tof/src/PamVMCTofDig.cxx

#include "PamVMCTofDig.h"
#include "TDatabasePDG.h"

#include <TMath.h>
#include <TRandom.h>

using TMath::Power;
using TMath::Exp;
using TMath::Abs;

ClassImp(PamVMCTofDig)


void PamVMCTofDig::LoadCalib(){

 cout<<"Loading Tof Calibrations..."<<endl;

  Int_t time=3;
  Int_t type=202;

  fdberr = fsql->Query_GL_PARAM(time,type); 

  fquery.str("");
  fquery << fsql->GetPAR()->PATH.Data() << "/";
  fquery << fsql->GetPAR()->NAME.Data();

  ThrowCalFileUsage("TOF",fquery.str().c_str());
  
  fcfile.open(fquery.str().c_str());

  if(!fcfile) ThrowCalFileWarning("TOF"); else {

    Int_t temp;
  
    for(Int_t i=0; i<NP; i++){
      fcfile >> temp;
      fcfile >> fatte1[i];
      fcfile >> flambda1[i];
      fcfile >> fatte2[i];
      fcfile >> flambda2[i];
      fcfile >> temp;
    }

  }

  fcfile.close();
}


void PamVMCTofDig::DigitizeTOF(Int_t EventNo, Int_t PrimaryPDG){

  fDEBUG = kFALSE;

  // pC < 800 
  const Float_t ADC_pC0A =  -4.437616e+01;
  const Float_t ADC_pC1A =   1.573329e+00;
  const Float_t ADC_pC2A =   2.780518e-04;
  const Float_t ADC_pC3A =  -2.302160e-07;
  // pC > 800:
  const Float_t ADC_pC0B =    -2.245756e+02;
  const Float_t ADC_pC1B =     2.184156e+00;
  const Float_t ADC_pC2B =    -4.171825e-04;
  const Float_t ADC_pC3B =     3.789715e-08;
  
  const Float_t pCthres=40.;     // threshold in charge
  const Int_t ADClast=4095;      // no signal --> ADC ch=4095
  const Int_t ADCsat=3100;       // saturation value for the ADCs
  const Int_t TDClast=4095;


  for(Int_t i =0; i<NP; i++){
    fQevePmt_pC[i]=ftdc[i]=ftdc1[i]=0.;
    ftdcpmt[i]=1000.;
  }

  
  TClonesArray* hc = 0;
  const char* keyplane [6] = {"S11Y","S12X","S21X","S22Y","S31Y","S32X"};
  for(Int_t i=0; i<6; i++){
    hc = (TClonesArray*)fhitscolmap.GetValue(keyplane[i]);
    if (hc) DigitizeTofPlane(i,hc, PrimaryPDG);
    hc = 0;
  }

  if(fDEBUG){
    cout<<"Summarized values for ADC in PC:"<<endl;
    for(Int_t i=0; i<NP; i++){
      cout<<"PMT #"<<i<<" fQevePmt_pC="<<fQevePmt_pC[i]<<endl;
    }
  }
  //+++++ ADC +++++

  for(Int_t i=0; i<NP; i++){
    if (fQevePmt_pC[i] <= 800.)  
      fADCtof[i]= (Int_t)(ADC_pC0A + ADC_pC1A*fQevePmt_pC[i] 
                          + ADC_pC2A*Power(fQevePmt_pC[i],2) 
                          + ADC_pC3A*Power(fQevePmt_pC[i],3));
    if ((fQevePmt_pC[i] > 800.) && (fQevePmt_pC[i] <= 2485.))
      fADCtof[i]= (Int_t)(ADC_pC0B + ADC_pC1B*fQevePmt_pC[i] 
                          + ADC_pC2B*Power(fQevePmt_pC[i],2) 
                          + ADC_pC3B*Power(fQevePmt_pC[i],3));
    if (fQevePmt_pC[i] > 2485.) fADCtof[i]= (Int_t)(1758. + 0.54*fQevePmt_pC[i]);  
    //assuming a fictional 0.54 ch/pC above ADCsat
    if (fADCtof[i]>ADCsat) fADCtof[i]=ADCsat;
    if (fQevePmt_pC[i] < pCthres)  fADCtof[i]= ADClast;
    if (fADCtof[i] < 0) fADCtof[i]=ADClast;    
    if (fADCtof[i] > ADClast) fADCtof[i]=ADClast;
  }

  // ======  TDC coincidence  ======


  for(Int_t i=0; i<NP; i++) {
    if((ftdcpmt[i] - fc1_S[i]) > 1e-7) {
      ftdcpmt[i] = 0.;
      ftdc[i] = 0.;
    }
  }// cycle to introduce a window for tdc

  Double_t t_coinc = 0;
  Int_t ilast = 100;
  for (Int_t ii=0; ii<NP;ii++)
    if (ftdc[ii] > t_coinc) {
      t_coinc = ftdc[ii];
      ilast = ii;
    }

  for (Int_t ii=0; ii<NP;ii++){
    if (ftdc[ii] != 0) ftdc1[ii] = t_coinc - ftdcpmt[ii];  // test 2
    ftdc1[ii] = ftdc1[ii]/ftdcres[ii];                     // divide by TDC resolution 
    if (ftdc[ii] != 0) ftdc1[ii] = ftdc1[ii] + fc3_S[ii];  // add cable length c3
  } 
  
  if (fDEBUG)cout<<"====== TOF coincidence ======"<<endl;
  for(Int_t i=0; i<NP; i++){
    if(ftdc1[i] != 0.){
      fTDCint[i]=(Int_t)ftdc1[i];
      if (fTDCint[i]>4093) fTDCint[i]=TDClast;  // 18-oct WM
      if (fDEBUG)cout<<"PMT: "<<i<<" ADC: "<<fADCtof[i]<<" TDC: "
                     <<fTDCint[i]<<endl;
    } else
      fTDCint[i]= TDClast;
  }
  if (fDEBUG)cout<<"============================="<<endl;

  //------ use channelmap for ToF: 18-oct WM
  Int_t  channelmap[] =  {3,21,11,29,19,45,27,37,36,28,44,20,5,12,13,4,
                          6,47,14,39,22,31,30,23,38,15,46,7,0,33,16,24,
                          8,41,32,40,25,17,34,9,42,1,2,10,18,26,35,43};
  Int_t ADChelp[NP],TDChelp[NP];
  for(Int_t i=0; i<NP; i++){
    Int_t ii=channelmap[i];
    ADChelp[ii]= fADCtof[i];
    TDChelp[ii]= fTDCint[i];
  }
  for(Int_t i=0; i<NP; i++){
    fADCtof[i]= ADChelp[i];
    fTDCint[i]= TDChelp[i];
  }

  if (fDEBUG){
    cout<<"====== TOF coincidence after... ======"<<endl;
    for(Int_t i=0; i<NP; i++){
      cout<<"PMT: "<<i<<" ADC: "<<fADCtof[i]<<" TDC: "
          <<fTDCint[i]<<endl;
    }
    cout<<"============================="<<endl;
  }
  // ======  write DataTof  =======

