#include <XtMdcCalib.h>

Inheritance diagram for XtMdcCalib:

Public Member Functions
	XtMdcCalib ()

	~XtMdcCalib ()

void	initialize (TObjArray hlist, IMdcGeomSvc mdcGeomSvc, IMdcCalibFunSvc mdcFunSvc, IMdcUtilitySvc mdcUtilitySvc)

void	setParam (MdcCalParams &param)

int	fillHist (MdcCalEvent *event)

int	updateConst (MdcCalibConst *calconst)

void	clear ()

int	getHxtKey (int lay, int entr, int lr, int bin) const

Public Member Functions inherited from MdcCalib
	MdcCalib ()

virtual	~MdcCalib ()

virtual void	initialize (TObjArray hlist, IMdcGeomSvc mdcGeomSvc, IMdcCalibFunSvc mdcFunSvc, IMdcUtilitySvc mdcUtilitySvc)=0

virtual void	setParam (MdcCalParams &param)=0

virtual int	fillHist (MdcCalEvent *event)=0

virtual int	updateConst (MdcCalibConst *calconst)=0

virtual void	clear ()=0

Static Public Member Functions
static void	fcnXT (Int_t &npar, Double_t gin, Double_t &f, Double_t par, Int_t iflag)

static void	fcnXtEdge (Int_t &npar, Double_t gin, Double_t &f, Double_t par, Int_t iflag)

static double	xtFun (double t, double xtpar[])

Static Public Attributes
static std::vector< double >	XMEAS

static std::vector< double >	TBINCEN

static std::vector< double >	ERR

static double	Tmax

static double	Dmax

static std::vector< double >	XMEASED

static std::vector< double >	TBINCENED

static std::vector< double >	ERRED

Detailed Description

Definition at line 10 of file XtMdcCalib.h.

Constructor & Destructor Documentation

◆ XtMdcCalib()

XtMdcCalib::XtMdcCalib ( )

Definition at line 34 of file XtMdcCalib.cxx.

                      {
     m_nbin = 50;       // m_nbin=50 before 2011-11-16
     m_nLR = 3;
     m_nxtpar = 8;
 
     for(int lay=0; lay<43; lay++){
      if(lay < 15) m_nEntr[lay] = 1;
      else  m_nEntr[lay] = 2;       // for entr>0 and entr<0
     }
 
     m_tbinw = 10.0;
     m_fgIni = false;
}

◆ ~XtMdcCalib()

XtMdcCalib::~XtMdcCalib ( )

Definition at line 48 of file XtMdcCalib.cxx.

48 {

49}

Member Function Documentation

◆ clear()

void XtMdcCalib::clear ( )

virtual

Implements MdcCalib.

Definition at line 51 of file XtMdcCalib.cxx.

                      {
     cout << "~XtMdcCalib" << endl;
 
     unsigned int i;
     for(i=0; i<m_hxt.size(); i++){
      delete m_hxt[i];
          if(0 == (i % 1000)) cout << "delete hxt[" << i << "]" << endl;
     }
     delete m_fdXt;
     m_hxt.clear();
     m_hxtmap.clear();
 
     MdcCalib::clear();
}

◆ fcnXT()

void XtMdcCalib::fcnXT	(	Int_t &	npar,
		Double_t *	gin,
		Double_t &	f,
		Double_t *	par,
		Int_t	iflag
	)

static

Definition at line 517 of file XtMdcCalib.cxx.

                                          {
     unsigned int i;
     int ord;
     Double_t deta;
     Double_t chisq = 0.0;
     Double_t dfit;
 
     for(i=0; i<TBINCEN.size(); i++){
      dfit = 0;
      for(ord=0; ord<=5; ord++){
           dfit += par[ord] * pow(TBINCEN[i], ord);
      }
      deta = (dfit - XMEAS[i]) / ERR[i];
      chisq += deta * deta;
     }
 
     f = chisq;
}

Referenced by updateConst().

◆ fcnXtEdge()

void XtMdcCalib::fcnXtEdge	(	Int_t &	npar,
		Double_t *	gin,
		Double_t &	f,
		Double_t *	par,
		Int_t	iflag
	)

static

Definition at line 555 of file XtMdcCalib.cxx.

