Inn=100 Unn=10 Rmax=1m gmin=215.9 .PARAM RRf=391m Rrbond=6m Rtb=3.8 g2=656m .PARAM act=28.01 Rsp=0.8 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 10.14m Rthb Tb Tj {Rtb} Rth1 Tj t1 {1.06m+limit(Zthtype,0,1)*386.4u} Rth2 t1 t2 {12.88m+limit(Zthtype,0,1)*4.77m} Rth3 t2 t3 {46.96m+limit(Zthtype,0,1)*6.63m} Rth4 t3 t4 {63.21m+limit(Zthtype,0,1)*52.22m} Rth5 t4 Tcase {170.79m+limit(Zthtype,0,1)*141.09m} Cth1 Tj 0 292.471u Cth2 t1 0 985.377u Cth3 t2 0 6.362m Cth4 t3 0 4.761m Cth5 t4 0 140.094m Cth6 Tcase 0 190m .ENDS ********** .SUBCKT IPT012N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.7n Ld=0.1n Lg=2.7n .PARAM Rs=213u Rg=1.6 Rd=20u Rm=53u .PARAM Inn=100 Unn=10 Rmax=1.2m gmin=167.06 .PARAM RRf=500m Rrbond=4m Rtb=3 g2=999m .PARAM act=14.25 Rsp=0.9 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 8.19m Rthb Tb Tj {Rtb} Rth1 Tj t1 {2.08m+limit(Zthtype,0,1)*763.72u} Rth2 t1 t2 {25.01m+limit(Zthtype,0,1)*9.26m} Rth3 t2 t3 {89.99m+limit(Zthtype,0,1)*13.15m} Rth4 t3 t4 {100.31m+limit(Zthtype,0,1)*83.97m} Rth5 t4 Tcase {204.38m+limit(Zthtype,0,1)*171.09m} Cth1 Tj 0 148.794u Cth2 t1 0 507.52u Cth3 t2 0 3.329m Cth4 t3 0 2.511m Cth5 t4 0 55.297m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT IPB014N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.9n Ld=0.1n Lg=6.5n .PARAM Rs=360u Rg=1.6 Rd=20u Rm=86u .PARAM Inn=100 Unn=10 Rmax=1.4m gmin=161.77 .PARAM RRf=391m Rrbond=6m Rtb=3.8 g2=656m .PARAM act=14.25 Rsp=0.9 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 10.14m Rthb Tb Tj {Rtb} Rth1 Tj t1 {2.08m+limit(Zthtype,0,1)*763.72u} Rth2 t1 t2 {25.01m+limit(Zthtype,0,1)*9.26m} Rth3 t2 t3 {89.99m+limit(Zthtype,0,1)*13.15m} Rth4 t3 t4 {124.24m+limit(Zthtype,0,1)*70.43m} Rth5 t4 Tcase {232.99m+limit(Zthtype,0,1)*132.08m} Cth1 Tj 0 148.794u Cth2 t1 0 507.52u Cth3 t2 0 3.329m Cth4 t3 0 2.422m Cth5 t4 0 86.668m Cth6 Tcase 0 190m .ENDS ********** .SUBCKT IPI020N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=617u Rg=1.6 Rd=350u Rm=134u .PARAM Inn=100 Unn=10 Rmax=2m gmin=152.1 .PARAM RRf=339m Rrbond=11m Rtb=5.1 g2=721m .PARAM act=14.25 Rsp=0.9 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 7.75m Rthb Tb Tj {Rtb} Rth1 Tj t1 {2.08m+limit(Zthtype,0,1)*763.72u} Rth2 t1 t2 {25.01m+limit(Zthtype,0,1)*9.26m} Rth3 t2 t3 {89.99m+limit(Zthtype,0,1)*13.15m} Rth4 t3 t4 {124.24m+limit(Zthtype,0,1)*70.43m} Rth5 t4 Tcase {232.99m+limit(Zthtype,0,1)*132.08m} Cth1 Tj 0 148.794u Cth2 t1 0 507.52u Cth3 t2 0 3.329m Cth4 t3 0 2.422m Cth5 t4 0 86.668m Cth6 Tcase 0 190m .ENDS ********** .SUBCKT IPP020N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=617u Rg=1.6 Rd=350u Rm=134u .PARAM Inn=100 Unn=10 Rmax=2m gmin=152.1 .PARAM RRf=339m Rrbond=11m Rtb=5.1 g2=721m .PARAM act=14.25 Rsp=0.9 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 7.75m Rthb Tb Tj {Rtb} Rth1 Tj t1 {2.08m+limit(Zthtype,0,1)*763.72u} Rth2 t1 t2 {25.01m+limit(Zthtype,0,1)*9.26m} Rth3 t2 t3 {89.99m+limit(Zthtype,0,1)*13.15m} Rth4 t3 t4 {124.24m+limit(Zthtype,0,1)*70.43m} Rth5 t4 Tcase {232.99m+limit(Zthtype,0,1)*132.08m} Cth1 Tj 0 148.794u Cth2 t1 0 507.52u Cth3 t2 0 3.329m Cth4 t3 0 2.422m Cth5 t4 0 86.668m Cth6 Tcase 0 220m .ENDS ********** .SUBCKT IPA029N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=721u Rg=1.3 Rd=350u Rm=178u .PARAM Inn=83 Unn=10 Rmax=2.9m gmin=103.29 .PARAM RRf=393m Rrbond=16m Rtb=6.3 g2=761m .PARAM act=7.52 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 9.51m Rthb Tb Tj {Rtb} Rth1 Tj t1 {3.93m+limit(Zthtype,0,1)*1.46m} Rth2 t1 t2 {46.64m+limit(Zthtype,0,1)*17.27m} Rth3 t2 t3 {307.82m+limit(Zthtype,0,1)*25.19m} Rth4 t3 t4 {987.33m+limit(Zthtype,0,1)*522.45m} Rth5 t4 Tcase {1.3+limit(Zthtype,0,1)*687.91m} Cth1 Tj 0 78.521u Cth2 t1 0 272.165u Cth3 t2 0 988.298u Cth4 t3 0 16.966m Cth5 t4 0 1.36 Cth6 Tcase 0 100m .ENDS ********** .SUBCKT IPA029N06NM5S drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=977u Rg=1.3 Rd=350u Rm=272u .PARAM Inn=84 Unn=10 Rmax=2.9m gmin=99.68 .PARAM RRf=452m Rrbond=36m Rtb=9.4 g2=827m .PARAM act=7.52 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 6.34m Rthb Tb Tj {Rtb} Rth1 Tj t1 {3.93m+limit(Zthtype,0,1)*1.46m} Rth2 t1 t2 {46.64m+limit(Zthtype,0,1)*17.27m} Rth3 t2 t3 {307.82m+limit(Zthtype,0,1)*25.19m} Rth4 t3 t4 {987.33m+limit(Zthtype,0,1)*522.45m} Rth5 t4 Tcase {1.3+limit(Zthtype,0,1)*687.91m} Cth1 Tj 0 78.521u Cth2 t1 0 272.165u Cth3 t2 0 988.298u Cth4 t3 0 16.966m Cth5 t4 0 1.36 Cth6 Tcase 0 100m .ENDS ********** .SUBCKT IPB026N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=3.6n Ld=0.1n Lg=6.5n .PARAM Rs=721u Rg=1.3 Rd=50u Rm=178u .PARAM Inn=100 Unn=10 Rmax=2.6m gmin=112.56 .PARAM RRf=393m Rrbond=16m Rtb=6.3 g2=761m .PARAM act=7.52 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 9.51m Rthb Tb Tj {Rtb} Rth1 Tj t1 {3.93m+limit(Zthtype,0,1)*1.46m} Rth2 t1 t2 {46.64m+limit(Zthtype,0,1)*17.27m} Rth3 t2 t3 {165.08m+limit(Zthtype,0,1)*25.19m} Rth4 t3 t4 {235.43m+limit(Zthtype,0,1)*123.93m} Rth5 t4 Tcase {315.16m+limit(Zthtype,0,1)*165.91m} Cth1 Tj 0 78.521u Cth2 t1 0 272.165u Cth3 t2 0 1.822m Cth4 t3 0 1.278m Cth5 t4 0 60.58m Cth6 Tcase 0 190m .ENDS ********** .SUBCKT IPI029N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=721u Rg=1.3 Rd=350u Rm=178u .PARAM Inn=100 Unn=10 Rmax=2.9m gmin=112.56 .PARAM RRf=393m Rrbond=16m Rtb=6.3 g2=761m .PARAM act=7.52 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 9.51m Rthb Tb Tj {Rtb} Rth1 Tj t1 {3.93m+limit(Zthtype,0,1)*1.46m} Rth2 t1 t2 {46.64m+limit(Zthtype,0,1)*17.27m} Rth3 t2 t3 {165.08m+limit(Zthtype,0,1)*25.19m} Rth4 t3 t4 {235.43m+limit(Zthtype,0,1)*123.93m} Rth5 t4 Tcase {315.16m+limit(Zthtype,0,1)*165.91m} Cth1 Tj 0 78.521u Cth2 t1 0 272.165u Cth3 t2 0 1.822m Cth4 t3 0 1.278m Cth5 t4 0 60.58m Cth6 Tcase 0 190m .ENDS ********** .SUBCKT IPP029N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=721u Rg=1.3 Rd=350u Rm=178u .PARAM Inn=100 Unn=10 Rmax=2.9m gmin=112.56 .PARAM RRf=393m Rrbond=16m Rtb=6.3 g2=761m .PARAM act=7.52 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 9.51m Rthb Tb Tj {Rtb} Rth1 Tj t1 {3.93m+limit(Zthtype,0,1)*1.46m} Rth2 t1 t2 {46.64m+limit(Zthtype,0,1)*17.27m} Rth3 t2 t3 {165.08m+limit(Zthtype,0,1)*25.19m} Rth4 t3 t4 {235.43m+limit(Zthtype,0,1)*123.93m} Rth5 t4 Tcase {315.16m+limit(Zthtype,0,1)*165.91m} Cth1 Tj 0 78.521u Cth2 t1 0 272.165u Cth3 t2 0 1.822m Cth4 t3 0 1.278m Cth5 t4 0 60.58m Cth6 Tcase 0 220m .ENDS ********** .SUBCKT IPD033N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.5n Ld=1n Lg=3n .PARAM Rs=690u Rg=1.2 Rd=20u Rm=211u .PARAM Inn=90 Unn=10 Rmax=3.3m gmin=89.41 .PARAM RRf=390m Rrbond=12m Rtb=5.5 g2=758m .PARAM act=5.03 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 3.71m Rthb Tb Tj {Rtb} Rth1 Tj t1 {5.88m+limit(Zthtype,0,1)*2.17m} Rth2 t1 t2 {68.84m+limit(Zthtype,0,1)*25.47m} Rth3 t2 t3 {240.48m+limit(Zthtype,0,1)*37.99m} Rth4 t3 t4 {284.16m+limit(Zthtype,0,1)*164.57m} Rth5 t4 Tcase {361.24m+limit(Zthtype,0,1)*209.2m} Cth1 Tj 0 52.522u Cth2 t1 0 184.425u Cth3 t2 0 1.255m Cth4 t3 0 886.382u Cth5 t4 0 27.152m Cth6 Tcase 0 70m .ENDS ********** .SUBCKT IPA040N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=960u Rg=1.3 Rd=350u Rm=255u .PARAM Inn=80 Unn=10 Rmax=4.0m gmin=82.31 .PARAM RRf=452m Rrbond=36m Rtb=9.4 g2=827m .PARAM act=5.03 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 6.34m Rthb Tb Tj {Rtb} Rth1 Tj t1 {5.88m+limit(Zthtype,0,1)*2.17m} Rth2 t1 t2 {68.84m+limit(Zthtype,0,1)*25.47m} Rth3 t2 t3 {627.12m+limit(Zthtype,0,1)*37.99m} Rth4 t3 t4 {994.34m+limit(Zthtype,0,1)*461.55m} Rth5 t4 Tcase {1.35+limit(Zthtype,0,1)*626.64m} Cth1 Tj 0 52.522u Cth2 t1 0 184.425u Cth3 t2 0 1.255m Cth4 t3 0 15.439m Cth5 t4 0 1.53 Cth6 Tcase 0 100m .ENDS ********** .SUBCKT IPA040N06NM5S drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=960u Rg=1.3 Rd=350u Rm=255u .PARAM Inn=69 Unn=10 Rmax=4.0m gmin=76.88 .PARAM RRf=452m Rrbond=36m Rtb=9.4 g2=827m .PARAM act=5.03 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 6.34m Rthb Tb Tj {Rtb} Rth1 Tj t1 {5.88m+limit(Zthtype,0,1)*2.17m} Rth2 t1 t2 {68.84m+limit(Zthtype,0,1)*25.47m} Rth3 t2 t3 {627.12m+limit(Zthtype,0,1)*37.99m} Rth4 t3 t4 {994.34m+limit(Zthtype,0,1)*461.55m} Rth5 t4 Tcase {1.35+limit(Zthtype,0,1)*626.64m} Cth1 Tj 0 52.522u Cth2 t1 0 184.425u Cth3 t2 0 1.255m Cth4 t3 0 15.439m Cth5 t4 0 1.53 Cth6 Tcase 0 100m .ENDS ********** .SUBCKT IPP040N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=960u Rg=1.3 Rd=350u Rm=255u .PARAM Inn=80 Unn=10 Rmax=4.0m gmin=82.31 .PARAM RRf=452m Rrbond=36m Rtb=9.4 g2=827m .PARAM act=5.03 Rsp=0.7 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 6.34m Rthb Tb Tj {Rtb} Rth1 Tj t1 {5.88m+limit(Zthtype,0,1)*2.17m} Rth2 t1 t2 {68.84m+limit(Zthtype,0,1)*25.47m} Rth3 t2 t3 {240.48m+limit(Zthtype,0,1)*37.99m} Rth4 t3 t4 {308.75m+limit(Zthtype,0,1)*146.49m} Rth5 t4 Tcase {382.47m+limit(Zthtype,0,1)*181.46m} Cth1 Tj 0 52.522u Cth2 t1 0 184.425u Cth3 t2 0 1.255m Cth4 t3 0 855.025u Cth5 t4 0 50.32m Cth6 Tcase 0 220m .ENDS ********** .SUBCKT IPB057N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=1n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=50u Rm=535u .PARAM Inn=45 Unn=10 Rmax=5.7m gmin=50.64 .PARAM RRf=487m Rrbond=133m Rtb=17.9 g2=901m .PARAM act=3.59 Rsp=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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 3.02m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {392.48m+limit(Zthtype,0,1)*216.99m} Rth5 t4 Tcase {450.72m+limit(Zthtype,0,1)*249.19m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 610.246u Cth5 t4 0 44.151m Cth6 Tcase 0 190m .ENDS ********** .SUBCKT IPD053N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2n Ld=1n Lg=3n .PARAM Rs=1.33m Rg=1.6 Rd=20u Rm=535u .PARAM Inn=45 Unn=10 Rmax=5.3m gmin=52 .PARAM RRf=475m Rrbond=55m Rtb=11.6 g2=868m .PARAM act=3.59 Rsp=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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {398.15m+limit(Zthtype,0,1)*242.6m} Rth5 t4 Tcase {415.48m+limit(Zthtype,0,1)*253.15m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 632.626u Cth5 t4 0 25.164m Cth6 Tcase 0 70m .ENDS ********** .SUBCKT IPA060N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=2.5n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=350u Rm=535u .PARAM Inn=45 Unn=10 Rmax=6m gmin=50.64 .PARAM RRf=487m Rrbond=133m Rtb=17.9 g2=901m .PARAM act=3.59 Rsp=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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 3.02m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {1.34+limit(Zthtype,0,1)*640.78m} Rth5 t4 Tcase {1.44+limit(Zthtype,0,1)*688.6m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 1.447m Cth5 t4 0 672.286m Cth6 Tcase 0 100m .ENDS ********** .SUBCKT IPA060N06NM5S drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=2.5n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=350u Rm=535u .PARAM Inn=45 Unn=10 Rmax=6m gmin=50.64 .PARAM RRf=487m Rrbond=133m Rtb=17.9 g2=901m .PARAM act=3.59 Rsp=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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 3.02m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {1.34+limit(Zthtype,0,1)*640.78m} Rth5 t4 Tcase {1.44+limit(Zthtype,0,1)*688.6m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 3.52m Cth5 t4 0 672.286m Cth6 Tcase 0 100m .ENDS ********** .SUBCKT IPP060N06N drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=2.5n Ld=2.5n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=350u Rm=535u .PARAM Inn=45 Unn=10 Rmax=6m gmin=50.64 .PARAM RRf=487m Rrbond=133m Rtb=17.9 g2=901m .PARAM act=3.59 Rsp=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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 3.02m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {392.48m+limit(Zthtype,0,1)*216.99m} Rth5 t4 Tcase {450.72m+limit(Zthtype,0,1)*249.19m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 610.246u Cth5 t4 0 44.151m Cth6 Tcase 0 220m .ENDS ********** .SUBCKT BSZ037N06LS5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=268u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=3.7m gmin=39 .PARAM RRf=471m Rrbond=1m Rtb=1.7 g2=859m .PARAM act=3.59 Rsp=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 sp Tj S5_60_j2_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 7.47m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {398.15m+limit(Zthtype,0,1)*242.6m} Rth5 t4 Tcase {415.48m+limit(Zthtype,0,1)*253.15m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 632.626u Cth5 t4 0 25.164m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSZ040N06LS5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=513u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=4.0m gmin=38 .PARAM RRf=498m Rrbond=17m Rtb=6.5 g2=958m .PARAM act=3.59 Rsp=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 sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 1.97m Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.04m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {398.15m+limit(Zthtype,0,1)*242.6m} Rth5 t4 Tcase {415.48m+limit(Zthtype,0,1)*253.15m} Cth1 Tj 0 37.486u Cth2 t1 0 133.351u Cth3 t2 0 852.933u Cth4 t3 0 632.626u Cth5 t4 0 25.164m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSZ065N06LS5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=465u Rg=1.2 Rd=20u Rm=102u .PARAM Inn=20 Unn=10 Rmax=6.5m gmin=29 .PARAM RRf=498m Rrbond=17m Rtb=6.5 g2=958m .PARAM act=2.04 Rsp=0.7 .