  UChar_t Ctrl3bit[8]={32,0,96,64,160,128,224,192};  // DC (msb in 8 bit word )
  UChar_t tofBin;
  UChar_t DataTof[276];
  for (Int_t j=0; j < 276; j++)DataTof[j]=0x00;
  UChar_t *pTof=DataTof;
  for (Int_t j=0; j < 12; j++){   // loop on TDC #12
    Int_t j12=j*23;               // for each TDC 23 bytes (8 bits)
    DataTof[j12+0]=0x00;   // TDC_ID
    DataTof[j12+1]=0x00;   // EV_COUNT
    DataTof[j12+2]=0x00;   // TDC_MASK (1)
    DataTof[j12+3]=0x00;   // TDC_MASK (2)
    for (Int_t k=0; k < 4; k++){   // for each TDC 4 channels (ADC+TDC)
      Int_t jk12=j12+4*k;         // ADC,TDC channel (0-47)
      tofBin =(UChar_t)(fADCtof[k+4*j]/256);   // ADC# (msb) 
      DataTof[jk12+4] = Bin2GrayTof(tofBin,DataTof[jk12+4]);
      /* control bits inserted here, after the bin to gray conv - DC*/ 
      DataTof[jk12+4] = Ctrl3bit[2*k] | DataTof[jk12+4];
      tofBin=(UChar_t)(fADCtof[k+4*j]%256);   // ADC# (lsb)
      DataTof[jk12+5] = Bin2GrayTof(tofBin,DataTof[jk12+5]);
      tofBin=(UChar_t)(fTDCint[k+4*j]/256);   // TDC# (msb)
      DataTof[jk12+6]=Bin2GrayTof(tofBin,DataTof[jk12+6]);
      /* control bits inserted here, after the bin to gray conv - DC*/ 
      DataTof[jk12+6] = Ctrl3bit[2*k+1] | DataTof[jk12+6];
      tofBin=(UChar_t)(fTDCint[k+4*j]%256);   // TDC# (lsb)
      //if(fDEBUG) cout<<" digit TDC: "<<jk12<<" TDC:"<<(Int_t)tofBin<<endl;
      DataTof[jk12+7]=Bin2GrayTof(tofBin,DataTof[jk12+7]);
    }
    DataTof[j12+20]=0x00;   // TEMP1
    DataTof[j12+21]=0x00;   // TEMP2
    DataTof[j12+22]= EvaluateCrc(pTof,22);   // CRC
    pTof+=23;
  }

  //===== write DataTrigger =======

  UChar_t DataTrigger[152];
  for (Int_t j=0; j < 152; j++)DataTrigger[j]=0x00;
  UChar_t *pTrg=DataTrigger;
  // Only the variables with a (*) are modified; the others are set to 0
  // info given in #bites data + #bites crc
  // TB_READ_PMT_PLANE      :  6 + 1
  // TB_READ_EVENT_COUNT    :  3 + 1 (*)
  // TB_READ_TRIGGER_RATE   : 12 + 1
  // TB_READ_D_L_TIME       :  4 + 1
  // TB_READ_S4_CAL_COUNT   :  4 + 1
  // TB_READ_PMT_COUNT1     : 48 + 1
  // TB_READ_PMT_COUNT2     : 48 + 1
  // TB_READ_PATTERN_BUSY   :  8 + 1
  // TB_READ_PATTERN_TRIGGER:  7 + 1 (*)
  // TB_READ_TRIGGER_CONF   :  2 + 1 (*)
  // TB_READ_EVENT_COUNT
  UInt_t cTrg  = EventNo;  //counter
  UInt_t cTrg2 = 0;  //counter with bits inverted, according to document 
                     //"formato dati provenienti dalla trigger board"
  for (Int_t i=0; i < 24; i++){  // Use the first 24 bits
    if (cTrg & (0x1 << i) )
      cTrg2 = cTrg2 | (0x1 << (24-i));
  }
  DataTrigger[7] = (UChar_t)(cTrg2 >> 16); // 8 MSbits (out  of 24)
  DataTrigger[8] = (UChar_t)(cTrg2 >> 8);  // 8 "middle" bits
  DataTrigger[9] = (UChar_t)(cTrg2);       // 8 LSbits
  pTrg=DataTrigger+7;
  DataTrigger[10]=EvaluateCrc(pTrg, 3);
  
  // TB_READ_PATTERN_TRIGGER: bytes 141-148:
  // PatternTrigMap[i] corresponds to bit i in TB_READ_PATTERN_TRIGGER:
  // mapping according to documents:
  // 1. "formato dati provenienti dalla trigger board"
  // 2. "The ToF quicklook software", Appendix A (Campana, Nagni)
  Int_t PatternTrigMap[]={29,42,43,1,16,7,17,28,33,41,46,2,15,8,18,27,
                          30,40,44,3,14,9,19,26,32,37,47,4,13,10,20,25,
                          34,31,38,45,5,12,21,24,36,35,39,48,6,11,22,23};
  for (Int_t i=0; i<NP; i++){
    if (ftdc1[channelmap[i]]!=0)
      DataTrigger[147-(Int_t)((PatternTrigMap[i]+1)/8)]=DataTrigger[147-(Int_t)((PatternTrigMap[i]+1)/8)] | (0x1 << (PatternTrigMap[i]%8));
  }
  pTrg=DataTrigger+141;
  DataTrigger[148]=EvaluateCrc(pTrg, 7);
  
  // TB_READ_TRIGGER_CONF   : set always acq.mode TOF4
  //
  // TOF1: S1-S2-S3 (&,|)
  // TOF4: S2-S3 (&,&)
  DataTrigger[149]=0x02;
  DataTrigger[150]=0x0;
  pTrg=DataTrigger+149;
  DataTrigger[151]=EvaluateCrc(pTrg, 2);


  //++++++ WRITE EVERYTHING TO DIGITIZER'S BUFFER +++//
  cout<<"TOF Digitizing"<<endl;

  fDataC.clear(); //clearing Tof & Trig data buffer

  for(Int_t i= 0; i<152; i++) fDataC.push_back(DataTrigger[i]);

  for(Int_t i= 0; i<276; i++) fDataC.push_back(DataTof[i]);

}

Float_t PamVMCTofDig::TimeRes(Int_t PrimaryPDG){

  Float_t time_res[8] = {425.,210.,170.,130.,120.,120.,120.,120.}; 
  for(Int_t i=0;i<8;i++) time_res[i]/=1.4;//1.17;1.5;1.3*/
  Int_t Z = Int_t((TDatabasePDG::Instance()->GetParticle(PrimaryPDG))->Charge()/3.);
    
  Float_t dt1 = 1.e-12*time_res[0];  // single PMT resolution for Z=1  (WM, Nov'07)
  if ((Z > 1) && (Z < 9)) dt1=1.e-12*time_res[(Z-1)];
  if  (Z > 8) dt1=120.e-12;
  
  return dt1;
}

void PamVMCTofDig::DigitizeTofPlane(Int_t planeNo, TClonesArray* HitColl, Int_t PrimaryPDG){
  
  PamVMCDetectorHit * hit = 0;
  const Float_t veff0 = 100.*1.0e8;//(m/s) light velocity in scintillator
  const Float_t veff1 = 100.*1.5e8;//(m/s) light velocity in lightguide
  const Float_t FGeo[2] = {0.5, 0.5}; //geometrical factor
  const Float_t Pho_keV = 10.;// photons per keV in scintillator
  const Float_t effi = 0.21; //photocathofe efficiency
  const Float_t pmGain = 3.5e6; //PMT Gain: the same for all PMTs
  const Float_t echarge = 1.6e-19; // electron charge
  const Float_t thresh=20.; // to be defined better... (Wolfgang)

  const Float_t dimel[6] = {33.0, 40.8 ,18.0, 15.0, 15.0, 18.0}; //(cm) TOF paddles dimensions
  //  S11 8 paddles  33.0 x 5.1 cm
  //  S12 6 paddles  40.8 x 5.5 cm
  //  S21 2 paddles  18.0 x 7.5 cm
  //  S22 2 paddles  15.0 x 9.0 cm
  //  S31 3 paddles  15.0 x 6.0 cm
  //  S32 3 paddles  18.0 x 5.0 cm

  const Float_t s_l_g[6] = {8.0, 8.0, 20.9, 22.0, 9.8, 8.3 };  //(cm) length of the lightguide

  const Float_t ScaleFact[48]={0.39, 0.49, 0.38, 0.40, 0.65, 0.51, 0.43,
        0.49, 0.58, 0.38, 0.53, 0.57, 0.53, 0.45, 0.49, 0.16,
        0.15, 0.44, 0.28, 0.57, 0.26, 0.72, 0.37, 0.29, 0.30, 0.89,
        0.37, 0.08,  0.27, 0.23, 0.12, 0.22, 0.15, 0.16, 0.21,
        0.19, 0.41, 0.32, 0.39, 0.38, 0.28, 0.66, 0.28, 0.40, 0.39, 0.40, 0.37, 0.35 };

  Float_t t1, t2, tpos, Npho;
  Float_t path[2], knorm[2], Atten[2], QhitPad_pC[2], QhitPmt_pC[2];
  Int_t padNo, pmtleft, pmtright;
  //LOOP
  for(Int_t i =0; i<HitColl->GetEntriesFast(); i++){
    
    hit = (PamVMCDetectorHit*)HitColl->At(i);
    
    t1=t2 = hit->GetTOF();
    padNo = hit->GetPOS()-1;
    pmtleft=pmtright=0;
    if(planeNo==2){
      if(padNo==0)
        padNo=1;
      else
        padNo=0;
    }

    Paddle2Pmt(planeNo,padNo, &pmtleft, &pmtright);
    
    switch(planeNo){
    case 0:
    case 3:
    case 4:
      tpos = (hit->GetYIN()+hit->GetYOUT())/2.; //Y-planes
      break;
    case 1:
    case 2:
    case 5:
      tpos = (hit->GetXIN()+hit->GetXOUT())/2.; //X-planes
      break;
    default:
      cout<<"PamVMCTofDig::DigitizeTOFPlane wrong plane no "<<planeNo<<endl;
      tpos = -100.;
      break;
    }

    path[0]= tpos + dimel[planeNo]/2.;   // path to left PMT
    path[1]= dimel[planeNo]/2.- tpos;    // path to right PMT

    if (fDEBUG) {
      cout <<"+++++  TOF HIT VERBOSE INFORMATION: +++++"<<endl;
      cout <<"planeNo "<<planeNo<<" padNo "<< padNo <<" tpos  "<< tpos <<"\n";
      cout <<"pmtleft, pmtright "<<pmtleft<<","<<pmtright<<endl;
    }

    Npho = hit->GetEREL()*Pho_keV*1.0e6; //calculation of photons number

    for(Int_t j=0; j<2; j++){
      QhitPad_pC[j]= Npho*FGeo[j]*effi*pmGain*echarge*1.E12*ScaleFact[pmtleft+j];
      knorm[j]=fatte1[pmtleft+j]*Exp(flambda1[pmtleft+j]*dimel[planeNo]/2.*Power(-1,j+1)) + 
        fatte2[pmtleft+j]*Exp(flambda2[pmtleft+j]*dimel[planeNo]/2.*Power(-1,j+1));
      Atten[j]=fatte1[pmtleft+j]*Exp(tpos*flambda1[pmtleft+j]) + 
        fatte2[pmtleft+j]*Exp(tpos*flambda2[pmtleft+j]) ;
      QhitPmt_pC[j]= QhitPad_pC[j]*Atten[j]/knorm[j];
      if (fDEBUG) {
        cout<<"pmtleft:"<<pmtleft<<" j:"<<j<<endl;
        cout<<"atte1:"<<fatte1[pmtleft+j]<<" lambda1:"<<flambda1[pmtleft+j]
            <<" atte2:"<<fatte2[pmtleft+j]<<" lambda2:"<<flambda2[pmtleft+j] 
            <<endl;    
        cout<<j<<" tpos:"<<tpos<<" knorm:"<<knorm[j]<<" "<<Atten[j]<<" "
            <<"QhitPmt_pC "<<QhitPmt_pC[j]<<endl;    
      }
    }
    
    if(fDEBUG)cout<<"Energy release (keV):"<<hit->GetEREL()*1.e6<<" Npho:"<<Npho<<
               " QhitPmt_pC(left,right):"<<QhitPmt_pC[0]<<" "<<QhitPmt_pC[1]<<endl;

    fQevePmt_pC[pmtleft]  += QhitPmt_pC[0];  //cdding charge from separate hits
    fQevePmt_pC[pmtright] += QhitPmt_pC[1];

    // TDC
    // WM right and left <->    
    t1 += Abs(path[0]/veff0) + s_l_g[planeNo]/veff1;
    t2 += Abs(path[1]/veff0) + s_l_g[planeNo]/veff1;  // Signal reaches PMT
    t1 = frandom->Gaus(t1,TimeRes(PrimaryPDG)); //apply gaussian error  dt
    t2 = frandom->Gaus(t2,TimeRes(PrimaryPDG)); //apply gaussian error  dt
    t1 += fc1_S[pmtleft] ;  // Signal reaches Discriminator ,TDC starts  to run
    t2 += fc1_S[pmtright] ;

