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psp model 102 initial import

pre-master-46
pnenzi 19 years ago
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  1. 184
      src/spicelib/devices/adms/psp102/admsva/JUNCAP200_InitModel.include
  2. 285
      src/spicelib/devices/adms/psp102/admsva/JUNCAP200_macrodefs.include
  3. 65
      src/spicelib/devices/adms/psp102/admsva/JUNCAP200_parlist.include
  4. 67
      src/spicelib/devices/adms/psp102/admsva/JUNCAP200_varlist.include
  5. 303
      src/spicelib/devices/adms/psp102/admsva/PSP102_ChargesNQS.include
  6. 190
      src/spicelib/devices/adms/psp102/admsva/PSP102_InitNQS.include
  7. 127
      src/spicelib/devices/adms/psp102/admsva/PSP102_binning.include
  8. 233
      src/spicelib/devices/adms/psp102/admsva/PSP102_binpars.include
  9. 250
      src/spicelib/devices/adms/psp102/admsva/PSP102_macrodefs.include
  10. 2356
      src/spicelib/devices/adms/psp102/admsva/PSP102_module.include
  11. 117
      src/spicelib/devices/adms/psp102/admsva/PSP102_nqs_macrodefs.include
  12. 121
      src/spicelib/devices/adms/psp102/admsva/SIMKIT_macrodefs.include
  13. 48
      src/spicelib/devices/adms/psp102/admsva/psp102.va
  14. 118
      src/spicelib/devices/adms/psp102/admsva/readme.txt

184
src/spicelib/devices/adms/psp102/admsva/JUNCAP200_InitModel.include
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//======================================================================================
//======================================================================================
// Filename: JUNCAP200_InitModel.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1 (PSP), 200.2 (JUNCAP), October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
//////////////////////////////////////////////////////////////
//
// Calculation of internal paramters which are independent
// on instance parameters
//
//////////////////////////////////////////////////////////////
TRJ_i = `CLIP_LOW( TRJ , `TRJ_cliplow);
IMAX_i = `CLIP_LOW( IMAX , `IMAX_cliplow);
CJORBOT_i = `CLIP_LOW( CJORBOT , `CJORBOT_cliplow);
CJORSTI_i = `CLIP_LOW( CJORSTI , `CJORSTI_cliplow);
CJORGAT_i = `CLIP_LOW( CJORGAT , `CJORGAT_cliplow);
VBIRBOT_i = `CLIP_LOW( VBIRBOT , `VBIR_cliplow);
VBIRSTI_i = `CLIP_LOW( VBIRSTI , `VBIR_cliplow);
VBIRGAT_i = `CLIP_LOW( VBIRGAT , `VBIR_cliplow);
PBOT_i = `CLIP_BOTH(PBOT , `P_cliplow,`P_cliphigh);
PSTI_i = `CLIP_BOTH(PSTI , `P_cliplow,`P_cliphigh);
PGAT_i = `CLIP_BOTH(PGAT , `P_cliplow,`P_cliphigh);
IDSATRBOT_i = `CLIP_LOW( IDSATRBOT , `IDSATR_cliplow);
IDSATRSTI_i = `CLIP_LOW( IDSATRSTI , `IDSATR_cliplow);
IDSATRGAT_i = `CLIP_LOW( IDSATRGAT , `IDSATR_cliplow);
CSRHBOT_i = `CLIP_LOW( CSRHBOT , `CSRH_cliplow);
CSRHSTI_i = `CLIP_LOW( CSRHSTI , `CSRH_cliplow);
CSRHGAT_i = `CLIP_LOW( CSRHGAT , `CSRH_cliplow);
XJUNSTI_i = `CLIP_LOW( XJUNSTI , `XJUN_cliplow);
XJUNGAT_i = `CLIP_LOW( XJUNGAT , `XJUN_cliplow);
CTATBOT_i = `CLIP_LOW( CTATBOT , `CTAT_cliplow);
CTATSTI_i = `CLIP_LOW( CTATSTI , `CTAT_cliplow);
CTATGAT_i = `CLIP_LOW( CTATGAT , `CTAT_cliplow);
MEFFTATBOT_i = `CLIP_LOW( MEFFTATBOT, `MEFFTAT_cliplow);
MEFFTATSTI_i = `CLIP_LOW( MEFFTATSTI, `MEFFTAT_cliplow);
MEFFTATGAT_i = `CLIP_LOW( MEFFTATGAT, `MEFFTAT_cliplow);
CBBTBOT_i = `CLIP_LOW( CBBTBOT , `CBBT_cliplow);
CBBTSTI_i = `CLIP_LOW( CBBTSTI , `CBBT_cliplow);
CBBTGAT_i = `CLIP_LOW( CBBTGAT , `CBBT_cliplow);
VBRBOT_i = `CLIP_LOW( VBRBOT , `VBR_cliplow);
VBRSTI_i = `CLIP_LOW( VBRSTI , `VBR_cliplow);
VBRGAT_i = `CLIP_LOW( VBRGAT , `VBR_cliplow);
PBRBOT_i = `CLIP_LOW( PBRBOT , `PBR_cliplow);
PBRSTI_i = `CLIP_LOW( PBRSTI , `PBR_cliplow);
PBRGAT_i = `CLIP_LOW( PBRGAT , `PBR_cliplow);
tkr = `KELVINCONVERSION + TRJ_i;
tkd = max($temperature + DTA, `KELVINCONVERSION + `MINTEMP);
auxt = tkd / tkr;
KBOL_over_QELE = `KBOL / `QELE;
phitr = KBOL_over_QELE * tkr;
phitrinv = 1.0 / phitr;
phitd = KBOL_over_QELE * tkd;
phitdinv = 1.0 / phitd;
// bandgap voltages at reference temperature
deltaphigr = -(7.02e-4 * tkr * tkr) / (1108.0 + tkr);
phigrbot = PHIGBOT + deltaphigr;
phigrsti = PHIGSTI + deltaphigr;
phigrgat = PHIGGAT + deltaphigr;
// bandgap voltages at device temperature
deltaphigd = -(7.02e-4 * tkd * tkd) / (1108.0 + tkd);
phigdbot = PHIGBOT + deltaphigd;
phigdsti = PHIGSTI + deltaphigd;
phigdgat = PHIGGAT + deltaphigd;
// factors ftd for ideal-current model
ftdbot = (pow(auxt, 1.5)) * exp(0.5 * ((phigrbot * phitrinv) - (phigdbot * phitdinv)));
ftdsti = (pow(auxt, 1.5)) * exp(0.5 * ((phigrsti * phitrinv) - (phigdsti * phitdinv)));
ftdgat = (pow(auxt, 1.5)) * exp(0.5 * ((phigrgat * phitrinv) - (phigdgat * phitdinv)));
// temperature-scaled saturation current for ideal-current model
idsatbot = IDSATRBOT_i * ftdbot * ftdbot;
idsatsti = IDSATRSTI_i * ftdsti * ftdsti;
idsatgat = IDSATRGAT_i * ftdgat * ftdgat;
// built-in voltages before limiting
ubibot = VBIRBOT_i * auxt - 2 * phitd * ln(ftdbot);
ubisti = VBIRSTI_i * auxt - 2 * phitd * ln(ftdsti);
ubigat = VBIRGAT_i * auxt - 2 * phitd * ln(ftdgat);
// built-in voltages limited to phitd
vbibot = ubibot + phitd * ln(1 + exp((`vbilow - ubibot) * phitdinv));
vbisti = ubisti + phitd * ln(1 + exp((`vbilow - ubisti) * phitdinv));
vbigat = ubigat + phitd * ln(1 + exp((`vbilow - ubigat) * phitdinv));
// inverse values of built-in voltages
vbiinvbot = 1.0 / vbibot;
vbiinvsti = 1.0 / vbisti;
vbiinvgat = 1.0 / vbigat;
// one minus the grading coefficient
one_minus_PBOT = 1 - PBOT_i;
one_minus_PSTI = 1 - PSTI_i;
one_minus_PGAT = 1 - PGAT_i;
// one over "one minus the grading coefficient"
one_over_one_minus_PBOT = 1 / one_minus_PBOT;
one_over_one_minus_PSTI = 1 / one_minus_PSTI;
one_over_one_minus_PGAT = 1 / one_minus_PGAT;
// temperature-scaled zero-bias capacitance
cjobot = CJORBOT_i * pow((VBIRBOT_i * vbiinvbot), PBOT_i);
cjosti = CJORSTI_i * pow((VBIRSTI_i * vbiinvsti), PSTI_i);
cjogat = CJORGAT_i * pow((VBIRGAT_i * vbiinvgat), PGAT_i);
// prefactor in physical part of charge model
qprefbot = cjobot * vbibot * one_over_one_minus_PBOT;
qprefsti = cjosti * vbisti * one_over_one_minus_PSTI;
qprefgat = cjogat * vbigat * one_over_one_minus_PGAT;
// prefactor in mathematical extension of charge model
qpref2bot = `a * cjobot;
qpref2sti = `a * cjosti;
qpref2gat = `a * cjogat;
// zero-bias depletion widths at reference temperature, needed in SRH and TAT model
wdepnulrbot = `EPSSI / CJORBOT_i;
wdepnulrsti = XJUNSTI_i * `EPSSI / CJORSTI_i;
wdepnulrgat = XJUNGAT_i * `EPSSI / CJORGAT_i;
// inverse values of "wdepnulr", used in BBT model
wdepnulrinvbot = 1 / wdepnulrbot;
wdepnulrinvsti = 1 / wdepnulrsti;
wdepnulrinvgat = 1 / wdepnulrgat;
// inverse values of built-in voltages at reference temperature, needed in SRH and BBT model
VBIRBOTinv = 1 / VBIRBOT_i;
VBIRSTIinv = 1 / VBIRSTI_i;
VBIRGATinv = 1 / VBIRGAT_i;
// some constants needed in erfc-approximation, needed in TAT model
perfc = (`SQRTPI * `aerfc);
berfc = ((-5 * (`aerfc) + 6 - pow((perfc), -2)) / 3);
cerfc = (1.0 - (`aerfc) - (berfc));
// half the bandgap energy, limited to values > phitd, needed in TAT model
deltaEbot = max(0.5 * phigdbot, phitd);
deltaEsti = max(0.5 * phigdsti, phitd);
deltaEgat = max(0.5 * phigdgat, phitd);
// values of atat, needed in TAT model
atatbot = deltaEbot * phitdinv;
atatsti = deltaEsti * phitdinv;
atatgat = deltaEgat * phitdinv;
// values of btatpart, needed in TAT model
btatpartbot = sqrt(32 * MEFFTATBOT_i * `MELE * `QELE * (deltaEbot * deltaEbot * deltaEbot)) / (3 * `HBAR);
btatpartsti = sqrt(32 * MEFFTATSTI_i * `MELE * `QELE * (deltaEsti * deltaEsti * deltaEsti)) / (3 * `HBAR);
btatpartgat = sqrt(32 * MEFFTATGAT_i * `MELE * `QELE * (deltaEgat * deltaEgat * deltaEgat)) / (3 * `HBAR);
// temperature-scaled values of FBBT, needed in BBT model
fbbtbot = FBBTRBOT * (1 + STFBBTBOT * (tkd - tkr));
fbbtsti = FBBTRSTI * (1 + STFBBTSTI * (tkd - tkr));
fbbtgat = FBBTRGAT * (1 + STFBBTGAT * (tkd - tkr));
// values of fstop, needed in avalanche/breakdown model
fstopbot = 1 / (1 - pow(`alphaav, PBRBOT_i));
fstopsti = 1 / (1 - pow(`alphaav, PBRSTI_i));
fstopgat = 1 / (1 - pow(`alphaav, PBRGAT_i));
// inverse values of breakdown voltages, needed in avalanche/breakdown model
VBRinvbot = 1 / VBRBOT_i;
VBRinvsti = 1 / VBRSTI_i;
VBRinvgat = 1 / VBRGAT_i;
// slopes for linear extraploation close to and beyond breakdown, needed in avalanche/breakdown model
slopebot = -(fstopbot * fstopbot * pow(`alphaav, (PBRBOT_i - 1))) * PBRBOT_i * VBRinvbot;
slopesti = -(fstopsti * fstopsti * pow(`alphaav, (PBRSTI_i - 1))) * PBRSTI_i * VBRinvsti;
slopegat = -(fstopgat * fstopgat * pow(`alphaav, (PBRGAT_i - 1))) * PBRGAT_i * VBRinvgat;

285
src/spicelib/devices/adms/psp102/admsva/JUNCAP200_macrodefs.include
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//======================================================================================
//======================================================================================
// Filename: JUNCAP200_macrodefs.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1 (PSP), 200.2 (JUNCAP), October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
///////////////////////////////////////////
//
// Macros and constants used in JUNCAP2
//
///////////////////////////////////////////
// Other constants
`define MINTEMP -250
`define vbilow 0.050
`define a 2
`define epsch 0.1
`define dvbi 0.050
`define epsav 1E-6
`define vbrmax 1000
`define alphaav 0.999
`define vmaxlarge 1E8
`define aerfc 0.29214664
`define twothirds 0.666666666666667
// Clipping values
`define levelnumber 200
`define AB_cliplow 0
`define LS_cliplow 0
`define LG_cliplow 0
`define MULT_cliplow 0
`define TRJ_cliplow `MINTEMP
`define IMAX_cliplow 1E-12
`define CJORBOT_cliplow 1E-12
`define CJORSTI_cliplow 1E-18
`define CJORGAT_cliplow 1E-18
`define VBIR_cliplow `vbilow
`define P_cliplow 0.05
`define P_cliphigh 0.95
`define IDSATR_cliplow 0
`define CSRH_cliplow 0
`define XJUN_cliplow 1E-9
`define CTAT_cliplow 0
`define MEFFTAT_cliplow 0.01
`define CBBT_cliplow 0
`define VBR_cliplow 0.1
`define PBR_cliplow 0.1
/////////////////////////////////////////////////////////////////////////////
//
// Macro definitions.
//
// Note that because at present locally scoped variables
// can only be in named blocks, the intermediate variables
// used in the macros below must be explicitly declared
// as variables.
//
/////////////////////////////////////////////////////////////////////////////
// Instance parameter dependent initialization
`define JuncapInitInstance(AB_i, LS_i, LG_i, VMAX, vbimin, vch, vfmin, vbbtlim) \
if (idsatbot * AB_i > 0) begin \
vmaxbot = phitd * ln(IMAX_i / (idsatbot * AB_i) + 1); \
end else begin \
vmaxbot = `vmaxlarge; \
end \
if (idsatsti * LS_i > 0) begin \
vmaxsti = phitd * ln(IMAX_i / (idsatsti * LS_i) + 1); \
end else begin \
vmaxsti = `vmaxlarge; \
end \
if (idsatgat * LG_i > 0) begin \
vmaxgat = phitd * ln(IMAX_i / (idsatgat * LG_i) + 1); \
end else begin \
vmaxgat = `vmaxlarge; \
end \
VMAX = min(min(vmaxbot, vmaxsti), vmaxgat); \
\
/* determination of minimum value of the relevant built-in voltages */ \
vbibot2 = vbibot; \
vbisti2 = vbisti; \
vbigat2 = vbigat; \
if (AB_i == 0) begin vbibot2 = vbisti + vbigat; end \
if (LS_i == 0) begin vbisti2 = vbibot + vbigat; end \
if (LG_i == 0) begin vbigat2 = vbibot + vbisti; end \
vbimin = min(min(vbibot2, vbisti2), vbigat2); \
vch = vbimin * `epsch; \
if (vbimin == vbibot) begin vfmin = vbibot * (1 - (pow(`a, (-1.0 / PBOT_i)))); end \
if (vbimin == vbisti) begin vfmin = vbisti * (1 - (pow(`a, (-1.0 / PSTI_i)))); end \
if (vbimin == vbigat) begin vfmin = vbigat * (1 - (pow(`a, (-1.0 / PGAT_i)))); end \
\
/* determination of limiting value of conditioned voltage for BBT calculation */ \
vbibot2r = VBIRBOT_i; \
vbisti2r = VBIRSTI_i; \
vbigat2r = VBIRGAT_i; \
if (AB_i == 0) begin vbibot2r = VBIRSTI_i + VBIRGAT_i; end \
if (LS_i == 0) begin vbisti2r = VBIRBOT_i + VBIRGAT_i; end \
if (LG_i == 0) begin vbigat2r = VBIRBOT_i + VBIRSTI_i; end \
vbbtlim = min(min(vbibot2r, vbisti2r), vbigat2r) - `dvbi; \
// Special power-functions
`define mypower(x,power,result) \
if (power == 0.5) begin \
result = sqrt(x); \
end else begin \
result = pow(x, power); \
end
`define mypower2(x,power,result) \
if (power == -1) begin \
result = 1 / (x); \
end else begin \
result = pow(x, power); \
end
`define mypower3(x,power,result) \
if (power == 4) begin \
result = (x) * (x) * (x) * (x); \
end else begin \
result = pow(x, power); \
end
// Smoothing functions
`define hypfunction2(x,x0,eps,hyp2) \
hyp2 = 0.5 * ((x) + (x0) - sqrt(((x) - (x0)) * ((x) - (x0)) + 4 * (eps) * (eps)));
`define hypfunction5(x,x0,eps,hyp5) \
h1 = 4.0 * (eps) * (eps); \
h2 = (eps) / (x0); \
h2d = (x) + (eps) * h2; \
h3 = (x0) + h2d; \
h4 = (x0) - h2d; \
h5 = sqrt(h4 * h4 + h1); \
hyp5 = 2.0 * (x) * (x0) / (h3 + h5);
// A special function used to calculate TAT-currents,
// including an approximation of the erfc-function
`define calcerfcexpmtat(y,m,result) \
ysq = y * y; \
if (y > 0) begin \
terfc = 1 / (1 + perfc * y); \
end else begin \
terfc = 1 / (1 - perfc * y); \
end \
`expl_low(-ysq + m, tmp) \
erfcpos = (`aerfc * terfc + berfc * terfc * terfc + cerfc * terfc * terfc * terfc) * tmp; \
if (y > 0) begin \
result = erfcpos; \
end else begin\
`expl_low(m, tmp) \
result = 2* tmp - erfcpos; \
end
// This is the main function of the JUNCAP2-model. It returns the current and charge
// for a single diode
`define juncapfunction(qpref,qpref2,vbiinv,one_minus_P,idsat,CSRH,CTAT,vbi,wdepnulr,VBIRinv,P,ftd,btatpart,atat,one_over_one_minus_P,CBBT,VBIR,wdepnulrinv,fbbt,VBR,VBRinv,PBR,fstop,slope,Ijprime,Qjprime) \
`mypower((1 - vj * vbiinv), one_minus_P, tmp) \
Qjprime = qpref * (1 - tmp) + qpref2 * (VAK - vj); \
id = idsat * idmult; \
if ((CSRH == 0) && (CTAT == 0)) begin \
isrh = 0; \
end else begin \
vbi_minus_vjsrh = vbi-vjsrh; \
wsrhstep = 1 - sqrt(1 - two_psistar / vbi_minus_vjsrh); \
if (P == 0.5) begin \
dwsrh = 0; \
end else begin \
dwsrh = ((wsrhstep * wsrhstep * ln(wsrhstep) / (1 - wsrhstep)) + wsrhstep) * (1 - 2 * P); \
end \
wsrh = wsrhstep + dwsrh; \
`mypower(vbi_minus_vjsrh * VBIRinv, P, tmp) \
wdep = wdepnulr * tmp; \
asrh = ftd * (zinv - 1) * wdep; \
isrh = CSRH * asrh * wsrh; \
end \
if (CTAT == 0) begin \
itat = 0; \
end else begin \
btat = btatpart * (wdep * one_minus_P) / vbi_minus_vjsrh; \
twoatatoverthreebtat = `twothirds * atat / btat; \
umaxbeforelimiting = twoatatoverthreebtat * twoatatoverthreebtat; \
umax = sqrt(umaxbeforelimiting * umaxbeforelimiting / (umaxbeforelimiting * umaxbeforelimiting + 1)); \
sqrtumax = sqrt(abs(umax)); \
umaxpoweronepointfive = umax * sqrtumax; \
`mypower2((1 + btat * umaxpoweronepointfive), (-P * one_over_one_minus_P), wgamma) \
wtat = wsrh * wgamma / (wsrh + wgamma); \
ktat = sqrt(0.375 * btat / sqrtumax); \
ltat = 2 * twoatatoverthreebtat * sqrtumax - umax; \
mtat = atat * twoatatoverthreebtat * sqrtumax - atat * umax + 0.5 * btat * umaxpoweronepointfive; \
xerfc = (ltat - 1) * ktat; \
`calcerfcexpmtat(xerfc, mtat, erfctimesexpmtat) \
gammamax = atat * erfctimesexpmtat * `SQRTPI / (2 * ktat); \
itat = CTAT * asrh * gammamax * wtat; \
end \
if (CBBT == 0) begin \
ibbt = 0; \
end else begin \
`mypower(((VBIR - vbbt) * VBIRinv), P, tmp) \
Fmaxr = (VBIR - vbbt) * one_over_one_minus_P * wdepnulrinv / tmp; \
`expl(-fbbt / Fmaxr, tmp) \
ibbt = CBBT * VAK * Fmaxr * Fmaxr * tmp; \
end \
if (VBR > `vbrmax) begin \
fbreakdown = 1; \
end else begin \
if (vav > -`alphaav * VBR) begin \
`mypower3(abs(vav * VBRinv), PBR, tmp) \
fbreakdown = 1 / (1 - tmp); \
end else begin \
fbreakdown = fstop + (vav + `alphaav * VBR) * slope; \
end \
end \
Ijprime = (id + isrh + itat + ibbt) * fbreakdown;
// The following code is written as a macro because the naming of the instance parameters is
// different for JUNCAP2 stand-alone and JUNCAP2-in-PSP: AB, LS, LG for JUNCAP2 stand-alone,
// ABSOURCE, LSSOURCE, LGSOURCE for source junction in PSP and ABDRAIN, LSDRAIN, LGDRAIN for
// drain junction in PSP
`define juncapcommon(AB_i,LS_i,LG_i,ijunbot,qjunbot,ijunsti,qjunsti,ijungat,qjungat) \
vbbt = 0.0; \
two_psistar = 0.0; \
if ( !( ((AB_i) == 0) && ((LS_i) == 0) && ((LG_i) == 0) ) ) begin \
`hypfunction5(VAK, vfmin, vch, vj) \
if (VAK < VMAX) begin \
`expl(0.5 * VAK * phitdinv, zinv) \
idmult = zinv * zinv; \
end else begin \
`expl(VMAX * phitdinv, exp_VMAX_over_phitd) \
idmult = (1 + (VAK - VMAX) * phitdinv) * exp_VMAX_over_phitd; \
zinv = sqrt(idmult); \
end \
idmult = idmult - 1.0; \
z = 1 / zinv; \
if (VAK > 0) begin \
two_psistar = 2.0 * phitd * ln(2.0 + z + sqrt((z + 1.0) * (z + 3.0))); \
end else begin \
two_psistar = -VAK + 2.0 * phitd * ln(2 * zinv + 1 + sqrt((1 + zinv) * (1 + 3 * zinv))); \
end \
vjlim = vbimin - two_psistar; \
`hypfunction2(VAK, vjlim, phitd, vjsrh) \
`hypfunction2(VAK, vbbtlim, phitr, vbbt) \
`hypfunction2(VAK, 0, `epsav, vav) \
end \
if ((AB_i) == 0) begin \
ijunbot = 0; \
qjunbot = 0; \
end else begin \
`juncapfunction(qprefbot,qpref2bot,vbiinvbot,one_minus_PBOT,idsatbot,CSRHBOT_i,CTATBOT_i,vbibot,wdepnulrbot,VBIRBOTinv,PBOT_i,ftdbot,btatpartbot,atatbot,one_over_one_minus_PBOT,CBBTBOT_i,VBIRBOT_i,wdepnulrinvbot,fbbtbot,VBRBOT_i,VBRinvbot,PBRBOT_i,fstopbot,slopebot,ijunbot, qjunbot) \
end \
if ((LS_i) == 0) begin \
ijunsti = 0; \
qjunsti = 0; \
end else begin \
`juncapfunction(qprefsti,qpref2sti,vbiinvsti,one_minus_PSTI,idsatsti,CSRHSTI_i,CTATSTI_i,vbisti,wdepnulrsti,VBIRSTIinv,PSTI_i,ftdsti,btatpartsti,atatsti,one_over_one_minus_PSTI,CBBTSTI_i,VBIRSTI_i,wdepnulrinvsti,fbbtsti,VBRSTI_i,VBRinvsti,PBRSTI_i,fstopsti,slopesti,ijunsti, qjunsti) \
end \
if ((LG_i) == 0) begin \
ijungat = 0; \
qjungat = 0; \
end else begin \
`juncapfunction(qprefgat,qpref2gat,vbiinvgat,one_minus_PGAT,idsatgat,CSRHGAT_i,CTATGAT_i,vbigat,wdepnulrgat,VBIRGATinv,PGAT_i,ftdgat,btatpartgat,atatgat,one_over_one_minus_PGAT,CBBTGAT_i,VBIRGAT_i,wdepnulrinvgat,fbbtgat,VBRGAT_i,VBRinvgat,PBRGAT_i,fstopgat,slopegat,ijungat, qjungat) \
end

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src/spicelib/devices/adms/psp102/admsva/JUNCAP200_parlist.include
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//======================================================================================
//======================================================================================
// Filename: JUNCAP200_parlist.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1 (PSP), 200.2 (JUNCAP), October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
//////////////////////////////////////////
//
// JUNCAP2 - Reduced parameterlist
//
//////////////////////////////////////////
parameter real IMAX = 1000 `from(`IMAX_cliplow ,inf ) `P(info="Maximum current up to which forward current behaves exponentially" unit="A" );
parameter real CJORBOT = 1E-3 `from(`CJORBOT_cliplow ,inf ) `P(info="Zero-bias capacitance per unit-of-area of bottom component" unit="Fm^-2" );
parameter real CJORSTI = 1E-9 `from(`CJORSTI_cliplow ,inf ) `P(info="Zero-bias capacitance per unit-of-length of STI-edge component" unit="Fm^-1" );
parameter real CJORGAT = 1E-9 `from(`CJORGAT_cliplow ,inf ) `P(info="Zero-bias capacitance per unit-of-length of gate-edge component" unit="Fm^-1" );
parameter real VBIRBOT = 1 `from(`VBIR_cliplow ,inf ) `P(info="Built-in voltage at the reference temperature of bottom component" unit="V" );
parameter real VBIRSTI = 1 `from(`VBIR_cliplow ,inf ) `P(info="Built-in voltage at the reference temperature of STI-edge component" unit="V" );
parameter real VBIRGAT = 1 `from(`VBIR_cliplow ,inf ) `P(info="Built-in voltage at the reference temperature of gate-edge component" unit="V" );
parameter real PBOT = 0.5 `from(`P_cliplow ,`P_cliphigh ) `P(info="Grading coefficient of bottom component" unit="" );
parameter real PSTI = 0.5 `from(`P_cliplow ,`P_cliphigh ) `P(info="Grading coefficient of STI-edge component" unit="" );