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 sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 1.97m Rthb Tb Tj {Rtb} Rth1 Tj t1 {14.49m+limit(Zthtype,0,1)*5.37m} Rth2 t1 t2 {163.05m+limit(Zthtype,0,1)*60.35m} Rth3 t2 t3 {564.7m+limit(Zthtype,0,1)*31.4m} Rth4 t3 t4 {700.66m+limit(Zthtype,0,1)*389.22m} Rth5 t4 Tcase {495.51m+limit(Zthtype,0,1)*275.25m} Cth1 Tj 0 21.301u Cth2 t1 0 77.858u Cth3 t2 0 502.837u Cth4 t3 0 359.487u Cth5 t4 0 28.973m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSZ099N06LS5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=860u Rg=1.1 Rd=20u Rm=363u .PARAM Inn=20 Unn=10 Rmax=9.9m gmin=24 .PARAM RRf=499m Rrbond=34m Rtb=9 g2=970m .PARAM act=1.37 Rsp=0.6 .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 sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 1.41m Rthb Tb Tj {Rtb} Rth1 Tj t1 {21.58m+limit(Zthtype,0,1)*7.99m} Rth2 t1 t2 {237.05m+limit(Zthtype,0,1)*87.73m} Rth3 t2 t3 {816.13m+limit(Zthtype,0,1)*48.88m} Rth4 t3 t4 {1.04+limit(Zthtype,0,1)*472.76m} Rth5 t4 Tcase {527.91m+limit(Zthtype,0,1)*239.97m} Cth1 Tj 0 14.305u Cth2 t1 0 53.554u Cth3 t2 0 348.793u Cth4 t3 0 241.42u Cth5 t4 0 59.521m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSC027N06LS5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=213u Rg=1.3 Rd=20u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.7m gmin=71 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.99m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {70.04m+limit(Zthtype,0,1)*25.93m} Rth3 t2 t3 {245.08m+limit(Zthtype,0,1)*11.97m} Rth4 t3 t4 {289.34m+limit(Zthtype,0,1)*214.85m} Rth5 t4 Tcase {364.17m+limit(Zthtype,0,1)*270.42m} Cth1 Tj 0 51.582u Cth2 t1 0 181.242u Cth3 t2 0 1.154m Cth4 t3 0 870.522u Cth5 t4 0 26.987m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC065N06LS5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=332u Rg=1.2 Rd=20u Rm=140u .PARAM Inn=32 Unn=10 Rmax=6.5m gmin=36.91 .PARAM act=2.04 Rsp=0.7 X1 d1 g s sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {14.49m+limit(Zthtype,0,1)*5.37m} Rth2 t1 t2 {163.05m+limit(Zthtype,0,1)*60.35m} Rth3 t2 t3 {564.7m+limit(Zthtype,0,1)*31.4m} Rth4 t3 t4 {700.66m+limit(Zthtype,0,1)*389.22m} Rth5 t4 Tcase {495.51m+limit(Zthtype,0,1)*275.25m} Cth1 Tj 0 21.301u Cth2 t1 0 77.858u Cth3 t2 0 502.837u Cth4 t3 0 359.487u Cth5 t4 0 28.973m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT BSC094N06LS5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=323u Rg=1.1 Rd=20u Rm=131u .PARAM Inn=24 Unn=10 Rmax=9.4m gmin=26.43 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {21.58m+limit(Zthtype,0,1)*7.99m} Rth2 t1 t2 {237.05m+limit(Zthtype,0,1)*87.73m} Rth3 t2 t3 {816.13m+limit(Zthtype,0,1)*48.88m} Rth4 t3 t4 {1.04+limit(Zthtype,0,1)*472.76m} Rth5 t4 Tcase {527.91m+limit(Zthtype,0,1)*239.97m} Cth1 Tj 0 14.305u Cth2 t1 0 53.554u Cth3 t2 0 348.793u Cth4 t3 0 241.42u Cth5 t4 0 59.521m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT IRL60HS118 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=0.3n Ld=1n Lg=3n .PARAM Rs=2.25m Rg=1.2 Rd=20u Rm=257u .PARAM Inn=11 Unn=10 Rmax=17m gmin=13.49 .PARAM RRf=500m Rrbond=985m Rtb=62.7 g2=996m .PARAM act=0.915 Rsp=0.6 .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 sp Tj S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 38.04u Rthb Tb Tj {Rtb} Rth1 Tj t1 {32.32m+limit(Zthtype,0,1)*11.96m} Rth2 t1 t2 {344.69m+limit(Zthtype,0,1)*127.57m} Rth3 t2 t3 {1.18+limit(Zthtype,0,1)*75.13m} Rth4 t3 t4 {1.56+limit(Zthtype,0,1)*6.87} Rth5 t4 Tcase {516.72m+limit(Zthtype,0,1)*2.28} Cth1 Tj 0 9.554u Cth2 t1 0 36.83u Cth3 t2 0 242.306u Cth4 t3 0 161.24u Cth5 t4 0 3m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT BSC016N06NSSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=122u Rg=1.8 Rd=10u Rm=14u .PARAM Inn=50 Unn=10 Rmax=1.6m gmin=97 .PARAM act=9.5 Rsp=1 X1 d1 g s sp Tj S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {3.11m+limit(Zthtype,0,1)*1.15m} Rth2 t1 t2 {37.16m+limit(Zthtype,0,1)*13.76m} Rth3 t2 t3 {130.74m+limit(Zthtype,0,1)*5.95m} Rth4 t3 t4 {150.46m+limit(Zthtype,0,1)*108.1m} Rth5 t4 Tbottom {261.61m+limit(Zthtype,0,1)*187.96m} Cth1 Tj 0 99.2u Cth2 t1 0 341.61u Cth3 t2 0 2.16m Cth4 t3 0 1.67m Cth5 t4 0 38.28m Cth6 Tbottom 0 30m Rth1t Tj tt1 {233.64m+limit(Zthtype,0,1)*154.95m} Rth2t tt1 tt2 {87.8m+limit(Zthtype,0,1)*154.95m} Rth3t tt2 Ttop {69.01m+limit(Zthtype,0,1)*159.65m} Cth1t tt1 0 1.18m Cth2t tt2 0 2.63m Cth3t Ttop 0 3.87m .ENDS ********** .SUBCKT IPTG007N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=1.1n Ld=0.1n Lg=4.6n .PARAM Rs=252u Rg=1.8 Rd=20u Rm=96u .PARAM Inn=150 Unn=10 Rmax=750u gmin=192 .PARAM RRf=500m Rrbond=0.003 Rtb=2.6 g2=999m .PARAM act=27.96 Rsp=0.8 .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 sp Tj S5_60_f4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 10.974m Rthb Tb Tj {Rtb} Rth1 Tj t1 {1.06m+limit(Zthtype,0,1)*388.99u} Rth2 t1 t2 {12.91m+limit(Zthtype,0,1)*4.77m} Rth3 t2 t3 {47.04m+limit(Zthtype,0,1)*6.64m} Rth4 t3 t4 {51.12m+limit(Zthtype,0,1)*44.65m} Rth5 t4 Tcase {123.53m+limit(Zthtype,0,1)*107.89m} Cth1 Tj 0 291.949u Cth2 t1 0 983.645u Cth3 t2 0 6.351m Cth4 t3 0 4.927m Cth5 t4 0 115m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT IQE030N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=30 Unn=10 Rmax=3m gmin=40 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.95m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {69.68m+limit(Zthtype,0,1)*25.78m} Rth3 t2 t3 {243.81m+limit(Zthtype,0,1)*11.89m} Rth4 t3 t4 {287.77m+limit(Zthtype,0,1)*172.22m} Rth5 t4 Tcase {363.28m+limit(Zthtype,0,1)*217.41m} Cth1 Tj 0 51.86u Cth2 t1 0 182.2u Cth3 t2 0 1.16m Cth4 t3 0 875.28u Cth5 t4 0 27.04m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQE030N06NM5CG drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=20 Unn=10 Rmax=3m gmin=33 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.95m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {69.68m+limit(Zthtype,0,1)*25.78m} Rth3 t2 t3 {243.81m+limit(Zthtype,0,1)*11.89m} Rth4 t3 t4 {287.77m+limit(Zthtype,0,1)*172.22m} Rth5 t4 Tcase {363.28m+limit(Zthtype,0,1)*217.41m} Cth1 Tj 0 51.86u Cth2 t1 0 182.2u Cth3 t2 0 1.16m Cth4 t3 0 875.28u Cth5 t4 0 27.04m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IQE030N06NM5CGSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=20 Unn=10 Rmax=3m gmin=33 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.95m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {69.68m+limit(Zthtype,0,1)*25.78m} Rth3 t2 t3 {243.81m+limit(Zthtype,0,1)*11.89m} Rth4 t3 t4 {143.88m+limit(Zthtype,0,1)*247.69m} Rth5 t4 Tbottom {275.25m+limit(Zthtype,0,1)*473.85m} Cth1 Tj 0 51.86u Cth2 t1 0 182.2u Cth3 t2 0 1.16m Cth4 t3 0 875.28u Cth5 t4 0 6.3m Cth6 Tbottom 0 10m Rth1t Tj tt1 {406.25m+limit(Zthtype,0,1)*222.2m} Rth2t tt1 tt2 {150.94m+limit(Zthtype,0,1)*222.2m} Rth3t tt2 Ttop {169.48m+limit(Zthtype,0,1)*228.93m} Cth1t tt1 0 176.8u Cth2t tt2 0 603.63u Cth3t Ttop 0 1.67m .ENDS ********** .SUBCKT IQE030N06NM5SC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=30 Unn=10 Rmax=3m gmin=40 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {5.95m+limit(Zthtype,0,1)*2.21m} Rth2 t1 t2 {69.68m+limit(Zthtype,0,1)*25.78m} Rth3 t2 t3 {243.81m+limit(Zthtype,0,1)*11.89m} Rth4 t3 t4 {143.88m+limit(Zthtype,0,1)*247.69m} Rth5 t4 Tbottom {275.25m+limit(Zthtype,0,1)*473.85m} Cth1 Tj 0 51.86u Cth2 t1 0 182.2u Cth3 t2 0 1.16m Cth4 t3 0 875.28u Cth5 t4 0 6.3m Cth6 Tbottom 0 10m Rth1t Tj tt1 {406.25m+limit(Zthtype,0,1)*222.2m} Rth2t tt1 tt2 {150.94m+limit(Zthtype,0,1)*222.2m} Rth3t tt2 Ttop {169.48m+limit(Zthtype,0,1)*228.93m} Cth1t tt1 0 176.8u Cth2t tt2 0 603.63u Cth3t Ttop 0 1.67m .ENDS ********** .SUBCKT ISC009N06LM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=168u Rg=2.5 Rd=10u Rm=35u .PARAM Inn=50 Unn=10 Rmax=900u gmin=108 .PARAM act=14.73 Rsp=1.6 X1 d1 g s sp Tj S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.01m+limit(Zthtype,0,1)*740.42u} Rth2 t1 t2 {24.22m+limit(Zthtype,0,1)*8.96m} Rth3 t2 t3 {86.16m+limit(Zthtype,0,1)*7.55m} Rth4 t3 t4 {97.04m+limit(Zthtype,0,1)*89.31m} Rth5 t4 Tcase {199.97m+limit(Zthtype,0,1)*184.04m} Cth1 Tj 0 153.81u Cth2 t1 0 524.25u Cth3 t2 0 3.36m Cth4 t3 0 2.6m Cth5 t4 0 57.39m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT ISC011N06LM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=176u Rg=2.1 Rd=10u Rm=38u .PARAM Inn=50 Unn=10 Rmax=1.1m gmin=116 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.48m+limit(Zthtype,0,1)*918.8u} Rth2 t1 t2 {29.78m+limit(Zthtype,0,1)*11.03m} Rth3 t2 t3 {104.94m+limit(Zthtype,0,1)*4.68m} Rth4 t3 t4 {119.91m+limit(Zthtype,0,1)*102.27m} Rth5 t4 Tcase {228.82m+limit(Zthtype,0,1)*195.17m} Cth1 Tj 0 124.46u Cth2 t1 0 426.24u Cth3 t2 0 2.69m Cth4 t3 0 2.1m Cth5 t4 0 46.2m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT ISC015N06NM5LF2 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=159u Rg=2 Rd=10u Rm=21u .PARAM Inn=50 Unn=10 Rmax=1.55m .PARAM act=11.6 Rsp=2.15 X1 d1 g s sp Tj S5_60_lf2_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} Inn={Inn} Unn={Unn} +Rmax={Rmax} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} Rg g1 g {Rg} Lg gate g1 {Lg} 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} Rda d1 d2 {Rd} Ld drain d2 {Ld} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {2.84m+limit(Zthtype,0,1)*1.05m} Rth2 t1 t2 {30.73m+limit(Zthtype,0,1)*11.37m} Rth3 t2 t3 {45.99m+limit(Zthtype,0,1)*7.6m} Rth4 t3 t4 {247.59m+limit(Zthtype,0,1)*69.57m} Rth5 t4 Tcase {213.32m+limit(Zthtype,0,1)*59.94m} Cth1 Tj 0 160.75u Cth2 t1 0 826.34u Cth3 t2 0 1.69m Cth4 t3 0 2.65m Cth5 t4 0 19.42m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT ISC0702NLS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=223u Rg=1.3 Rd=10u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.8m gmin=55 .PARAM act=3.794 Rsp=1.24 X1 d1 g s sp Tj S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {7.79m+limit(Zthtype,0,1)*2.89m} Rth2 t1 t2 {90.29m+limit(Zthtype,0,1)*33.41m} Rth3 t2 t3 {315.06m+limit(Zthtype,0,1)*15.92m} Rth4 t3 t4 {376.74m+limit(Zthtype,0,1)*120.79m} Rth5 t4 Tcase {406.71m+limit(Zthtype,0,1)*130.4m} Cth1 Tj 0 39.62u Cth2 t1 0 140.61u Cth3 t2 0 898.61u Cth4 t3 0 668.57u Cth5 t4 0 25.33m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT ISC0703NLS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=284u Rg=1.2 Rd=10u Rm=96u .PARAM Inn=32 Unn=10 Rmax=6.9m gmin=27 .PARAM act=1.445 Rsp=0.98 X1 d1 g s sp Tj S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {20.46m+limit(Zthtype,0,1)*7.57m} Rth2 t1 t2 {225.47m+limit(Zthtype,0,1)*83.44m} Rth3 t2 t3 {776.92m+limit(Zthtype,0,1)*46.04m} Rth4 t3 t4 {988.89m+limit(Zthtype,0,1)*473.9m} Rth5 t4 Tcase {525.48m+limit(Zthtype,0,1)*251.82m} Cth1 Tj 0 15.09u Cth2 t1 0 56.3u Cth3 t2 0 366.26u Cth4 t3 0 254.71u Cth5 t4 0 49.59m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT ISG0614N06NM5H drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=31u Rg=1.8 Rd=62u Rm=30u .PARAM Inn=50 Unn=10 Rmax=1.61m gmin=97 .PARAM act=8.63 Rsp=1 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {3.11m+limit(Zthtype,0,1)*1.15m} Rth2 