    // check if signal is above threshold
    // then check if tdcpmt is already filled by another hit...
    // only re-fill if time is smaller
    if (QhitPmt_pC[0] > thresh) {
      if (ftdcpmt[pmtleft] == 1000.) {  // fill for the first time
        ftdcpmt[pmtleft] = t1;
        ftdc[pmtleft] = t1 + fc2_S[pmtleft] ;  // Signal reaches Coincidence
      }
      if (ftdcpmt[pmtleft] < 1000.) // is already filled!
        if (t1 <  ftdcpmt[pmtleft]) {
          ftdcpmt[pmtleft] = t1;
          t1 += fc2_S[pmtleft] ;  // Signal reaches Coincidence
          ftdc[pmtleft] = t1;
        }
    }
    if (QhitPmt_pC[1] > thresh) {
      if (ftdcpmt[pmtright] == 1000.) {  // fill for the first time
        ftdcpmt[pmtright] = t2;
        ftdc[pmtright] = t2 + fc2_S[pmtright] ;  // Signal reaches Coincidence
      }
      if (ftdcpmt[pmtright] < 1000.)  // is already filled!
        if (t2 <  ftdcpmt[pmtright]) {
          ftdcpmt[pmtright] = t2;
          t2 += fc2_S[pmtright] ;
          ftdc[pmtright] = t2;
        }
    }
    if(fDEBUG)cout<<"Time(s):"<<hit->GetTOF()<<" t1:"<<t1<<" t2:"<<t2<<endl
                 <<"+++++  END OF TOF HIT +++++"<<endl;
  }; 
  //END OF HIT COLLECTION LOOP 
}

void PamVMCTofDig::Paddle2Pmt(Int_t planeNo, Int_t padNo, Int_t *pl, Int_t *pr){
  //* @param plane    (0 - 5)
  //* @param paddle   (plane=0, paddle = 0,...5)
  //* @param padid    (0 - 23)  
  //
  Int_t padid=-1;
  Int_t pads[6]={8,6,2,2,3,3};
  //
  Int_t somma=0;
  for(Int_t j=0; j<planeNo; j++) somma+=pads[j];
  padid=padNo+somma;
  *pl = padid*2;
  *pr = *pl + 1; // WM

}


UChar_t PamVMCTofDig::Bin2GrayTof(UChar_t binaTOF,UChar_t grayTOF){
  union graytof_data {
    UChar_t word;
    struct bit_field {
      unsigned b0:1;
      unsigned b1:1;
      unsigned b2:1;
      unsigned b3:1;
      unsigned b4:1;
      unsigned b5:1;
      unsigned b6:1;
      unsigned b7:1;
    } bit;
  } bi,gr;
  //
  bi.word = binaTOF;
  gr.word = grayTOF;
  // 
  gr.bit.b0 = bi.bit.b1 ^ bi.bit.b0;
  gr.bit.b1 = bi.bit.b2 ^ bi.bit.b1;
  gr.bit.b2 = bi.bit.b3 ^ bi.bit.b2;
  gr.bit.b3 = bi.bit.b3;
  //
  /* bin to gray conversion 4 bit per time*/
  //
  gr.bit.b4 = bi.bit.b5 ^ bi.bit.b4;
  gr.bit.b5 = bi.bit.b6 ^ bi.bit.b5;
  gr.bit.b6 = bi.bit.b7 ^ bi.bit.b6;
  gr.bit.b7 = bi.bit.b7;
  //
  return(gr.word); 
}

void PamVMCTofDig::Crc8Tof(UChar_t *oldCRC, UChar_t *crcTof){
  union crctof_data {
    UChar_t word;
    struct bit_field {
      unsigned b0:1;
      unsigned b1:1;
      unsigned b2:1;
      unsigned b3:1;
      unsigned b4:1;
      unsigned b5:1;
      unsigned b6:1;
      unsigned b7:1;
    } bit;
  } c,d,r;

  c.word = *oldCRC;
  //d.word = *newCRC;
  d.word = *crcTof;
  r.word = 0;

  r.bit.b0 = c.bit.b7 ^ c.bit.b6 ^ c.bit.b0 ^ 
             d.bit.b0 ^ d.bit.b6 ^ d.bit.b7;

  r.bit.b1 = c.bit.b6 ^ c.bit.b1 ^ c.bit.b0 ^ 
             d.bit.b0 ^ d.bit.b1 ^ d.bit.b6;

  r.bit.b2 = c.bit.b6 ^ c.bit.b2 ^ c.bit.b1 ^ c.bit.b0 ^
             d.bit.b0 ^ d.bit.b1 ^ d.bit.b2 ^ d.bit.b6;

  r.bit.b3 = c.bit.b7 ^ c.bit.b3 ^ c.bit.b2 ^ c.bit.b1 ^ 
             d.bit.b1 ^ d.bit.b2 ^ d.bit.b3 ^ d.bit.b7;

  r.bit.b4 = c.bit.b4 ^ c.bit.b3 ^ c.bit.b2 ^
             d.bit.b2 ^ d.bit.b3 ^ d.bit.b4;

  r.bit.b5 = c.bit.b5 ^ c.bit.b4 ^ c.bit.b3 ^
             d.bit.b3 ^ d.bit.b4 ^ d.bit.b5;

  r.bit.b6 = c.bit.b6 ^ c.bit.b5 ^ c.bit.b4 ^ 
             d.bit.b4 ^ d.bit.b5 ^ d.bit.b6;

  r.bit.b7 = c.bit.b7 ^ c.bit.b6 ^ c.bit.b5 ^ 
             d.bit.b5 ^ d.bit.b6 ^ d.bit.b7 ;

  *crcTof=r.word;
  //return r.word; 
};


UChar_t PamVMCTofDig::EvaluateCrc(UChar_t *pTrg, Int_t nb) {
  Bool_t DEBUG=false;
  if (DEBUG)
    return(0x00);