parameter real PGAT = 0.5 `from(`P_cliplow ,`P_cliphigh ) `P(info="Grading coefficient of gate-edge component" unit="" );
parameter real PHIGBOT = 1.16 `P(info="Zero-temperature bandgap voltage of bottom component" unit="V" );
parameter real PHIGSTI = 1.16 `P(info="Zero-temperature bandgap voltage of STI-edge component" unit="V" );
parameter real PHIGGAT = 1.16 `P(info="Zero-temperature bandgap voltage of gate-edge component" unit="V" );
parameter real IDSATRBOT = 1E-12 `from(`IDSATR_cliplow ,inf ) `P(info="Saturation current density at the reference temperature of bottom component" unit="Am^-2" );
parameter real IDSATRSTI = 1E-18 `from(`IDSATR_cliplow ,inf ) `P(info="Saturation current density at the reference temperature of STI-edge component" unit="Am^-1" );
parameter real IDSATRGAT = 1E-18 `from(`IDSATR_cliplow ,inf ) `P(info="Saturation current density at the reference temperature of gate-edge component" unit="Am^-1" );
parameter real CSRHBOT = 1E2 `from(`CSRH_cliplow ,inf ) `P(info="Shockley-Read-Hall prefactor of bottom component" unit="Am^-3" );
parameter real CSRHSTI = 1E-4 `from(`CSRH_cliplow ,inf ) `P(info="Shockley-Read-Hall prefactor of STI-edge component" unit="Am^-2" );
parameter real CSRHGAT = 1E-4 `from(`CSRH_cliplow ,inf ) `P(info="Shockley-Read-Hall prefactor of gate-edge component" unit="Am^-2" );
parameter real XJUNSTI = 100E-9 `from(`XJUN_cliplow ,inf ) `P(info="Junction depth of STI-edge component" unit="m" );
parameter real XJUNGAT = 100E-9 `from(`XJUN_cliplow ,inf ) `P(info="Junction depth of gate-edge component" unit="m" );
parameter real CTATBOT = 1E2 `from(`CTAT_cliplow ,inf ) `P(info="Trap-assisted tunneling prefactor of bottom component" unit="Am^-3" );
parameter real CTATSTI = 1E-4 `from(`CTAT_cliplow ,inf ) `P(info="Trap-assisted tunneling prefactor of STI-edge component" unit="Am^-2" );
parameter real CTATGAT = 1E-4 `from(`CTAT_cliplow ,inf ) `P(info="Trap-assisted tunneling prefactor of gate-edge component" unit="Am^-2" );
parameter real MEFFTATBOT = 0.25 `from(`MEFFTAT_cliplow ,inf ) `P(info="Effective mass (in units of m0) for trap-assisted tunneling of bottom component" unit="" );
parameter real MEFFTATSTI = 0.25 `from(`MEFFTAT_cliplow ,inf ) `P(info="Effective mass (in units of m0) for trap-assisted tunneling of STI-edge component" unit="" );
parameter real MEFFTATGAT = 0.25 `from(`MEFFTAT_cliplow ,inf ) `P(info="Effective mass (in units of m0) for trap-assisted tunneling of gate-edge component" unit="" );
parameter real CBBTBOT = 1E-12 `from(`CBBT_cliplow ,inf ) `P(info="Band-to-band tunneling prefactor of bottom component" unit="AV^-3" );
parameter real CBBTSTI = 1E-18 `from(`CBBT_cliplow ,inf ) `P(info="Band-to-band tunneling prefactor of STI-edge component" unit="AV^-3m" );
parameter real CBBTGAT = 1E-18 `from(`CBBT_cliplow ,inf ) `P(info="Band-to-band tunneling prefactor of gate-edge component" unit="AV^-3m" );
parameter real FBBTRBOT = 1E9 `P(info="Normalization field at the reference temperature for band-to-band tunneling of bottom component" unit="Vm^-1" );
parameter real FBBTRSTI = 1E9 `P(info="Normalization field at the reference temperature for band-to-band tunneling of STI-edge component" unit="Vm^-1" );
parameter real FBBTRGAT = 1E9 `P(info="Normalization field at the reference temperature for band-to-band tunneling of gate-edge component" unit="Vm^-1" );
parameter real STFBBTBOT = -1E-3 `P(info="Temperature scaling parameter for band-to-band tunneling of bottom component" unit="K^-1" );
parameter real STFBBTSTI = -1E-3 `P(info="Temperature scaling parameter for band-to-band tunneling of STI-edge component" unit="K^-1" );
parameter real STFBBTGAT = -1E-3 `P(info="Temperature scaling parameter for band-to-band tunneling of gate-edge component" unit="K^-1" );
parameter real VBRBOT = 10 `from(`VBR_cliplow ,inf ) `P(info="Breakdown voltage of bottom component" unit="V" );
parameter real VBRSTI = 10 `from(`VBR_cliplow ,inf ) `P(info="Breakdown voltage of STI-edge component" unit="V" );
parameter real VBRGAT = 10 `from(`VBR_cliplow ,inf ) `P(info="Breakdown voltage of gate-edge component" unit="V" );
parameter real PBRBOT = 4 `from(`PBR_cliplow ,inf ) `P(info="Breakdown onset tuning parameter of bottom component" unit="V" );
parameter real PBRSTI = 4 `from(`PBR_cliplow ,inf ) `P(info="Breakdown onset tuning parameter of STI-edge component" unit="V" );
parameter real PBRGAT = 4 `from(`PBR_cliplow ,inf ) `P(info="Breakdown onset tuning parameter of gate-edge component" unit="V" );

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src/spicelib/devices/adms/psp102/admsva/JUNCAP200_varlist.include
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//======================================================================================
//======================================================================================
// Filename: JUNCAP200_varlist.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1 (PSP), 200.2 (JUNCAP), October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
// declaration of variables needed in macro "calcerfcexpmtat"
real ysq, terfc, erfcpos;
// declaration of variables needed in hypfunction 5
real h1, h2, h2d, h3, h4, h5;
// declaration of variables used within macro "juncapfunction"
real tmp, id;
real isrh, vbi_minus_vjsrh, wsrhstep, dwsrh, wsrh, wdep, asrh;
real itat, btat, twoatatoverthreebtat, umaxbeforelimiting, umax, sqrtumax, umaxpoweronepointfive;
real wgamma, wtat, ktat, ltat, mtat, xerfc, erfctimesexpmtat, gammamax;
real ibbt, Fmaxr;
real fbreakdown;
// declaration of clipped parameters
real TRJ_i, IMAX_i;
real CJORBOT_i, CJORSTI_i, CJORGAT_i, VBIRBOT_i, VBIRSTI_i, VBIRGAT_i;
real PBOT_i, PSTI_i, PGAT_i;
real IDSATRBOT_i, IDSATRSTI_i, IDSATRGAT_i, XJUNSTI_i, XJUNGAT_i;
real CSRHBOT_i, CSRHSTI_i, CSRHGAT_i, CTATBOT_i, CTATSTI_i, CTATGAT_i;
real MEFFTATBOT_i, MEFFTATSTI_i, MEFFTATGAT_i;
real CBBTBOT_i, CBBTSTI_i, CBBTGAT_i;
real VBRBOT_i, VBRSTI_i, VBRGAT_i, PBRBOT_i, PBRSTI_i, PBRGAT_i;
// declaration of variables calculated outside macro "juncapfunction", voltage-independent part
real tkr, tkd, auxt, KBOL_over_QELE, phitr, phitrinv, phitd, phitdinv;
real deltaphigr, phigrbot, phigrsti, phigrgat, deltaphigd, phigdbot, phigdsti, phigdgat;
real ftdbot, ftdsti, ftdgat, idsatbot, idsatsti, idsatgat, exp_VMAX_over_phitd;
real ubibot, ubisti, ubigat, vbibot, vbisti, vbigat;
real vbibot2, vbisti2, vbigat2, vbibot2r, vbisti2r, vbigat2r;
real vbiinvbot, vbiinvsti, vbiinvgat;
real one_minus_PBOT, one_minus_PSTI, one_minus_PGAT;
real one_over_one_minus_PBOT, one_over_one_minus_PSTI, one_over_one_minus_PGAT;
real cjobot, cjosti, cjogat, qprefbot, qprefsti, qprefgat;
real vbimin, vch, vfmin, vbbtlim;
real qpref2bot, qpref2sti, qpref2gat;
real wdepnulrbot, wdepnulrsti, wdepnulrgat, wdepnulrinvbot, wdepnulrinvsti, wdepnulrinvgat;
real VBIRBOTinv, VBIRSTIinv, VBIRGATinv;
real perfc, berfc, cerfc;
real deltaEbot, deltaEsti, deltaEgat, atatbot, atatsti, atatgat;
real btatpartbot, btatpartsti, btatpartgat;
real fbbtbot, fbbtsti, fbbtgat;
real fstopbot, fstopsti, fstopgat, VBRinvbot, VBRinvsti, VBRinvgat;
real slopebot, slopesti, slopegat;
real vmaxbot, vmaxsti, vmaxgat, VMAX;
// declaration of variables calculated outside macro "juncapfunction", voltage-dependent part
real VAK, idmult, vj, z, zinv, two_psistar, vjlim, vjsrh, vbbt, vav;

303
src/spicelib/devices/adms/psp102/admsva/PSP102_ChargesNQS.include
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//======================================================================================
//======================================================================================
// Filename: PSP102_ChargesNQS.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
///////////////////////////////////////////////
//
// Calculate NQS-charge contributions
//
///////////////////////////////////////////////
Qp1 = vnorm * V(SPLINE1);
Qp2 = vnorm * V(SPLINE2);
Qp3 = vnorm * V(SPLINE3);
Qp4 = vnorm * V(SPLINE4);
Qp5 = vnorm * V(SPLINE5);
Qp6 = vnorm * V(SPLINE6);
Qp7 = vnorm * V(SPLINE7);
Qp8 = vnorm * V(SPLINE8);
Qp9 = vnorm * V(SPLINE9);
Tnorm = 0.0;
if (SWNQS_i != 0) begin
// Dimension and mobility information is included in Tnorm
Tnorm = MUNQS_i * phit1 * BET_i / (COX_qm * Gmob_dL);
thesat2 = thesat1 * thesat1 * phit1 * phit1;
if (SWNQS_i == 1) begin
dQy = QpN - Qp0;
d2Qy = 6.0 * (Qp0 + QpN) - 12.0 * Qp1;
end else if (SWNQS_i == 2) begin
dQy = (-7.0 * Qp0 - 3.0 * Qp1 + 12.0 * Qp2 - 2.0 * QpN) / 5.0;
d2Qy = -18.0 / 5.0 * (-4.0 * Qp0 + 9.0 * Qp1 - 6.0 * Qp2 + QpN);
end else if (SWNQS_i == 3) begin
dQy = (-13.0 * Qp0 - 6.0 * Qp1 + 24.0 * Qp2 - 6.0 * Qp3 + QpN) / 7.0;
d2Qy = (180.0 * Qp0 - 408.0 * Qp1 + 288.0 * Qp2 - 72.0 * Qp3 + 12.0 * QpN) / 7.0;
end else if (SWNQS_i == 5) begin
dQy = (-181.0 * Qp0 - 84.0 * Qp1 + 24.0 * Qp4 - 6.0 * Qp5 - 90.0 * Qp3 + QpN
+ 336.0 * Qp2) / 65.0;
d2Qy = (432.0 * Qp4 - 108.0 * Qp5 - 1620.0 * Qp3 + 18.0 * QpN + 3762.0 * Qp0
- 8532.0 * Qp1 + 6048.0 * Qp2) / 65.0;
end else if (SWNQS_i == 9) begin
dQy = (1680.0 * Qp6 + 23400.0 * Qp4 + 5.0 * QpN - 87330.0 * Qp3 + 120.0 * Qp8
- 450.0 * Qp7 - 81480.0 * Qp1 + 325920.0 * Qp2
-175565.0 * Qp0 - 30.0 * Qp9) / 37829.0 - 30.0 / 181.0 * Qp5;
d2Qy = (-13500.0 * Qp7 + 702000.0 * Qp4 - 2619900 * Qp3 - 13793100.0 * Qp1
+ 9777600.0 * Qp2 + 6081750.0 * Qp0 + 150.0 * QpN + 3600.0 * Qp8
- 900.0 * Qp9 + 50400 * Qp6) / 37829.0 - 900.0 / 181.0 * Qp5;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp1, xg, dQy, d2Qy, fk1)
end
if (SWNQS_i >= 2) begin