t1 t2 {37.16m+limit(Zthtype,0,1)*13.76m} Rth3 t2 t3 {183.08m+limit(Zthtype,0,1)*8.332m} Rth4 t3 t4 {150.46m+limit(Zthtype,0,1)*108.1m} Rth5 t4 Tcase {229.65m+limit(Zthtype,0,1)*164.995m} Cth1 Tj 0 99.196u Cth2 t1 0 341.611u Cth3 t2 0 312u Cth4 t3 0 1.674m Cth5 t4 0 38.28m Cth6 Tcase 0 30m .ENDS ********** .SUBCKT ISG0614N06NM5HSC drain gate source Tj Ttop Tbottom PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=31u Rg=1.8 Rd=62u Rm=30u .PARAM Inn=50 Unn=10 Rmax=1.61m gmin=97 .PARAM act=8.63 Rsp=1 X1 d1 g s sp Tj S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb drain d2 10 Rth1 Tj t1 {3.11m+limit(Zthtype,0,1)*1.15m} Rth2 t1 t2 {37.16m+limit(Zthtype,0,1)*13.76m} Rth3 t2 t3 {183.08m+limit(Zthtype,0,1)*8.332m} Rth4 t3 t4 {150.46m+limit(Zthtype,0,1)*108.1m} Rth5 t4 Tbottom {229.65m+limit(Zthtype,0,1)*164.995m} Cth1 Tj 0 99.196u Cth2 t1 0 341.611u Cth3 t2 0 312u Cth4 t3 0 1.674m Cth5 t4 0 38.28m Cth6 Tbottom 0 30m Rth1t Tj tt1 {233.64m+limit(Zthtype,0,1)*154.95m} Rth2t tt1 tt2 {87.8m+limit(Zthtype,0,1)*154.95m} Rth3t tt2 Ttop {69.01m+limit(Zthtype,0,1)*159.65m} Cth1t tt1 0 1.18m Cth2t tt2 0 2.63m Cth3t Ttop 0 3.87m .ENDS ********** .SUBCKT IST011N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=300p Ld=500p Lg=3n .PARAM Rs=116u Rg=1 Rd=20u Rm=17u .PARAM Inn=100 Unn=10 Rmax=1.1m gmin=71.99 .PARAM RRf=496m Rrbond=0.001 Rtb=1.7 g2=925m .PARAM act=14.82 Rsp=1.75 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 2.143m Rthb Tb Tj {Rtb} Rth1 Tj t1 {2m+limit(Zthtype,0,1)*733.72u} Rth2 t1 t2 {24.07m+limit(Zthtype,0,1)*8.91m} Rth3 t2 t3 {86.68m+limit(Zthtype,0,1)*12.63m} Rth4 t3 t4 {96.45m+limit(Zthtype,0,1)*16.1m} Rth5 t4 Tcase {199.17m+limit(Zthtype,0,1)*33.25m} Cth1 Tj 0 154.75u Cth2 t1 0 527.38u Cth3 t2 0 3.46m Cth4 t3 0 2.61m Cth5 t4 0 57.79m Cth6 Tcase 0 20m .ENDS ********** .SUBCKT IST015N06NM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=300p Ld=500p Lg=3n .PARAM Rs=128u Rg=1.85 Rd=20u Rm=20u .PARAM Inn=50 Unn=10 Rmax=1.5m gmin=71 .PARAM RRf=500m Rrbond=0.001 Rtb=1.8 g2=933m .PARAM act=9.58 Rsp=1.75 .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 sp Tj S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 {3.09m+limit(Zthtype,0,1)*1.14m} Rth2 t1 t2 {36.86m+limit(Zthtype,0,1)*13.64m} Rth3 t2 t3 {129.68m+limit(Zthtype,0,1)*5.9m} Rth4 t3 t4 {149.2m+limit(Zthtype,0,1)*109.34m} Rth5 t4 Tcase {260.36m+limit(Zthtype,0,1)*190.8m} Cth1 Tj 0 100.03u Cth2 t1 0 344.41u Cth3 t2 0 2.18m Cth4 t3 0 1.69m Cth5 t4 0 38.52m Cth6 Tcase 0 20m .ENDS ********** .SUBCKT ISZ0702NLS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=300p Ld=100p Lg=1.2n .PARAM Rs=836u Rg=1.8 Rd=20u Rm=298u .PARAM Inn=20 Unn=10 Rmax=4.5m gmin=29 .PARAM RRf=499m Rrbond=0.038 Rtb=9.4 g2=971m .PARAM act=2.591 Rsp=1.84 .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 sp Tj S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 210u Rthb Tb Tj {Rtb} Rth1 Tj t1 {11.41m+limit(Zthtype,0,1)*4.22m} Rth2 t1 t2 {129.96m+limit(Zthtype,0,1)*48.1m} Rth3 t2 t3 {451.51m+limit(Zthtype,0,1)*24.13m} Rth4 t3 t4 {551.6m+limit(Zthtype,0,1)*333.53m} Rth5 t4 Tcase {464.6m+limit(Zthtype,0,1)*280.93m} Cth1 Tj 0 27.06u Cth2 t1 0 97.68u Cth3 t2 0 628.1u Cth4 t3 0 456.63u Cth5 t4 0 25.76m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT ISZ0703NLS drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=300p Ld=100p Lg=1.2n .PARAM Rs=824u Rg=1.3 Rd=20u Rm=286u .PARAM Inn=20 Unn=10 Rmax=7.3m gmin=27 .PARAM RRf=499m Rrbond=0.038 Rtb=9.4 g2=971m .PARAM act=1.445 Rsp=0.98 .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 sp Tj S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 210u Rthb Tb Tj {Rtb} Rth1 Tj t1 {20.46m+limit(Zthtype,0,1)*7.57m} Rth2 t1 t2 {225.47m+limit(Zthtype,0,1)*83.44m} Rth3 t2 t3 {776.92m+limit(Zthtype,0,1)*46.04m} Rth4 t3 t4 {988.89m+limit(Zthtype,0,1)*473.9m} Rth5 t4 Tcase {525.48m+limit(Zthtype,0,1)*251.82m} Cth1 Tj 0 15.09u Cth2 t1 0 56.3u Cth3 t2 0 366.26u Cth4 t3 0 254.71u Cth5 t4 0 49.59m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT ISZ034N06LM5 drain gate source Tj Tcase PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Zthtype=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=488u Rg=1.8 Rd=20u Rm=104u .PARAM Inn=20 Unn=10 Rmax=3.4m gmin=34 .PARAM RRf=498m Rrbond=0.018 Rtb=6.5 g2=959m .PARAM act=3.59 Rsp=1.86 .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 sp Tj S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} Rsb source s1 10 Rga gate g1 10 Rdb 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 301u Rthb Tb Tj {Rtb} Rth1 Tj t1 {8.24m+limit(Zthtype,0,1)*3.05m} Rth2 t1 t2 {95.2m+limit(Zthtype,0,1)*35.23m} Rth3 t2 t3 {332.01m+limit(Zthtype,0,1)*16.9m} Rth4 t3 t4 {398.15m+limit(Zthtype,0,1)*242.59m} Rth5 t4 Tcase {415.48m+limit(Zthtype,0,1)*253.15m} Cth1 Tj 0 37.49u Cth2 t1 0 133.35u Cth3 t2 0 852.93u Cth4 t3 0 632.63u Cth5 t4 0 25.16m Cth6 Tcase 0 10m .ENDS ********** .SUBCKT IPT009N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.5n Ld=0.1n Lg=2.7n .PARAM Rs=234u Rg=1.8 Rd=20u Rm=96u .PARAM Inn=150 Unn=10 Rmax=900u gmin=175.04 .PARAM act=22.06 Rsp=0.8 X1 d1 g s sp Tj1 S5_60_f1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPTC007N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.9n Ld=0.6n Lg=4.4n .PARAM Rs=224u Rg=1.8 Rd=30u Rm=86u .PARAM Inn=150 Unn=10 Rmax=750u gmin=197 .PARAM act=27.96 Rsp=0.8 X1 d1 g s sp Tj1 S5_60_f4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPTC012N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1n Ld=0.6n Lg=4.4n .PARAM Rs=246u Rg=1.6 Rd=30u Rm=53u .PARAM Inn=100 Unn=10 Rmax=1.2m gmin=117 .PARAM act=14.25 Rsp=0.9 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQD009N06NM5CGSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQD009N06NM5CG_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQD009N06NM5SC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQD009N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=61u Rg=0.5 Rd=62u Rm=10u .PARAM Inn=50 Unn=10 Rmax=900u gmin=88 .PARAM act=15.93 Rsp=0.58 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQDH88N06LM5CGSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=860u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQDH88N06LM5CG_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=860u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQDH88N06LM5SC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=860u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQDH88N06LM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=11u Rg=0.55 Rd=75u Rm=10u .PARAM Inn=50 Unn=10 Rmax=880u gmin=113 .PARAM act=15.93 Rsp=0.29 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE022N06LM5CGSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE022N06LM5CG_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE022N06LM5SC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE022N06LM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=250p Lg=1n .PARAM Rs=11u Rg=1.1 Rd=80u Rm=10u .PARAM Inn=20 Unn=10 Rmax=2.2m gmin=49 .PARAM act=4.79 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_j4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQFH68N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=57u Rg=0.6 Rd=3u Rm=8u .PARAM Inn=100 Unn=10 Rmax=680u gmin=150 .PARAM act=21.734 Rsp=0.18 X1 d1 g s sp Tj1 S5_60_e4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQFH86N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=125u Rg=0.6 Rd=5u Rm=36u .PARAM Inn=100 Unn=10 Rmax=860u gmin=135 .PARAM act=17.595 Rsp=0.23 X1 d1 g s sp Tj1 S5_60_e4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQFH99N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=125u Rg=0.6 Rd=5u Rm=36u .PARAM Inn=100 Unn=10 Rmax=990u gmin=124 .PARAM act=14.733 Rsp=2.57 X1 d1 g s sp Tj1 S5_60_e4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISC010N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=300p Ld=100p Lg=2.2n .PARAM Rs=159u Rg=2.2 Rd=10u Rm=35u .PARAM Inn=50 Unn=10 Rmax=1.05m gmin=87 .PARAM act=14.73 Rsp=1.6 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC012N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=158u Rg=2.2 Rd=20u Rm=35u .PARAM Inn=50 Unn=10 Rmax=1.2m gmin=122 .PARAM act=14.73 Rsp=1.6 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC014N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.3n Ld=100p Lg=2.2n .PARAM Rs=297u Rg=2 Rd=20u Rm=126u .PARAM Inn=50 Unn=10 Rmax=1.45m gmin=107 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC014N06NSSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=127u Rg=2 Rd=10u Rm=19u .PARAM Inn=50 Unn=10 Rmax=1.4m gmin=108.11 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC014N06NST_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=300p Ld=100p Lg=2.2n .PARAM Rs=297u Rg=2 Rd=20u Rm=126u .PARAM Inn=50 Unn=10 Rmax=1.45m gmin=107 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC016N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=273u Rg=1.8 Rd=20u Rm=102u .PARAM Inn=50 Unn=10 Rmax=1.6m gmin=97 .PARAM act=9.5 Rsp=1 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC016N06NST_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=273u Rg=1.8 Rd=20u Rm=102u .PARAM Inn=50 Unn=10 Rmax=1.6m gmin=97 .PARAM act=9.5 Rsp=1 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC016N06NSSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=122u Rg=1.8 Rd=10u Rm=14u .PARAM Inn=50 Unn=10 Rmax=1.6m gmin=97 .PARAM act=9.5 Rsp=1 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC028N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=213u Rg=1.3 Rd=20u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.8m gmin=71 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC028N06NST_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=213u Rg=1.3 Rd=20u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.8m gmin=71 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC028N06NSSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=140u Rg=1.3 Rd=10u Rm=32u .PARAM Inn=30 Unn=10 Rmax=2.8m gmin=56 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC019N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=251u Rg=1.7 Rd=20u Rm=80u .PARAM Inn=50 Unn=10 Rmax=1.95m gmin=86 .PARAM act=7.35 Rsp=0.9 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC034N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=216u Rg=1.3 Rd=20u Rm=45u .PARAM Inn=50 Unn=10 Rmax=3.4m gmin=65 .PARAM act=4.13 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC039N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=365u Rg=1.6 Rd=20u Rm=173u .PARAM Inn=50 Unn=10 Rmax=3.9m gmin=60 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ039N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=268u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=3.9m gmin=39 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ042N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=513u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=4.2m gmin=38 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_e_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC066N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=332u Rg=1.2 Rd=20u Rm=140u .PARAM Inn=50 Unn=10 Rmax=6.6m gmin=46 .PARAM act=2.04 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ068N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=465u Rg=1.2 Rd=20u Rm=102u .PARAM Inn=20 Unn=10 Rmax=6.8m gmin=29 .PARAM act=2.04 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC097N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=323u Rg=1.1 Rd=20u Rm=131u .PARAM Inn=40 Unn=10 Rmax=9.7m gmin=34.03 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC097N06NST_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=323u Rg=1.1 Rd=20u Rm=131u .PARAM Inn=40 Unn=10 Rmax=9.7m gmin=34.03 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ100N06NS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=860u Rg=1.1 Rd=20u Rm=363u .PARAM Inn=20 Unn=10 Rmax=10m gmin=24 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPD025N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.5n Ld=1n Lg=3n .PARAM Rs=878u Rg=1.8 Rd=20u Rm=399u .PARAM Inn=90 Unn=10 Rmax=2.5m gmin=114.44 .PARAM act=9.5 Rsp=1 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPT007N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.5n