// Drift velocity - Currently common drift velocity - functionality of AliTPCParam
// ExB effect -
//
+// Time of flight correction -
+// - Depends on the vertex position
+// - by default
+//
// Usage:
// AliTPCclustererMI::AddCluster
// AliTPCtrackerMI::Transform
#include "AliLog.h"
#include "AliTPCExB.h"
#include "TGeoMatrix.h"
+#include "AliTPCRecoParam.h"
+#include "AliTPCCalibVdrift.h"
#include "AliTPCTransform.h"
+#include <AliCTPTimeParams.h>
ClassImp(AliTPCTransform)
-AliTPCTransform::AliTPCTransform() {
+AliTPCTransform::AliTPCTransform():
+ AliTransform(),
+ fCurrentRecoParam(0), //! current reconstruction parameters
+ fCurrentRun(0), //! current run
+ fCurrentTimeStamp(0) //! current time stamp
+{
//
// Speed it up a bit!
//
fSins[i]=TMath::Sin(alpha);
fCoss[i]=TMath::Cos(alpha);
}
+ fPrimVtx[0]=0;
+ fPrimVtx[1]=0;
+ fPrimVtx[2]=0;
+}
+AliTPCTransform::AliTPCTransform(const AliTPCTransform& transform):
+ AliTransform(transform),
+ fCurrentRecoParam(transform.fCurrentRecoParam), //! current reconstruction parameters
+ fCurrentRun(transform.fCurrentRun), //! current run
+ fCurrentTimeStamp(transform.fCurrentTimeStamp) //! current time stamp
+{
+ //
+ // Speed it up a bit!
+ //
+ for (Int_t i=0;i<18;++i) {
+ Double_t alpha=TMath::DegToRad()*(10.+20.*(i%18));
+ fSins[i]=TMath::Sin(alpha);
+ fCoss[i]=TMath::Cos(alpha);
+ }
+ fPrimVtx[0]=0;
+ fPrimVtx[1]=0;
+ fPrimVtx[2]=0;
}
AliTPCTransform::~AliTPCTransform() {
//
}
+void AliTPCTransform::SetPrimVertex(Double_t *vtx){
+ //
+ //
+ //
+ fPrimVtx[0]=vtx[0];
+ fPrimVtx[1]=vtx[1];
+ fPrimVtx[2]=vtx[2];
+}
+
+
void AliTPCTransform::Transform(Double_t *x,Int_t *i,UInt_t /*time*/,
- Int_t /*coordinateType*/, Float_t *primvtx) {
+ Int_t /*coordinateType*/) {
// input: x[0] - pad row
// x[1] - pad
// x[2] - time in us
// line approximation
//
-
Int_t row=TMath::Nint(x[0]);
Int_t pad=TMath::Nint(x[1]);
Int_t sector=i[0];
- AliTPCcalibDB* calib=AliTPCcalibDB::Instance();
+ AliTPCcalibDB* calib=AliTPCcalibDB::Instance();
//
AliTPCCalPad * time0TPC = calib->GetPadTime0();
AliTPCParam * param = calib->GetParameters();
//
// ExB correction
//
- calib->GetExB()->Correct(x,xx);
+ if(fCurrentRecoParam&&fCurrentRecoParam->GetUseExBCorrection()) {
+
+ calib->GetExB()->Correct(x,xx);
+
+ } else {
+
+ xx[0] = x[0];
+ xx[1] = x[1];
+ xx[2] = x[2];
+ }
+
//
// Time of flight correction
- //
- Float_t deltaDr =0
- if (primvtx){
+ //
+ if (fCurrentRecoParam&&fCurrentRecoParam->GetUseTOFCorrection()){
+ const Int_t kNIS=param->GetNInnerSector(), kNOS=param->GetNOuterSector();
+ Float_t sign=1;
+ if (sector < kNIS) {
+ sign = (sector < kNIS/2) ? 1 : -1;
+ } else {
+ sign = ((sector-kNIS) < kNOS/2) ? 1 : -1;
+ }
+ Float_t deltaDr =0;
Float_t dist=0;
- dist+=(primvtx[0]-x[0])*(primvtx[0]-x[0]);
- dist+=(primvtx[1]-x[1])*(primvtx[1]-x[1]);
- dist+=(primvtx[0]-x[2])*(primvtx[0]-x[2]);
+ dist+=(fPrimVtx[0]-x[0])*(fPrimVtx[0]-x[0]);
+ dist+=(fPrimVtx[1]-x[1])*(fPrimVtx[1]-x[1]);
+ dist+=(fPrimVtx[2]-x[2])*(fPrimVtx[2]-x[2]);
dist = TMath::Sqrt(dist);
// drift length correction because of TOF
// the drift velocity is in cm/s therefore multiplication by 0.01
- deltaDr = (dist*(0.01*param->GetDriftV()))/TMath::C();
+ deltaDr = (dist*(0.01*param->GetDriftV()))/TMath::C();
+ xx[2]+=sign*deltaDr;
}
- xx[2]-=deltaDr;
//
- Global2RotatedGlobal(sector,xx);
+ //
+ //
+ //
+ Global2RotatedGlobal(sector,xx);
+ //
x[0]=xx[0];x[1]=xx[1];x[2]=xx[2];
}
//
//
//
+ const Int_t kMax =60; // cache for 60 seconds
+ static Int_t lastStamp=-1; //cached values
+ static Double_t lastCorr = 1;
+ //
AliTPCcalibDB* calib=AliTPCcalibDB::Instance();
AliTPCParam * param = calib->GetParameters();
+ AliTPCCalibVdrift *driftCalib = AliTPCcalibDB::Instance()->GetVdrift(fCurrentRun);
+ Double_t driftCorr = 1.;
+ if (driftCalib){
+ //
+ // caching drift correction - temp. fix