if (SWNQS_i == 2) begin
dQy = (2.0 * Qp0 - 12.0 * Qp1 + 3.0 * Qp2 + 7.0 * QpN) / 5.0;
d2Qy = -18.0 / 5.0 * (-4.0 * QpN + 9.0 * Qp2 - 6.0 * Qp1 + Qp0);
end else if (SWNQS_i == 3) begin
dQy = 0.5 * Qp0 - 3.0 * Qp1 + 3.0 * Qp3 - 0.5 * QpN;
d2Qy = (-48.0 * Qp0 + 288.0 * Qp1 - 480.0 * Qp2 + 288.0 * Qp3 - 48.0 * QpN) / 7.0;
end else if (SWNQS_i == 5) begin
dQy = (-291.0 * Qp1 - 6.0 * Qp2 - 84.0 * Qp4 + 21.0 * Qp5) / 65.0
+ (630.0 * Qp3 - 7.0 * QpN + 97.0 * Qp0) / 130.0;
d2Qy = (-1728.0 * Qp4 + 432.0 * Qp5 + 6480.0 * Qp3 - 72.0 * QpN - 1008 * Qp0
+ 6048 * Qp1 - 10152 * Qp2) / 65.0;
end else if (SWNQS_i == 9) begin
dQy = (-5880.0 * Qp6 - 81900.0 * Qp4 + 305655.0 * Qp3 - 420.0 * Qp8
+ 105.0 * Qp9 - 282255.0 * Qp1 + 1575.0 * Qp7 - 5850.0 * Qp2) / 37829.0
+ 105.0 / 181.0 * Qp5 + (94085.0 * Qp0 - 35.0 * QpN) / 75658.0;
d2Qy = (9777600.0 * Qp1 + 54000.0 * Qp7 - 2808000.0 * Qp4 + 10479600.0 * Qp3
- 16413000.0 * Qp2 - 1629600.0 * Qp0 - 600.0 * QpN - 14400.0 * Qp8
+ 3600.0 * Qp9 - 201600.0 * Qp6) / 37829.0 + 3600.0 * Qp5 / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp2, xg, dQy, d2Qy, fk2)
end
if (SWNQS_i >= 3) begin
if (SWNQS_i == 3) begin
dQy = (13.0 * QpN + 6.0 * Qp3 - 24.0 * Qp2 + 6.0 * Qp1 - Qp0) / 7.0;
d2Qy = (180.0 * QpN - 408.0 * Qp3 + 288.0 * Qp2 - 72.0 * Qp1 + 12.0 * Qp0) / 7.0;
end else if (SWNQS_i == 5) begin
dQy = (QpN - 6.0 * Qp5 + 24.0 * Qp4 - 24.0 * Qp2 + 6.0 * Qp1 - Qp0) / 5.0;
d2Qy = (1296.0 * (Qp4 + Qp2) - 324.0 * (Qp5 + Qp1) - 2052.0 * Qp3
+ 54.0 * (QpN + Qp0)) / 13.0;
end else if (SWNQS_i == 9) begin
dQy = (21840.0 * Qp6 + 304200.0 * Qp4 + 65.0 * QpN - 420.0 * Qp3 + 1560.0 * Qp8
- 12605.0 * Qp0-390.0 * Qp9 + 75630.0 * Qp1 - 5850.0 * Qp7
- 302520.0 * Qp2) / 37829.0 - 390.0 / 181.0 * Qp5;
d2Qy = (-2619900.0 * Qp1 - 202500.0 * Qp7 + 10530000.0 * Qp4 - 16601100.0 * Qp3
+ 10479600.0 * Qp2 + 436650.0 * Qp0 + 2250.0 * QpN + 54000.0 * Qp8
- 13500.0 * Qp9 + 756000.0 * Qp6) / 37829.0 - 13500.0 * Qp5 / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp3, xg, dQy, d2Qy, fk3)
end
if (SWNQS_i >= 4) begin
if (SWNQS_i == 5) begin
dQy = (-630.0 * Qp3 + 12.0 * Qp4 + 582.0 * Qp5 - 97.0 * QpN + 7.0 * Qp0
- 42.0 * Qp1 + 168.0 * Qp2)/130.0;
d2Qy = (-10152.0 * Qp4 + 6048.0 * Qp5 + 6480.0 * Qp3 - 1008.0 * QpN
- 72.0 * Qp0 + 432.0 * Qp1 - 1728.0 * Qp2) / 65.0;
end
else if (SWNQS_i == 9) begin
dQy = (-81480.0 * Qp6 - 30.0 * Qp4 - 303975.0 * Qp3 - 5820.0 * Qp8
+ 1455.0 * Qp9 - 20265.0 * Qp1 + 21825.0 * Qp7 + 81060.0 * Qp2) / 37829.0
- 485.0 / 75658.0 * QpN + 1455.0 * Qp5 / 181.0 + 6755.0 * Qp0 / 75658.0;
d2Qy = (702000.0 * Qp1 + 756000.0 * Qp7 - 16614600.0 * Qp4 + 10530000.0 * Qp3
- 2808000.0 * Qp2 - 117000.0 * Qp0 - 8400.0 * QpN - 201600.0 * Qp8
+ 50400.0 * Qp9 - 2822400.0 * Qp6) / 37829.0 + 50400.0 * Qp5 / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp4, xg, dQy, d2Qy, fk4)
end
if (SWNQS_i >= 5) begin
if (SWNQS_i == 5) begin
dQy = (-336.0 * Qp4 + 84.0 * Qp5 + 90.0 * Qp3 + 181.0 * QpN - Qp0 + 6.0 * Qp1
- 24.0 * Qp2) / 65.0;
d2Qy = (18.0 * Qp0 + 3762.0 * QpN + 6048.0 * Qp4 + 432.0 * Qp2 - 1620.0 * Qp3
- 108.0 * Qp1 - 8532.0 * Qp5) / 65.0;
end else if (SWNQS_i == 9) begin
dQy = (1680.0 * (Qp6 - Qp4) + 5.0 * (QpN - Qp0) + 450.0 * (Qp3 - Qp7)
+ 120.0 * (Qp8 - Qp2) - 30.0 * (Qp9 - Qp1)) / 209.0;
d2Qy = (-900.0 * (Qp1 + Qp9) - 13500.0 * (Qp7 + Qp3) - 79500.0 * Qp5
+ 50400.0 * (Qp4 + Qp6) + 3600.0 * (Qp2 + Qp8) + 150.0 * (Qp0 + QpN)) / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp5, xg, dQy, d2Qy, fk5)
end
if (SWNQS_i >= 6) begin
if (SWNQS_i == 9) begin
dQy = (30.0 * Qp6 + 81480.0 * Qp4 - 21825.0 * Qp3 - 81060.0 * Qp8 + 20265.0 * Qp9
- 1455.0 * Qp1 + 303975.0 * Qp7 + 5820.0 * Qp2) / 37829.0
-(6755.0 * QpN - 485.0 * Qp0) / 75658.0 - 1455.0 / 181.0 * Qp5;
d2Qy = (50400.0 * Qp1 + 10530000.0 * Qp7 - 2822400.0 * Qp4 + 756000.0 * Qp3
- 201600.0 * Qp2 - 8400.0 * Qp0 - 117000.0 * QpN - 2808000.0 * Qp8
+ 702000.0 * Qp9 - 16614600.0 * Qp6) / 37829.0 + 50400.0 * Qp5 / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp6, xg, dQy, d2Qy, fk6)
end
if (SWNQS_i >= 7) begin
if (SWNQS_i == 9) begin
dQy = (-304200.0 * Qp6 - 21840.0 * Qp4 + 12605.0 * QpN + 5850.0 * Qp3
+ 302520.0 * Qp8 - 65.0 * Qp0 - 75630.0 * Qp9 + 390.0 * Qp1 + 420.0 * Qp7
- 1560.0 * Qp2) / 37829.0 + 390.0 / 181.0 * Qp5;
d2Qy = (-13500.0 * Qp1 - 16601100.0 * Qp7 + 756000.0 * Qp4 - 202500.0 * Qp3
+ 54000.0 * Qp2 + 2250.0 * Qp0 + 436650.0 * QpN + 10479600.0 * Qp8
- 2619900.0 * Qp9 + 10530000.0 * Qp6) / 37829.0 - 13500.0 * Qp5 / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp7, xg, dQy, d2Qy, fk7)
end
if (SWNQS_i >= 8) begin
if (SWNQS_i == 9) begin
dQy = (81900.0 * Qp6 + 5880.0 * Qp4 - 1575.0 * Qp3 + 5850.0 * Qp8 + 282255.0 * Qp9
- 105.0 * Qp1 - 305655.0 * Qp7 + 420.0 * Qp2) / 37829.0 + (35.0 * Qp0
- 94085.0 * QpN) / 75658.0 - 105.0 / 181.0 * Qp5;
d2Qy = (3600.0 * Qp1 + 10479600.0 * Qp7 - 201600.0 * Qp4 + 54000.0 * Qp3
- 14400.0 * Qp2 - 600.0 * Qp0 - 1629600.0 * QpN - 16413000.0 * Qp8
+ 9777600.0 * Qp9 - 2808000.0 * Qp6) / 37829.0 + 3600.0 * Qp5 / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp8, xg, dQy, d2Qy, fk8)
end
if (SWNQS_i >= 9) begin
if (SWNQS_i == 9) begin
dQy = (-23400.0 * Qp6 - 1680.0 * Qp4 + 175565.0 * QpN + 450.0 * Qp3
- 325920.0 * Qp8 - 5.0 * Qp0 + 81480.0 * Qp9 + 30.0 * Qp1
+ 87330.0 * Qp7 - 120.0 * Qp2) / 37829.0 + 30.0 * Qp5 / 181.0;
d2Qy = (-900.0 * Qp1 - 2619900.0 * Qp7 + 50400.0 * Qp4 - 13500.0 * Qp3
+ 3600.0 * Qp2 + 150.0 * Qp0 + 6081750.0 * QpN + 9777600.0 * Qp8
- 13793100.0 * Qp9 + 702000.0 * Qp6) / 37829.0 - 900.0 * Qp5 / 181.0;
end else begin
dQy = 0;
d2Qy = 0;
end
`fq(Qp9, xg, dQy, d2Qy, fk9)
end
//--------------------------------------------------------------------
// Terminal charges for NQS
if (SWNQS_i != 0) begin
if (SWNQS_i == 1) begin
QS_NQS = (17.0 * Qp0 + 30.0 * Qp1 + QpN) / 96.0;
QD_NQS = (Qp0 + 30.0 * Qp1 + 17.0 * QpN) / 96.0;
`QiToPhi(Qp1,xg, temp1)
QG_NQS = xg - (x_sp + 4.0 * temp1 + x_dp) * `oneSixth;
end else if (SWNQS_i == 2) begin
QS_NQS = (11.0 * Qp0 + 24.0 * Qp1 + 9.0 * Qp2 + QpN) / 90.0;
QD_NQS = (11.0 * QpN + 24.0 * Qp2 + 9.0 * Qp1 + Qp0) / 90.0;
`QiToPhi(Qp1, xg, temp1)
`QiToPhi(Qp2, xg, temp2)
QG_NQS = xg - (x_sp + 3.0 * (temp1 + temp2) + x_dp) * 0.125;
end else if (SWNQS_i == 3) begin
QS_NQS = (251.0 * Qp0 + 594.0 * Qp1 + 312.0 * Qp2 + 174.0 * Qp3 + 13.0 * QpN) / 2688.0;
QD_NQS = (251.0 * QpN + 594.0 * Qp3 + 312.0 * Qp2 + 174.0 * Qp1 + 13.0 * Qp0) / 2688.0;
`QiToPhi(Qp1, xg, temp1)
`QiToPhi(Qp2, xg, temp2)
`QiToPhi(Qp3, xg, temp3)
QG_NQS = xg - (x_sp + 4.0 * temp1 + 2.0 * temp2 + 4.0 * temp3 + x_dp) / 12.0;
end else if (SWNQS_i == 5) begin
QS_NQS = (1187.0 * Qp0 + 43.0 * QpN) / 18720.0 + (503.0 * Qp1 + 172.0 * Qp4
+ 87.0 * Qp5 + 265.0 * Qp3 + 328.0 * Qp2) / 3120.0;
QD_NQS = (1187.0 * QpN + 43.0 * Qp0) / 18720.0 + (503.0 * Qp5 + 172.0 * Qp2
+ 87.0 * Qp1 + 265.0 * Qp3 + 328.0 * Qp4) / 3120.0;
`QiToPhi(Qp1, xg, temp1)
`QiToPhi(Qp2, xg, temp2)
`QiToPhi(Qp3, xg, temp3)
`QiToPhi(Qp4, xg, temp4)
`QiToPhi(Qp5, xg, temp5)
QG_NQS = xg - (x_sp + 4.0 * (temp1 + temp3 + temp5) + 2.0 * (temp2 + temp4) + x_dp) / 18.0;
end else if (SWNQS_i == 9) begin
QS_NQS = (75653.0 * Qp8 + 225999.0 * Qp4) / 3782900.0 + (151321.0 * Qp9
+ 454023.0 * Qp7 + 1073767.0 * Qp3 + 1564569.0 * Qp1) / 15131600.0
+ 75623.0 * Qp6 / 1891450.0 + 145.0 * Qp5 / 2896.0 + 72263.0 * Qp2 / 945725.0
+ (3504517.0 * Qp0 + 75653.0 * QpN) / 90789600.0;
QD_NQS = (75653.0 * Qp2 + 225999.0 * Qp6) / 3782900.0 + (151321.0 * Qp1
+ 454023.0 * Qp3 + 1073767.0 * Qp7 + 1564569.0 * Qp9) / 15131600.0
+ 75623.0 * Qp4 / 1891450.0 + 145.0 * Qp5 / 2896.0 + 72263.0 * Qp8 / 945725.0
+ (3504517.0 * QpN + 75653.0 * Qp0) / 90789600.0;
`QiToPhi(Qp1, xg, temp1)
`QiToPhi(Qp2, xg, temp2)
`QiToPhi(Qp3, xg, temp3)
`QiToPhi(Qp4, xg, temp4)
`QiToPhi(Qp5, xg, temp5)
`QiToPhi(Qp6, xg, temp6)
`QiToPhi(Qp7, xg, temp7)
`QiToPhi(Qp8, xg, temp8)
`QiToPhi(Qp9, xg, temp9)
QG_NQS = xg - (x_sp + 4.0 * (temp1 + temp3 + temp5 + temp7 + temp9)
+ 2.0 * (temp2 + temp4 + temp6 + temp8) + x_dp) / 30.0;
end
QG_NQS = pd * QG_NQS;
if (sigVds > 0) begin
Qs = COX_qm * phit1 * QS_NQS;
Qd = COX_qm * phit1 * QD_NQS;
end else begin
Qs = COX_qm * phit1 * QD_NQS;
Qd = COX_qm * phit1 * QS_NQS;
end
Qg = COX_qm * phit1 * QG_NQS;
Qb = -Qg - Qs - Qd;
end
// Update internal nodes
V(RES1) <+ vnorm_inv * I(RES1) * r_nqs;
V(SPLINE1) <+ vnorm_inv * idt(-Tnorm * fk1, Qp1_0);
V(RES2) <+ vnorm_inv * I(RES2) * r_nqs;
V(SPLINE2) <+ vnorm_inv * idt(-Tnorm * fk2, Qp2_0);
V(RES3) <+ vnorm_inv * I(RES3) * r_nqs;
V(SPLINE3) <+ vnorm_inv * idt(-Tnorm * fk3, Qp3_0);
V(RES4) <+ vnorm_inv * I(RES4) * r_nqs;
V(SPLINE4) <+ vnorm_inv * idt(-Tnorm * fk4, Qp4_0);
V(RES5) <+ vnorm_inv * I(RES5) * r_nqs;
V(SPLINE5) <+ vnorm_inv * idt(-Tnorm * fk5, Qp5_0);
V(RES6) <+ vnorm_inv * I(RES6) * r_nqs;
V(SPLINE6) <+ vnorm_inv * idt(-Tnorm * fk6, Qp6_0);
V(RES7) <+ vnorm_inv * I(RES7) * r_nqs;
V(SPLINE7) <+ vnorm_inv * idt(-Tnorm * fk7, Qp7_0);
V(RES8) <+ vnorm_inv * I(RES8) * r_nqs;
V(SPLINE8) <+ vnorm_inv * idt(-Tnorm * fk8, Qp8_0);
V(RES9) <+ vnorm_inv * I(RES9) * r_nqs;
V(SPLINE9) <+ vnorm_inv * idt(-Tnorm * fk9, Qp9_0);

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//======================================================================================
//======================================================================================
// Filename: PSP102_InitNQS.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
/////////////////////////////////////////////////////////////////////////////
//
// Computing initial (dc) values for internal nodes.
// This code is independent of internal-node voltages
//
/////////////////////////////////////////////////////////////////////////////
Qp1_0 = 0.0;
Qp2_0 = 0.0;
Qp3_0 = 0.0;
Qp4_0 = 0.0;
Qp5_0 = 0.0;
Qp6_0 = 0.0;
Qp7_0 = 0.0;
Qp8_0 = 0.0;
Qp9_0 = 0.0;
fk1 = 0.0;
fk2 = 0.0;
fk3 = 0.0;
fk4 = 0.0;
fk5 = 0.0;
fk6 = 0.0;
fk7 = 0.0;
fk8 = 0.0;
fk9 = 0.0;
if (SWNQS_i != 0) begin
dQis = 0.0;
dQy = 0.0;
dfQi = 0.0;
fQi = 0.0;
d2Qy = 0.0;
Qp1 = 0.0;
Qp2 = 0.0;
Qp3 = 0.0;
Qp4 = 0.0;
Qp5 = 0.0;
Qp6 = 0.0;
Qp7 = 0.0;
Qp8 = 0.0;
Qp9 = 0.0;
phi_p1 = 0.0;
phi_p2 = 0.0;
phi_p3 = 0.0;
phi_p4 = 0.0;
phi_p5 = 0.0;
phi_p6 = 0.0;
phi_p7 = 0.0;
phi_p8 = 0.0;
phi_p9 = 0.0;
// Setting initial values for charge along the channel
// from interpolated DC-solution
if (xg > 0) begin
if (SWNQS_i == 1) begin
phi_p1 = `Phiy(0.5);
`PhiToQb(phi_p1,Qb_tmp)
Qp1_0 = -pd * (xg - phi_p1) - Qb_tmp;
end else if (SWNQS_i == 2) begin
phi_p1 = `Phiy(`oneThird);
`PhiToQb(phi_p1,Qb_tmp)
Qp1_0 = -pd * (xg - phi_p1) - Qb_tmp;
phi_p2 = `Phiy(`twoThirds);
`PhiToQb(phi_p2,Qb_tmp)
Qp2_0 = -pd * (xg - phi_p2) - Qb_tmp;
if (sigVds < 0) begin
`swap(Qp1_0, Qp2_0)
end
end else if (SWNQS_i == 3) begin
phi_p1 = `Phiy(0.25);
`PhiToQb(phi_p1,Qb_tmp)
Qp1_0 = -pd * (xg - phi_p1) - Qb_tmp;
phi_p2 = `Phiy(0.5);
`PhiToQb(phi_p2,Qb_tmp)
Qp2_0 = -pd * (xg - phi_p2) - Qb_tmp;
phi_p3 = `Phiy(0.75);
`PhiToQb(phi_p3,Qb_tmp)
Qp3_0 = -pd * (xg - phi_p3) - Qb_tmp;
if (sigVds < 0) begin
`swap(Qp1_0, Qp3_0)
end
end else if (SWNQS_i == 5) begin
phi_p1 = `Phiy(`oneSixth);
`PhiToQb(phi_p1,Qb_tmp)
Qp1_0 = -pd * (xg - phi_p1) - Qb_tmp;
phi_p2 = `Phiy(`oneThird);
`PhiToQb(phi_p2,Qb_tmp)
Qp2_0 = -pd * (xg - phi_p2) - Qb_tmp;
phi_p3 = `Phiy(0.5);
`PhiToQb(phi_p3,Qb_tmp)
Qp3_0 = -pd * (xg - phi_p3) - Qb_tmp;
phi_p4 = `Phiy(`twoThirds);
`PhiToQb(phi_p4,Qb_tmp)
Qp4_0 = -pd * (xg - phi_p4) - Qb_tmp;
phi_p5 = `Phiy(0.8333333333333333);
`PhiToQb(phi_p5,Qb_tmp)
Qp5_0 = -pd * (xg - phi_p5) - Qb_tmp;
if (sigVds < 0) begin
`swap(Qp1_0, Qp5_0)
`swap(Qp2_0, Qp4_0)
end
end else if (SWNQS_i == 9) begin
phi_p1 = `Phiy(0.1);
`PhiToQb(phi_p1,Qb_tmp)
Qp1_0 = -pd * (xg - phi_p1) - Qb_tmp;
phi_p2 = `Phiy(0.2);
`PhiToQb(phi_p2,Qb_tmp)
Qp2_0 = -pd * (xg - phi_p2) - Qb_tmp;
phi_p3 = `Phiy(0.3);
`PhiToQb(phi_p3,Qb_tmp)
Qp3_0 = -pd * (xg - phi_p3) - Qb_tmp;
phi_p4 = `Phiy(0.4);
`PhiToQb(phi_p4,Qb_tmp)
Qp4_0 = -pd * (xg - phi_p4) - Qb_tmp;
phi_p5 = `Phiy(0.5);
`PhiToQb(phi_p5,Qb_tmp)
Qp5_0 = -pd * (xg - phi_p5) - Qb_tmp;
phi_p6 = `Phiy(0.6);
`PhiToQb(phi_p6,Qb_tmp)
Qp6_0 = -pd * (xg - phi_p6) - Qb_tmp;
phi_p7 = `Phiy(0.7);
`PhiToQb(phi_p7,Qb_tmp)
Qp7_0 = -pd * (xg - phi_p7) - Qb_tmp;
phi_p8 = `Phiy(0.8);
`PhiToQb(phi_p8,Qb_tmp)
Qp8_0 = -pd * (xg - phi_p8) - Qb_tmp;
phi_p9 = `Phiy(0.9);
`PhiToQb(phi_p9,Qb_tmp)
Qp9_0 = -pd * (xg - phi_p9) - Qb_tmp;
if (sigVds < 0) begin
`swap(Qp1_0, Qp9_0)
`swap(Qp2_0, Qp8_0)
`swap(Qp3_0, Qp7_0)
`swap(Qp4_0, Qp6_0)
end
end
end // (x_g >0)
end // (SWNQS_i != 0)
x_sp = 0.0;
x_dp = 0.0;
Qp0 = 0.0;
QpN = 0.0;
if (SWNQS_i != 0.0) begin
x_sp = x_m - sigVds * 0.5 * dps * inv_phit1;
x_dp = x_m + sigVds * 0.5 * dps * inv_phit1;
Qp0 = 0.0;
QpN = 0.0;
if (x_sp > 0) begin
`PhiToQb(x_sp, QbSIGN)
Qp0 = -pd * (xg - x_sp) - QbSIGN;
end
if (x_dp > 0) begin
`PhiToQb(x_dp, QbSIGN)
QpN = -pd * (xg - x_dp) - QbSIGN;
end
end

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//======================================================================================
//======================================================================================
// Filename: PSP102_binning.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
// auxiliary variables
iLEWE = iLE * iWE;
iiLE = LE / LEN;
iiWE = WE / WEN;
iiLEWE = iiLE * iiWE;
iiiLEWE = iiWE / iiLE;
// auxiliary variables for COX only
iiLEcv = LEcv / LEN;
iiWEcv = WEcv / WEN;
iiLEWEcv = iiLEcv * iiWEcv;
// auxiliary variables for CGOV only
iLEcv = LEN / LEcv;
iiiLEWEcv = iiWEcv / iiLEcv;
// auxiliary variables for CGBOV only
iiLcv = Lcv / LEN;
iiWcv = Wcv / WEN;
iiLWcv = iiLcv * iiWcv;
// auxiliary variables for CFR only
iLcv = LEN / Lcv;
iiiLWcv = iiWcv / iiLcv;
// Process parameters
VFB = POVFB + iLE * PLVFB + iWE * PWVFB + iLEWE * PLWVFB;
STVFB = POSTVFB + iLE * PLSTVFB + iWE * PWSTVFB + iLEWE * PLWSTVFB;
TOX = POTOX;
NEFF = PONEFF + iLE * PLNEFF + iWE * PWNEFF + iLEWE * PLWNEFF;
VNSUB = POVNSUB;
NSLP = PONSLP;
DNSUB = PODNSUB;
DPHIB = PODPHIB + iLE * PLDPHIB + iWE * PWDPHIB + iLEWE * PLWDPHIB;
NP = PONP + iLE * PLNP + iWE * PWNP + iLEWE * PLWNP;
CT = POCT + iLE * PLCT + iWE * PWCT + iLEWE * PLWCT;
TOXOV = POTOXOV;
NOV = PONOV + iLE * PLNOV + iWE * PWNOV + iLEWE * PLWNOV;
// DIBL parameters
CF = POCF + iLE * PLCF + iWE * PWCF + iLEWE * PLWCF;
CFB = POCFB;
// Mobility parameters
BETN = POBETN + iLE * PLBETN + iiWE * PWBETN + iiiLEWE * PLWBETN;
STBET = POSTBET + iLE * PLSTBET + iWE * PWSTBET + iLEWE * PLWSTBET;
MUE = POMUE + iLE * PLMUE + iWE * PWMUE + iLEWE * PLWMUE;
STMUE = POSTMUE;
THEMU = POTHEMU;
STTHEMU = POSTTHEMU;
CS = POCS + iLE * PLCS + iWE * PWCS + iLEWE * PLWCS;
STCS = POSTCS;
XCOR = POXCOR + iLE * PLXCOR + iWE * PWXCOR + iLEWE * PLWXCOR;
STXCOR = POSTXCOR;
FETA = POFETA;
// Series resistance parameters
RS = PORS + iLE * PLRS + iWE * PWRS + iLEWE * PLWRS;
STRS = POSTRS;
RSB = PORSB;
RSG = PORSG;
// Velocity saturation parameters
THESAT = POTHESAT + iLE * PLTHESAT + iWE * PWTHESAT + iLEWE * PLWTHESAT;
STTHESAT = POSTTHESAT + iLE * PLSTTHESAT + iWE * PWSTTHESAT + iLEWE * PLWSTTHESAT;
THESATB = POTHESATB + iLE * PLTHESATB + iWE * PWTHESATB + iLEWE * PLWTHESATB;
THESATG = POTHESATG + iLE * PLTHESATG + iWE * PWTHESATG + iLEWE * PLWTHESATG;
// Saturation voltage parameters
AX = POAX + iLE * PLAX + iWE * PWAX + iLEWE * PLWAX;
// Channel length modulation (CLM) parameters
ALP = POALP + iLE * PLALP + iWE * PWALP + iLEWE * PLWALP;
ALP1 = POALP1 + iLE * PLALP1 + iWE * PWALP1 + iLEWE * PLWALP1;
ALP2 = POALP2 + iLE * PLALP2 + iWE * PWALP2 + iLEWE * PLWALP2;
VP = POVP;
// Impact ionization parameters
A1 = POA1 + iLE * PLA1 + iWE * PWA1 + iLEWE * PLWA1;
A2 = POA2;
STA2 = POSTA2;
A3 = POA3 + iLE * PLA3 + iWE * PWA3 + iLEWE * PLWA3;
A4 = POA4 + iLE * PLA4 + iWE * PWA4 + iLEWE * PLWA4;
GCO = POGCO;
// Gate current parameters
IGINV = POIGINV + iiLE * PLIGINV + iiWE * PWIGINV + iiLEWE * PLWIGINV;
IGOV = POIGOV + iLE * PLIGOV + iiWE * PWIGOV + iiiLEWE * PLWIGOV;
STIG = POSTIG;
GC2 = POGC2;
GC3 = POGC3;
CHIB = POCHIB;
// Gate-induced drain leakage (GIDL) parameters
AGIDL = POAGIDL + iLE * PLAGIDL + iiWE * PWAGIDL + iiiLEWE * PLWAGIDL;
BGIDL = POBGIDL;
STBGIDL = POSTBGIDL;
CGIDL = POCGIDL;
// Charge model parameters
COX = POCOX + iiLEcv * PLCOX + iiWEcv * PWCOX + iiLEWEcv * PLWCOX;
CGOV = POCGOV + iLEcv * PLCGOV + iiWEcv * PWCGOV + iiiLEWEcv * PLWCGOV;
CGBOV = POCGBOV + iiLcv * PLCGBOV + iiWcv * PWCGBOV + iiLWcv * PLWCGBOV;
CFR = POCFR + iLcv * PLCFR + iiWcv * PWCFR + iiiLWcv * PLWCFR;
// Noise model parameters
FNT = POFNT;
NFA = PONFA + iLE * PLNFA + iWE * PWNFA + iLEWE * PLWNFA;
NFB = PONFB + iLE * PLNFB + iWE * PWNFB + iLEWE * PLWNFB;
NFC = PONFC + iLE * PLNFC + iWE * PWNFC + iLEWE * PLWNFC;

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//======================================================================================
//======================================================================================
// Filename: PSP102_binpars.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
///////////////////////////////////////////////////
// PSP global model parameters (binning)
///////////////////////////////////////////////////
parameter real LEVEL = 1021 `P(info="Model level" unit="" );
parameter real TYPE = 1 `from( -1.0,1.0 ) `P(info="Channel type parameter, +1=NMOS -1=PMOS" unit="" );
parameter real TR = 21 `from( -273.0,inf ) `P(info="nominal (reference) temperature" unit="C" );
// Switch parameters
parameter real SWIGATE = 0 `from( 0.0,1.0 ) `P(info="Flag for gate current, 0=turn off IG" unit="" );
parameter real SWIMPACT = 0 `from( 0.0,1.0 ) `P(info="Flag for impact ionization current, 0=turn off II" unit="" );
parameter real SWGIDL = 0 `from( 0.0,1.0 ) `P(info="Flag for GIDL current, 0=turn off IGIDL" unit="" );
parameter real SWJUNCAP = 0 `from( 0.0,3.0 ) `P(info="Flag for juncap, 0=turn off juncap" unit="" );
parameter real QMC = 1 `from( 0.0,inf ) `P(info="Quantum-mechanical correction factor" unit="" );
// Process parameters
parameter real LVARO = 0 `P(info="Geometry independent difference between actual and programmed poly-silicon gate length" unit="m" );
parameter real LVARL = 0 `P(info="Length dependence of difference between actual and programmed poly-silicon gate length" unit="" );
parameter real LAP = 0 `P(info="Effective channel length reduction per side due to lateral diffusion of source/drain dopant ions" unit="m" );
parameter real WVARO = 0 `P(info="Geometry independent difference between actual and programmed field-oxide opening" unit="m" );
parameter real WVARW = 0 `P(info="Width dependence of difference between actual and programmed field-oxide opening" unit="" );
parameter real WOT = 0 `P(info="Effective reduction of channel width per side due to lateral diffusion of channel-stop dopant ions" unit="m" );
parameter real DLQ = 0 `P(info="Effective channel length reduction for CV" unit="m" );
parameter real DWQ = 0 `P(info="Effective channel width reduction for CV" unit="m" );
parameter real POVFB = -1 `P(info="Coefficient for the geometry independent part of VFB" unit="V" );
parameter real PLVFB = 0.0 `P(info="Coefficient for the length dependence of VFB" unit="V" );
parameter real PWVFB = 0.0 `P(info="Coefficient for the width dependence of VFB" unit="V" );
parameter real PLWVFB = 0.0 `P(info="Coefficient for the length times width dependence of VFB" unit="V" );
parameter real POSTVFB = 0.0005 `P(info="Coefficient for the geometry independent part of STVFB" unit="V/K" );
parameter real PLSTVFB = 0.0 `P(info="Coefficient for the length dependence of STVFB" unit="V/K" );
parameter real PWSTVFB = 0.0 `P(info="Coefficient for the width dependence of STVFB" unit="V/K" );
parameter real PLWSTVFB = 0.0 `P(info="Coefficient for the length times width dependence of STVFB" unit="V/K" );
parameter real POTOX = 2E-09 `P(info="Coefficient for the geometry independent part of TOX" unit="m" );
parameter real PONEFF = 5E+23 `P(info="Coefficient for the geometry independent part of NEFF" unit="m^-3" );
parameter real PLNEFF = 0.0 `P(info="Coefficient for the length dependence of NEFF" unit="m^-3" );
parameter real PWNEFF = 0.0 `P(info="Coefficient for the width dependence of NEFF" unit="m^-3" );
parameter real PLWNEFF = 0.0 `P(info="Coefficient for the length times width dependence of NEFF" unit="m^-3" );
parameter real POVNSUB = 0 `P(info="Coefficient for the geometry independent part of VNSUB" unit="V" );
parameter real PONSLP = 0.05 `P(info="Coefficient for the geometry independent part of NSLP" unit="V" );
parameter real PODNSUB = 0 `P(info="Coefficient for the geometry independent part of DNSUB" unit="V^-1" );
parameter real PODPHIB = 0 `P(info="Coefficient for the geometry independent part of DPHIB" unit="V" );
parameter real PLDPHIB = 0.0 `P(info="Coefficient for the length dependence of DPHIB" unit="V" );
parameter real PWDPHIB = 0.0 `P(info="Coefficient for the width dependence of DPHIB" unit="V" );
parameter real PLWDPHIB = 0.0 `P(info="Coefficient for the length times width dependence of DPHIB" unit="V" );
parameter real PONP = 1E+26 `P(info="Coefficient for the geometry independent part of NP" unit="m^-3" );
parameter real PLNP = 0.0 `P(info="Coefficient for the length dependence of NP" unit="m^-3" );
parameter real PWNP = 0.0 `P(info="Coefficient for the width dependence of NP" unit="m^-3" );
parameter real PLWNP = 0.0 `P(info="Coefficient for the length times width dependence of NP" unit="m^-3" );
parameter real POCT = 0 `P(info="Coefficient for the geometry independent part of CT" unit="" );
parameter real PLCT = 0.0 `P(info="Coefficient for the length dependence of CT" unit="" );
parameter real PWCT = 0.0 `P(info="Coefficient for the width dependence of CT" unit="" );
parameter real PLWCT = 0.0 `P(info="Coefficient for the length times width dependence of CT" unit="" );
parameter real POTOXOV = 2E-09 `P(info="Coefficient for the geometry independent part of TOXOV" unit="m" );
parameter real PONOV = 5E+25 `P(info="Coefficient for the geometry independent part of NOV" unit="m^-3" );
parameter real PLNOV = 0.0 `P(info="Coefficient for the length dependence of NOV" unit="m^-3" );
parameter real PWNOV = 0.0 `P(info="Coefficient for the width dependence of NOV" unit="m^-3" );
parameter real PLWNOV = 0.0 `P(info="Coefficient for the length times width dependence of NOV" unit="m^-3" );
// DIBL parameters
parameter real POCF = 0 `P(info="Coefficient for the geometry independent part of CF" unit="V^-1" );
parameter real PLCF = 0.0 `P(info="Coefficient for the length dependence of CF" unit="V^-1" );
parameter real PWCF = 0.0 `P(info="Coefficient for the width dependence of CF" unit="V^-1" );
parameter real PLWCF = 0.0 `P(info="Coefficient for the length times width dependence of CF" unit="V^-1" );
parameter real POCFB = 0 `P(info="Coefficient for the geometry independent part of CFB" unit="V^-1" );
// Mobility parameters
parameter real POBETN = 0.07 `P(info="Coefficient for the geometry independent part of BETN" unit="m^2/V/s" );
parameter real PLBETN = 0.0 `P(info="Coefficient for the length dependence of BETN" unit="m^2/V/s" );
parameter real PWBETN = 0.0 `P(info="Coefficient for the width dependence of BETN" unit="m^2/V/s" );
parameter real PLWBETN = 0.0 `P(info="Coefficient for the length times width dependence of BETN" unit="m^2/V/s" );
parameter real POSTBET = 1 `P(info="Coefficient for the geometry independent part of STBET" unit="" );
parameter real PLSTBET = 0.0 `P(info="Coefficient for the length dependence of STBET" unit="" );
parameter real PWSTBET = 0.0 `P(info="Coefficient for the width dependence of STBET" unit="" );
parameter real PLWSTBET = 0.0 `P(info="Coefficient for the length times width dependence of STBET" unit="" );