Ld=0.1n Lg=2.7n .PARAM Rs=234u Rg=1.8 Rd=20u Rm=96u .PARAM Inn=150 Unn=10 Rmax=0.75m gmin=276 .PARAM act=27.96 Rsp=0.8 X1 d1 g s sp Tj1 S5_60_f1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPTG007N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.1n Ld=0.1n Lg=4.6n .PARAM Rs=252u Rg=1.8 Rd=20u Rm=96u .PARAM Inn=150 Unn=10 Rmax=750u gmin=192 .PARAM act=27.96 Rsp=0.8 X1 d1 g s sp Tj1 S5_60_f4_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPB010N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.9n Ld=0.1n Lg=6.5n .PARAM Rs=395u Rg=1.8 Rd=20u Rm=121u .PARAM Inn=100 Unn=10 Rmax=1m gmin=215.9 .PARAM act=28.01 Rsp=0.8 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPT012N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.7n Ld=0.1n Lg=2.7n .PARAM Rs=213u Rg=1.6 Rd=20u Rm=53u .PARAM Inn=100 Unn=10 Rmax=1.2m gmin=167.06 .PARAM act=14.25 Rsp=0.9 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPB014N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.9n Ld=0.1n Lg=6.5n .PARAM Rs=360u Rg=1.6 Rd=20u Rm=86u .PARAM Inn=100 Unn=10 Rmax=1.4m gmin=161.77 .PARAM act=14.25 Rsp=0.9 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPI020N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=617u Rg=1.6 Rd=350u Rm=134u .PARAM Inn=100 Unn=10 Rmax=2m gmin=152.1 .PARAM act=14.25 Rsp=0.9 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPP020N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=617u Rg=1.6 Rd=350u Rm=134u .PARAM Inn=100 Unn=10 Rmax=2m gmin=152.1 .PARAM act=14.25 Rsp=0.9 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPA029N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=721u Rg=1.3 Rd=350u Rm=178u .PARAM Inn=83 Unn=10 Rmax=2.9m gmin=103.29 .PARAM act=7.52 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPA029N06NM5S_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=977u Rg=1.3 Rd=350u Rm=272u .PARAM Inn=84 Unn=10 Rmax=2.9m gmin=99.68 .PARAM act=7.52 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPB026N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=3.6n Ld=0.1n Lg=6.5n .PARAM Rs=721u Rg=1.3 Rd=50u Rm=178u .PARAM Inn=100 Unn=10 Rmax=2.6m gmin=112.56 .PARAM act=7.52 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPI029N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=721u Rg=1.3 Rd=350u Rm=178u .PARAM Inn=100 Unn=10 Rmax=2.9m gmin=112.56 .PARAM act=7.52 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPP029N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.8n Ld=2.5n Lg=4n .PARAM Rs=721u Rg=1.3 Rd=350u Rm=178u .PARAM Inn=100 Unn=10 Rmax=2.9m gmin=112.56 .PARAM act=7.52 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPD033N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=1.5n Ld=1n Lg=3n .PARAM Rs=690u Rg=1.2 Rd=20u Rm=211u .PARAM Inn=90 Unn=10 Rmax=3.3m gmin=89.41 .PARAM act=5.03 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPA040N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=960u Rg=1.3 Rd=350u Rm=255u .PARAM Inn=80 Unn=10 Rmax=4.0m gmin=82.31 .PARAM act=5.03 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPA040N06NM5S_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=960u Rg=1.3 Rd=350u Rm=255u .PARAM Inn=69 Unn=10 Rmax=4.0m gmin=76.88 .PARAM act=5.03 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPP040N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=2.5n Lg=4n .PARAM Rs=960u Rg=1.3 Rd=350u Rm=255u .PARAM Inn=80 Unn=10 Rmax=4.0m gmin=82.31 .PARAM act=5.03 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPB057N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=1n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=50u Rm=535u .PARAM Inn=45 Unn=10 Rmax=5.7m gmin=50.64 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPD053N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2n Ld=1n Lg=3n .PARAM Rs=1.33m Rg=1.6 Rd=20u Rm=535u .PARAM Inn=45 Unn=10 Rmax=5.3m gmin=52 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPA060N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=2.5n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=350u Rm=535u .PARAM Inn=45 Unn=10 Rmax=6m gmin=50.64 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPA060N06NM5S_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=2.5n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=350u Rm=535u .PARAM Inn=45 Unn=10 Rmax=6m gmin=50.64 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPP060N06N_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=2.5n Ld=2.5n Lg=4n .PARAM Rs=1.68m Rg=1.6 Rd=350u Rm=535u .PARAM Inn=45 Unn=10 Rmax=6m gmin=50.64 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE030N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=30 Unn=10 Rmax=3m gmin=40 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE030N06NM5CG_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=20 Unn=10 Rmax=3m gmin=33 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE030N06NM5CGSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=20 Unn=10 Rmax=3m gmin=33 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IQE030N06NM5SC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=0.25n Lg=1n .PARAM Rs=61u Rg=0.9 Rd=80u Rm=50u .PARAM Inn=30 Unn=10 Rmax=3m gmin=40 .PARAM act=4.967 Rsp=0.85 X1 d1 g s sp Tj1 S5_60_e3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISC015N06NM5LF2_L1 drain gate source PARAMS: dVth=0 dRdson=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=159u Rg=2 Rd=10u Rm=21u .PARAM Inn=50 Unn=10 Rmax=1.55m .PARAM act=11.6 Rsp=2.15 X1 d1 g s sp Tj1 S5_60_lf2_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} Inn={Inn} Unn={Unn} +Rmax={Rmax} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} Rg g1 g {Rg} Lg gate g1 {Lg} 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} Rda d1 d2 {Rd} Ld drain d2 {Ld} E1 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISG0614N06NM5HSC_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=31u Rg=1.8 Rd=62u Rm=30u .PARAM Inn=50 Unn=10 Rmax=1.61m gmin=97 .PARAM act=8.63 Rsp=1 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISG0614N06NM5H_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=100p Ld=300p Lg=1n .PARAM Rs=31u Rg=1.8 Rd=62u Rm=30u .PARAM Inn=50 Unn=10 Rmax=1.61m gmin=97 .PARAM act=8.63 Rsp=1 X1 d1 g s sp Tj1 S5_60_e1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IST011N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=300p Ld=500p Lg=3n .PARAM Rs=116u Rg=1 Rd=20u Rm=17u .PARAM Inn=100 Unn=10 Rmax=1.1m gmin=71.99 .PARAM act=14.82 Rsp=1.75 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IST015N06NM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=300p Ld=500p Lg=3n .PARAM Rs=128u Rg=1.85 Rd=20u Rm=20u .PARAM Inn=50 Unn=10 Rmax=1.5m gmin=71 .PARAM act=9.58 Rsp=1.75 X1 d1 g s sp Tj1 S5_60_f_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ037N06LS5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=268u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=3.7m gmin=39 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_j2_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ040N06LS5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=513u Rg=1.6 Rd=20u Rm=150u .PARAM Inn=20 Unn=10 Rmax=4.0m gmin=38 .PARAM act=3.59 Rsp=1 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ065N06LS5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=465u Rg=1.2 Rd=20u Rm=102u .PARAM Inn=20 Unn=10 Rmax=6.5m gmin=29 .PARAM act=2.04 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSZ099N06LS5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.3n Ld=100p Lg=1.2n .PARAM Rs=860u Rg=1.1 Rd=20u Rm=363u .PARAM Inn=20 Unn=10 Rmax=9.9m gmin=24 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC027N06LS5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=213u Rg=1.3 Rd=20u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.7m gmin=71 .PARAM act=4.94 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC065N06LS5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=332u Rg=1.2 Rd=20u Rm=140u .PARAM Inn=32 Unn=10 Rmax=6.5m gmin=36.91 .PARAM act=2.04 Rsp=0.7 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT BSC094N06LS5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=323u Rg=1.1 Rd=20u Rm=131u .PARAM Inn=24 Unn=10 Rmax=9.4m gmin=26.43 .PARAM act=1.37 Rsp=0.6 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IRL60HS118_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=0.3n Ld=1n Lg=3n .PARAM Rs=2.25m Rg=1.2 Rd=20u Rm=257u .PARAM Inn=11 Unn=10 Rmax=17m gmin=13.49 .PARAM act=0.915 Rsp=0.6 X1 d1 g s sp Tj1 S5_60_j1_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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)} E2 Tj w VALUE={TEMP} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE ={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISC009N06LM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=168u Rg=2.5 Rd=10u Rm=35u .PARAM Inn=50 Unn=10 Rmax=900u gmin=108 .PARAM act=14.73 Rsp=1.6 X1 d1 g s sp Tj1 S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISC011N06LM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=2.2n .PARAM Rs=176u Rg=2.1 Rd=10u Rm=38u .PARAM Inn=50 Unn=10 Rmax=1.1m gmin=116 .PARAM act=11.92 Rsp=1.2 X1 d1 g s sp Tj1 S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISC0702NLS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=350p Ld=100p Lg=2.2n .PARAM Rs=223u Rg=1.3 Rd=10u Rm=42u .PARAM Inn=50 Unn=10 Rmax=2.8m gmin=55 .PARAM act=3.794 Rsp=1.24 X1 d1 g s sp Tj1 S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISC0703NLS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=460p Ld=100p Lg=2.2n .PARAM Rs=284u Rg=1.2 Rd=10u Rm=96u .PARAM Inn=32 Unn=10 Rmax=6.9m gmin=27 .PARAM act=1.445 Rsp=0.98 X1 d1 g s sp Tj1 S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISZ0702NLS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=300p Ld=100p Lg=1.2n .PARAM Rs=836u Rg=1.8 Rd=20u Rm=298u .PARAM Inn=20 Unn=10 Rmax=4.5m gmin=29 .PARAM act=2.591 Rsp=1.84 X1 d1 g s sp Tj1 S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISZ0703NLS_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=300p Ld=100p Lg=1.2n .PARAM Rs=824u Rg=1.3 Rd=20u Rm=286u .PARAM Inn=20 Unn=10 Rmax=7.3m gmin=27 .PARAM act=1.445 Rsp=0.98 X1 d1 g s sp Tj1 S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT ISZ034N06LM5_L1 drain gate source PARAMS: dVth=0 dRdson=0 dgfs=0 dC=0 Ls=250p Ld=100p Lg=1.2n .PARAM Rs=488u Rg=1.8 Rd=20u Rm=104u .PARAM Inn=20 Unn=10 Rmax=3.4m gmin=34 .PARAM act=3.59 Rsp=1.86 X1 d1 g s sp Tj1 S5_60_j3_var PARAMS: a={act} Rsp={Rsp} dVth={dVth} dR={dRdson} dgfs={dgfs} Inn={Inn} Unn={Unn} +Rmax={Rmax} gmin={gmin} Rs={Rs} Rp={Rd} dC={dC} Rm={Rm} 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} Vp Tj1 Tj 0 R1 Tj Tj1 1u G_power 0 Tj VALUE={V(s1,s)*V(s1,s)/(Rs*(1+(limit(V(Tj),-200,999)-25)*4m)-Rm)+V(g,g1)*V(g,g1)/Rg+V(d1,d2)*V(d1,d2)/Rd+I(Vp)} R2 w 0 1u .ENDS ********** .SUBCKT IPT009N06NM5_L0 drain gate source Lg gate g1 2.7n Ld drain d1 0.1n Ls source s1 0.5n Rs s1 s2 234u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1103 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.39m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=5.52n VJ=2.5V) Rsp s2 s3 0.8 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=12.72n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=94.6p N=1.12 RS=0.02u EG=1.12 TT=3n) Rdiode d1 21 0.28m TC=3m .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 2.79n .MODEL DGD D(M=0.4 CJO=2.79n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 12.21n .ENDS IPT009N06NM5_L0 ***************** .SUBCKT IPTC007N06NM5_L0 drain gate source Lg gate g1 4.4n Ld drain d1 0.6n Ls source s1 0.9n Rs s1 s2 224u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1398 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.32m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=6.99n VJ=2.5V) Rsp s2 s3 0.8 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=15.99n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=119.9p N=1.12 RS=0.02u EG=1.12 TT=3n) Rdiode d1 21 0.22m TC=3m .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 3.52n .MODEL DGD D(M=0.51 CJO=3.52n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 15.46n .ENDS IPTC007N06NM5_L0 ***************** .SUBCKT IPTC012N06NM5_L0 drain gate source Lg gate g1 4.4n Ld drain d1 0.6n Ls source s1 1n Rs s1 s2 246u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=712.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.6m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.56n VJ=2.5V) Rsp s2 s3 0.9 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.36n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=61.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.44m TC=3m .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 1.65n .MODEL DGD D(M=0.4 CJO=1.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 7.7n .ENDS IPTC012N06NM5_L0 ***************** .SUBCKT IQD009N06NM5CGSC_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.5 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=796.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.51m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.58 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.39m TC=3m .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 2.02n .MODEL DGD D(M=0.5 CJO=2.02n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.84n .ENDS IQD009N06NM5CGSC_L0 ***************** .SUBCKT IQD009N06NM5CG_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.5 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=796.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.51m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.58 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.39m TC=3m .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 2.02n .MODEL DGD D(M=0.5 CJO=2.02n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.84n .ENDS IQD009N06NM5CG_L0 ***************** .SUBCKT IQD009N06NM5SC_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.5 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=796.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.51m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.58 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.39m TC=3m .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 2.02n .MODEL DGD D(M=0.5 CJO=2.02n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.84n .ENDS IQD009N06NM5SC_L0 ***************** .SUBCKT IQD009N06NM5_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.5 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=796.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.51m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.58 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.39m TC=3m .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 2.02n .MODEL DGD D(M=0.5 CJO=2.02n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.84n .ENDS IQD009N06NM5_L0 ***************** .SUBCKT IQDH88N06LM5CGSC_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 0.55 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1162.9 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.56m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.29 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.06 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.31m TC=3m .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 2.73n .MODEL DGD D(M=0.55 CJO=2.73n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 10.56n .ENDS IQDH88N06LM5CGSC_L0 ***************** .SUBCKT IQDH88N06LM5CG_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 0.55 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1162.9 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.56m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.29 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.06 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.31m TC=3m .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 2.73n .MODEL DGD D(M=0.55 CJO=2.73n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 10.56n .ENDS IQDH88N06LM5CG_L0 ***************** .SUBCKT IQDH88N06LM5SC_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 0.55 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1162.9 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.56m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.29 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.06 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.31m TC=3m .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 2.73n .MODEL DGD D(M=0.55 CJO=2.73n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 10.56n .ENDS IQDH88N06LM5SC_L0 ***************** .SUBCKT IQDH88N06LM5_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 0.55 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1162.9 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.56m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 0.29 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=68.3p N=1.06 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.31m TC=3m .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 2.73n .MODEL DGD D(M=0.55 CJO=2.73n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 10.56n .ENDS IQDH88N06LM5_L0 ***************** .SUBCKT IQE022N06LM5CGSC_L0 drain gate source Lg gate g1 1n Ld drain d1 250p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=526.9 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.5m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.29n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.25n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=20.5p N=1.06 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 0.73m TC=3m .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 1.33n .MODEL DGD D(M=0.65 CJO=1.33n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 3.4n .ENDS IQE022N06LM5CGSC_L0 ***************** .SUBCKT IQE022N06LM5CG_L0 drain gate source Lg gate g1 1n Ld drain d1 250p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=526.9 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.5m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.29n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.25n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=20.5p N=1.06 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 0.73m TC=3m .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 1.33n .MODEL DGD D(M=0.65 CJO=1.33n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 3.4n .ENDS IQE022N06LM5CG_L0 ***************** .SUBCKT IQE022N06LM5SC_L0 drain gate source Lg gate g1 1n Ld drain d1 250p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=526.9 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.5m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.29n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.25n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=20.5p N=1.06 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 0.73m TC=3m .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 1.33n .MODEL DGD D(M=0.65 CJO=1.33n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 3.4n .ENDS IQE022N06LM5SC_L0 ***************** .SUBCKT IQE022N06LM5_L0 drain gate source Lg gate g1 1n Ld drain d1 250p Ls source s1 100p Rs s1 s2 11u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=526.9 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.5m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.29n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.25n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=20.5p N=1.06 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 0.73m TC=3m .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 1.33n .MODEL DGD D(M=0.65 CJO=1.33n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 3.4n .ENDS IQE022N06LM5_L0 ***************** .SUBCKT IQFH68N06NM5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 57u TC=3m Rg g1 g2 0.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1086.7 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.33m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=5.43n VJ=2.5V) Rsp s2 s3 0.18 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=12.54n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=93.2p N=1.12 RS=0.02u EG=1.12 TT=3n) Rdiode d1 21 0.29m TC=3m .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 2.74n .MODEL DGD D(M=0.4 CJO=2.74n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 12.03n .ENDS IQFH68N06NM5_L0 ***************** .SUBCKT IQFH86N06NM5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 125u TC=3m Rg g1 g2 0.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=879.8 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.41m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=4.4n VJ=2.5V) Rsp s2 s3 0.23 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=10.23n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=75.5p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.35m TC=3m .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 2.23n .MODEL DGD D(M=0.4 CJO=2.23n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 9.76n .ENDS IQFH86N06NM5_L0 ***************** .SUBCKT IQFH99N06NM5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 125u TC=3m Rg g1 g2 0.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=736.7 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.49m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.68n VJ=2.5V) Rsp s2 s3 2.57 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.64n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=63.2p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.42m TC=3m .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 1.87n .MODEL DGD D(M=0.4 CJO=1.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.18n .ENDS IQFH99N06NM5_L0 ***************** .SUBCKT ISC010N06NM5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 300p Rs s1 s2 159u TC=3m Rg g1 g2 2.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=736.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.49m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.68n VJ=2.5V) Rsp s2 s3 1.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.63n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=63.2p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.42m TC=3m .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 1.87n .MODEL DGD D(M=0.4 CJO=1.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.18n .ENDS ISC010N06NM5_L0 ***************** .SUBCKT BSC012N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 158u TC=3m Rg g1 g2 2.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 736.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.5m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.68n VJ=2.5V) Rsp s2 s3 1.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.63n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=63.2p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.42m TC=3m .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 1.87n .MODEL DGD D(M=0.4 CJO=1.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.18n .ENDS BSC012N06NS_L0 ****** .SUBCKT BSC014N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 0.3n Rs s1 s2 297u TC=3m Rg g1 g2 2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 596 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.62m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.98n VJ=2.5V) Rsp s2 s3 1.2 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=7.06n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=51.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.52m TC=3m .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 1.38n .MODEL DGD D(M=0.4 CJO=1.38n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 6.44n .ENDS BSC014N06NS_L0 ****** .SUBCKT BSC014N06NSSC_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 127u TC=3m Rg g1 g2 2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=596 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.61m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.98n VJ=2.5V) Rsp s2 s3 1.2 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=7.06n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=51.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.52m TC=3m .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 1.38n .MODEL DGD D(M=0.4 CJO=1.38n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 6.44n .ENDS BSC014N06NSSC_L0 ***************** .SUBCKT BSC014N06NST_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 300p Rs s1 s2 297u TC=3m Rg g1 g2 2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 596 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.62m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.98n VJ=2.5V) Rsp s2 s3 1.2 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=7.06n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=51.