  UChar_t crcTrg=0x00;
  UChar_t *pc=&crcTrg, *pc2;
  pc2=pTrg;
  for (Int_t jp=0; jp < nb; jp++)
    Crc8Tof(pc2++,pc);
  return(crcTrg);
}
1	#include "PamVMCTofDig.h"
2	#include "TDatabasePDG.h"
3
4	#include <TMath.h>
5	#include <TRandom.h>
6
7	using TMath::Power;
8	using TMath::Exp;
9	using TMath::Abs;
10
11	ClassImp(PamVMCTofDig)
12
13
14	void PamVMCTofDig::LoadCalib(){
15
16	cout<<"Loading Tof Calibrations..."<<endl;
17
18	Int_t time=3;
19	Int_t type=202;
20
21	fdberr = fsql->Query_GL_PARAM(time,type);
22
23	fquery.str("");
24	fquery << fsql->GetPAR()->PATH.Data() << "/";
25	fquery << fsql->GetPAR()->NAME.Data();
26
27	ThrowCalFileUsage("TOF",fquery.str().c_str());
28
29	fcfile.open(fquery.str().c_str());
30
31	if(!fcfile) ThrowCalFileWarning("TOF"); else {
32
33	Int_t temp;
34
35	for(Int_t i=0; i<NP; i++){
36	fcfile >> temp;
37	fcfile >> fatte1[i];
38	fcfile >> flambda1[i];
39	fcfile >> fatte2[i];
40	fcfile >> flambda2[i];
41	fcfile >> temp;
42	}
43
44	}
45
46	fcfile.close();
47	}
48
49
50
51
52	void PamVMCTofDig::DigitizeTOF(Int_t EventNo, Int_t PrimaryPDG){
53
54	fDEBUG = kFALSE;
55
56	// pC < 800
57	const Float_t ADC_pC0A = -4.437616e+01;
58	const Float_t ADC_pC1A = 1.573329e+00;
59	const Float_t ADC_pC2A = 2.780518e-04;
60	const Float_t ADC_pC3A = -2.302160e-07;
61	// pC > 800:
62	const Float_t ADC_pC0B = -2.245756e+02;
63	const Float_t ADC_pC1B = 2.184156e+00;
64	const Float_t ADC_pC2B = -4.171825e-04;
65	const Float_t ADC_pC3B = 3.789715e-08;
66
67	const Float_t pCthres=40.; // threshold in charge
68	const Int_t ADClast=4095; // no signal --> ADC ch=4095
69	const Int_t ADCsat=3100; // saturation value for the ADCs
70	const Int_t TDClast=4095;
71
72
73	for(Int_t i =0; i<NP; i++){
74	fQevePmt_pC[i]=ftdc[i]=ftdc1[i]=0.;
75	ftdcpmt[i]=1000.;
76	}
77
78
79
80	TClonesArray* hc = 0;
81	const char* keyplane [6] = {"S11Y","S12X","S21X","S22Y","S31Y","S32X"};
82	for(Int_t i=0; i<6; i++){
83	hc = (TClonesArray*)fhitscolmap.GetValue(keyplane[i]);
84	if (hc) DigitizeTofPlane(i,hc, PrimaryPDG);
85	hc = 0;
86	}
87
88	if(fDEBUG){
89	cout<<"Summarized values for ADC in PC:"<<endl;
90	for(Int_t i=0; i<NP; i++){
91	cout<<"PMT #"<<i<<" fQevePmt_pC="<<fQevePmt_pC[i]<<endl;
92	}
93	}
94	//+++++ ADC +++++
95
96	for(Int_t i=0; i<NP; i++){
97	if (fQevePmt_pC[i] <= 800.)
98	fADCtof[i]= (Int_t)(ADC_pC0A + ADC_pC1A*fQevePmt_pC[i]
99	+ ADC_pC2A*Power(fQevePmt_pC[i],2)
100	+ ADC_pC3A*Power(fQevePmt_pC[i],3));
101	if ((fQevePmt_pC[i] > 800.) && (fQevePmt_pC[i] <= 2485.))
102	fADCtof[i]= (Int_t)(ADC_pC0B + ADC_pC1B*fQevePmt_pC[i]
103	+ ADC_pC2B*Power(fQevePmt_pC[i],2)
104	+ ADC_pC3B*Power(fQevePmt_pC[i],3));
105	if (fQevePmt_pC[i] > 2485.) fADCtof[i]= (Int_t)(1758. + 0.54*fQevePmt_pC[i]);
106	//assuming a fictional 0.54 ch/pC above ADCsat
107	if (fADCtof[i]>ADCsat) fADCtof[i]=ADCsat;
108	if (fQevePmt_pC[i] < pCthres) fADCtof[i]= ADClast;
109	if (fADCtof[i] < 0) fADCtof[i]=ADClast;
110	if (fADCtof[i] > ADClast) fADCtof[i]=ADClast;
111	}
112
113	// ====== TDC coincidence ======
114
115
116	for(Int_t i=0; i<NP; i++) {
117	if((ftdcpmt[i] - fc1_S[i]) > 1e-7) {
118	ftdcpmt[i] = 0.;
119	ftdc[i] = 0.;
120	}
121	}// cycle to introduce a window for tdc
122
123	Double_t t_coinc = 0;
124	Int_t ilast = 100;
125	for (Int_t ii=0; ii<NP;ii++)
126	if (ftdc[ii] > t_coinc) {
127	t_coinc = ftdc[ii];
128	ilast = ii;
129	}
130
131	for (Int_t ii=0; ii<NP;ii++){
132	if (ftdc[ii] != 0) ftdc1[ii] = t_coinc - ftdcpmt[ii]; // test 2
133	ftdc1[ii] = ftdc1[ii]/ftdcres[ii]; // divide by TDC resolution
134	if (ftdc[ii] != 0) ftdc1[ii] = ftdc1[ii] + fc3_S[ii]; // add cable length c3
135	}
136
137	if (fDEBUG)cout<<"====== TOF coincidence ======"<<endl;
138	for(Int_t i=0; i<NP; i++){
139	if(ftdc1[i] != 0.){
140	fTDCint[i]=(Int_t)ftdc1[i];
141	if (fTDCint[i]>4093) fTDCint[i]=TDClast; // 18-oct WM
142	if (fDEBUG)cout<<"PMT: "<<i<<" ADC: "<<fADCtof[i]<<" TDC: "
143	<<fTDCint[i]<<endl;
144	} else
145	fTDCint[i]= TDClast;
146	}
147	if (fDEBUG)cout<<"============================="<<endl;
148
149	//------ use channelmap for ToF: 18-oct WM
150	Int_t channelmap[] = {3,21,11,29,19,45,27,37,36,28,44,20,5,12,13,4,
151	6,47,14,39,22,31,30,23,38,15,46,7,0,33,16,24,
152	8,41,32,40,25,17,34,9,42,1,2,10,18,26,35,43};
153	Int_t ADChelp[NP],TDChelp[NP];
154	for(Int_t i=0; i<NP; i++){