parameter real POMUE = 0.5 `P(info="Coefficient for the geometry independent part of MUE" unit="m/V" );
parameter real PLMUE = 0.0 `P(info="Coefficient for the length dependence of MUE" unit="m/V" );
parameter real PWMUE = 0.0 `P(info="Coefficient for the width dependence of MUE" unit="m/V" );
parameter real PLWMUE = 0.0 `P(info="Coefficient for the length times width dependence of MUE" unit="m/V" );
parameter real POSTMUE = 0 `P(info="Coefficient for the geometry independent part of STMUE" unit="" );
parameter real POTHEMU = 1.5 `P(info="Coefficient for the geometry independent part of THEMU" unit="" );
parameter real POSTTHEMU = 1.5 `P(info="Coefficient for the geometry independent part of STTHEMU" unit="" );
parameter real POCS = 0 `P(info="Coefficient for the geometry independent part of CS" unit="" );
parameter real PLCS = 0.0 `P(info="Coefficient for the length dependence of CS" unit="" );
parameter real PWCS = 0.0 `P(info="Coefficient for the width dependence of CS" unit="" );
parameter real PLWCS = 0.0 `P(info="Coefficient for the length times width dependence of CS" unit="" );
parameter real POSTCS = 0 `P(info="Coefficient for the geometry independent part of STCS" unit="" );
parameter real POXCOR = 0 `P(info="Coefficient for the geometry independent part of XCOR" unit="V^-1" );
parameter real PLXCOR = 0.0 `P(info="Coefficient for the length dependence of XCOR" unit="V^-1" );
parameter real PWXCOR = 0.0 `P(info="Coefficient for the width dependence of XCOR" unit="V^-1" );
parameter real PLWXCOR = 0.0 `P(info="Coefficient for the length times width dependence of XCOR" unit="V^-1" );
parameter real POSTXCOR = 0 `P(info="Coefficient for the geometry independent part of STXCOR" unit="" );
parameter real POFETA = 1 `P(info="Coefficient for the geometry independent part of FETA" unit="" );
// Series resistance parameters
parameter real PORS = 30 `P(info="Coefficient for the geometry independent part of RS" unit="Ohm" );
parameter real PLRS = 0.0 `P(info="Coefficient for the length dependence of RS" unit="Ohm" );
parameter real PWRS = 0.0 `P(info="Coefficient for the width dependence of RS" unit="Ohm" );
parameter real PLWRS = 0.0 `P(info="Coefficient for the length times width dependence of RS" unit="Ohm" );
parameter real POSTRS = 1 `P(info="Coefficient for the geometry independent part of STRS" unit="" );
parameter real PORSB = 0 `P(info="Coefficient for the geometry independent part of RSB" unit="V^-1" );
parameter real PORSG = 0 `P(info="Coefficient for the geometry independent part of RSG" unit="V^-1" );
// Velocity saturation parameters
parameter real POTHESAT = 1 `P(info="Coefficient for the geometry independent part of THESAT" unit="V^-1" );
parameter real PLTHESAT = 0.0 `P(info="Coefficient for the length dependence of THESAT" unit="V^-1" );
parameter real PWTHESAT = 0.0 `P(info="Coefficient for the width dependence of THESAT" unit="V^-1" );
parameter real PLWTHESAT = 0.0 `P(info="Coefficient for the length times width dependence of THESAT" unit="V^-1" );
parameter real POSTTHESAT = 1 `P(info="Coefficient for the geometry independent part of STTHESAT" unit="" );
parameter real PLSTTHESAT = 0.0 `P(info="Coefficient for the length dependence of STTHESAT" unit="" );
parameter real PWSTTHESAT = 0.0 `P(info="Coefficient for the width dependence of STTHESAT" unit="" );
parameter real PLWSTTHESAT = 0.0 `P(info="Coefficient for the length times width dependence of STTHESAT" unit="" );
parameter real POTHESATB = 0 `P(info="Coefficient for the geometry independent part of THESATB" unit="V^-1" );
parameter real PLTHESATB = 0.0 `P(info="Coefficient for the length dependence of THESATB" unit="V^-1" );
parameter real PWTHESATB = 0.0 `P(info="Coefficient for the width dependence of THESATB" unit="V^-1" );
parameter real PLWTHESATB = 0.0 `P(info="Coefficient for the length times width dependence of THESATB" unit="V^-1" );
parameter real POTHESATG = 0 `P(info="Coefficient for the geometry independent part of THESATG" unit="V^-1" );
parameter real PLTHESATG = 0.0 `P(info="Coefficient for the length dependence of THESATG" unit="V^-1" );
parameter real PWTHESATG = 0.0 `P(info="Coefficient for the width dependence of THESATG" unit="V^-1" );
parameter real PLWTHESATG = 0.0 `P(info="Coefficient for the length times width dependence of THESATG" unit="V^-1" );
// Saturation voltage parameters
parameter real POAX = 3 `P(info="Coefficient for the geometry independent part of AX" unit="" );
parameter real PLAX = 0.0 `P(info="Coefficient for the length dependence of AX" unit="" );
parameter real PWAX = 0.0 `P(info="Coefficient for the width dependence of AX" unit="" );
parameter real PLWAX = 0.0 `P(info="Coefficient for the length times width dependence of AX" unit="" );
// Channel length modulation (CLM) parameters
parameter real POALP = 0.01 `P(info="Coefficient for the geometry independent part of ALP" unit="" );
parameter real PLALP = 0.0 `P(info="Coefficient for the length dependence of ALP" unit="" );
parameter real PWALP = 0.0 `P(info="Coefficient for the width dependence of ALP" unit="" );
parameter real PLWALP = 0.0 `P(info="Coefficient for the length times width dependence of ALP" unit="" );
parameter real POALP1 = 0 `P(info="Coefficient for the geometry independent part of ALP1" unit="V" );
parameter real PLALP1 = 0.0 `P(info="Coefficient for the length dependence of ALP1" unit="V" );
parameter real PWALP1 = 0.0 `P(info="Coefficient for the width dependence of ALP1" unit="V" );
parameter real PLWALP1 = 0.0 `P(info="Coefficient for the length times width dependence of ALP1" unit="V" );
parameter real POALP2 = 0 `P(info="Coefficient for the geometry independent part of ALP2" unit="V^-1" );
parameter real PLALP2 = 0.0 `P(info="Coefficient for the length dependence of ALP2" unit="V^-1" );
parameter real PWALP2 = 0.0 `P(info="Coefficient for the width dependence of ALP2" unit="V^-1" );
parameter real PLWALP2 = 0.0 `P(info="Coefficient for the length times width dependence of ALP2" unit="V^-1" );
parameter real POVP = 0.05 `P(info="Coefficient for the geometry independent part of VP" unit="V" );
// Impact ionization parameters
parameter real POA1 = 1 `P(info="Coefficient for the geometry independent part of A1" unit="" );
parameter real PLA1 = 0.0 `P(info="Coefficient for the length dependence of A1" unit="" );
parameter real PWA1 = 0.0 `P(info="Coefficient for the width dependence of A1" unit="" );
parameter real PLWA1 = 0.0 `P(info="Coefficient for the length times width dependence of A1" unit="" );
parameter real POA2 = 10 `P(info="Coefficient for the geometry independent part of A2" unit="V" );
parameter real POSTA2 = 0 `P(info="Coefficient for the geometry independent part of STA2" unit="V" );
parameter real POA3 = 1 `P(info="Coefficient for the geometry independent part of A3" unit="" );
parameter real PLA3 = 0.0 `P(info="Coefficient for the length dependence of A3" unit="" );
parameter real PWA3 = 0.0 `P(info="Coefficient for the width dependence of A3" unit="" );
parameter real PLWA3 = 0.0 `P(info="Coefficient for the length times width dependence of A3" unit="" );
parameter real POA4 = 0 `P(info="Coefficient for the geometry independent part of A4" unit="V^-0.5" );
parameter real PLA4 = 0.0 `P(info="Coefficient for the length dependence of A4" unit="V^-0.5" );
parameter real PWA4 = 0.0 `P(info="Coefficient for the width dependence of A4" unit="V^-0.5" );
parameter real PLWA4 = 0.0 `P(info="Coefficient for the length times width dependence of A4" unit="V^-0.5" );
parameter real POGCO = 0 `P(info="Coefficient for the geometry independent part of GCO" unit="" );
// Gate current parameters
parameter real POIGINV = 0 `P(info="Coefficient for the geometry independent part of IGINV" unit="A" );
parameter real PLIGINV = 0.0 `P(info="Coefficient for the length dependence of IGINV" unit="A" );
parameter real PWIGINV = 0.0 `P(info="Coefficient for the width dependence of IGINV" unit="A" );
parameter real PLWIGINV = 0.0 `P(info="Coefficient for the length times width dependence of IGINV" unit="A" );
parameter real POIGOV = 0 `P(info="Coefficient for the geometry independent part of IGOV" unit="A" );
parameter real PLIGOV = 0.0 `P(info="Coefficient for the length dependence of IGOV" unit="A" );
parameter real PWIGOV = 0.0 `P(info="Coefficient for the width dependence of IGOV" unit="A" );
parameter real PLWIGOV = 0.0 `P(info="Coefficient for the length times width dependence of IGOV" unit="A" );
parameter real POSTIG = 2 `P(info="Coefficient for the geometry independent part of STIG" unit="" );
parameter real POGC2 = 0.375 `P(info="Coefficient for the geometry independent part of GC2" unit="" );
parameter real POGC3 = 0.063 `P(info="Coefficient for the geometry independent part of GC3" unit="" );
parameter real POCHIB = 3.1 `P(info="Coefficient for the geometry independent part of CHIB" unit="V" );
// Gate-induced drain leakage (GIDL) parameters
parameter real POAGIDL = 0 `P(info="Coefficient for the geometry independent part of AGIDL" unit="A/V^3" );
parameter real PLAGIDL = 0.0 `P(info="Coefficient for the length dependence of AGIDL" unit="A/V^3" );
parameter real PWAGIDL = 0.0 `P(info="Coefficient for the width dependence of AGIDL" unit="A/V^3" );
parameter real PLWAGIDL = 0.0 `P(info="Coefficient for the length times width dependence of AGIDL" unit="A/V^3" );
parameter real POBGIDL = 41 `P(info="Coefficient for the geometry independent part of BGIDL" unit="V" );
parameter real POSTBGIDL = 0 `P(info="Coefficient for the geometry independent part of STBGIDL" unit="V/K" );
parameter real POCGIDL = 0 `P(info="Coefficient for the geometry independent part of CGIDL" unit="" );
// Charge model parameters
parameter real POCOX = 1E-14 `P(info="Coefficient for the geometry independent part of COX" unit="F" );
parameter real PLCOX = 0.0 `P(info="Coefficient for the length dependence of COX" unit="F" );
parameter real PWCOX = 0.0 `P(info="Coefficient for the width dependence of COX" unit="F" );
parameter real PLWCOX = 0.0 `P(info="Coefficient for the length times width dependence of COX" unit="F" );
parameter real POCGOV = 1E-15 `P(info="Coefficient for the geometry independent part of CGOV" unit="F" );
parameter real PLCGOV = 0.0 `P(info="Coefficient for the length dependence of CGOV" unit="F" );
parameter real PWCGOV = 0.0 `P(info="Coefficient for the width dependence of CGOV" unit="F" );
parameter real PLWCGOV = 0.0 `P(info="Coefficient for the length times width dependence of CGOV" unit="F" );
parameter real POCGBOV = 0 `P(info="Coefficient for the geometry independent part of CGBOV" unit="F" );
parameter real PLCGBOV = 0.0 `P(info="Coefficient for the length dependence of CGBOV" unit="F" );
parameter real PWCGBOV = 0.0 `P(info="Coefficient for the width dependence of CGBOV" unit="F" );
parameter real PLWCGBOV = 0.0 `P(info="Coefficient for the length times width dependence of CGBOV" unit="F" );
parameter real POCFR = 0 `P(info="Coefficient for the geometry independent part of CFR" unit="F" );
parameter real PLCFR = 0.0 `P(info="Coefficient for the length dependence of CFR" unit="F" );
parameter real PWCFR = 0.0 `P(info="Coefficient for the width dependence of CFR" unit="F" );
parameter real PLWCFR = 0.0 `P(info="Coefficient for the length times width dependence of CFR" unit="F" );
// Noise model parameters
parameter real POFNT = 1 `P(info="Coefficient for the geometry independent part of FNT" unit="" );
parameter real PONFA = 8E+22 `P(info="Coefficient for the geometry independent part of NFA" unit="V^-1/m^4" );
parameter real PLNFA = 0.0 `P(info="Coefficient for the length dependence of NFA" unit="V^-1/m^4" );
parameter real PWNFA = 0.0 `P(info="Coefficient for the width dependence of NFA" unit="V^-1/m^4" );
parameter real PLWNFA = 0.0 `P(info="Coefficient for the length times width dependence of NFA" unit="V^-1/m^4" );
parameter real PONFB = 3E+07 `P(info="Coefficient for the geometry independent part of NFB" unit="V^-1/m^2" );
parameter real PLNFB = 0.0 `P(info="Coefficient for the length dependence of NFB" unit="V^-1/m^2" );
parameter real PWNFB = 0.0 `P(info="Coefficient for the width dependence of NFB" unit="V^-1/m^2" );
parameter real PLWNFB = 0.0 `P(info="Coefficient for the length times width dependence of NFB" unit="V^-1/m^2" );
parameter real PONFC = 0 `P(info="Coefficient for the geometry independent part of NFC" unit="V^-1" );
parameter real PLNFC = 0.0 `P(info="Coefficient for the length dependence of NFC" unit="V^-1" );
parameter real PWNFC = 0.0 `P(info="Coefficient for the width dependence of NFC" unit="V^-1" );
parameter real PLWNFC = 0.0 `P(info="Coefficient for the length times width dependence of NFC" unit="V^-1" );
// Other parameters
parameter real DTA = 0 `P(info="Temperature offset w.r.t. ambient temperature" unit="K" );

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//======================================================================================
//======================================================================================
// Filename: PSP102_macrodefs.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
/////////////////////////////////////////////
//
// Macros and constants used in PSP
//
/////////////////////////////////////////////
// Explicit Gmin
`define GMIN 1E-15
`define PMOS -1
`define NMOS +1
// Some functions
`define MINA(x,y,a) 0.5*((x)+(y)-sqrt(((x)-(y))*((x)-(y))+(a)))
`define MAXA(x,y,a) 0.5*((x)+(y)+sqrt(((x)-(y))*((x)-(y))+(a)))
// Physical constants
`define EPSOX 3.453E-11
`define QMN 5.951993
`define QMP 7.448711
// Other constants (PSP-mos)
`define DELTA1 0.02
`define invSqrt2 7.0710678118654746e-01
`define oneSixth 1.6666666666666667e-01
`define exp80 5.5406223843935098e+34
`define exp160 3.0698496406442424e+69
`ifdef NQSmodel
`define Gint GP
`define Bint BP
`define Bjs BS
`define Bjd BD
`else // NQSmodel
`define Gint G
`define Bint B
`define Bjs B
`define Bjd B
`endif // NQSModel
/////////////////////////////////////////////////////////////////////////////
//
// Macro definitions.
//
// Note that because at present locally scoped variables
// can only be in named blocks, the intermediate variables
// used in the macros below must be explicitly declared
// as variables in the main code.
//
/////////////////////////////////////////////////////////////////////////////
// sigma function used in surface potential and other calculations
// (one call uses expressions for arguments so parentheses
// around the arguments in the expressions are necessary)
`define sigma(a,c,tau,eta,y) \
nu = (a) + (c); \
mu = nu * nu / (tau) + 0.5 * (c) * (c) - (a); \
y = (eta) + (a) * nu / (mu + (nu / mu) * (c) * ((c) * (c) * `oneThird - (a)));
// modified version of sigma, which takes 4 arguments
`define sigma2(a,b,c,tau,eta,y) \
nu = (a) + (c); \
if (abs(tau) < 1e-120) begin /*sometimes tau is extremely small...*/\
y = (eta); \
end else begin \
mu = (nu) * (nu) / (tau) + 0.5 * (c) * (c) - (a) * (b); \
y = (eta) + (a) * nu / (mu + (nu / mu) * (c) * ((c) * (c) * `oneThird - (a) * (b))); \
end
//
// sp_s surface potential calculation
//
`define sp_s(sp,xg,xn,delta) \
if (abs(xg) <= margin) begin \
SP_S_temp1 = inv_xi * inv_xi * `oneSixth * `invSqrt2; \
sp = xg * inv_xi * (1.0 + xg * (1.0 - (delta)) * Gf * SP_S_temp1); \
end else begin \
if (xg < -margin) begin \
SP_S_yg = -xg; \
SP_S_ysub = 1.25 * SP_S_yg * inv_xi; \
SP_S_eta = 0.5 * (SP_S_ysub + 10 - sqrt((SP_S_ysub - 6.0) * (SP_S_ysub - 6.0) + 64.0)); \
SP_S_temp = SP_S_yg - SP_S_eta; \
SP_S_a = SP_S_temp * SP_S_temp + Gf2*(SP_S_eta + 1.0);\
SP_S_c = 2.0 * SP_S_temp - Gf2; \
SP_S_tau = -SP_S_eta + ln(SP_S_a * inv_Gf2); \
`sigma(SP_S_a, SP_S_c, SP_S_tau, SP_S_eta, SP_S_y0) \
`expl_high(SP_S_y0, SP_S_delta0) \
SP_S_delta1 = 1.0 / SP_S_delta0; \
SP_S_temp = 1.0 / (2.0 + SP_S_y0 * SP_S_y0); \
SP_S_xi0 = SP_S_y0 * SP_S_y0 * SP_S_temp; \
SP_S_xi1 = 4.0 * SP_S_y0 * SP_S_temp * SP_S_temp; \
SP_S_xi2 = (8.0 * SP_S_temp - 12.0 * SP_S_xi0) * SP_S_temp * SP_S_temp; \
SP_S_temp = SP_S_yg - SP_S_y0; \
SP_S_temp1 = (delta) * SP_S_delta1; \
SP_S_pC = 2.0 * SP_S_temp + Gf2 * (SP_S_delta0 - 1.0 - SP_S_temp1 + (delta) * (1.0 - SP_S_xi1)); \
SP_S_qC = SP_S_temp * SP_S_temp - Gf2 * (SP_S_delta0 - SP_S_y0 - 1.0 + SP_S_temp1 + (delta) * (SP_S_y0 - 1.0 - SP_S_xi0)); \
SP_S_temp = 2.0 - Gf2*(SP_S_delta0 + SP_S_temp1 - (delta) * SP_S_xi2); \
SP_S_temp = SP_S_pC * SP_S_pC - 2.0 * SP_S_qC * SP_S_temp; \
sp = -SP_S_y0 - 2.0 * SP_S_qC / (SP_S_pC + sqrt(SP_S_temp)); \
end else begin \
SP_xg1 = 1.0 / (x1 + Gf * 7.324648775608221e-001); \
SP_S_A_fac= (xi * x1 * SP_xg1 - 1.0) * SP_xg1; \
SP_S_xbar = xg * inv_xi * (1.0 + SP_S_A_fac * xg); \
`expl_low(-SP_S_xbar, SP_S_temp) \
SP_S_w = 1.0 - SP_S_temp; \
SP_S_x1 = xg + Gf2 * 0.5 - Gf * sqrt(xg + Gf2 * 0.25 - SP_S_w); \
SP_S_bx = (xn) + 3.0; \
SP_S_eta = `MINA(SP_S_x1, SP_S_bx, 5.0) - 0.5 * (SP_S_bx - sqrt(SP_S_bx * SP_S_bx + 5.0)); \
SP_S_temp = xg - SP_S_eta; \
SP_S_temp1= exp(-SP_S_eta); \
SP_S_temp2= 1.0 / (2.0 + SP_S_eta * SP_S_eta); \
SP_S_xi0 = SP_S_eta * SP_S_eta * SP_S_temp2; \
SP_S_xi1 = 4.0 * SP_S_eta * SP_S_temp2 * SP_S_temp2; \
SP_S_xi2 = (8.0 * SP_S_temp2 - 12.0 * SP_S_xi0) * SP_S_temp2 * SP_S_temp2; \
SP_S_a = max(1.0e-40, SP_S_temp * SP_S_temp - Gf2 * (SP_S_temp1 + SP_S_eta - 1.0 - (delta) * (SP_S_eta + 1.0 + SP_S_xi0))); \
SP_S_b = 1.0 - 0.5 * Gf2 * (SP_S_temp1 - (delta) * SP_S_xi2); \
SP_S_c = 2.0 * SP_S_temp + Gf2 * (1.0 - SP_S_temp1 - (delta) * (1.0 + SP_S_xi1)); \
SP_S_tau = (xn) - SP_S_eta + ln(SP_S_a / Gf2); \
`sigma2(SP_S_a, SP_S_b, SP_S_c, SP_S_tau, SP_S_eta, SP_S_x0) \
if (SP_S_x0 < `se05) begin \
SP_S_delta0 = exp(SP_S_x0); \
SP_S_delta1 = 1.0 / SP_S_delta0; \
SP_S_delta0 = (delta) * SP_S_delta0; \
end else begin \
if (SP_S_x0 > (xn) - `se05) begin \
SP_S_delta0 = exp(SP_S_x0 - (xn)); \
SP_S_delta1 = (delta) / SP_S_delta0; \
end else begin \
SP_S_delta0 = `ke05 / `P3((xn) - SP_S_x0 - `se05); \
SP_S_delta1 = `ke05 / `P3(SP_S_x0 - `se05); \
end \
end \
SP_S_temp = 1.0 / (2.0 + SP_S_x0 * SP_S_x0); \
SP_S_xi0 = SP_S_x0 * SP_S_x0 * SP_S_temp; \
SP_S_xi1 = 4.0 * SP_S_x0 * SP_S_temp * SP_S_temp; \
SP_S_xi2 = (8.0 * SP_S_temp - 12.0 * SP_S_xi0) * SP_S_temp * SP_S_temp; \
SP_S_temp = xg - SP_S_x0; \
SP_S_pC = 2.0 * SP_S_temp + Gf2 * (1.0 - SP_S_delta1 + SP_S_delta0 - (delta) * (1.0 + SP_S_xi1)); \
SP_S_qC = SP_S_temp * SP_S_temp - Gf2 * (SP_S_delta1 + SP_S_x0 - 1.0 + SP_S_delta0 - (delta) * (SP_S_x0 + 1.0 + SP_S_xi0)); \
SP_S_temp = 2.0 - Gf2 * (SP_S_delta1 + SP_S_delta0 - (delta) * SP_S_xi2); \
SP_S_temp = SP_S_pC * SP_S_pC - 2.0 * SP_S_qC * SP_S_temp; \
sp = SP_S_x0 + 2.0 * SP_S_qC / (SP_S_pC + sqrt(SP_S_temp)); \
end \
end
//
// sp_s_d surface potential calculation at drain (subset of function sp_s)
//
`define sp_s_d(sp,xg,xn,delta) \
if (abs(xg) <= margin) begin \
SP_S_temp1 = inv_xi * inv_xi * `oneSixth * `invSqrt2; \
sp = xg * inv_xi * (1.0 + xg * (1.0 - (delta)) * Gf * SP_S_temp1); \
end else begin \
SP_S_bx = (xn) + 3; \
SP_S_eta = `MINA(SP_S_x1, SP_S_bx, 5.0) - 0.5 * (SP_S_bx - sqrt(SP_S_bx * SP_S_bx + 5.0)); \
SP_S_temp = xg - SP_S_eta; \
SP_S_temp1= exp(-SP_S_eta); \
SP_S_temp2= 1.0 / (2.0 + SP_S_eta * SP_S_eta); \
SP_S_xi0 = SP_S_eta * SP_S_eta * SP_S_temp2; \
SP_S_xi1 = 4.0 * SP_S_eta * SP_S_temp2 * SP_S_temp2; \
SP_S_xi2 = (8.0 * SP_S_temp2 - 12.0 * SP_S_xi0) * SP_S_temp2 * SP_S_temp2; \
SP_S_a = max(1.0e-40, SP_S_temp * SP_S_temp - Gf2 * (SP_S_temp1 + SP_S_eta - 1.0 - (delta) * (SP_S_eta + 1.0 + SP_S_xi0))); \
SP_S_b = 1.0 - 0.5 * Gf2 * (SP_S_temp1 - (delta) * SP_S_xi2); \
SP_S_c = 2.0 * SP_S_temp + Gf2 * (1.0 - SP_S_temp1 - (delta) * (1.0 + SP_S_xi1)); \
SP_S_tau = (xn) - SP_S_eta + ln(SP_S_a / Gf2); \
`sigma2(SP_S_a, SP_S_b, SP_S_c, SP_S_tau, SP_S_eta, SP_S_x0) \
if (SP_S_x0 < `se05) begin \
SP_S_delta0 = exp(SP_S_x0); \
SP_S_delta1 = 1.0 / SP_S_delta0; \
SP_S_delta0 = (delta) * SP_S_delta0; \
end else begin \
if (SP_S_x0 > (xn) - `se05) begin \
SP_S_delta0 = exp(SP_S_x0 - (xn)); \
SP_S_delta1 = (delta) / SP_S_delta0; \
end else begin \
SP_S_delta0 = `ke05 / `P3((xn) - SP_S_x0 - `se05); \
SP_S_delta1 = `ke05 / `P3(SP_S_x0 - `se05); \
end \
end \
SP_S_temp = 1.0 / (2.0 + SP_S_x0 * SP_S_x0); \
SP_S_xi0 = SP_S_x0 * SP_S_x0 * SP_S_temp; \
SP_S_xi1 = 4.0 * SP_S_x0 * SP_S_temp * SP_S_temp; \
SP_S_xi2 = (8.0 * SP_S_temp-12.0 * SP_S_xi0) * SP_S_temp * SP_S_temp; \
SP_S_temp = xg - SP_S_x0; \
SP_S_pC = 2.0 * SP_S_temp + Gf2 * (1.0 - SP_S_delta1 + SP_S_delta0 - (delta) * (1.0 + SP_S_xi1)); \
SP_S_qC = SP_S_temp * SP_S_temp - Gf2 * (SP_S_delta1 + SP_S_x0 - 1.0 + SP_S_delta0 - (delta) * (SP_S_x0 + 1.0 + SP_S_xi0)); \
SP_S_temp = 2.0 - Gf2*(SP_S_delta1+SP_S_delta0-(delta)*SP_S_xi2); \
SP_S_temp = SP_S_pC * SP_S_pC - 2.0 * SP_S_qC * SP_S_temp; \
sp = SP_S_x0 + 2.0 * SP_S_qC / (SP_S_pC + sqrt(SP_S_temp));\
end
//
// sp_ov surface potential calculation for the overlap regions
//
`define sp_ov(sp,xg) \
if (abs(xg) <= x_mrg_ov) begin \
sp = (-(xg) * inv_xi_ov); \
end else begin \
if (xg < -x_mrg_ov) begin \
SP_OV_yg = -xg; \
SP_OV_z = x1 * SP_OV_yg * inv_xi_ov; \
SP_OV_eta = 0.5 * (SP_OV_z + 10.0 - sqrt((SP_OV_z - 6.0) * (SP_OV_z - 6.0) + 64.0)); \
SP_OV_a = (SP_OV_yg - SP_OV_eta) * (SP_OV_yg - SP_OV_eta) + GOV2 * (SP_OV_eta + 1.0); \
SP_OV_c = 2.0 * (SP_OV_yg - SP_OV_eta) - GOV2; \
SP_OV_tau = ln(SP_OV_a / GOV2) - SP_OV_eta; \
`sigma(SP_OV_a, SP_OV_c, SP_OV_tau, SP_OV_eta, SP_OV_y0) \
SP_OV_D0 = exp(SP_OV_y0); \
SP_OV_temp = SP_OV_yg - SP_OV_y0; \
SP_OV_p = 2.0 * SP_OV_temp + GOV2 * (SP_OV_D0 - 1.0); \
SP_OV_q = SP_OV_temp * SP_OV_temp + GOV2 * (SP_OV_y0 + 1.0 - SP_OV_D0); \
SP_OV_xi = 1.0 - GOV2 * 0.5 * SP_OV_D0; \
SP_OV_temp = SP_OV_p * SP_OV_p - 4.0 * SP_OV_xi * SP_OV_q; \
SP_OV_w = 2.0 * SP_OV_q / (SP_OV_p + sqrt(SP_OV_temp)); \
sp = -(SP_OV_y0 + SP_OV_w); \
end else begin \
SP_OV_Afac = (xi_ov * x1 * inv_xg1 - 1.0) * inv_xg1; \
SP_OV_xbar = xg * inv_xi_ov * (1.0 + SP_OV_Afac * xg); \
`expl_low(-SP_OV_xbar, SP_OV_temp) \
SP_OV_w = 1.0 - SP_OV_temp; \
SP_OV_x0 = xg + GOV2 * 0.5 - GOV * sqrt(xg + GOV2 * 0.25 - SP_OV_w); \
`expl_low(-SP_OV_x0, SP_OV_D0) \
SP_OV_p = 2.0 * (xg - SP_OV_x0) + GOV2 * (1 - SP_OV_D0); \
SP_OV_q = (xg - SP_OV_x0) * (xg - SP_OV_x0) - GOV2 * (SP_OV_x0 - 1.0 + SP_OV_D0); \
SP_OV_xi = 1.0 - GOV2 * 0.5 * SP_OV_D0; \
SP_OV_temp = SP_OV_p * SP_OV_p - 4.0 * SP_OV_xi * SP_OV_q; \
SP_OV_u = 2.0 * SP_OV_q / (SP_OV_p + sqrt(SP_OV_temp)); \
sp = SP_OV_x0 + SP_OV_u; \
end \
sp = -sp; \
end

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//======================================================================================
//======================================================================================
// Filename: PSP102_nqs_macrodefs.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
//////////////////////////////////////////
//
// Macros used in PSP-NQS
//
//////////////////////////////////////////
// Function to calculate bulk charge from surface potential
`define PhiToQb(phi,Qb_tmp) \
if (abs(phi) <= margin) \
Qb_tmp = -0.70710678 * phi * Gf * (1.0 - `oneSixth * phi * (1.0 - `oneSixth * phi)); \
else begin \
`expl((-phi), temp) \
Qb_tmp = Gf * sqrt(temp + phi - 1.0); \
if (phi > margin) \
Qb_tmp = -Qb_tmp; \
end
// Function used in fq-macro
`define PhiTod2Qis(xphi,d2Qis) \
if (abs(xphi) <= margin) begin \
Qb_tmp = -0.70710678 * xphi * Gf * (1.0 - `oneSixth * xphi * (1.0 - `oneSixth * xphi)); \
dQbs = -0.70710678 * Gf * (1.0 - `oneThird * xphi * (1.0 - 0.25 * xphi)); \
d2Qis = -0.235702 * Gf * (1.0 - 0.5 * xphi); \
end else begin \
`expl((-xphi),temp) \
Qb_tmp = Gf * sqrt(temp + xphi - 1.0); \
if (xphi > margin) \
Qb_tmp = -Qb_tmp; \
dQbs = 0.5 * Gf2 * (1.0 - temp) / Qb_tmp; \
d2Qis = (dQbs * dQbs - 0.5 * Gf * Gf) / Qb_tmp + dQbs; \
end
// Function used in QiToPhi
`define sps(sp, xg) \
if (abs(xg) <= marginp) begin \
sp = xg / a_factrp; \
end else begin \
if (xg < -marginp) begin \
NQS_yg = -xg; \
NQS_z = 1.25 * NQS_yg / a_factrp; \
NQS_eta = (NQS_z + 10.0 - sqrt((NQS_z - 6.0) * (NQS_z - 6.0) + 64.0)) * 0.5; \
NQS_a = (NQS_yg - NQS_eta) * (NQS_yg - NQS_eta) + Gp2 * (NQS_eta + 1.0); \
NQS_c = 2.0 * (NQS_yg - NQS_eta) - Gp2; \
NQS_tau = ln(NQS_a / Gp2) - NQS_eta; \
`sigma(NQS_a, NQS_c, NQS_tau, NQS_eta, NQS_y0) \
`expl(NQS_y0, NQS_D0) \
NQS_xi = 1.0 - Gp2 * NQS_D0 * 0.5; \
NQS_p = 2.0 * (NQS_yg - NQS_y0) + Gp2 * (NQS_D0 - 1.0); \
NQS_q = (NQS_yg - NQS_y0) * (NQS_yg - NQS_y0) + Gp2 * (NQS_y0 + 1.0 - NQS_D0); \
NQS_temp = NQS_p * NQS_p - 4.0 * NQS_xi * NQS_q; \
NQS_w = 2.0 * NQS_q / (NQS_p + sqrt(NQS_temp)); \
sp = -(NQS_y0 + NQS_w); \
end else begin \
NQS_xg1 = 1.0 / ( 1.25 + 7.32464877560822e-01 * Gp); \
NQS_A_fac = (1.25 * a_factrp * NQS_xg1 - 1.0) * NQS_xg1; \
NQS_xbar = xg / a_factrp * (1.0 + NQS_A_fac * xg); \
`expl(-NQS_xbar, NQS_temp) \
NQS_w = 1.0 - NQS_temp; \
NQS_x0 = xg + Gp2 * 0.5 - Gp * sqrt(xg + Gp2 * 0.25 - NQS_w); \
`expl((-NQS_x0), NQS_D0) \
NQS_xi = 1.0 - Gp2 * 0.5 * NQS_D0; \
NQS_p = 2.0 * (xg - NQS_x0) + Gp2 * (1.0 - NQS_D0); \
NQS_q = (xg - NQS_x0) * (xg - NQS_x0) - Gp2 * (NQS_x0 - 1.0 + NQS_D0); \
NQS_temp = NQS_p * NQS_p - 4.0 * NQS_xi * NQS_q; \