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.52m TC=3m .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 1.38n .MODEL DGD D(M=0.4 CJO=1.38n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 6.44n .ENDS BSC014N06NST_L0 ****** .SUBCKT BSC016N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 273u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 475 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.77m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.38n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=5.69n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=40.8p N=1.12 RS=0.05u EG=1.12 TT=3n) Rdiode d1 21 0.65m TC=3m .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 1.1n .MODEL DGD D(M=0.4 CJO=1.1n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 5.13n .ENDS BSC016N06NS_L0 ****** .SUBCKT BSC016N06NST_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 273u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 475 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.77m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.38n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=5.69n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=40.8p N=1.12 RS=0.05u EG=1.12 TT=3n) Rdiode d1 21 0.65m TC=3m .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 1.1n .MODEL DGD D(M=0.4 CJO=1.1n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 5.13n .ENDS BSC016N06NST_L0 ****** .SUBCKT BSC028N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 213u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 247 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.46m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.08n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.2p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.26m TC=3m .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 0.57n .MODEL DGD D(M=0.4 CJO=0.57n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.67n .ENDS BSC028N06NS_L0 ****** .SUBCKT BSC028N06NST_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 213u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 247 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.46m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.08n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.2p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.26m TC=3m .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 0.57n .MODEL DGD D(M=0.4 CJO=0.57n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.67n .ENDS BSC028N06NST_L0 ****** .SUBCKT BSC028N06NSSC_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 140u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=247 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.45m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.08n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.2p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.26m TC=3m .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 0.57n .MODEL DGD D(M=0.4 CJO=0.57n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.67n .ENDS BSC028N06NSSC_L0 ***************** .SUBCKT BSC019N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 251u TC=3m Rg g1 g2 1.7 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 367.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.99m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.84n VJ=2.5V) Rsp s2 s3 0.9 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=4.47n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=31.5p N=1.12 RS=0.07u EG=1.12 TT=3n) Rdiode d1 21 0.84m TC=3m .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 0.95n .MODEL DGD D(M=0.4 CJO=0.95n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.12n .ENDS BSC019N06NS_L0 ****** .SUBCKT BSC034N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 216u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 206.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.74m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.03n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.61n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=17.7p N=1.12 RS=0.12u EG=1.12 TT=3n) Rdiode d1 21 1.5m TC=3m .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 0.54n .MODEL DGD D(M=0.4 CJO=0.54n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.35n .ENDS BSC034N06NS_L0 ****** .SUBCKT BSC039N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 460p Rs s1 s2 365u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS BSC039N06NS_L0 ****** .SUBCKT BSZ039N06NS_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 268u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS BSZ039N06NS_L0 ***************** .SUBCKT BSZ042N06NS_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 513u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS BSZ042N06NS_L0 ****** .SUBCKT BSC066N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 460p Rs s1 s2 332u TC=3m Rg g1 g2 1.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 102 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 3.5m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.51n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=1.38n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=8.8p N=1.12 RS=0.25u EG=1.12 TT=3n) Rdiode d1 21 3.04m TC=3m .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 0.28n .MODEL DGD D(M=0.4 CJO=0.28n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.2n .ENDS BSC066N06NS_L0 ****** .SUBCKT BSZ068N06NS_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 0.3n Rs s1 s2 465u TC=3m Rg g1 g2 1.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 102 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 3.5m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.51n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=1.38n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=8.8p N=1.12 RS=0.25u EG=1.12 TT=3n) Rdiode d1 21 3.04m TC=3m .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 0.28n .MODEL DGD D(M=0.4 CJO=0.28n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.2n .ENDS BSZ068N06NS_L0 ****** .SUBCKT BSC097N06NS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 460p Rs s1 s2 323u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 68.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 5.2m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.34n VJ=2.5V) Rsp s2 s3 0.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=0.97n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=5.9p N=1.12 RS=0.36u EG=1.12 TT=3n) Rdiode d1 21 4.53m TC=3m .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 0.19n .MODEL DGD D(M=0.4 CJO=0.19n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 0.83n .ENDS BSC097N06NS_L0 ****** .SUBCKT BSC097N06NST_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 460p Rs s1 s2 323u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 68.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 5.2m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.34n VJ=2.5V) Rsp s2 s3 0.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=0.97n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=5.9p N=1.12 RS=0.36u EG=1.12 TT=3n) Rdiode d1 21 4.53m TC=3m .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 0.19n .MODEL DGD D(M=0.4 CJO=0.19n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 0.83n .ENDS BSC097N06NST_L0 ****** .SUBCKT BSZ100N06NS_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 0.3n Rs s1 s2 860u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 68.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 5.2m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.34n VJ=2.5V) Rsp s2 s3 0.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=0.97n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=5.9p N=1.12 RS=0.36u EG=1.12 TT=3n) Rdiode d1 21 4.53m TC=3m .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 0.19n .MODEL DGD D(M=0.4 CJO=0.19n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 0.83n .ENDS BSZ100N06NS_L0 ****** .SUBCKT IPD025N06N_L0 drain gate source Lg gate g1 3n Ld drain d1 1n Ls source s1 1.5n Rs s1 s2 878u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 475 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.87m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.38n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=5.69n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=40.8p N=1.12 RS=0.05u EG=1.12 TT=3n) Rdiode d1 21 0.65m TC=3m .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 1.1n .MODEL DGD D(M=0.4 CJO=1.1n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 5.13n .ENDS IPD025N06N_L0 ****** .SUBCKT IPT007N06N_L0 drain gate source Lg gate g1 2.7n Ld drain d1 0.1n Ls source s1 0.5n Rs s1 s2 234u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 1398 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.27m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=6.99n VJ=2.5V) Rsp s2 s3 0.8 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=15.99n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=119.9p N=1.12 RS=0.02u EG=1.12 TT=3n) Rdiode d1 21 0.22m TC=3m .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 3.52n .MODEL DGD D(M=0.4 CJO=3.52n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 15.46n .ENDS IPT007N06N_L0 ****** .SUBCKT IPB010N06N_L0 drain gate source Lg gate g1 6.5n Ld drain d1 0.1n Ls source s1 1.9n Rs s1 s2 395u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 1400.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.31m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=7n VJ=2.5V) Rsp s2 s3 0.8 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=16.02n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=120.2p N=1.12 RS=0.02u EG=1.12 TT=3n) Rdiode d1 21 0.22m TC=3m .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 3.25n .MODEL DGD D(M=0.4 CJO=3.25n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 15.13n .ENDS IPB010N06N_L0 ****** .SUBCKT IPT012N06N_L0 drain gate source Lg gate g1 2.7n Ld drain d1 0.1n Ls source s1 0.7n Rs s1 s2 213u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 712.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.59m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.56n VJ=2.5V) Rsp s2 s3 0.9 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.36n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=61.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.44m TC=3m .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 1.65n .MODEL DGD D(M=0.4 CJO=1.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 7.7n .ENDS IPT012N06N_L0 ****** .SUBCKT IPB014N06N_L0 drain gate source Lg gate g1 6.5n Ld drain d1 0.1n Ls source s1 1.9n Rs s1 s2 360u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 712.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.59m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.56n VJ=2.5V) Rsp s2 s3 0.9 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.36n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=61.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.44m TC=3m .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 1.65n .MODEL DGD D(M=0.4 CJO=1.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 7.7n .ENDS IPB014N06N_L0 ****** .SUBCKT IPI020N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 1.8n Rs s1 s2 617u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 712.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.92m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.56n VJ=2.5V) Rsp s2 s3 0.9 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.36n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=61.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.44m TC=3m .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 1.65n .MODEL DGD D(M=0.4 CJO=1.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 7.7n .ENDS IPI020N06N_L0 ****** .SUBCKT IPP020N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 1.8n Rs s1 s2 617u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 712.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.92m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.56n VJ=2.5V) Rsp s2 s3 0.9 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.36n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=61.1p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.44m TC=3m .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 1.65n .MODEL DGD D(M=0.4 CJO=1.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 7.7n .ENDS IPP020N06N_L0 ****** .SUBCKT IPA029N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 1.8n Rs s1 s2 721u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 376 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.43m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.88n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=4.56n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=32.3p N=1.12 RS=0.07u EG=1.12 TT=3n) Rdiode d1 21 0.82m TC=3m .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 0.87n .MODEL DGD D(M=0.4 CJO=0.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.06n .ENDS IPA029N06N_L0 ****** .SUBCKT IPA029N06NM5S_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 2n Rs s1 s2 977u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=376 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.43m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.88n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=4.56n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=32.3p N=1.12 RS=0.07u EG=1.12 TT=3n) Rdiode d1 21 0.82m TC=3m .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 0.87n .MODEL DGD D(M=0.4 CJO=0.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.06n .ENDS IPA029N06NM5S_L0 ***************** .SUBCKT IPB026N06N_L0 drain gate source Lg gate g1 6.5n Ld drain d1 0.1n Ls source s1 3.6n Rs s1 s2 721u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 376 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.13m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.88n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=4.56n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=32.3p N=1.12 RS=0.07u EG=1.12 TT=3n) Rdiode d1 21 0.82m TC=3m .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 0.87n .MODEL DGD D(M=0.4 CJO=0.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.06n .ENDS IPB026N06N_L0 ****** .SUBCKT IPI029N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 1.8n Rs s1 s2 721u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 376 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.43m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.88n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=4.56n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=32.3p N=1.12 RS=0.07u EG=1.12 TT=3n) Rdiode d1 21 0.82m TC=3m .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 0.87n .MODEL DGD D(M=0.4 CJO=0.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.06n .ENDS IPI029N06N_L0 ****** .SUBCKT IPD033N06N_L0 drain gate source Lg gate g1 3n Ld drain d1 1n Ls source s1 1.5n Rs s1 s2 690u TC=3m Rg g1 g2 1.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 251.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.63m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.26n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.13n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.6p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.23m TC=3m .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 0.58n .MODEL DGD D(M=0.4 CJO=0.58n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.72n .ENDS IPD033N06N_L0 ****** .SUBCKT IPP029N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 1.8n Rs s1 s2 721u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 376 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.43m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.88n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=4.56n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=32.3p N=1.12 RS=0.07u EG=1.12 TT=3n) Rdiode d1 21 0.82m TC=3m .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 0.87n .MODEL DGD D(M=0.4 CJO=0.87n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.06n .ENDS IPP029N06N_L0 ****** .SUBCKT IPA040N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 2n Rs s1 s2 960u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 251.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.96m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.26n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.13n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.6p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.23m TC=3m .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 0.58n .MODEL DGD D(M=0.4 CJO=0.58n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.72n .ENDS IPA040N06N_L0 ****** .SUBCKT IPA040N06NM5S_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 2n Rs s1 s2 960u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=251.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.96m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.26n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.13n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.6p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.23m TC=3m .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 0.58n .MODEL DGD D(M=0.4 CJO=0.58n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.72n .ENDS IPA040N06NM5S_L0 ***************** .SUBCKT IPP040N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 2n Rs s1 s2 960u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 251.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.96m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.26n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.13n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.6p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.23m TC=3m .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 0.58n .MODEL DGD D(M=0.4 CJO=0.58n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.72n .ENDS IPP040N06N_L0 ****** .SUBCKT IPB057N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 1n Ls source s1 2.5n Rs s1 s2 1.68m TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.31m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS IPB057N06N_L0 ****** .SUBCKT IPD053N06N_L0 drain gate source Lg gate g1 3n Ld drain d1 1n Ls source s1 2n Rs s1 s2 1.33m TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.28m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS IPD053N06N_L0 ****** .SUBCKT IPA060N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 2.5n Rs s1 s2 1.68m TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.61m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS IPA060N06N_L0 ****** .SUBCKT IPA060N06NM5S_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 2.5n Rs s1 s2 1.68m TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.61m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS IPA060N06NM5S_L0 ***************** .SUBCKT IPP060N06N_L0 drain gate source Lg gate g1 4n Ld drain d1 2.5n Ls source s1 2.5n Rs s1 s2 1.68m TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 179.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.61m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.12 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.73m TC=3m .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 0.42n .MODEL DGD D(M=0.4 CJO=0.42n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.94n .ENDS IPP060N06N_L0 ****** .SUBCKT BSZ037N06LS5_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 268u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=262.1 VTO=2.5 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.19m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.06 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.39m TC=3m .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 0.65n .MODEL DGD D(M=0.55 CJO=0.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.42n .ENDS BSZ037N06LS5_L0 ***************** .SUBCKT BSZ040N06LS5_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 513u TC=3m Rg g1 g2 1.6 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 262.1 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.19m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.9n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.3n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.06 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 1.39m TC=3m .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 0.65n .MODEL DGD D(M=0.55 CJO=0.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.42n .ENDS BSZ040N06LS5_L0 ****** .SUBCKT BSZ065N06LS5_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 0.3n Rs s1 s2 465u TC=3m Rg g1 g2 1.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 148.9 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 3.84m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.51n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=1.38n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=8.8p N=1.06 RS=0.25u EG=1.12 TT=3n) Rdiode d1 21 2.45m TC=3m .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 0.38n .MODEL DGD D(M=0.55 CJO=0.38n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.4n .ENDS BSZ065N06LS5_L0 ****** .SUBCKT BSZ099N06LS5_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 0.3n Rs s1 s2 860u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 100 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 5.71m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.34n VJ=2.5V) Rsp s2 s3 0.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=0.97n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=5.9p N=1.06 RS=0.36u EG=1.12 TT=3n) Rdiode d1 21 3.65m TC=3m .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 0.26n .MODEL DGD D(M=0.55 CJO=0.26n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 0.95n .ENDS BSZ099N06LS5_L0 ****** .SUBCKT BSC027N06LS5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 213u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 360.6 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.6m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.08n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.2p N=1.06 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.01m TC=3m .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 0.88n .MODEL DGD D(M=0.55 CJO=0.88n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 3.31n .ENDS BSC027N06LS5_L0 ****** .SUBCKT BSC065N06LS5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 460p Rs s1 s2 332u TC=3m Rg g1 g2 1.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 148.9 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 3.84m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.51n VJ=2.5V) Rsp s2 s3 0.7 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=1.38n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=8.8p N=1.06 RS=0.25u EG=1.12 TT=3n) Rdiode d1 21 2.45m TC=3m .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 0.38n .MODEL DGD D(M=0.55 CJO=0.38n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.4n .ENDS BSC065N06LS5_L0 ****** .SUBCKT BSC094N06LS5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 460p Rs s1 s2 323u TC=3m Rg g1 g2 1.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 100 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 5.71m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.34n VJ=2.5V) Rsp s2 s3 0.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=0.97n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=5.9p N=1.06 RS=0.36u EG=1.12 TT=3n) Rdiode d1 21 3.65m TC=3m .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 0.26n .MODEL DGD D(M=0.55 CJO=0.26n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 0.95n .ENDS BSC094N06LS5_L0 ****** .SUBCKT IRL60HS118_L0 drain gate source Lg gate g1 3n Ld drain d1 1n Ls source s1 0.3n Rs s1 s2 2.25m TC=3m Rg g1 g2 1.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP= 66.8 VTO=2.42 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 8.54m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.23n VJ=2.5V) Rsp s2 s3 0.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=0.68n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=3.9p N=1.06 RS=0.55u EG=1.12 TT=3n) Rdiode d1 21 5.46m TC=3m .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 0.18n .MODEL DGD D(M=0.55 CJO=0.18n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 0.65n .ENDS IRL60HS118_L0 ****** .SUBCKT BSC016N06NSSC_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 122u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=475 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.76m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.38n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=5.69n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=40.8p N=1.12 RS=0.05u EG=1.12 TT=3n) Rdiode d1 21 0.65m TC=3m .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 1.1n .MODEL DGD D(M=0.4 CJO=1.1n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 5.13n .ENDS BSC016N06NSSC_L0 ***************** .SUBCKT IPTG007N06NM5_L0 drain gate source Lg gate g1 4.6n Ld drain d1 0.1n Ls source s1 1.1n Rs s1 s2 252u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1398 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.31m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=6.99n VJ=2.5V) Rsp s2 s3 0.8 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=15.99n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=119.9p N=1.12 RS=0.02u EG=1.12 TT=3n) Rdiode d1 21 0.22m TC=3m .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 3.52n .MODEL DGD D(M=0.51 CJO=3.52n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 15.46n .ENDS IPTG007N06NM5_L0 ***************** .SUBCKT IQE030N06NM5_L0 drain gate source Lg gate g1 1n Ld drain d1 0.25n Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.9 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=248.4 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.53m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.1n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.3p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.25m TC=3m .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 0.65n .MODEL DGD D(M=0.5 CJO=0.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.81n .ENDS IQE030N06NM5_L0 ***************** .SUBCKT IQE030N06NM5CG_L0 drain gate source Lg gate g1 1n Ld drain d1 0.25n Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.9 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=248.4 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.53m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.1n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.3p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.25m TC=3m .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 0.65n .MODEL DGD D(M=0.5 CJO=0.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.81n .ENDS IQE030N06NM5CG_L0 ***************** .SUBCKT IQE030N06NM5CGSC_L0 drain gate source Lg gate g1 1n Ld drain d1 0.25n Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.9 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=248.4 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.53m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.1n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.3p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.25m TC=3m .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 0.65n .MODEL DGD D(M=0.5 CJO=0.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.81n .ENDS IQE030N06NM5CGSC_L0 ***************** .SUBCKT IQE030N06NM5SC_L0 drain gate source Lg gate g1 1n Ld drain d1 0.25n Ls source s1 100p Rs s1 s2 61u TC=3m Rg g1 g2 0.9 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=248.4 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.53m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.24n VJ=2.5V) Rsp s2 s3 0.85 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=3.1n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=21.3p N=1.12 RS=0.1u EG=1.12 TT=3n) Rdiode d1 21 1.25m TC=3m .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 0.65n .MODEL DGD D(M=0.5 CJO=0.65n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.81n .ENDS IQE030N06NM5SC_L0 ***************** .SUBCKT ISC009N06LM5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 168u TC=3m Rg g1 g2 2.5 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1620.3 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.47m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.98n VJ=2.5V) Rsp s2 s3 1.6 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=9.18n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=63.2p N=1.06 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.24m TC=3m .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 3.64n .MODEL DGD D(M=0.65 CJO=3.64n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 10.36n .ENDS ISC009N06LM5_L0 ***************** .SUBCKT ISC011N06LM5_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 176u TC=3m Rg g1 g2 2.1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=1311.2 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.58m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.22n VJ=2.5V) Rsp s2 s3 1.2 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=7.52n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=51.1p N=1.06 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.29m TC=3m .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 3n .MODEL DGD D(M=0.65 CJO=3n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8.39n .ENDS ISC011N06LM5_L0 ***************** .SUBCKT ISC015N06NM5LF2_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 159u TC=3m Rg g1 g2 2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=36 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) M2 d2 g2 s2 s2 DMOS1 L=1u W=1u .MODEL DMOS1 NMOS ( KP=54.5 VTO=5.2 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) M3 d2 g2 s2 s2 DMOS2 L=1u W=1u .MODEL DMOS2 NMOS ( KP=272.6 VTO=6.4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.46m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.13n VJ=2.5V) Rsp s2 s3 2.15 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=6.48n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=49.8p N=1.12 RS=0.04u EG=1.12 TT=3n) Rdiode d1 21 0.53m TC=3m .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 1.48n .MODEL DGD D(M=0.5 CJO=1.48n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 6.46n .ENDS ISC015N06NM5LF2_L0 ***************** .SUBCKT ISC0702NLS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 350p Rs s1 s2 223u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=417.3 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.8m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=1.02n VJ=2.5V) Rsp s2 s3 1.24 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.63n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=16.3p N=1.06 RS=0.13u EG=1.12 TT=3n) Rdiode d1 21 0.92m TC=3m .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 1.09n .MODEL DGD D(M=0.65 CJO=1.09n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.71n .ENDS ISC0702NLS_L0 ***************** .SUBCKT ISC0703NLS_L0 drain gate source Lg gate g1 2.2n Ld drain d1 100p Ls source s1 460p Rs s1 s2 284u TC=3m Rg g1 g2 1.2 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=159 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 4.71m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.39n VJ=2.5V) Rsp s2 s3 0.98 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=1.13n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=6.2p N=1.06 RS=0.35u EG=1.12 TT=3n) Rdiode d1 21 2.42m TC=3m .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=0.65 CJO=0.49n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.06n .ENDS ISC0703NLS_L0 ***************** .SUBCKT ISG0614N06NM5HSC_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 31u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=431.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.88m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.16n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=5.2n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=37p N=1.12 RS=0.06u EG=1.12 TT=3n) Rdiode d1 21 0.72m TC=3m .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 1.11n .MODEL DGD D(M=0.4 CJO=1.11n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.83n .ENDS ISG0614N06NM5HSC_L0 ***************** .SUBCKT ISG0614N06NM5H_L0 drain gate source Lg gate g1 1n Ld drain d1 300p Ls source s1 100p Rs s1 s2 31u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=431.5 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.88m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.16n VJ=2.5V) Rsp s2 s3 1 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=5.2n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=37p N=1.12 RS=0.06u EG=1.12 TT=3n) Rdiode d1 21 0.72m TC=3m .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 1.11n .MODEL DGD D(M=0.4 CJO=1.11n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 4.83n .ENDS ISG0614N06NM5H_L0 ***************** .SUBCKT IST011N06NM5_L0 drain gate source Lg gate g1 3n Ld drain d1 500p Ls source s1 300p Rs s1 s2 116u TC=3m Rg g1 g2 1 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=741 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.57m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=3.71n VJ=2.5V) Rsp s2 s3 1.75 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=8.68n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=63.6p N=1.12 RS=0.03u EG=1.12 TT=3n) Rdiode d1 21 0.42m TC=3m .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 1.72n .MODEL DGD D(M=0.4 CJO=1.72n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 8n .ENDS IST011N06NM5_L0 ***************** .SUBCKT IST015N06NM5_L0 drain gate source Lg gate g1 3n Ld drain d1 500p Ls source s1 300p Rs s1 s2 128u TC=3m Rg g1 g2 1.85 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=479 VTO=4 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 0.87m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=2.4n VJ=2.5V) Rsp s2 s3 1.75 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=5.73n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=41.1p N=1.12 RS=0.05u EG=1.12 TT=3n) Rdiode d1 21 0.65m TC=3m .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 1.11n .MODEL DGD D(M=0.4 CJO=1.11n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 5.17n .ENDS IST015N06NM5_L0 ***************** .SUBCKT ISZ0702NLS_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 300p Rs s1 s2 836u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=285 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 2.64m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.7n VJ=2.5V) Rsp s2 s3 1.84 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=1.88n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=11.1p N=1.06 RS=0.19u EG=1.12 TT=3n) Rdiode d1 21 1.35m TC=3m .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 0.79n .MODEL DGD D(M=0.65 CJO=0.79n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.86n .ENDS ISZ0702NLS_L0 ***************** .SUBCKT ISZ0703NLS_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 300p Rs s1 s2 824u TC=3m Rg g1 g2 1.3 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=159 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 4.72m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.39n VJ=2.5V) Rsp s2 s3 0.98 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=1.13n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=6.2p N=1.06 RS=0.35u EG=1.12 TT=3n) Rdiode d1 21 2.42m TC=3m .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=0.65 CJO=0.49n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 1.06n .ENDS ISZ0703NLS_L0 ***************** .SUBCKT ISZ034N06LM5_L0 drain gate source Lg gate g1 1.2n Ld drain d1 100p Ls source s1 250p Rs s1 s2 488u TC=3m Rg g1 g2 1.8 M1 d2 g2 s2 s2 DMOS L=1u W=1u .MODEL DMOS NMOS ( KP=394.9 VTO=2.33 THETA=0 VMAX=1.5e5 ETA=0.005 LEVEL=3) Rd d1 d2 1.91m TC=7m Dbd s2 d2 Dbt .MODEL Dbt D(BV=66 M=0.8 CJO=0.97n VJ=2.5V) Rsp s2 s3 1.86 Dbd1 s3 d2 Dbt1 .MODEL Dbt1 D(BV=1000 M=0.8 CJO=2.51n VJ=2.5V) Dbody s2 21 DBODY .MODEL DBODY D(IS=15.4p N=1.06 RS=0.14u EG=1.12 TT=3n) Rdiode d1 21 0.97m TC=3m .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=0.65 CJO=1.04n VJ=0.5) Rpar b d2 1Meg Dgd a d2 DGD Rpar2 d2 a 10Meg Cgs g2 s2 2.56n .ENDS ISZ034N06LM5_L0 *****************