                                                      {
     unsigned int i;
     Double_t deta;
     Double_t chisq = 0.0;
     Double_t dfit;
 
     for(i=0; i<TBINCENED.size(); i++){
          dfit = par[0] * (TBINCENED[i] - Tmax) + Dmax;
          deta = (dfit - XMEASED[i]) / ERRED[i];
          chisq += deta * deta;
     }
 
     f = chisq;
}

Referenced by updateConst().

◆ fillHist()

int XtMdcCalib::fillHist ( MdcCalEvent * event )

virtual

Implements MdcCalib.

Definition at line 114 of file XtMdcCalib.cxx.

                                          {
     IMessageSvc* msgSvc;
     Gaudi::svcLocator() -> service("MessageSvc", msgSvc);
     MsgStream log(msgSvc, "XtMdcCalib");
     log << MSG::DEBUG << "XtMdcCalib::fillHist()" << endreq;
 
     MdcCalib::fillHist(event);
 
     // get EsTimeCol
     bool esCutFg = event->getEsCutFlag();
     if( ! esCutFg ) return -1;
 
     int i;
     int k;
     int lay;
     int iLR;
     int iEntr;
     int bin;
     int key;
     int hid;
 
     double dr;
     double dz;
     double tdr;
     double doca;
     double resi;
     double entrance;
     int stat;
 
     double xtpar[MdcCalXtNPars];
     int nhitlay;
     bool fgHitLay[MdcCalNLayer];
 
     if(! m_fgIni){
      for(lay=0; lay<MdcCalNLayer; lay++){
           if(lay < 8) m_docaMax[lay] = m_param.maxDocaInner;
           else m_docaMax[lay] = m_param.maxDocaOuter;
      }
 
      for(lay=0; lay<MdcCalNLayer; lay++){
           for(iEntr=0; iEntr<m_nEntr[lay]; iEntr++){
            for(iLR=0; iLR<MdcCalLR; iLR++){
//           m_mdcFunSvc -> getXtpar(lay, iEntr, iLR, xtpar);
             if(0 == iEntr) m_mdcFunSvc -> getXtpar(lay, 8, iLR, xtpar);
             else if(1 == iEntr) m_mdcFunSvc -> getXtpar(lay, 9, iLR, xtpar);
             m_tm[lay][iEntr][iLR] = xtpar[6];
            }
           }
      }
      m_fgIni = true;
     }
 
     MdcCalRecTrk* rectrk;
     MdcCalRecHit* rechit;
 
     int nhit;
     int ntrk = event -> getNTrk();
     if((ntrk < m_param.nTrkCut[0]) || (ntrk > m_param.nTrkCut[1])) return -1;
     for(i=0; i<ntrk; i++){
      rectrk = event->getRecTrk(i);
      nhit = rectrk -> getNHits();
 
      // dr cut
      dr = rectrk->getDr();
      if(fabs(dr) > m_param.drCut) continue;
 
      // dz cut
      dz = rectrk->getDz();
      if(fabs(dz) > m_param.dzCut) continue;
 
      for(lay=0; lay<MdcCalNLayer; lay++){
           fgHitLay[lay] = false;
      }
 
      for(k=0; k<nhit; k++){
           rechit = rectrk -> getRecHit(k);
           lay = rechit -> getLayid();
           fgHitLay[lay] = true;
      }
 
      nhitlay = 0;
      for(lay=0; lay<MdcCalNLayer; lay++){
           if(fgHitLay[lay]) nhitlay++;
      }
      if(nhitlay < m_param.nHitLayCut) continue;
 
//    bool fgNoise = rectrk->getFgNoiseRatio();
//    if(m_param.noiseCut && (!fgNoise)) continue;
 
      for(k=0; k<nhit; k++){
           rechit = rectrk -> getRecHit(k);
           lay = rechit -> getLayid();
           doca = rechit -> getDocaInc();
           iLR = rechit -> getLR();
           entrance = rechit -> getEntra();
           resi = rechit -> getResiInc();
           tdr = rechit -> getTdrift();
           stat = rechit -> getStat();
 
           if(1 != stat) continue;
 
           if( (fabs(doca) > m_docaMax[lay]) || 
           (fabs(resi) > m_param.resiCut[lay]) ){
            continue;
           }
 
           if(0 == lay){
            if( ! fgHitLay[1] ) continue;
           } else if(42 == lay){
            if( ! fgHitLay[41] ) continue;
           } else{
            if( (!fgHitLay[lay-1]) && (!fgHitLay[lay+1]) ) continue;
           }
 
           iEntr = m_mdcFunSvc -> getXtEntrIndex(entrance);
           if(1 == m_nEntr[lay]){
            iEntr = 0;
           } else if(2 == m_nEntr[lay]){
            if(entrance > 0.0) iEntr = 1;
            else iEntr = 0;
           }
 
           bin = (int)(tdr / m_tbinw);
 
