#include <NtupleManager.h>
Definition at line 20 of file NtupleManager.h.
NtupleManager::NtupleManager | ( | ) | [inline] |
NtupleManager::~NtupleManager | ( | ) | [inline] |
Definition at line 26 of file NtupleManager.h.
{ };
NtupleManager::NtupleManager | ( | ) | [inline] |
Definition at line 25 of file NtupleManager.h.
{ };
NtupleManager::~NtupleManager | ( | ) | [inline] |
Definition at line 26 of file NtupleManager.h.
{ };
void NtupleManager::BookNtuple | ( | ) |
Definition at line 41 of file NtupleManager.cc.
References Chi2CalibratedParameters, Chi2Measurements, CloneCopsMeas, CloneDistancemeter1DimMeas, CloneDistancemeterMeas, CloneFitParam, CloneOptObject, CloneSensor2DMeas, CloneTiltmeterMeas, CocoaTree, NCops, NDegreesOfFreedom, NDistancemeter, NDistancemeter1Dim, NFitParameters, NOptObjects, NSensor2D, NTiltmeter, and theRootFile.
Referenced by Fit::startFit().
{ theRootFile = new TFile("report.root","RECREATE","Simple ROOT Ntuple"); CocoaTree = new TTree("CocoaTree","CocoaTree"); CocoaTree->Branch("Chi2Measurements",&Chi2Measurements,"Chi2Measurements/D"); CocoaTree->Branch("Chi2CalibratedParameters",&Chi2CalibratedParameters,"Chi2CalibratedParameters/D"); CocoaTree->Branch("NDegreesOfFreedom",&NDegreesOfFreedom,"NDegreesOfFreedom/I"); CloneFitParam = new TClonesArray("FitParam"); CocoaTree->Branch("FitParameters",&CloneFitParam,32000,2); CocoaTree->Branch("NFitParameters",&NFitParameters,"NFitParameters/I"); CloneOptObject = new TClonesArray("OptObject"); CocoaTree->Branch("OptObjects",&CloneOptObject,32000,2); CocoaTree->Branch("NOptObjects",&NOptObjects,"NOptObjects/I"); CloneSensor2DMeas = new TClonesArray("Sensor2DMeas"); CocoaTree->Branch("Sensor2DMeasurements",&CloneSensor2DMeas,32000,2); CocoaTree->Branch("NSensor2D",&NSensor2D,"NSensor2D/I"); CloneDistancemeterMeas = new TClonesArray("DistancemeterMeas"); CocoaTree->Branch("DistancemeterMeasurements",&CloneDistancemeterMeas,32000,2); CocoaTree->Branch("NDistancemeter",&NDistancemeter,"NDistancemeter/I"); CloneDistancemeter1DimMeas = new TClonesArray("Distancemeter1DimMeas"); CocoaTree->Branch("Distancemeter1DimMeasurements",&CloneDistancemeter1DimMeas,32000,2); CocoaTree->Branch("NDistancemeter1Dim",&NDistancemeter1Dim,"NDistancemeter1Dim/I"); CloneTiltmeterMeas = new TClonesArray("TiltmeterMeas"); CocoaTree->Branch("TiltmeterMeasurements",&CloneTiltmeterMeas,32000,2); CocoaTree->Branch("NTiltmeter",&NTiltmeter,"NTiltmeter/I"); CloneCopsMeas = new TClonesArray("CopsMeas"); CocoaTree->Branch("CopsMeasurements",&CloneCopsMeas,32000,2); CocoaTree->Branch("NCops",&NCops,"NCops/I"); theRootFile->Add(CocoaTree); // FitParametersTree = new TTree("FitParametersTree","FitParametersTree"); // FitParametersTree->Branch("NFitParameters",&NFitParameters,"NFitParameters/I"); // BookFitParameters = false; // theRootFile->Add(FitParametersTree); // MeasurementsTree = new TTree("MeasurementsTree","MeasurementsTree"); // MeasurementsTree->Branch("NMeasurements",&NMeasurements,"NMeasurements/I"); // BookMeasurements = false; // theRootFile->Add(MeasurementsTree); }
void NtupleManager::BookNtuple | ( | ) |
void NtupleManager::FillChi2 | ( | ) |
void NtupleManager::FillChi2 | ( | ) |
Definition at line 129 of file NtupleManager.cc.
