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if(fNDCTracks == 2) {
THcDCTrack *theDCTrack1 = static_cast<THcDCTrack*>( fDCTracks->At(0));
THcDCTrack *theDCTrack2 = static_cast<THcDCTrack*>( fDCTracks->At(1));
// Int_t itrack=0;
THcDCHit* hit=theDCTrack1->GetHit(ihit);
Int_t plane=hit->GetPlaneNum()-1;
Int_t chamber=fNChamber[plane];
if(chamber==1) {
hit=theDCTrack2->GetHit(ihit);
plane=hit->GetPlaneNum()-1;
chamber=fNChamber[plane];
if(chamber==2) {
Double_t ray1[4];
Double_t ray2[4];
theDCTrack1->GetRay(ray1);
theDCTrack2->GetRay(ray2);
for(Int_t ihit=0;ihit < theDCTrack2->GetNHits();ihit++) {
// Calculate residual in second chamber from first chamber track
THcDCHit* hit=theDCTrack2->GetHit(ihit);
Int_t plane=hit->GetPlaneNum()-1;
Double_t pos = DpsiFun(ray1,plane);
Double_t coord;
if(fFixLR) {
if(fFixPropagationCorrection) {
coord = hit->GetPos()
+ theDCTrack2->GetHitLR(ihit)*theDCTrack2->GetHitDist(ihit);
} else {
coord = hit->GetPos()
+ theDCTrack2->GetHitLR(ihit)*hit->GetDist();
}
} else {
if(fFixPropagationCorrection) {
coord = hit->GetPos()
+ hit->GetLR()*theDCTrack2->GetHitDist(ihit);
} else {
coord = hit->GetCoord();
}
}
theDCTrack1->SetDoubleResidual(plane,coord - pos);
// hdc_dbl_res(pln) = hdc_double_residual(1,pln) for hists
}
for(Int_t ihit=0;ihit < theDCTrack1->GetNHits();ihit++) {
// Calculate residual in first chamber from second chamber track
THcDCHit* hit=theDCTrack1->GetHit(ihit);
Int_t plane=hit->GetPlaneNum()-1;
Double_t pos = DpsiFun(ray1,plane);
Double_t coord;
if(fFixLR) {
if(fFixPropagationCorrection) {
coord = hit->GetPos()
+ theDCTrack1->GetHitLR(ihit)*theDCTrack1->GetHitDist(ihit);
} else {
coord = hit->GetPos()
+ theDCTrack1->GetHitLR(ihit)*hit->GetDist();
}
} else {
if(fFixPropagationCorrection) {
coord = hit->GetPos()
+ hit->GetLR()*theDCTrack1->GetHitDist(ihit);
} else {
coord = hit->GetCoord();
}
}
theDCTrack2->SetDoubleResidual(plane,coord - pos);
// hdc_dbl_res(pln) = hdc_double_residual(1,pln) for hists
}
}
}
}
}
//
if (fdebugtrackprint) {
printf("%5s %-14s %-14s %-14s %-14s %-10s %-10s \n","Track","x_t","y_t","xp_t","yp_t","chi2","DOF");
printf("%5s %-14s %-14s %-14s %-14s %-10s %-10s \n"," ","[cm]","[cm]","[rad]","[rad]"," "," ");
for(UInt_t itr=0;itr < fNDCTracks;itr++) {
THcDCTrack *theDCTrack = static_cast<THcDCTrack*>( fDCTracks->At(itr));
printf("%-5d %14.6e %14.6e %14.6e %14.6e %10.3e %3d \n", itr+1,theDCTrack->GetX(),theDCTrack->GetY(),theDCTrack->GetXP(),theDCTrack->GetYP(),theDCTrack->GetChisq(),theDCTrack->GetNFree());
}
for(UInt_t itr=0;itr < fNDCTracks;itr++) {
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printf("%s %5d \n","Hit info for track number = ",itr+1);
printf("%5s %-15s %-15s %-15s \n","Plane","WIRE_COORD","Fit postiion","Residual");
THcDCTrack *theDCTrack = static_cast<THcDCTrack*>( fDCTracks->At(itr));
for(Int_t ihit=0;ihit < theDCTrack->GetNHits();ihit++) {
THcDCHit* hit=theDCTrack->GetHit(ihit);
Int_t plane=hit->GetPlaneNum()-1;
Double_t coords_temp;
if(fFixLR) {
if(fFixPropagationCorrection) {
coords_temp = hit->GetPos()
+ theDCTrack->GetHitLR(ihit)*theDCTrack->GetHitDist(ihit);
} else {
coords_temp = hit->GetPos()
+ theDCTrack->GetHitLR(ihit)*hit->GetDist();
}
} else {
if(fFixPropagationCorrection) {
coords_temp = hit->GetPos()
+ hit->GetLR()*theDCTrack->GetHitDist(ihit);
} else {
coords_temp = hit->GetCoord();
}
}
printf("%-5d %15.7e %15.7e %15.7e \n",plane+1,coords_temp,theDCTrack->GetCoord(plane),theDCTrack->GetResidual(plane));
}
}
}
//
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Double_t THcDC::DpsiFun(Double_t ray[4], Int_t plane)
{
/*
this function calculates the psi coordinate of the intersection
of a ray (defined by ray) with a hms wire chamber plane. the geometry
of the plane is contained in the coeff array calculated in the
array hplane_coeff
Note it is call by MINUIT via H_FCNCHISQ and so uses double precision
variables
the ray is defined by
x = (z-zt)*tan(xp) + xt
y = (z-zt)*tan(yp) + yt
at some fixed value of zt*
ray(1) = xt
ray(2) = yt
ray(3) = tan(xp)
ray(4) = tan(yp)
*/
Double_t infinity = 1.0E+20;
Double_t cinfinity = 1/infinity;
Double_t DpsiFun =
ray[2]*ray[1]*fPlaneCoeffs[plane][0] +
ray[3]*ray[0]*fPlaneCoeffs[plane][1] +
ray[2]*fPlaneCoeffs[plane][2] +
ray[3]*fPlaneCoeffs[plane][3] +
ray[0]*fPlaneCoeffs[plane][4] +
ray[1]*fPlaneCoeffs[plane][5];
Double_t denom = ray[2]*fPlaneCoeffs[plane][6]
+ ray[3]*fPlaneCoeffs[plane][7]
+ fPlaneCoeffs[plane][8];
if(TMath::Abs(denom) < cinfinity) {
DpsiFun = infinity;
DpsiFun = DpsiFun/denom;
}
return(DpsiFun);
//_____________________________________________________________________________
Int_t THcDC::End(THaRunBase* run)
{
// EffCalc();
}
//_____________________________________________________________________________
void THcDC::EffInit()
{
// Create, and initialize counters used to calculate
// efficiencies. Register the counters in gHcParms so that the
// variables can be used in end of run reports.
delete [] fNChamHits; fNChamHits = new Int_t [fNChambers];
delete [] fPlaneEvents; fPlaneEvents = new Int_t [fNPlanes];
fTotEvents = 0;
for(UInt_t i=0;i<fNChambers;i++) {
fNChamHits[i] = 0;
}
for(Int_t i=0;i<fNPlanes;i++) {
}
gHcParms->Define(Form("%sdc_tot_events",fPrefix),"Total DC Events",fTotEvents);
gHcParms->Define(Form("%sdc_cham_hits[%d]",fPrefix,fNChambers),"N events with hits per chamber",*fNChamHits);
gHcParms->Define(Form("%sdc_events[%d]",fPrefix,fNPlanes),"N events with hits per plane",*fPlaneEvents);
}
//_____________________________________________________________________________
void THcDC::Eff()
{
// Accumulate statistics for efficiency calculations
fTotEvents++;
for(UInt_t i=0;i<fNChambers;i++) {
if(fChambers[i]->GetNHits()>0) fNChamHits[i]++;
}
for(Int_t i=0;i<fNPlanes;i++) {
if(fPlanes[i]->GetNHits() > 0) fPlaneEvents[i]++;
}
return;
}
ClassImp(THcDC)
////////////////////////////////////////////////////////////////////////////////