155	Int_t ii=channelmap[i];
156	ADChelp[ii]= fADCtof[i];
157	TDChelp[ii]= fTDCint[i];
158	}
159	for(Int_t i=0; i<NP; i++){
160	fADCtof[i]= ADChelp[i];
161	fTDCint[i]= TDChelp[i];
162	}
163
164	if (fDEBUG){
165	cout<<"====== TOF coincidence after... ======"<<endl;
166	for(Int_t i=0; i<NP; i++){
167	cout<<"PMT: "<<i<<" ADC: "<<fADCtof[i]<<" TDC: "
168	<<fTDCint[i]<<endl;
169	}
170	cout<<"============================="<<endl;
171	}
172	// ====== write DataTof =======
173
174	UChar_t Ctrl3bit[8]={32,0,96,64,160,128,224,192}; // DC (msb in 8 bit word )
175	UChar_t tofBin;
176	UChar_t DataTof[276];
177	for (Int_t j=0; j < 276; j++)DataTof[j]=0x00;
178	UChar_t *pTof=DataTof;
179	for (Int_t j=0; j < 12; j++){ // loop on TDC #12
180	Int_t j12=j*23; // for each TDC 23 bytes (8 bits)
181	DataTof[j12+0]=0x00; // TDC_ID
182	DataTof[j12+1]=0x00; // EV_COUNT
183	DataTof[j12+2]=0x00; // TDC_MASK (1)
184	DataTof[j12+3]=0x00; // TDC_MASK (2)
185	for (Int_t k=0; k < 4; k++){ // for each TDC 4 channels (ADC+TDC)
186	Int_t jk12=j12+4*k; // ADC,TDC channel (0-47)
187	tofBin =(UChar_t)(fADCtof[k+4*j]/256); // ADC# (msb)
188	DataTof[jk12+4] = Bin2GrayTof(tofBin,DataTof[jk12+4]);
189	/* control bits inserted here, after the bin to gray conv - DC*/
190	DataTof[jk12+4] = Ctrl3bit[2*k] \| DataTof[jk12+4];
191	tofBin=(UChar_t)(fADCtof[k+4*j]%256); // ADC# (lsb)
192	DataTof[jk12+5] = Bin2GrayTof(tofBin,DataTof[jk12+5]);
193	tofBin=(UChar_t)(fTDCint[k+4*j]/256); // TDC# (msb)
194	DataTof[jk12+6]=Bin2GrayTof(tofBin,DataTof[jk12+6]);
195	/* control bits inserted here, after the bin to gray conv - DC*/
196	DataTof[jk12+6] = Ctrl3bit[2*k+1] \| DataTof[jk12+6];
197	tofBin=(UChar_t)(fTDCint[k+4*j]%256); // TDC# (lsb)
198	//if(fDEBUG) cout<<" digit TDC: "<<jk12<<" TDC:"<<(Int_t)tofBin<<endl;
199	DataTof[jk12+7]=Bin2GrayTof(tofBin,DataTof[jk12+7]);
200	}
201	DataTof[j12+20]=0x00; // TEMP1
202	DataTof[j12+21]=0x00; // TEMP2
203	DataTof[j12+22]= EvaluateCrc(pTof,22); // CRC
204	pTof+=23;
205	}
206
207	//===== write DataTrigger =======
208
209	UChar_t DataTrigger[152];
210	for (Int_t j=0; j < 152; j++)DataTrigger[j]=0x00;
211	UChar_t *pTrg=DataTrigger;
212	// Only the variables with a (*) are modified; the others are set to 0
213	// info given in #bites data + #bites crc
214	// TB_READ_PMT_PLANE : 6 + 1
215	// TB_READ_EVENT_COUNT : 3 + 1 (*)
216	// TB_READ_TRIGGER_RATE : 12 + 1
217	// TB_READ_D_L_TIME : 4 + 1
218	// TB_READ_S4_CAL_COUNT : 4 + 1
219	// TB_READ_PMT_COUNT1 : 48 + 1
220	// TB_READ_PMT_COUNT2 : 48 + 1
221	// TB_READ_PATTERN_BUSY : 8 + 1
222	// TB_READ_PATTERN_TRIGGER: 7 + 1 (*)
223	// TB_READ_TRIGGER_CONF : 2 + 1 (*)
224	// TB_READ_EVENT_COUNT
225	UInt_t cTrg = EventNo; //counter
226	UInt_t cTrg2 = 0; //counter with bits inverted, according to document
227	//"formato dati provenienti dalla trigger board"
228	for (Int_t i=0; i < 24; i++){ // Use the first 24 bits
229	if (cTrg & (0x1 << i) )
230	cTrg2 = cTrg2 \| (0x1 << (24-i));
231	}
232	DataTrigger[7] = (UChar_t)(cTrg2 >> 16); // 8 MSbits (out of 24)
233	DataTrigger[8] = (UChar_t)(cTrg2 >> 8); // 8 "middle" bits
234	DataTrigger[9] = (UChar_t)(cTrg2); // 8 LSbits
235	pTrg=DataTrigger+7;
236	DataTrigger[10]=EvaluateCrc(pTrg, 3);
237
238	// TB_READ_PATTERN_TRIGGER: bytes 141-148:
239	// PatternTrigMap[i] corresponds to bit i in TB_READ_PATTERN_TRIGGER:
240	// mapping according to documents:
241	// 1. "formato dati provenienti dalla trigger board"
242	// 2. "The ToF quicklook software", Appendix A (Campana, Nagni)
243	Int_t PatternTrigMap[]={29,42,43,1,16,7,17,28,33,41,46,2,15,8,18,27,
244	30,40,44,3,14,9,19,26,32,37,47,4,13,10,20,25,
245	34,31,38,45,5,12,21,24,36,35,39,48,6,11,22,23};
246	for (Int_t i=0; i<NP; i++){
247	if (ftdc1[channelmap[i]]!=0)
248	DataTrigger[147-(Int_t)((PatternTrigMap[i]+1)/8)]=DataTrigger[147-(Int_t)((PatternTrigMap[i]+1)/8)] \| (0x1 << (PatternTrigMap[i]%8));
249	}
250	pTrg=DataTrigger+141;
251	DataTrigger[148]=EvaluateCrc(pTrg, 7);
252
253	// TB_READ_TRIGGER_CONF : set always acq.mode TOF4
254	//
255	// TOF1: S1-S2-S3 (&,\|)
256	// TOF4: S2-S3 (&,&)
257	DataTrigger[149]=0x02;
258	DataTrigger[150]=0x0;
259	pTrg=DataTrigger+149;
260	DataTrigger[151]=EvaluateCrc(pTrg, 2);
261
262
263	//++++++ WRITE EVERYTHING TO DIGITIZER'S BUFFER +++//
264	cout<<"TOF Digitizing"<<endl;
265