           // left-right separately
           key = getHxtKey(lay, iEntr, iLR, bin);
           if((bin < m_nbin) && (1 == m_hxtmap.count(key))){
            hid = m_hxtmap[key];
            m_hxt[hid] -> Fill( resi );
           }
 
           // left-right in common
           key = getHxtKey(lay, iEntr, 2, bin);
           if((bin < m_nbin) && (1 == m_hxtmap.count(key))){
            hid = m_hxtmap[key];
            m_hxt[hid] -> Fill( resi );
           }
 
           if(fabs(tdr - m_tm[lay][iEntr][iLR]) < 5){
            key = getHxtKey(lay, iEntr, iLR, m_nbin);
            if( 1 == m_hxtmap.count(key) ){
             hid = m_hxtmap[key];
             m_hxt[hid] -> Fill( resi );
            }
 
            key = getHxtKey(lay, iEntr, 2, m_nbin);
            if( 1 == m_hxtmap.count(key) ){
             hid = m_hxtmap[key];
             m_hxt[hid] -> Fill( resi );
            }
           }
 
      } // hit loop
     } // track loop
     return 1;
}

◆ getHxtKey()

int XtMdcCalib::getHxtKey	(	int	lay,
		int	entr,
		int	lr,
		int	bin
	)		const

Definition at line 506 of file XtMdcCalib.cxx.

                                                                  {
     int key;
 
     key = ( (lay << HXTLAYER_INDEX) & HXTLAYER_MASK ) |
      ( (entr << HXTENTRA_INDEX) & HXTENTRA_MASK ) |
      ( (lr << HXTLR_INDEX) & HXTLR_MASK ) |
      ( (bin << HXTBIN_INDEX) & HXTBIN_MASK );
 
     return key;
}

Referenced by fillHist(), initialize(), and updateConst().

◆ initialize()

void XtMdcCalib::initialize	(	TObjArray *	hlist,
		IMdcGeomSvc *	mdcGeomSvc,
		IMdcCalibFunSvc *	mdcFunSvc,
		IMdcUtilitySvc *	mdcUtilitySvc
	)

virtual

Implements MdcCalib.

Definition at line 67 of file XtMdcCalib.cxx.

                                                                           {
     IMessageSvc* msgSvc;
     Gaudi::svcLocator() -> service("MessageSvc", msgSvc);
     MsgStream log(msgSvc, "XtMdcCalib");
     log << MSG::INFO << "XtMdcCalib::initialize()" << endreq;
 
     m_hlist = hlist;
     m_mdcGeomSvc = mdcGeomSvc;
     m_mdcFunSvc = mdcFunSvc;
     m_mdcUtilitySvc = mdcUtilitySvc;
 
     MdcCalib::initialize(m_hlist, m_mdcGeomSvc, m_mdcFunSvc, m_mdcUtilitySvc);
 
     int lay;
     int iLR;
     int iEntr;
     int bin;
     int hid;
     int key;
     char hname[200];
     TH1D* hist;
 
     m_fdXt = new TFolder("fdXt", "fdXt");
     m_hlist -> Add(m_fdXt);
 
     m_nlayer = m_mdcGeomSvc -> getLayerSize();
 
     hid = 0;
     for(lay=0; lay<m_nlayer; lay++){
      for(iEntr=0; iEntr<m_nEntr[lay]; iEntr++){
           for(iLR=0; iLR<m_nLR; iLR++){
            for(bin=0; bin<=m_nbin; bin++){
             sprintf(hname, "Hxt%02d_E%02d_LR%01d_B%02d", lay, iEntr, iLR, bin);
             hist = new TH1D(hname, "", 300, -1.5, 1.5);
             m_hxt.push_back( hist );
             m_fdXt -> Add( hist );
 
             key = getHxtKey(lay, iEntr, iLR, bin);
             m_hxtmap.insert( valType2( key, hid ) );
             hid++;
            }
           }
      }
     }
}

◆ setParam()

void XtMdcCalib::setParam ( MdcCalParams & param )

inlinevirtual

Implements MdcCalib.

Definition at line 79 of file XtMdcCalib.h.

                                                   {
     MdcCalib::setParam(param);
     m_param = param;
}

◆ updateConst()

int XtMdcCalib::updateConst ( MdcCalibConst * calconst )

virtual

Implements MdcCalib.

Definition at line 271 of file XtMdcCalib.cxx.

                                                  {
     IMessageSvc* msgSvc;
     Gaudi::svcLocator() -> service("MessageSvc", msgSvc);
     MsgStream log(msgSvc, "XtMdcCalib");
     log << MSG::INFO << "XtMdcCalib::updateConst()" << endreq;
 
     MdcCalib::updateConst(calconst);
 
     int i;
     int hid;
     int lay;
     int iLR;
     int iEntr;
     int bin;
     int ord;
     int key;
 
     Stat_t entry;
     double xtpar;
     double xterr;
     double tbcen;
     double deltx;
     double xcor;
     double xerr;
     double xtini[8];
     double xtfit[8];
 
     Int_t ierflg;
     Int_t istat;
     Int_t nvpar;
     Int_t nparx;
     Double_t fmin;
     Double_t edm;
     Double_t errdef;
     Double_t arglist[10];
 
     TMinuit* gmxt = new TMinuit(6);
     gmxt -> SetPrintLevel(-1);
     gmxt -> SetFCN(fcnXT);
     gmxt -> SetErrorDef(1.0);
     gmxt -> mnparm(0, "xtpar0", 0, 0.1, 0, 0, ierflg);
     gmxt -> mnparm(1, "xtpar1", 0, 0.1, 0, 0, ierflg);
     gmxt -> mnparm(2, "xtpar2", 0, 0.1, 0, 0, ierflg);
     gmxt -> mnparm(3, "xtpar3", 0, 0.1, 0, 0, ierflg);
     gmxt -> mnparm(4, "xtpar4", 0, 0.1, 0, 0, ierflg);
     gmxt -> mnparm(5, "xtpar5", 0, 0.1, 0, 0, ierflg);
     arglist[0] = 0;
     gmxt -> mnexcm("SET NOW", arglist, 0, ierflg);
 
     TMinuit* gmxtEd = new TMinuit(1);
     gmxtEd -> SetPrintLevel(-1);
     gmxtEd -> SetFCN(fcnXtEdge);
     gmxtEd -> SetErrorDef(1.0);
     gmxtEd -> mnparm(0, "xtpar0", 0, 0.1, 0, 0, ierflg);
     arglist[0] = 0;
     gmxtEd -> mnexcm("SET NOW", arglist, 0, ierflg);
 
     ofstream fxtlog("xtlog");
     for(lay=0; lay<m_nlayer; lay++){
      if(0 == m_param.fgCalib[lay]) continue;
 
      for(iEntr=0; iEntr<m_nEntr[lay]; iEntr++){
           for(iLR=0; iLR<m_nLR; iLR++){
 
            fxtlog << "Layer " << setw(3) << lay << setw(3) << iEntr
               << setw(3) << iLR << endl;
 
            for(ord=0; ord<m_nxtpar; ord++){
//           xtpar = calconst -> getXtpar(lay, iEntr, iLR, ord);
             if(0 == iEntr) xtpar = calconst -> getXtpar(lay, 8, iLR, ord);
             else if(1 == iEntr) xtpar = calconst -> getXtpar(lay, 9, iLR, ord);
 
             xtini[ord] = xtpar;
             xtfit[ord] = xtpar;
            }
 
            Tmax = xtini[6];
 
            for(bin=0; bin<=m_nbin; bin++){
             key = getHxtKey(lay, iEntr, iLR, bin);
             hid = m_hxtmap[key];
 
