📄 vbicnoise.c
字号:
/**********Copyright 1990 Regents of the University of California. All rights reserved.Author: 1987 Gary W. NgModel Author: 1995 Colin McAndrew MotorolaSpice3 Implementation: 2003 Dietmar Warning DAnalyse GmbH**********/#include "ngspice.h"#include "vbicdefs.h"#include "cktdefs.h"#include "iferrmsg.h"#include "noisedef.h"#include "suffix.h"/* * VBICnoise (mode, operation, firstModel, ckt, data, OnDens) * * This routine names and evaluates all of the noise sources * associated with VBIC's. It starts with the model *firstModel and * traverses all of its insts. It then proceeds to any other models * on the linked list. The total output noise density generated by * all of the VBIC's is summed with the variable "OnDens". */extern void NevalSrc();extern double Nintegrate();intVBICnoise (int mode, int operation, GENmodel *genmodel, CKTcircuit *ckt, Ndata *data, double *OnDens){ VBICmodel *firstModel = (VBICmodel *) genmodel; VBICmodel *model; VBICinstance *inst; char name[N_MXVLNTH]; double tempOnoise; double tempInoise; double noizDens[VBICNSRCS]; double lnNdens[VBICNSRCS]; int i; /* define the names of the noise sources */ static char *VBICnNames[VBICNSRCS] = { /* Note that we have to keep the order consistent with the strchr definitions in VBICdefs.h */ "_rc", /* noise due to rc */ "_rci", /* noise due to rci */ "_rb", /* noise due to rb */ "_rbi", /* noise due to rbi */ "_re", /* noise due to re */ "_rbp", /* noise due to rbp */ "_ic", /* noise due to ic */ "_ib", /* noise due to ib */ "_ibep", /* noise due to ibep */ "_1overfbe", /* flicker (1/f) noise ibe */ "_1overfbep", /* flicker (1/f) noise ibep */ "_rs", /* noise due to rs */ "_iccp", /* noise due to iccp */ "" /* total transistor noise */ }; for (model=firstModel; model != NULL; model=model->VBICnextModel) { for (inst=model->VBICinstances; inst != NULL; inst=inst->VBICnextInstance) { if (inst->VBICowner != ARCHme) continue; switch (operation) { case N_OPEN: /* see if we have to to produce a summary report */ /* if so, name all the noise generators */ if (((NOISEAN*)ckt->CKTcurJob)->NStpsSm != 0) { switch (mode) { case N_DENS: for (i=0; i < VBICNSRCS; i++) { (void)sprintf(name,"onoise_%s%s", inst->VBICname,VBICnNames[i]); data->namelist = (IFuid *) trealloc((char *)data->namelist, (data->numPlots + 1)*sizeof(IFuid)); if (!data->namelist) return(E_NOMEM); (*(SPfrontEnd->IFnewUid))(ckt, &(data->namelist[data->numPlots++]), (IFuid)NULL,name,UID_OTHER,(void **)NULL); /* we've added one more plot */ } break; case INT_NOIZ: for (i=0; i < VBICNSRCS; i++) { (void)sprintf(name,"onoise_total_%s%s", inst->VBICname,VBICnNames[i]); data->namelist = (IFuid *) trealloc((char *)data->namelist, (data->numPlots + 1)*sizeof(IFuid)); if (!data->namelist) return(E_NOMEM); (*(SPfrontEnd->IFnewUid))(ckt, &(data->namelist[data->numPlots++]), (IFuid)NULL,name,UID_OTHER,(void **)NULL); /* we've added one more plot */ (void)sprintf(name,"inoise_total_%s%s", inst->VBICname,VBICnNames[i]);data->namelist = (IFuid *)trealloc((char *)data->namelist,(data->numPlots + 1)*sizeof(IFuid));if (!data->namelist) return(E_NOMEM); (*(SPfrontEnd->IFnewUid))(ckt, &(data->namelist[data->numPlots++]), (IFuid)NULL,name,UID_OTHER,(void **)NULL); /* we've added one more plot */ } break; } } break; case N_CALC: switch (mode) { case N_DENS: NevalSrc(&noizDens[VBICRCNOIZ],&lnNdens[VBICRCNOIZ], ckt,THERMNOISE,inst->VBICcollCXNode,inst->VBICcollNode, model->VBICcollectorConduct * inst->VBICarea * inst->VBICm); NevalSrc(&noizDens[VBICRCINOIZ],&lnNdens[VBICRCINOIZ], ckt,THERMNOISE,inst->VBICcollCXNode,inst->VBICcollCINode, *(ckt->CKTstate0 + inst->VBICirci_Vrci)); NevalSrc(&noizDens[VBICRBNOIZ],&lnNdens[VBICRBNOIZ], ckt,THERMNOISE,inst->VBICbaseBXNode,inst->VBICbaseNode, model->VBICbaseConduct * inst->VBICarea * inst->VBICm); NevalSrc(&noizDens[VBICRBINOIZ],&lnNdens[VBICRBINOIZ], ckt,THERMNOISE,inst->VBICbaseBXNode,inst->VBICbaseBINode, *(ckt->CKTstate0 + inst->VBICirbi_Vrbi)); NevalSrc(&noizDens[VBICRENOIZ],&lnNdens[VBICRENOIZ], ckt,THERMNOISE,inst->VBICemitEINode,inst->VBICemitNode, model->VBICemitterConduct * inst->VBICarea * inst->VBICm); NevalSrc(&noizDens[VBICRBPNOIZ],&lnNdens[VBICRBPNOIZ], ckt,THERMNOISE,inst->VBICemitEINode,inst->VBICemitNode, *(ckt->CKTstate0 + inst->VBICirbp_Vrbp)); NevalSrc(&noizDens[VBICRSNOIZ],&lnNdens[VBICRSNOIZ], ckt,THERMNOISE,inst->VBICsubsSINode,inst->VBICsubsNode, model->VBICsubstrateConduct * inst->VBICarea * inst->VBICm); NevalSrc(&noizDens[VBICICNOIZ],&lnNdens[VBICICNOIZ], ckt,SHOTNOISE,inst->VBICcollCINode, inst->VBICemitEINode, *(ckt->CKTstate0 + inst->VBICitzf)); NevalSrc(&noizDens[VBICIBNOIZ],&lnNdens[VBICIBNOIZ], ckt,SHOTNOISE,inst->VBICbaseBINode, inst->VBICemitEINode, *(ckt->CKTstate0 + inst->VBICibe)); NevalSrc(&noizDens[VBICIBEPNOIZ],&lnNdens[VBICIBEPNOIZ], ckt,SHOTNOISE,inst->VBICbaseBXNode, inst->VBICbaseBPNode, *(ckt->CKTstate0 + inst->VBICibep)); NevalSrc(&noizDens[VBICICCPNOIZ],&lnNdens[VBICICCPNOIZ], ckt,SHOTNOISE,inst->VBICbaseBXNode, inst->VBICsubsSINode, *(ckt->CKTstate0 + inst->VBICiccp)); NevalSrc(&noizDens[VBICFLBENOIZ],(double*)NULL,ckt, N_GAIN,inst->VBICbaseBINode, inst->VBICemitEINode, (double)0.0); noizDens[VBICFLBENOIZ] *= inst->VBICm * model->VBICfNcoef * exp(model->VBICfNexpA * log(MAX(fabs(*(ckt->CKTstate0 + inst->VBICibe)/inst->VBICm),N_MINLOG))) / pow(data->freq, model->VBICfNexpB); lnNdens[VBICFLBENOIZ] = log(MAX(noizDens[VBICFLBENOIZ],N_MINLOG)); NevalSrc(&noizDens[VBICFLBEPNOIZ],(double*)NULL,ckt, N_GAIN,inst->VBICbaseBXNode, inst->VBICbaseBPNode, (double)0.0); noizDens[VBICFLBEPNOIZ] *= inst->VBICm * model->VBICfNcoef * exp(model->VBICfNexpA * log(MAX(fabs(*(ckt->CKTstate0 + inst->VBICibep)/inst->VBICm),N_MINLOG))) / pow(data->freq, model->VBICfNexpB); lnNdens[VBICFLBEPNOIZ] = log(MAX(noizDens[VBICFLBEPNOIZ],N_MINLOG)); noizDens[VBICTOTNOIZ] = noizDens[VBICRCNOIZ] + noizDens[VBICRCINOIZ] + noizDens[VBICRBNOIZ] + noizDens[VBICRBINOIZ] + noizDens[VBICRENOIZ] + noizDens[VBICRBPNOIZ] + noizDens[VBICICNOIZ] + noizDens[VBICIBNOIZ] + noizDens[VBICIBEPNOIZ] + noizDens[VBICFLBENOIZ] + noizDens[VBICFLBEPNOIZ]; lnNdens[VBICTOTNOIZ] = log(noizDens[VBICTOTNOIZ]); *OnDens += noizDens[VBICTOTNOIZ]; if (data->delFreq == 0.0) { /* if we haven't done any previous integration, we need to */ /* initialize our "history" variables */ for (i=0; i < VBICNSRCS; i++) { inst->VBICnVar[LNLSTDENS][i] = lnNdens[i]; } /* clear out our integration variables if it's the first pass */ if (data->freq == ((NOISEAN*)ckt->CKTcurJob)->NstartFreq) { for (i=0; i < VBICNSRCS; i++) { inst->VBICnVar[OUTNOIZ][i] = 0.0; inst->VBICnVar[INNOIZ][i] = 0.0; } } } else { /* data->delFreq != 0.0 (we have to integrate) *//* In order to get the best curve fit, we have to integrate each component separately */ for (i=0; i < VBICNSRCS; i++) { if (i != VBICTOTNOIZ) { tempOnoise = Nintegrate(noizDens[i], lnNdens[i], inst->VBICnVar[LNLSTDENS][i], data); tempInoise = Nintegrate(noizDens[i] * data->GainSqInv , lnNdens[i] + data->lnGainInv, inst->VBICnVar[LNLSTDENS][i] + data->lnGainInv, data); inst->VBICnVar[LNLSTDENS][i] = lnNdens[i]; data->outNoiz += tempOnoise; data->inNoise += tempInoise; if (((NOISEAN*)ckt->CKTcurJob)->NStpsSm != 0) { inst->VBICnVar[OUTNOIZ][i] += tempOnoise; inst->VBICnVar[OUTNOIZ][VBICTOTNOIZ] += tempOnoise; inst->VBICnVar[INNOIZ][i] += tempInoise; inst->VBICnVar[INNOIZ][VBICTOTNOIZ] += tempInoise; } } } } if (data->prtSummary) { for (i=0; i < VBICNSRCS; i++) { /* print a summary report */ data->outpVector[data->outNumber++] = noizDens[i]; } } break; case INT_NOIZ: /* already calculated, just output */ if (((NOISEAN*)ckt->CKTcurJob)->NStpsSm != 0) { for (i=0; i < VBICNSRCS; i++) { data->outpVector[data->outNumber++] = inst->VBICnVar[OUTNOIZ][i]; data->outpVector[data->outNumber++] = inst->VBICnVar[INNOIZ][i]; } } /* if */ break; } /* switch (mode) */ break; case N_CLOSE: return (OK); /* do nothing, the main calling routine will close */ break; /* the plots */ } /* switch (operation) */ } /* for inst */ } /* for model */return(OK);}⌨️ 快捷键说明
复制代码
Ctrl + C
搜索代码
Ctrl + F
全屏模式
F11
切换主题
Ctrl + Shift + D
显示快捷键
?
增大字号
Ctrl + =
减小字号
Ctrl + -