266	fDataC.clear(); //clearing Tof & Trig data buffer
267
268	for(Int_t i= 0; i<152; i++) fDataC.push_back(DataTrigger[i]);
269
270	for(Int_t i= 0; i<276; i++) fDataC.push_back(DataTof[i]);
271
272	}
273
274	Float_t PamVMCTofDig::TimeRes(Int_t PrimaryPDG){
275
276	Float_t time_res[8] = {425.,210.,170.,130.,120.,120.,120.,120.};
277	for(Int_t i=0;i<8;i++) time_res[i]/=1.4;//1.17;1.5;1.3*/
278	Int_t Z = Int_t((TDatabasePDG::Instance()->GetParticle(PrimaryPDG))->Charge()/3.);
279
280	Float_t dt1 = 1.e-12*time_res[0]; // single PMT resolution for Z=1 (WM, Nov'07)
281	if ((Z > 1) && (Z < 9)) dt1=1.e-12*time_res[(Z-1)];
282	if (Z > 8) dt1=120.e-12;
283
284	return dt1;
285	}
286
287	void PamVMCTofDig::DigitizeTofPlane(Int_t planeNo, TClonesArray* HitColl, Int_t PrimaryPDG){
288
289	PamVMCDetectorHit * hit = 0;
290	const Float_t veff0 = 100.*1.0e8;//(m/s) light velocity in scintillator
291	const Float_t veff1 = 100.*1.5e8;//(m/s) light velocity in lightguide
292	const Float_t FGeo[2] = {0.5, 0.5}; //geometrical factor
293	const Float_t Pho_keV = 10.;// photons per keV in scintillator
294	const Float_t effi = 0.21; //photocathofe efficiency
295	const Float_t pmGain = 3.5e6; //PMT Gain: the same for all PMTs
296	const Float_t echarge = 1.6e-19; // electron charge
297	const Float_t thresh=20.; // to be defined better... (Wolfgang)
298
299	const Float_t dimel[6] = {33.0, 40.8 ,18.0, 15.0, 15.0, 18.0}; //(cm) TOF paddles dimensions
300	// S11 8 paddles 33.0 x 5.1 cm
301	// S12 6 paddles 40.8 x 5.5 cm
302	// S21 2 paddles 18.0 x 7.5 cm
303	// S22 2 paddles 15.0 x 9.0 cm
304	// S31 3 paddles 15.0 x 6.0 cm
305	// S32 3 paddles 18.0 x 5.0 cm
306
307	const Float_t s_l_g[6] = {8.0, 8.0, 20.9, 22.0, 9.8, 8.3 }; //(cm) length of the lightguide
308
309	const Float_t ScaleFact[48]={0.39, 0.49, 0.38, 0.40, 0.65, 0.51, 0.43,
310	0.49, 0.58, 0.38, 0.53, 0.57, 0.53, 0.45, 0.49, 0.16,
311	0.15, 0.44, 0.28, 0.57, 0.26, 0.72, 0.37, 0.29, 0.30, 0.89,
312	0.37, 0.08, 0.27, 0.23, 0.12, 0.22, 0.15, 0.16, 0.21,
313	0.19, 0.41, 0.32, 0.39, 0.38, 0.28, 0.66, 0.28, 0.40, 0.39, 0.40, 0.37, 0.35 };
314
315	Float_t t1, t2, tpos, Npho;
316	Float_t path[2], knorm[2], Atten[2], QhitPad_pC[2], QhitPmt_pC[2];
317	Int_t padNo, pmtleft, pmtright;
318	//LOOP
319	for(Int_t i =0; i<HitColl->GetEntriesFast(); i++){
320
321	hit = (PamVMCDetectorHit*)HitColl->At(i);
322
323	t1=t2 = hit->GetTOF();
324	padNo = hit->GetPOS()-1;
325	pmtleft=pmtright=0;
326	if(planeNo==2){
327	if(padNo==0)
328	padNo=1;
329	else
330	padNo=0;
331	}
332
333	Paddle2Pmt(planeNo,padNo, &pmtleft, &pmtright);
334
335	switch(planeNo){
336	case 0:
337	case 3:
338	case 4:
339	tpos = (hit->GetYIN()+hit->GetYOUT())/2.; //Y-planes
340	break;
341	case 1:
342	case 2:
343	case 5:
344	tpos = (hit->GetXIN()+hit->GetXOUT())/2.; //X-planes
345	break;
346	default:
347	cout<<"PamVMCTofDig::DigitizeTOFPlane wrong plane no "<<planeNo<<endl;
348	tpos = -100.;
349	break;
350	}
351
352	path[0]= tpos + dimel[planeNo]/2.; // path to left PMT
353	path[1]= dimel[planeNo]/2.- tpos; // path to right PMT
354
355	if (fDEBUG) {
356	cout <<"+++++ TOF HIT VERBOSE INFORMATION: +++++"<<endl;
357	cout <<"planeNo "<<planeNo<<" padNo "<< padNo <<" tpos "<< tpos <<"\n";
358	cout <<"pmtleft, pmtright "<<pmtleft<<","<<pmtright<<endl;
359	}
360
361	Npho = hit->GetEREL()Pho_keV1.0e6; //calculation of photons number
362
363	for(Int_t j=0; j<2; j++){
364	QhitPad_pC[j]= NphoFGeo[j]effipmGainecharge1.E12ScaleFact[pmtleft+j];
365	knorm[j]=fatte1[pmtleft+j]Exp(flambda1[pmtleft+j]dimel[planeNo]/2.*Power(-1,j+1)) +
366	fatte2[pmtleft+j]Exp(flambda2[pmtleft+j]dimel[planeNo]/2.*Power(-1,j+1));
367	Atten[j]=fatte1[pmtleft+j]Exp(tposflambda1[pmtleft+j]) +
368	fatte2[pmtleft+j]Exp(tposflambda2[pmtleft+j]) ;
369	QhitPmt_pC[j]= QhitPad_pC[j]*Atten[j]/knorm[j];
370	if (fDEBUG) {
371	cout<<"pmtleft:"<<pmtleft<<" j:"<<j<<endl;
372	cout<<"atte1:"<<fatte1[pmtleft+j]<<" lambda1:"<<flambda1[pmtleft+j]
373	<<" atte2:"<<fatte2[pmtleft+j]<<" lambda2:"<<flambda2[pmtleft+j]
374	<<endl;
375	cout<<j<<" tpos:"<<tpos<<" knorm:"<<knorm[j]<<" "<<Atten[j]<<" "
376	<<"QhitPmt_pC "<<QhitPmt_pC[j]<<endl;
377	}
378	}
379
380	if(fDEBUG)cout<<"Energy release (keV):"<<hit->GetEREL()*1.e6<<" Npho:"<<Npho<<
381	" QhitPmt_pC(left,right):"<<QhitPmt_pC[0]<<" "<<QhitPmt_pC[1]<<endl;
382