             entry = m_hxt[hid] -> GetEntries();
             if(entry > 100){
                  deltx = m_hxt[hid] -> GetMean();
                  xerr = m_hxt[hid]->GetRMS();
             } else{
                  continue;
             }
 
             if(bin < m_nbin)
                  tbcen = ( (double)bin + 0.5 ) * m_tbinw;
             else tbcen = m_tm[lay][iEntr][iLR];
             xcor = xtFun(tbcen, xtini) - deltx;
 
             if((tbcen <= Tmax) || (bin == m_nbin)){
                  TBINCEN.push_back( tbcen );
                  XMEAS.push_back( xcor );
                  ERR.push_back( xerr );
             } else{
                  TBINCENED.push_back( tbcen );
                  XMEASED.push_back( xcor );
                  ERRED.push_back( xerr );                              
             } 
             fxtlog << setw(3) << bin
                << setw(15) << deltx
                << setw(15) << xcor
                << setw(15) << tbcen
                << setw(15) << xerr
                << endl;
            } // end of bin loop
 
            if( XMEAS.size() < 12 ){
             TBINCEN.clear();
             XMEAS.clear();
             ERR.clear();
 
             TBINCENED.clear();
             XMEASED.clear();
             ERRED.clear();
 
             continue;
            }               
 
            for(ord=0; ord<=5; ord++){
             arglist[0] = ord + 1;
             arglist[1] = xtini[ord];
             gmxt -> mnexcm("SET PARameter", arglist, 2, ierflg);
            }
 
            // fix the xtpar[0] at 0
            if(1 == m_param.fixXtC0){
             arglist[0] = 1;
             arglist[1] = 0.0;
             gmxt -> mnexcm("SET PARameter", arglist, 2, ierflg);
             gmxt -> mnexcm("FIX", arglist, 1, ierflg);
            }
 
            arglist[0] = 1000;
            arglist[1] = 0.1;
            gmxt -> mnexcm("MIGRAD", arglist, 2, ierflg);
            gmxt -> mnstat(fmin, edm, errdef, nvpar, nparx, istat);
 
            fxtlog << "Xtpar: " << endl;
            if( (0 == ierflg) && (istat >= 2) ){
             for(ord=0; ord<=5; ord++){
                  gmxt -> GetParameter(ord, xtpar, xterr);
//                calconst -> resetXtpar(lay, iEntr, iLR, ord, xtpar);
                  xtfit[ord] = xtpar;
 
                  if(1 == m_nEntr[lay]){
                   for(i=0; i<18; i++)
                    calconst -> resetXtpar(lay, i, iLR, ord, xtpar);
                  } else if(2 == m_nEntr[lay]){
                   if(0 == iEntr){
                    for(i=0; i<9; i++) // entr<0
                         calconst->resetXtpar(lay, i, iLR, ord, xtpar);
                   } else{
                    for(i=9; i<18; i++) // entr>0
                         calconst->resetXtpar(lay, i, iLR, ord, xtpar);
                   }
                  }
                  fxtlog << setw(15) << xtpar << setw(15) << xterr << endl;
             }
            } else{
             for(ord=0; ord<=5; ord++){
                  fxtlog << setw(15) << xtini[ord] << setw(15) << "0" << endl;
             } 
            }
            fxtlog << setw(15) << Tmax << setw(15) << "0" << endl;
 
            //   release the first parameter
            if(1 == m_param.fixXtC0){
             arglist[0] = 1;
             gmxt -> mnexcm("REL", arglist, 1, ierflg);
            }
 
            Dmax = xtFun(Tmax, xtfit);
 
            if( XMEASED.size() >= 3 ){
             // fit xt in the edge area
             arglist[0] = 1;
             arglist[1] = xtini[7];
             gmxtEd -> mnexcm("SET PARameter", arglist, 2, ierflg);
 
             arglist[0] = 1000;
             arglist[1] = 0.1;
             gmxtEd -> mnexcm("MIGRAD", arglist, 2, ierflg);
             gmxtEd -> mnstat(fmin, edm, errdef, nvpar, nparx, istat);
 
             if( (0 == ierflg) && (istat >=2) ){
                  gmxtEd -> GetParameter(0, xtpar, xterr);
                  if(xtpar < 0.0) xtpar = 0.0;
                  if(m_param.fixXtEdge) xtpar = xtini[7];
//                calconst -> resetXtpar(lay, iEntr, iLR, 7, xtpar);
 
                  if(1 == m_nEntr[lay]){
                   for(i=0; i<18; i++)
                    calconst -> resetXtpar(lay, i, iLR, 7, xtpar);
                  } else if(2 == m_nEntr[lay]){
                   if(0 == iEntr){
                    for(i=0; i<9; i++)
                         calconst->resetXtpar(lay, i, iLR, 7, xtpar);
                   } else{
                    for(i=9; i<18; i++)
                         calconst->resetXtpar(lay, i, iLR, 7, xtpar);
                   }
                  }
                  fxtlog << setw(15) << xtpar << setw(15) << xterr << endl;                  
             } else {
                  fxtlog << setw(15) << xtini[7] << setw(15) << "0" << endl;
             }
            } else {
             fxtlog << setw(15) << xtini[7] << setw(15) << "0" << endl;
            }    
            fxtlog << "Tm " << setw(15) << Tmax
               << "  Dmax " << setw(15) << Dmax << endl;
 
            TBINCEN.clear();
            XMEAS.clear();
            ERR.clear();
            TBINCENED.clear();
            XMEASED.clear();
            ERRED.clear();                    
           } // end of l-r loop
      } // end of entrance angle loop
     } // end of layer loop
 
     fxtlog.close();
     delete gmxt;
     delete gmxtEd;
     cout << "Xt update finished" << endl;
     return 1;
}

◆ xtFun()

double XtMdcCalib::xtFun	(	double	t,
		double	xtpar[]
	)

static

Definition at line 537 of file XtMdcCalib.cxx.

                                                {
     int ord;
     double dist = 0.0;
     double tmax = xtpar[6];
 
     if(t < tmax ){
      for(ord=0; ord<=5; ord++){
           dist += xtpar[ord] * pow(t, ord);
      }
     }else{
      for(ord=0; ord<=5; ord++){
           dist += xtpar[ord] * pow(tmax, ord);
      }
      dist += xtpar[7] * (t - tmax);
     }
 
     return dist;
}

Referenced by updateConst().

Member Data Documentation

◆ Dmax

double XtMdcCalib::Dmax

static

Definition at line 35 of file XtMdcCalib.h.

Referenced by fcnXtEdge(), and updateConst().

◆ ERR

vector< double > XtMdcCalib::ERR

static

Definition at line 32 of file XtMdcCalib.h.

Referenced by fcnXT(), and updateConst().

◆ ERRED

vector< double > XtMdcCalib::ERRED

static

Definition at line 38 of file XtMdcCalib.h.

Referenced by fcnXtEdge(), and updateConst().

◆ TBINCEN

vector< double > XtMdcCalib::TBINCEN

static

Definition at line 31 of file XtMdcCalib.h.

Referenced by fcnXT(), and updateConst().

◆ TBINCENED

vector< double > XtMdcCalib::TBINCENED

static

Definition at line 37 of file XtMdcCalib.h.

Referenced by fcnXtEdge(), and updateConst().

◆ Tmax

double XtMdcCalib::Tmax

static

Definition at line 34 of file XtMdcCalib.h.

Referenced by fcnXtEdge(), and updateConst().

◆ XMEAS

vector< double > XtMdcCalib::XMEAS

static

Definition at line 30 of file XtMdcCalib.h.

Referenced by fcnXT(), and updateConst().

◆ XMEASED

vector< double > XtMdcCalib::XMEASED

static

Definition at line 36 of file XtMdcCalib.h.

Referenced by fcnXtEdge(), and updateConst().

The documentation for this class was generated from the following files:

Public Member Functions

Static Public Member Functions

Static Public Attributes

Detailed Description

Constructor & Destructor Documentation

◆ XtMdcCalib()

◆ ~XtMdcCalib()

Member Function Documentation

◆ clear()

◆ fcnXT()

◆ fcnXtEdge()

◆ fillHist()

◆ getHxtKey()

◆ initialize()

◆ setParam()

◆ updateConst()

◆ xtFun()

Member Data Documentation

◆ Dmax

◆ ERR

◆ ERRED

◆ TBINCEN

◆ TBINCENED

◆ Tmax

◆ XMEAS

◆ XMEASED