References begin, Chi2CalibratedParameters, Chi2Measurements, Model::EntryList(), Model::MeasurementList(), and NDegreesOfFreedom.
Referenced by Fit::fitNextEvent().
{ double chi2meas = 0; double chi2cal = 0; ALIint nMeas = 0, nUnk = 0; //----- Calculate the chi2 of measurements std::vector< Measurement* >::const_iterator vmcite; for ( vmcite = Model::MeasurementList().begin(); vmcite != Model::MeasurementList().end(); vmcite++) { for ( ALIuint ii = 0; ii < ALIuint((*vmcite)->dim()); ii++ ){ nMeas++; double c2 = ( (*vmcite)->value(ii) - (*vmcite)->valueSimulated(ii) ) / (*vmcite)->sigma(ii); chi2meas += c2*c2; } } //----- Calculate the chi2 of calibrated parameters std::vector< Entry* >::iterator veite; for ( veite = Model::EntryList().begin(); veite != Model::EntryList().end(); veite++ ) { if ( (*veite)->quality() == 2 ) nUnk++; if ( (*veite)->quality() == 1 ) { // std::cout << " " << (*veite)->valueDisplacementByFitting() << " " // << (*veite)->value << " " << (*veite)->sigma() << std::endl; double c2 = (*veite)->valueDisplacementByFitting() / (*veite)->sigma(); chi2cal += c2*c2; } } Chi2Measurements = chi2meas; Chi2CalibratedParameters = chi2cal; NDegreesOfFreedom = nMeas - nUnk; }
void NtupleManager::FillFitParameters | ( | MatrixMeschach * | AtWAMatrix | ) |
void NtupleManager::FillFitParameters | ( | MatrixMeschach * | AtWAMatrix | ) |
Definition at line 166 of file NtupleManager.cc.
References begin, CloneOptObject, gather_cfg::cout, Model::EntryList(), FitParamA, FitParam::FittedSigma, FitParam::FittedValue, FittedEntry::getEntryName(), FittedEntry::getName(), FittedEntry::getOptOName(), FittedEntry::getOrder(), FittedEntry::getOrigSigma(), FittedEntry::getOrigValue(), FittedEntry::getQuality(), FittedEntry::getSigma(), FittedEntry::getValue(), if(), FitParam::InitialSigma, FitParam::InitialValue, MatrixMeschach::Mat(), OptObject::Name, FitParam::Name, NFitParameters, NOptObjects, FitParam::OptObjectIndex, FitParam::Quality, and mathSSE::sqrt().
Referenced by Fit::fitNextEvent().
{ // double ParValue[1000], ParError[1000]; int theMinEntryQuality = 1; int ii = 0; std::vector<Entry*>::const_iterator vecite; for ( vecite = Model::EntryList().begin(); vecite != Model::EntryList().end(); vecite++ ) { //--- Only for good quality parameters (='unk') if ( (*vecite)->quality() >= theMinEntryQuality ) { ALIint ipos = (*vecite)->fitPos(); FittedEntry* fe = new FittedEntry( (*vecite), ipos, sqrt(AtWAMatrix->Mat()->me[ipos][ipos])); // if (!BookFitParameters) { // CocoaTree->Branch("NFitParameters",&NFitParameters,"NFitParameters/I:"); // ALIstring partype = fe->getName() + "/D"; // FitParametersTree->Branch(fe->getName().c_str(), &ParValue[ii], partype.c_str()); // ALIstring parerrname = fe->getName() + "_err"; // ALIstring parerrtype = parerrname + "/D"; // FitParametersTree->Branch(parerrname.c_str(), &ParError[ii], parerrtype.c_str()); // } // ParValue[ii] = fe->getValue(); // ParError[ii] = fe->getSigma(); std::cout << "EEE " << (*vecite)->ValueDimensionFactor() << " " << (*vecite)->SigmaDimensionFactor() << " " << fe->getOptOName() << " " << fe->getEntryName() << " " << fe->getName() << " " << fe->getOrder() << " " << fe->getQuality() << " " << (*vecite)->type() << " " << std::endl; FitParamA = new( (*CloneFitParam)[ii] ) FitParam(); FitParamA->Name = fe->getName(); if (fe->getQuality()==1) FitParamA->Quality = "Calibrated"; else if (fe->getQuality()==2) FitParamA->Quality = "Unknown"; for (int no = 0; no<NOptObjects; no++) { OptObject* optobj = (OptObject*) CloneOptObject->At(no); if (optobj->Name==fe->getOptOName()) FitParamA->OptObjectIndex = no; } float DF = 1.; if ((*vecite)->type()=="centre" || (*vecite)->type()=="length") DF = 1000.; FitParamA->InitialValue = DF*fe->getOrigValue()*(*vecite)->ValueDimensionFactor(); FitParamA->InitialSigma = DF*fe->getOrigSigma()*(*vecite)->SigmaDimensionFactor(); FitParamA->FittedValue = DF*fe->getValue()*(*vecite)->ValueDimensionFactor(); FitParamA->FittedSigma = DF*fe->getSigma()*(*vecite)->SigmaDimensionFactor(); ii++; } } // BookFitParameters = true; NFitParameters = ii; // FitParametersTree->Fill(); /* //---------- Loop sets of entries std::vector< FittedEntriesSet* > theFittedEntriesSets; std::vector< FittedEntriesSet* >::const_iterator vfescite; std::vector< FittedEntry* >::const_iterator vfecite; ALIint jj = 1; for( vfescite = theFittedEntriesSets.begin(); vfescite != theFittedEntriesSets.end(); vfescite++) { //---------- Loop entries if( vfescite == theFittedEntriesSets.begin() ) { //----- dump entries names if first set ALIint ii = 0; for( vfecite = ((*vfescite)->FittedEntries()).begin(); vfecite != ((*vfescite)->FittedEntries()).end(); vfecite++) { ALIstring partype = (*vfecite)->getName() + "/D"; FitParametersTree->Branch((*vfecite)->getName().c_str(), &ParValue[ii], partype.c_str()); ALIstring parerrname = (*vfecite)->getName() + "_err"; ALIstring parerrtype = parerrname + "/D"; FitParametersTree->Branch(parerrname.c_str(), &ParError[ii], parerrtype.c_str()); ii++; } } ALIint ii = 0; for( vfecite = ((*vfescite)->FittedEntries()).begin(); vfecite != ((*vfescite)->FittedEntries()).end(); vfecite++) { ParValue[ii] = (*vfecite)->getValue(); ParError[ii] = (*vfecite)->getSigma(); ii++; } NFitParameters = ii; FitParametersTree->Fill(); jj++; } */ }
void NtupleManager::FillMeasurements | ( | ) |
Definition at line 307 of file NtupleManager.cc.
References TiltmeterMeas::AngError, TiltmeterMeas::Angle, begin, CloneOptObject, CopsMeasA, debug_cff::d1, createTree::dd, DistancemeterMeas::DisError, Distancemeter1DimMeas::DisError, DistancemeterMeas::Distance, Distancemeter1DimMeas::Distance, Distancemeter1DimMeasA, DistancemeterMeasA, i, prof2calltree::last, Model::MeasurementList(), OptObject::Name, Sensor2DMeas::Name, Distancemeter1DimMeas::Name, TiltmeterMeas::Name, CopsMeas::Name, DistancemeterMeas::Name, NCops, NDistancemeter, NDistancemeter1Dim, NOptObjects, NSensor2D, NTiltmeter, Distancemeter1DimMeas::OptObjectIndex, TiltmeterMeas::OptObjectIndex, CopsMeas::OptObjectIndex, Sensor2DMeas::OptObjectIndex, DistancemeterMeas::OptObjectIndex, CopsMeas::PosError, Sensor2DMeas::PosError, Sensor2DMeas::Position, CopsMeas::Position, Sensor2DMeasA, TiltmeterMeas::SimulatedAngle, Distancemeter1DimMeas::SimulatedDistance, DistancemeterMeas::SimulatedDistance, CopsMeas::SimulatedPosition, Sensor2DMeas::SimulatedPosition, and TiltmeterMeasA.
Referenced by Fit::fitNextEvent().
{ //---------- Loop Measurements int ss = 0, dd = 0, d1 = 0, tt = 0, cc = 0; std::vector< Measurement* >::const_iterator vmcite; for ( vmcite = Model::MeasurementList().begin(); vmcite != Model::MeasurementList().end(); vmcite++) { std::vector<ALIstring> optonamelist = (*vmcite)->OptONameList(); int last = optonamelist.size() - 1; ALIstring LastOptOName = optonamelist[last]; int optoind = -999; for (int no = 0; no<NOptObjects; no++) { OptObject* optobj = (OptObject*) CloneOptObject->At(no); if (optobj->Name==LastOptOName) optoind = no; } //std::cout << "DimSens " << (*vmcite)->type() << " " << (*vmcite)->sigma(0) << " " << LastOptOName << " " << optoind << std::endl; if ((*vmcite)->type()=="SENSOR2D") { Sensor2DMeasA = new( (*CloneSensor2DMeas)[ss] ) Sensor2DMeas(); Sensor2DMeasA->Name = (*vmcite)->name(); Sensor2DMeasA->OptObjectIndex = optoind; for (ALIuint i = 0; i<(*vmcite)->dim(); i++) { Sensor2DMeasA->Position[i] = 1000.*(*vmcite)->value()[i]; Sensor2DMeasA->PosError[i] = 1000.*(*vmcite)->sigma()[i]; Sensor2DMeasA->SimulatedPosition[i] = 1000.*(*vmcite)->valueSimulated(i); } ss++; } if ((*vmcite)->type()=="DISTANCEMETER") { DistancemeterMeasA = new( (*CloneDistancemeterMeas)[dd] ) DistancemeterMeas(); DistancemeterMeasA->Name = (*vmcite)->name(); DistancemeterMeasA->OptObjectIndex = optoind; DistancemeterMeasA->Distance = 1000.*(*vmcite)->value()[0]; DistancemeterMeasA->DisError = 1000.*(*vmcite)->sigma()[0]; DistancemeterMeasA->SimulatedDistance = 1000.*(*vmcite)->valueSimulated(0); dd++; } if ((*vmcite)->type()=="DISTANCEMETER1DIM") { Distancemeter1DimMeasA = new( (*CloneDistancemeter1DimMeas)[d1] ) Distancemeter1DimMeas(); Distancemeter1DimMeasA->Name = (*vmcite)->name(); Distancemeter1DimMeasA->OptObjectIndex = optoind; Distancemeter1DimMeasA->Distance = 1000.*(*vmcite)->value()[0]; Distancemeter1DimMeasA->DisError = 1000.*(*vmcite)->sigma()[0]; Distancemeter1DimMeasA->SimulatedDistance = 1000.*(*vmcite)->valueSimulated(0); d1++; } if ((*vmcite)->type()=="TILTMETER") { TiltmeterMeasA = new( (*CloneTiltmeterMeas)[tt] ) TiltmeterMeas(); TiltmeterMeasA->Name = (*vmcite)->name(); TiltmeterMeasA->OptObjectIndex = optoind; TiltmeterMeasA->Angle = (*vmcite)->value()[0]; TiltmeterMeasA->AngError = (*vmcite)->sigma()[0]; TiltmeterMeasA->SimulatedAngle = (*vmcite)->valueSimulated(0); tt++; } if ((*vmcite)->type()=="COPS") { CopsMeasA = new( (*CloneCopsMeas)[cc] ) CopsMeas(); CopsMeasA->Name = (*vmcite)->name(); CopsMeasA->OptObjectIndex = optoind; for (ALIuint i = 0; i<(*vmcite)->dim(); i++) { CopsMeasA->Position[i] = 1000.*(*vmcite)->value()[i]; CopsMeasA->PosError[i] = 1000.*(*vmcite)->sigma()[i]; CopsMeasA->SimulatedPosition[i] = 1000.*(*vmcite)->valueSimulated(i); } cc++; } } NSensor2D = ss; NDistancemeter = dd; NDistancemeter1Dim = d1; NTiltmeter = tt; NCops = cc; // MeasurementsTree->Fill(); }
void NtupleManager::FillMeasurements | ( | ) |
void NtupleManager::FillNtupleTree | ( | ) |
Definition at line 114 of file NtupleManager.cc.
References CocoaTree.
Referenced by Fit::fitNextEvent().
{ CocoaTree->Fill(); }
void NtupleManager::FillNtupleTree | ( | ) |
void NtupleManager::FillOptObjects | ( | MatrixMeschach * | AtWAMatrix | ) |
Definition at line 251 of file NtupleManager.cc.
References OptObject::AnglesGlobal, OptObject::AnglesLocal, begin, OptObject::CentreGlobal, OptObject::CentreLocal, GetGlobalAngles(), i, OptObject::Name, NOptObjects, OptObjectA, Model::OptOList(), OptObject::Parent, createTree::pp, theta(), OptObject::Type, XCoor, YCoor, and ZCoor.
Referenced by Fit::fitNextEvent().
{ int ii = 0; std::vector< OpticalObject* >::const_iterator vecobj; for ( vecobj = Model::OptOList().begin(); vecobj != Model::OptOList().end(); vecobj++ ) { OptObjectA = new( (*CloneOptObject)[ii] ) OptObject(); OptObjectA->Name = (*vecobj)->name(); OptObjectA->Type = (*vecobj)->type(); if (!(*vecobj)->parent()) { OptObjectA->Parent = ii; ii++; continue; } int pp = 0; std::vector< OpticalObject* >::const_iterator vecobj2; for ( vecobj2 = Model::OptOList().begin(); vecobj2 != Model::OptOList().end(); vecobj2++ ) { if ((*vecobj2)->name()==(*vecobj)->parent()->name()) { OptObjectA->Parent = pp; continue; } pp++; } OptObjectA->CentreGlobal[0] = 1000.*(*vecobj)->centreGlobal().x(); OptObjectA->CentreGlobal[1] = 1000.*(*vecobj)->centreGlobal().y(); OptObjectA->CentreGlobal[2] = 1000.*(*vecobj)->centreGlobal().z(); OptObjectA->CentreLocal[0] = 1000.*(*vecobj)->centreLocal().x(); OptObjectA->CentreLocal[1] = 1000.*(*vecobj)->centreLocal().y(); OptObjectA->CentreLocal[2] = 1000.*(*vecobj)->centreLocal().z(); OptObjectA->AnglesLocal[0] = (*vecobj)->getEntryRMangle(XCoor); OptObjectA->AnglesLocal[1] = (*vecobj)->getEntryRMangle(YCoor); OptObjectA->AnglesLocal[2] = (*vecobj)->getEntryRMangle(ZCoor); double theta[3]; GetGlobalAngles((*vecobj)->rmGlob(), theta); for (int i = 0; i<3; i++) OptObjectA->AnglesGlobal[i] = theta[i]; ii++; } NOptObjects = ii; }
void NtupleManager::FillOptObjects | ( | MatrixMeschach * | AtWAMatrix | ) |
void NtupleManager::GetGlobalAngles | ( | const CLHEP::HepRotation & | rmGlob, |
double * | theta | ||
) | [private] |
Definition at line 382 of file NtupleManager.cc.
References alpha, beta, funct::cos(), gather_cfg::cout, M_PI, funct::sin(), and xy().
Referenced by FillOptObjects().