NQS_u = 2.0 * NQS_q / (NQS_p + sqrt(NQS_temp)); \
sp = NQS_x0 + NQS_u; \
end \
end
// Function to calculate surface potential from inversion charge
`define QiToPhi(Qi,xg,xphi) \
temp = Qi / pd + xg; \
`sps(xphi,temp)
// Calculation of fk
`define fq(Qi,xg,dQy,d2Qy,fk) \
`QiToPhi(Qi, xg, xphi) \
`PhiTod2Qis(xphi, d2Qis) \
dQis = pd - dQbs; \
dQis_1 = 1.0 / dQis; \
fQi = Qi * dQis_1 - 1.0; \
dfQi = (1.0 - Qi * d2Qis * dQis_1 * dQis_1) * dQis_1; \
fk0 = dfQi * dQy * dQy + fQi * d2Qy; \
dpsy2 = dQy * dQy * dQis_1 * dQis_1; \
zsat = thesat2 * dpsy2; \
if (CHNL_TYPE == `PMOS) \
zsat = zsat / (1.0 + thesat1 * dps); \
temp = sqrt(1.0 + 2.0 * zsat); \
Fvsat = 2.0 / (1.0 + temp); \
temp1 = d2Qy - dpsy2 * d2Qis; \
fk = Fvsat * (fk0 - zsat * fQi * temp1 * Fvsat / temp);
// Interpolation of surface potential along channel
`define Phiy(y) \
x_m + H * (1.0 - sqrt(1.0 - 2.0 * dps / H * ((y) - ym))) * inv_phit1

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//======================================================================================
//======================================================================================
// Filename: SIMKIT_macrodefs.include
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
//////////////////////////////////////////////////////////////
//
// General macros and constants for compact va-models
//
//////////////////////////////////////////////////////////////
`define VERS "0.0"
`define VREV "0.0"
`define VERSreal 0.0
`define VREVreal 0.0
`define CLIP_LOW(val,min) ((val)>(min)?(val):(min))
`define CLIP_HIGH(val,max) ((val)<(max)?(val):(max))
`define CLIP_BOTH(val,min,max) ((val)>(min)?((val)<(max)?(val):(max)):(min))
// Note 1: In this va-code, the `P-macro is defined such that its argument
// is ignored during compilation; in this source code it acts as
// a comment
// Note 2: In this va-code, the "from" keyword in the parameter
// list is not used. Silent clipping is used instead. One could enable
// the Verilog-A range checking by redefining the `from-macro below.
`define P(txt)
`define AT_MODEL
`define AT_INSTANCE
`define AT_NOISE
`define from(lower,upper)
// `define from(lower,upper) from[lower:upper]
// Some functions
`define MAX(x,y) ((x)>(y)?(x):(y))
`define MIN(x,y) ((x)<(y)?(x):(y))
// Mathematical constants
`define PI 3.1415926535897931
`define SQRTPI 1.77245385090551603
// Physical constants
`define KELVINCONVERSION 273.15
`define KBOL 1.3806505E-23
`define QELE 1.6021918E-19
`define HBAR 1.05457168E-34
`define MELE 9.1093826E-31
`define EPSSI 1.045E-10
// Other constants
`define oneThird 3.3333333333333333e-01
`define twoThirds 6.6666666666666667e-01
// Constants needed in safe exponential function (called "expl")
`define se 4.6051701859880916e+02
`define se05 2.3025850929940458e+02
`define ke 1.0e-200
`define ke05 1.0e-100
`define keinv 1.0e200
`define ke05inv 1.0e100
/////////////////////////////////////////////////////////////////////////////
//
// Macro definitions.
//
// Note that because variables in macros are not locally scoped,
// the intermediate variables used in the macros below must be
// explicitly declared in the main code.
//
/////////////////////////////////////////////////////////////////////////////
// P3 3rd order polynomial expansion of exp()
`define P3(u) (1.0 + (u) * (1.0 + 0.5 * (u) * (1.0 + (u) * `oneThird)))
// expl exp() with 3rd order polynomial extrapolation
// for very low values (exp_low), very high
// values (exp_high), or both (expl), to avoid overflows
// and underflows and retain C-3 continuity
`define expl(x, res) \
if (abs(x) < `se05) begin\
res = exp(x); \
end else begin \
if ((x) < -`se05) begin\
res = `ke05 / `P3(-`se05 - (x)); \
end else begin\
res = `ke05inv * `P3((x) - `se05); \
end \
end
`define expl_low(x, res) \
if ((x) > -`se05) begin\
res = exp(x); \
end else begin\
res = `ke05 / `P3(-`se05 - (x)); \
end
`define expl_high(x, res) \
if ((x) < `se05) begin\
res = exp(x); \
end else begin \
res = `ke05inv * `P3((x) - `se05); \
end
`define swap(a, b) \
temp = a; \
a = b; \
b = temp;

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src/spicelib/devices/adms/psp102/admsva/psp102.va
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//======================================================================================
//======================================================================================
// Filename: psp102.va
//======================================================================================
//======================================================================================
//
// (c) Copyright 2006, All Rights Reserved, NXP Semiconductors
//
//
// Version: 102.1, October 2006 (Simkit 2.4)
//
//======================================================================================
//======================================================================================
//
// Further information can be found in the file readme.txt
//
`include "discipline.h"
`include "SIMKIT_macrodefs.include"
`include "JUNCAP200_macrodefs.include"
`include "PSP102_macrodefs.include"
/////////////////////////////////////////////////////////////////////////////
//
// PSP global model code
//
/////////////////////////////////////////////////////////////////////////////
// `undef LocalModel
// `define Binning
module psp102(D, G, S, B)
`P(
info = "PSP MOSFET Model"
version = `VERS
revision = `VREV
simkit:name = "psp1020"
simkit:desc = "psp_1020"
);
`include "PSP102_module.include"
endmodule

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======================================================================================
======================================================================================
---------------------------
Verilog-A definition of PSP
---------------------------
(c) Copyright 2006, All Rights Reserved, NXP Semiconductors
Version: PSP 102.1 (including JUNCAP2 200.2), October 2006 (Simkit 2.4)
======================================================================================
======================================================================================
Authors: G.D.J. Smit, A.J. Scholten, and D.B.M. Klaassen (NXP Semiconductors Research)
R. van Langevelde (Philips Research)
G. Gildenblat, X. Li, and W. Wu (The Arizona State University)
The most recent version of the model code, the documentation, and contact information
can be found on:
http://PSPmodel.asu.edu/
or
http://www.nxp.com/Philips_Models/
======================================================================================
======================================================================================
This package consists of several files:
- readme.txt This file
- psp102.va Main file for global ("geometrical") model
- psp102b.va Main file for global binning model
- psp102e.va Main file for local ("electrical") model
- psp102_nqs.va Main file for global ("geometrical") model with NQS-effects
- psp102b_nqs.va Main file for global binning model with NQS-effects
- psp102e_nqs.va Main file for local ("electrical") model with NQS-effects
- juncap200.va Main file for JUNCAP2 stand-alone model
- SIMKIT_macrodefs.include Common macro definitions
- PSP102_macrodefs.include Macro definitions for PSP
- PSP102_module.include Actual model code for intrinsic MOS model
- PSP102_binning.include Geometry scaling equation for binning
- PSP102_binpars.include Parameterlist for global PSP binning model
- PSP102_nqs_macrodefs.include Macro definitions for PSP-NQS
- PSP102_InitNQS.include PSP-NQS initialization code
- PSP102_ChargesNQS.include Calculation of NQS-charge contributions
- JUNCAP200_macrodefs.include Macro definitions for JUNCAP2 model
- JUNCAP200_parlist.include JUNCAP2 parameter list
- JUNCAP200_varlist.include JUNCAP2 variable declarations
- JUNCAP200_InitModel.include JUNCAP2 model initialization code
======================================================================================
======================================================================================
Usage
-----
Depending which model one wants to use, one should compile one of the seven .va-files
(psp102.va, psp102b.va, psp102e.va, psp102_nqs.va, psp102b_nqs.va, psp102e_nqs.va, and
juncap200.va). The module names are "PSP102VA" and "PSPNQS102VA" for the global PSP-model
(QS and NQS, respectively), and similarly "PSP102BVA" and "PSPNQS102BVA" for the binning
PSP-model, "PSP102EVA" and "PSPNQS102EVA" for the local PSP-model, and "JUNCAP200" for
the JUNCAP2-model.
======================================================================================
======================================================================================
Release notes va-code of PSP 102.1, including JUNCAP2 200.2 (October 2006)
--------------------------------------------------------------------------
PSP 102.1 is backwards compatible with the previous version, PSP 102.0, and
resolves some minor implementation issues and bugs. Next to the existing
verilog-A implementation, a test version of the NQS model is now available
in the SiMKit.
- Added clipping boundaries for SWNQS.
- Removed several "empty statements".
- Resolved SpectreRF hidden state problem
- Solved minor bugs in stress model
- Solved minor bug in juncap model
- Changed the NQS-module names in the verilog-A code
- Made some implementation changes for optimization and maintenance purposes
* Introduced verilog-macro for nodes G/GP, B/BP, B/BS, and B/BD
* Make drain junction voltage equal to V(D, B) instead of V(D, S) + V(S, B)
* Extra intermediate variables for parasitic resistor noise densities
* Modified implementation of NQS-model
======================================================================================
======================================================================================
The functionality of the Verilog-A code in this package is the same as that of the
C-code, which is contained in SIMKIT version 2.4. Note that Operating Point information
is available only in the C-code, not in Verilog-A code.
The PSP-NQS model is provided as Verilog-A code. In SiMKit 2.4, for the first time a
test version of the PSP-NQS model is included. This implementation circumvents the
of the SpectreVerilog-A-generated C-code being too large to compile. Moreover, it is
computationally more efficient as it uses less rows in the simulator matrix. On the
other hand, this implementation has some known limitations. More information is
available from the authors. Further improvements are expected in future releases.
This Verilog-A code of PSP is primarily intended as a source for C-code generation
using ADMS. Most of the testing has been done on the C-code which was generated from it.
The authors want to thank Laurent Lemaitre and Colin McAndrew (Freescale)
for their help with ADMS and the implementation of the model code. Geoffrey
Coram (Analog Devices) is acknowledged for his useful comments on the Verilog-A
code.
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