383	fQevePmt_pC[pmtleft] += QhitPmt_pC[0]; //cdding charge from separate hits
384	fQevePmt_pC[pmtright] += QhitPmt_pC[1];
385
386	// TDC
387	// WM right and left <->
388	t1 += Abs(path[0]/veff0) + s_l_g[planeNo]/veff1;
389	t2 += Abs(path[1]/veff0) + s_l_g[planeNo]/veff1; // Signal reaches PMT
390	t1 = frandom->Gaus(t1,TimeRes(PrimaryPDG)); //apply gaussian error dt
391	t2 = frandom->Gaus(t2,TimeRes(PrimaryPDG)); //apply gaussian error dt
392	t1 += fc1_S[pmtleft] ; // Signal reaches Discriminator ,TDC starts to run
393	t2 += fc1_S[pmtright] ;
394
395	// check if signal is above threshold
396	// then check if tdcpmt is already filled by another hit...
397	// only re-fill if time is smaller
398	if (QhitPmt_pC[0] > thresh) {
399	if (ftdcpmt[pmtleft] == 1000.) { // fill for the first time
400	ftdcpmt[pmtleft] = t1;
401	ftdc[pmtleft] = t1 + fc2_S[pmtleft] ; // Signal reaches Coincidence
402	}
403	if (ftdcpmt[pmtleft] < 1000.) // is already filled!
404	if (t1 < ftdcpmt[pmtleft]) {
405	ftdcpmt[pmtleft] = t1;
406	t1 += fc2_S[pmtleft] ; // Signal reaches Coincidence
407	ftdc[pmtleft] = t1;
408	}
409	}
410	if (QhitPmt_pC[1] > thresh) {
411	if (ftdcpmt[pmtright] == 1000.) { // fill for the first time
412	ftdcpmt[pmtright] = t2;
413	ftdc[pmtright] = t2 + fc2_S[pmtright] ; // Signal reaches Coincidence
414	}
415	if (ftdcpmt[pmtright] < 1000.) // is already filled!
416	if (t2 < ftdcpmt[pmtright]) {
417	ftdcpmt[pmtright] = t2;
418	t2 += fc2_S[pmtright] ;
419	ftdc[pmtright] = t2;
420	}
421	}
422	if(fDEBUG)cout<<"Time(s):"<<hit->GetTOF()<<" t1:"<<t1<<" t2:"<<t2<<endl
423	<<"+++++ END OF TOF HIT +++++"<<endl;
424	};
425	//END OF HIT COLLECTION LOOP
426	}
427
428	void PamVMCTofDig::Paddle2Pmt(Int_t planeNo, Int_t padNo, Int_t pl, Int_t pr){
429	//* @param plane (0 - 5)
430	//* @param paddle (plane=0, paddle = 0,...5)
431	//* @param padid (0 - 23)
432	//
433	Int_t padid=-1;
434	Int_t pads[6]={8,6,2,2,3,3};
435	//
436	Int_t somma=0;
437	for(Int_t j=0; j<planeNo; j++) somma+=pads[j];
438	padid=padNo+somma;
439	pl = padid2;
440	pr = pl + 1; // WM
441
442	}
443
444
445	UChar_t PamVMCTofDig::Bin2GrayTof(UChar_t binaTOF,UChar_t grayTOF){
446	union graytof_data {
447	UChar_t word;
448	struct bit_field {
449	unsigned b0:1;
450	unsigned b1:1;
451	unsigned b2:1;
452	unsigned b3:1;
453	unsigned b4:1;
454	unsigned b5:1;
455	unsigned b6:1;
456	unsigned b7:1;
457	} bit;
458	} bi,gr;
459	//
460	bi.word = binaTOF;
461	gr.word = grayTOF;
462	//
463	gr.bit.b0 = bi.bit.b1 ^ bi.bit.b0;
464	gr.bit.b1 = bi.bit.b2 ^ bi.bit.b1;
465	gr.bit.b2 = bi.bit.b3 ^ bi.bit.b2;
466	gr.bit.b3 = bi.bit.b3;
467	//
468	/* bin to gray conversion 4 bit per time*/
469	//
470	gr.bit.b4 = bi.bit.b5 ^ bi.bit.b4;
471	gr.bit.b5 = bi.bit.b6 ^ bi.bit.b5;
472	gr.bit.b6 = bi.bit.b7 ^ bi.bit.b6;
473	gr.bit.b7 = bi.bit.b7;
474	//
475	return(gr.word);
476	}
477
478	void PamVMCTofDig::Crc8Tof(UChar_t oldCRC, UChar_t crcTof){
479	union crctof_data {
480	UChar_t word;
481	struct bit_field {
482	unsigned b0:1;
483	unsigned b1:1;
484	unsigned b2:1;
485	unsigned b3:1;
486	unsigned b4:1;
487	unsigned b5:1;
488	unsigned b6:1;
489	unsigned b7:1;
490	} bit;
491	} c,d,r;
492
493	c.word = *oldCRC;
494	//d.word = *newCRC;
495	d.word = *crcTof;
496	r.word = 0;
497
498	r.bit.b0 = c.bit.b7 ^ c.bit.b6 ^ c.bit.b0 ^
499	d.bit.b0 ^ d.bit.b6 ^ d.bit.b7;
500
501	r.bit.b1 = c.bit.b6 ^ c.bit.b1 ^ c.bit.b0 ^
502	d.bit.b0 ^ d.bit.b1 ^ d.bit.b6;
503
504	r.bit.b2 = c.bit.b6 ^ c.bit.b2 ^ c.bit.b1 ^ c.bit.b0 ^
505	d.bit.b0 ^ d.bit.b1 ^ d.bit.b2 ^ d.bit.b6;
506
507	r.bit.b3 = c.bit.b7 ^ c.bit.b3 ^ c.bit.b2 ^ c.bit.b1 ^
508	d.bit.b1 ^ d.bit.b2 ^ d.bit.b3 ^ d.bit.b7;
509
510	r.bit.b4 = c.bit.b4 ^ c.bit.b3 ^ c.bit.b2 ^
511	d.bit.b2 ^ d.bit.b3 ^ d.bit.b4;
512
513	r.bit.b5 = c.bit.b5 ^ c.bit.b4 ^ c.bit.b3 ^
514	d.bit.b3 ^ d.bit.b4 ^ d.bit.b5;
515
516	r.bit.b6 = c.bit.b6 ^ c.bit.b5 ^ c.bit.b4 ^
517	d.bit.b4 ^ d.bit.b5 ^ d.bit.b6;
518
519	r.bit.b7 = c.bit.b7 ^ c.bit.b6 ^ c.bit.b5 ^
520	d.bit.b5 ^ d.bit.b6 ^ d.bit.b7 ;
521
522	*crcTof=r.word;
523	//return r.word;
524	};
525
526
527
528
529	UChar_t PamVMCTofDig::EvaluateCrc(UChar_t *pTrg, Int_t nb) {
530	Bool_t DEBUG=false;
531	if (DEBUG)
532	return(0x00);
533
534	UChar_t crcTrg=0x00;
535	UChar_t pc=&crcTrg, pc2;
536	pc2=pTrg;
537	for (Int_t jp=0; jp < nb; jp++)
538	Crc8Tof(pc2++,pc);
539	return(crcTrg);
540	}