{ double xx = rmGlob.xx(); if (fabs(xx)<1.e-08) xx = 0.; double xy = rmGlob.xy(); if (fabs(xy)<1.e-08) xy = 0.; double xz = rmGlob.xz(); if (fabs(xz)<1.e-08) xz = 0.; double yx = rmGlob.yx(); if (fabs(yx)<1.e-08) yx = 0.; double yy = rmGlob.yy(); if (fabs(yy)<1.e-08) yy = 0.; double yz = rmGlob.yz(); if (fabs(yz)<1.e-08) yz = 0.; double zx = rmGlob.zx(); if (fabs(zx)<1.e-08) zx = 0.; double zy = rmGlob.zy(); if (fabs(zy)<1.e-08) zy = 0.; double zz = rmGlob.zz(); if (fabs(zz)<1.e-08) zz = 0.; double beta = asin(-zx); double alpha, gamma; if (fabs(zx)!=1.) { double sinalpha = zy/cos(beta); double cosalpha = zz/cos(beta); if (cosalpha>=0) alpha = asin(sinalpha); else alpha = M_PI - asin(sinalpha); if (alpha>M_PI) alpha -= 2*M_PI; double singamma = yx/cos(beta); double cosgamma = xx/cos(beta); if (cosgamma>=0) gamma = asin(singamma); else gamma = M_PI - asin(singamma); if (gamma>M_PI) gamma -= 2*M_PI; } else { alpha = 0.; double singamma = yz/sin(beta); double cosgamma = yy; if (cosgamma>=0) gamma = asin(singamma); else gamma = M_PI - asin(singamma); if (gamma>M_PI) gamma -= 2*M_PI; } int GotGlobalAngles = 0; if (fabs(xy-(sin(alpha)*sin(beta)*cos(gamma)-sin(gamma)*cos(alpha)))>1.e-08) GotGlobalAngles += 1; if (fabs(xz-(cos(alpha)*sin(beta)*cos(gamma)+sin(gamma)*sin(alpha)))>1.e-08) GotGlobalAngles += 10; if (fabs(yy-(sin(alpha)*sin(beta)*sin(gamma)+cos(gamma)*cos(alpha)))>1.e-08) GotGlobalAngles += 100; if (fabs(yz-(cos(alpha)*sin(beta)*sin(gamma)-cos(gamma)*sin(alpha)))>1.e-08) GotGlobalAngles += 1000; if (GotGlobalAngles>0) std::cout << "NtupleManager Warning: cannot get global rotation: " << GotGlobalAngles << std::endl; theta[0] = alpha; theta[1] = beta; theta[2] = gamma; }
void NtupleManager::GetGlobalAngles | ( | const CLHEP::HepRotation & | rmGlob, |
double * | theta | ||
) | [private] |
NtupleManager * NtupleManager::getInstance | ( | ) | [static] |
Definition at line 29 of file NtupleManager.cc.
References instance, and NtupleManager().
{ if(!instance) { instance = new NtupleManager; } return instance; }
static NtupleManager* NtupleManager::getInstance | ( | ) | [static] |
void NtupleManager::InitNtuple | ( | ) |
void NtupleManager::InitNtuple | ( | ) |
Definition at line 96 of file NtupleManager.cc.
References Chi2CalibratedParameters, Chi2Measurements, CloneFitParam, NCops, NDegreesOfFreedom, NDistancemeter, NDistancemeter1Dim, NFitParameters, NOptObjects, NSensor2D, and NTiltmeter.
Referenced by Fit::fitNextEvent().
{ CloneFitParam->Clear(); Chi2Measurements = 0.; Chi2CalibratedParameters = 0.; NDegreesOfFreedom = 0; NFitParameters = 0; NOptObjects = 0; NSensor2D = 0; NDistancemeter = 0; NDistancemeter1Dim = 0; NTiltmeter = 0; NCops = 0; }
void NtupleManager::WriteNtuple | ( | ) |
void NtupleManager::WriteNtuple | ( | ) |
Definition at line 121 of file NtupleManager.cc.
References theRootFile.
Referenced by Fit::startFit().
{ theRootFile->Write(); theRootFile->Close(); }
double NtupleManager::Chi2CalibratedParameters [private] |
Definition at line 60 of file NtupleManager.h.
Referenced by BookNtuple(), FillChi2(), and InitNtuple().
double NtupleManager::Chi2Measurements [private] |
Definition at line 60 of file NtupleManager.h.
Referenced by BookNtuple(), FillChi2(), and InitNtuple().
TClonesArray * NtupleManager::CloneCopsMeas [private] |
Definition at line 55 of file NtupleManager.h.
Referenced by BookNtuple().
TClonesArray * NtupleManager::CloneDistancemeter1DimMeas [private] |
Definition at line 53 of file NtupleManager.h.
Referenced by BookNtuple().
TClonesArray * NtupleManager::CloneDistancemeterMeas [private] |
Definition at line 52 of file NtupleManager.h.
Referenced by BookNtuple().
TClonesArray * NtupleManager::CloneFitParam [private] |
Definition at line 49 of file NtupleManager.h.
Referenced by BookNtuple(), and InitNtuple().
TClonesArray * NtupleManager::CloneOptObject [private] |
Definition at line 50 of file NtupleManager.h.
Referenced by BookNtuple(), FillFitParameters(), and FillMeasurements().
TClonesArray * NtupleManager::CloneSensor2DMeas [private] |
Definition at line 51 of file NtupleManager.h.
Referenced by BookNtuple().
TClonesArray * NtupleManager::CloneTiltmeterMeas [private] |
Definition at line 54 of file NtupleManager.h.
Referenced by BookNtuple().
TTree * NtupleManager::CocoaTree [private] |
Definition at line 45 of file NtupleManager.h.
Referenced by BookNtuple(), and FillNtupleTree().
CopsMeas * NtupleManager::CopsMeasA [private] |
Definition at line 55 of file NtupleManager.h.
Referenced by FillMeasurements().
Definition at line 53 of file NtupleManager.h.
Referenced by FillMeasurements().
DistancemeterMeas * NtupleManager::DistancemeterMeasA [private] |
Definition at line 52 of file NtupleManager.h.
Referenced by FillMeasurements().
FitParam * NtupleManager::FitParamA [private] |
Definition at line 49 of file NtupleManager.h.
Referenced by FillFitParameters().
NtupleManager * NtupleManager::instance = 0 [static, private] |
Definition at line 39 of file NtupleManager.h.
Referenced by getInstance().
int NtupleManager::NCops [private] |
Definition at line 68 of file NtupleManager.h.
Referenced by BookNtuple(), FillMeasurements(), and InitNtuple().
int NtupleManager::NDegreesOfFreedom [private] |
Definition at line 61 of file NtupleManager.h.
Referenced by BookNtuple(), FillChi2(), and InitNtuple().
int NtupleManager::NDistancemeter [private] |
Definition at line 65 of file NtupleManager.h.
Referenced by BookNtuple(), FillMeasurements(), and InitNtuple().
int NtupleManager::NDistancemeter1Dim [private] |
Definition at line 66 of file NtupleManager.h.
Referenced by BookNtuple(), FillMeasurements(), and InitNtuple().
int NtupleManager::NFitParameters [private] |
Definition at line 62 of file NtupleManager.h.
Referenced by BookNtuple(), FillFitParameters(), and InitNtuple().
int NtupleManager::NOptObjects [private] |
Definition at line 63 of file NtupleManager.h.
Referenced by BookNtuple(), FillFitParameters(), FillMeasurements(), FillOptObjects(), and InitNtuple().
int NtupleManager::NSensor2D [private] |
Definition at line 64 of file NtupleManager.h.
Referenced by BookNtuple(), FillMeasurements(), and InitNtuple().
int NtupleManager::NTiltmeter [private] |
Definition at line 67 of file NtupleManager.h.
Referenced by BookNtuple(), FillMeasurements(), and InitNtuple().
OptObject * NtupleManager::OptObjectA [private] |
Definition at line 50 of file NtupleManager.h.
Referenced by FillOptObjects().
Sensor2DMeas * NtupleManager::Sensor2DMeasA [private] |
Definition at line 51 of file NtupleManager.h.
Referenced by FillMeasurements().
TFile * NtupleManager::theRootFile [private] |
Definition at line 43 of file NtupleManager.h.
Referenced by BookNtuple(), and WriteNtuple().
TiltmeterMeas * NtupleManager::TiltmeterMeasA [private] |
Definition at line 54 of file NtupleManager.h.
Referenced by FillMeasurements().