+ // Extremally slow procedure
+ if ( TMath::Abs((lastStamp)-Int_t(fCurrentTimeStamp))<kMax){
+ driftCorr = lastCorr;
+ }else{
+ driftCorr = 1.+(driftCalib->GetPTRelative(fCurrentTimeStamp,0)+ driftCalib->GetPTRelative(fCurrentTimeStamp,1))*0.5;
+ lastCorr=driftCorr;
+ lastStamp=fCurrentTimeStamp;
+
+ }
+ }
+ //
+ // simple caching non thread save
+ static Double_t vdcorrectionTime=1;
+ static Double_t time0corrTime=0;
+ static Int_t lastStampT=-1;
+ //
+ if (lastStampT!=(Int_t)fCurrentTimeStamp){
+ lastStampT=fCurrentTimeStamp;
+ if(fCurrentRecoParam&&fCurrentRecoParam->GetUseDriftCorrectionTime()>0) {
+ vdcorrectionTime = (1+AliTPCcalibDB::Instance()->
+ GetVDriftCorrectionTime(fCurrentTimeStamp,
+ fCurrentRun,
+ sector%36>=18,
+ fCurrentRecoParam->GetUseDriftCorrectionTime()));
+ time0corrTime= AliTPCcalibDB::Instance()->
+ GetTime0CorrectionTime(fCurrentTimeStamp,
+ fCurrentRun,
+ sector%36>=18,
+ fCurrentRecoParam->GetUseDriftCorrectionTime());
+ }
+ //
+ if(fCurrentRecoParam&&fCurrentRecoParam->GetUseDriftCorrectionGY()>0) {
+ Float_t xyzPad[3];
+ AliTPCROC::Instance()->GetPositionGlobal(sector, TMath::Nint(x[0]) ,TMath::Nint(x[1]), xyzPad);
+
+ Double_t corrGy= (1+(xyzPad[1])*AliTPCcalibDB::Instance()->
+ GetVDriftCorrectionGy(fCurrentTimeStamp,
+ AliTPCcalibDB::Instance()->GetRun(),
+ sector%36>=18,
+ fCurrentRecoParam->GetUseDriftCorrectionGY()));
+ vdcorrectionTime *=corrGy;
+ }
+ }
+
+
if (!param){
AliFatal("Parameters missing");
}
Int_t row=TMath::Nint(x[0]);
- Int_t pad=TMath::Nint(x[1]);
+ // Int_t pad=TMath::Nint(x[1]);
//
const Int_t kNIS=param->GetNInnerSector(), kNOS=param->GetNOuterSector();
Double_t sign = 1.;
- Double_t zwidth = param->GetZWidth();
+ Double_t zwidth = param->GetZWidth()*driftCorr*vdcorrectionTime;
Double_t padWidth = 0;
Double_t padLength = 0;
Double_t maxPad = 0;
// Y coordinate
//
x[1]=(x[1]-0.5*maxPad)*padWidth;
+ // pads are mirrorred on C-side
+ if (sector%36>17){
+ x[1]*=-1;
+ }
+
+ //
+
//
// Z coordinate
//
+ if (AliTPCcalibDB::Instance()->IsTrgL0()){
+ // by defualt we assume L1 trigger is used - make a correction in case of L0
+ AliCTPTimeParams* ctp = AliTPCcalibDB::Instance()->GetCTPTimeParams();
+ Double_t delay = ctp->GetDelayL1L0()*0.000000025;
+ x[2]-=delay/param->GetTSample();
+ }
+ x[2]-= param->GetNTBinsL1();
x[2]*= zwidth; // tranform time bin to the distance to the ROC
- x[2]-= 3.*param->GetZSigma() + param->GetNTBinsL1()*zwidth;
+ x[2]-= 3.*param->GetZSigma() + time0corrTime;
// subtract the time offsets
x[2] = sign*( param->GetZLength(sector) - x[2]);
}
-inline void AliTPCTransform::RotatedGlobal2Global(Int_t sector,Double_t *x) const {
+void AliTPCTransform::RotatedGlobal2Global(Int_t sector,Double_t *x) const {
//
// transform possition rotated global to the global
//
Double_t cos,sin;
GetCosAndSin(sector,cos,sin);
Double_t tmp=x[0];
- x[0]= cos*tmp+sin*x[1];
- x[1]=-sin*tmp+cos*x[1];
+ x[0]= cos*tmp-sin*x[1];
+ x[1]=+sin*tmp+cos*x[1];
}
-inline void AliTPCTransform::Global2RotatedGlobal(Int_t sector,Double_t *x) const {
+void AliTPCTransform::Global2RotatedGlobal(Int_t sector,Double_t *x) const {
//
// tranform possition Global2RotatedGlobal
//
Double_t cos,sin;
GetCosAndSin(sector,cos,sin);
Double_t tmp=x[0];
- x[0]= cos*tmp-sin*x[1];
- x[1]= sin*tmp+cos*x[1];
+ x[0]= cos*tmp+sin*x[1];
+ x[1]= -sin*tmp+cos*x[1];
}
-inline void AliTPCTransform::GetCosAndSin(Int_t sector,Double_t &cos,
+void AliTPCTransform::GetCosAndSin(Int_t sector,Double_t &cos,
Double_t &sin) const {
cos=fCoss[sector%18];
sin=fSins[sector%18];
}
+void AliTPCTransform::ApplyTransformations(Double_t */*xyz*/, Int_t /*volID*/){
+ //
+ // Modify global position
+ // xyz - global xyz position
+ // volID - volID of detector (sector number)
+ //
+ //
+
+}
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff