Esempio n. 1
0
void IntervalExamples()
{

   // Time this macro
   TStopwatch t;
   t.Start();


   // set RooFit random seed for reproducible results
   RooRandom::randomGenerator()->SetSeed(3001);

   // make a simple model via the workspace factory
   RooWorkspace* wspace = new RooWorkspace();
   wspace->factory("Gaussian::normal(x[-10,10],mu[-1,1],sigma[1])");
   wspace->defineSet("poi","mu");
   wspace->defineSet("obs","x");

   // specify components of model for statistical tools
   ModelConfig* modelConfig = new ModelConfig("Example G(x|mu,1)");
   modelConfig->SetWorkspace(*wspace);
   modelConfig->SetPdf( *wspace->pdf("normal") );
   modelConfig->SetParametersOfInterest( *wspace->set("poi") );
   modelConfig->SetObservables( *wspace->set("obs") );

   // create a toy dataset
   RooDataSet* data = wspace->pdf("normal")->generate(*wspace->set("obs"),100);
   data->Print();

   // for convenience later on
   RooRealVar* x = wspace->var("x");
   RooRealVar* mu = wspace->var("mu");

   // set confidence level
   double confidenceLevel = 0.95;

   // example use profile likelihood calculator
   ProfileLikelihoodCalculator plc(*data, *modelConfig);
   plc.SetConfidenceLevel( confidenceLevel);
   LikelihoodInterval* plInt = plc.GetInterval();

   // example use of Feldman-Cousins
   FeldmanCousins fc(*data, *modelConfig);
   fc.SetConfidenceLevel( confidenceLevel);
   fc.SetNBins(100); // number of points to test per parameter
   fc.UseAdaptiveSampling(true); // make it go faster

   // Here, we consider only ensembles with 100 events
   // The PDF could be extended and this could be removed
   fc.FluctuateNumDataEntries(false);

   // Proof
   //  ProofConfig pc(*wspace, 4, "workers=4", kFALSE);    // proof-lite
   //ProofConfig pc(w, 8, "localhost");    // proof cluster at "localhost"
   //  ToyMCSampler* toymcsampler = (ToyMCSampler*) fc.GetTestStatSampler();
   //  toymcsampler->SetProofConfig(&pc);     // enable proof

   PointSetInterval* interval = (PointSetInterval*) fc.GetInterval();


   // example use of BayesianCalculator
   // now we also need to specify a prior in the ModelConfig
   wspace->factory("Uniform::prior(mu)");
   modelConfig->SetPriorPdf(*wspace->pdf("prior"));

   // example usage of BayesianCalculator
   BayesianCalculator bc(*data, *modelConfig);
   bc.SetConfidenceLevel( confidenceLevel);
   SimpleInterval* bcInt = bc.GetInterval();

   // example use of MCMCInterval
   MCMCCalculator mc(*data, *modelConfig);
   mc.SetConfidenceLevel( confidenceLevel);
   // special options
   mc.SetNumBins(200);        // bins used internally for representing posterior
   mc.SetNumBurnInSteps(500); // first N steps to be ignored as burn-in
   mc.SetNumIters(100000);    // how long to run chain
   mc.SetLeftSideTailFraction(0.5); // for central interval
   MCMCInterval* mcInt = mc.GetInterval();

   // for this example we know the expected intervals
   double expectedLL = data->mean(*x)
      + ROOT::Math::normal_quantile(  (1-confidenceLevel)/2,1)
      / sqrt(data->numEntries());
   double expectedUL = data->mean(*x)
      + ROOT::Math::normal_quantile_c((1-confidenceLevel)/2,1)
      / sqrt(data->numEntries()) ;

   // Use the intervals
   std::cout << "expected interval is [" <<
      expectedLL << ", " <<
      expectedUL << "]" << endl;

   cout << "plc interval is [" <<
      plInt->LowerLimit(*mu) << ", " <<
      plInt->UpperLimit(*mu) << "]" << endl;

   std::cout << "fc interval is ["<<
      interval->LowerLimit(*mu) << " , "  <<
      interval->UpperLimit(*mu) << "]" << endl;

   cout << "bc interval is [" <<
      bcInt->LowerLimit() << ", " <<
      bcInt->UpperLimit() << "]" << endl;

   cout << "mc interval is [" <<
      mcInt->LowerLimit(*mu) << ", " <<
      mcInt->UpperLimit(*mu) << "]" << endl;

   mu->setVal(0);
   cout << "is mu=0 in the interval? " <<
      plInt->IsInInterval(RooArgSet(*mu)) << endl;


   // make a reasonable style
   gStyle->SetCanvasColor(0);
   gStyle->SetCanvasBorderMode(0);
   gStyle->SetPadBorderMode(0);
   gStyle->SetPadColor(0);
   gStyle->SetCanvasColor(0);
   gStyle->SetTitleFillColor(0);
   gStyle->SetFillColor(0);
   gStyle->SetFrameFillColor(0);
   gStyle->SetStatColor(0);


   // some plots
   TCanvas* canvas = new TCanvas("canvas");
   canvas->Divide(2,2);

   // plot the data
   canvas->cd(1);
   RooPlot* frame = x->frame();
   data->plotOn(frame);
   data->statOn(frame);
   frame->Draw();

   // plot the profile likelihood
   canvas->cd(2);
   LikelihoodIntervalPlot plot(plInt);
   plot.Draw();

   // plot the MCMC interval
   canvas->cd(3);
   MCMCIntervalPlot* mcPlot = new MCMCIntervalPlot(*mcInt);
   mcPlot->SetLineColor(kGreen);
   mcPlot->SetLineWidth(2);
   mcPlot->Draw();

   canvas->cd(4);
   RooPlot * bcPlot = bc.GetPosteriorPlot();
   bcPlot->Draw();

   canvas->Update();

   t.Stop();
   t.Print();

}
Esempio n. 2
0
void createWorkspace(const std::string &infilename, int nState, bool correctCtau, bool drawRapPt2D) {
    gROOT->SetStyle("Plain");
    gStyle->SetTitleBorderSize(0);

    delete gRandom;
    gRandom = new TRandom3(23101987);

    // Set some strings
    const std::string workspacename = "ws_masslifetime",
                      treename = "selectedData";

    // Get the tree from the data file
    TFile *f = TFile::Open(infilename.c_str());
    TTree *tree = (TTree*)f->Get(treename.c_str());

    // Set branch addresses in tree to be able to import tree to roofit
    TLorentzVector* chic = new TLorentzVector;
    tree->SetBranchAddress("chic",&chic);
    TLorentzVector* chic_rf = new TLorentzVector;
    tree->SetBranchAddress("chic_rf",&chic_rf);
    TLorentzVector* jpsi = new TLorentzVector;
    tree->SetBranchAddress("jpsi",&jpsi);
    double lifetime = 0;
    tree->SetBranchAddress("Jpsict",&lifetime);
    double lifetimeErr = 0;
    tree->SetBranchAddress("JpsictErr",&lifetimeErr);

    char lifetimeTitle[200];

    sprintf(lifetimeTitle,"l^{#psi} [mm]");
    if(correctCtau) sprintf(lifetimeTitle,"l^{#chi} [mm]");

    // define variables necessary for J/Psi(Psi(2S)) mass,lifetime fit
    RooRealVar* JpsiMass =
        new RooRealVar("JpsiMass", "M^{#psi} [GeV]", onia::massMin, onia::massMax);
    RooRealVar* JpsiPt =
        new RooRealVar("JpsiPt", "p^{#psi}_{T} [GeV]", 0. ,1000.);
    RooRealVar* JpsiRap =
        new RooRealVar("JpsiRap", "y^{#psi}", -2., 2.);
    RooRealVar* chicMass =
        new RooRealVar("chicMass", "M^{#chi} [GeV]", onia::chimassMin, onia::chimassMax);
    RooRealVar* chicRap =
        new RooRealVar("chicRap", "y^{#chi}", -onia::chirap, onia::chirap);
    RooRealVar* chicPt =
        new RooRealVar("chicPt", "p^{#chi}_{T} [GeV]", 0. ,100.);
    RooRealVar* Jpsict =
        new RooRealVar("Jpsict", lifetimeTitle, onia::ctVarMin, onia::ctVarMax);
    RooRealVar* JpsictErr =
        new RooRealVar("JpsictErr", Form("Error on %s",lifetimeTitle), 0.0001, 1.);

    // Set bins
    Jpsict->setBins(10000,"cache");
    JpsiMass->setBins(10000,"cache");
    JpsiPt->setBins(100);
    JpsiRap->setBins(10000,"cache");
    chicMass->setBins(10000,"cache");
    //JpsictErr->setBins(100);
    JpsictErr->setBins(10000,"cache");

    // The list of data variables
    RooArgList dataVars(*JpsiMass,*JpsiPt,*JpsiRap,*chicMass,*chicRap,*chicPt,*Jpsict,*JpsictErr);

    // construct dataset to contain events
    RooDataSet* fullData = new RooDataSet("fullData","The Full Data From the Input ROOT Trees",dataVars);

    int entries = tree->GetEntries();
    cout << "entries " << entries << endl;

    int numEntriesTotal=0;
    int numEntriesInAnalysis=0;
    int numEntriesNotInAnalysis=0;



    /*
    	/// Read in 2011 data ctauErr-histos

    	char saveDir[200];
    	char PlotID[200];
    	char savename[200];
    	sprintf(saveDir,"/afs/hephy.at/scratch/k/knuenz/ChicPol/macros/polFit/Figures/CtauErrModel");
    	gSystem->mkdir(saveDir);
    	sprintf(PlotID,"2014May26_MoreLbins");
    	sprintf(saveDir,"%s/%s",saveDir,PlotID);
    	gSystem->mkdir(saveDir);
    	sprintf(savename,"%s/CtauErrModel_histograms.root",saveDir);

    	TFile *infile = new TFile(savename,"READ");
    	cout<<"opened file"<<endl;

    	const int nPT=5;
    	const int nRAP=2;
    	const int nL=15;

    	const double bordersPT[nPT+1] = {0., 12., 16., 20., 30., 100.};
    	const double bordersRAP[nRAP+1] = {0., 0.6, 2.};
    	const double bordersL[nL+1] = {onia::ctVarMin, -0.05, -0.03, -0.02, -0.015, -0.01, -0.005,  0., 0.005, 0.01, 0.015, 0.02, 0.03, 0.05, 0.1, onia::ctVarMax};

    	TH1D* h_ctauerr_2011[nRAP+1][nPT+1][nL+1];
    	TH1D* h_ctauerr_2012[nRAP+1][nPT+1][nL+1];

    	for(int iRAP = 0; iRAP < nRAP+1; iRAP++){
    		for(int iPT = 0; iPT < nPT+1; iPT++){
    			for(int iL = 0; iL < nL+1; iL++){

    				h_ctauerr_2011[iRAP][iPT][iL] = (TH1D*)infile->Get(Form("h_ctauerr_2011_rap%d_pt%d_l%d",iRAP, iPT, iL));
    				h_ctauerr_2012[iRAP][iPT][iL] = (TH1D*)infile->Get(Form("h_ctauerr_2012_rap%d_pt%d_l%d",iRAP, iPT, iL));

    			}
    		}
    	}
    	cout<<"opened hists"<<endl;

    	/// Finished reading in 2011 data ctauErr-histos
    */


    // loop through events in tree and save them to dataset
    for (int ientries = 0; ientries < entries; ientries++) {
        numEntriesTotal++;
        if (ientries%10000==0) std::cout << "event " << ientries << " of " << entries <<  std::endl;

        tree->GetEntry(ientries);

        double M_jpsi =jpsi->M();
        double pt_jpsi =jpsi->Pt();
        double y_jpsi =jpsi->Rapidity();
        double M =chic_rf->M();
        //double M =chic->M()-jpsi->M()+onia::MpsiPDG;
        double y=chic->Rapidity();
        double pt=chic->Pt();

        //if (ientries%3==0){
        //	M_jpsi = gRandom->Uniform(JpsiMass->getMin(), JpsiMass->getMax());
        //}


        //double JpsictErrRand = h_JpsictErr->GetRandom();
        //double JpsictErrRand2 = h_JpsictErr->GetRandom();
        //double JpsictMeanRand=0.;
        ////double pTcorrection=(pt-20.)*0.002;
        //
        ////JpsictErrRand-=pTcorrection;
        //if(JpsictErrRand<0) JpsictErrRand=0.001;
        ////JpsictErrRand2-=pTcorrection;
        //if(JpsictErrRand2<0) JpsictErrRand2=0.001;
        //
        //if (ientries%1000000==0){
        //	double exponent=0.4;
        //	JpsictMeanRand=gRandom->Exp(exponent);
        //}
        //
        //
        //lifetime = gRandom->Gaus(JpsictMeanRand,0.8*JpsictErrRand);
        //lifetimeErr = JpsictErrRand2;
        //if (ientries%3==0){
        //	lifetime = gRandom->Gaus(JpsictMeanRand,1.5*JpsictErrRand);
        //}
        //

        //double resCorrFactor=1.08;
        //if(lifetime<0)
        //	lifetimeErr/=resCorrFactor;


        /*
        		int iRAPindex=0;
        		int iPTindex=0;
        		int iLindex=0;

        		for(int iRAP = 1; iRAP < nRAP+1; iRAP++){
        			for(int iPT = 1; iPT < nPT+1; iPT++){
        				for(int iL = 1; iL < nL+1; iL++){

        					Double_t ptMin = bordersPT[iPT-1];;
        					Double_t ptMax = bordersPT[iPT];;
        					Double_t rapMin = bordersRAP[iRAP-1];;
        					Double_t rapMax = bordersRAP[iRAP];  ;
        					Double_t lMin = bordersL[iL-1];;
        					Double_t lMax = bordersL[iL];  ;

        					if(pt_jpsi>ptMin && pt_jpsi<ptMax && TMath::Abs(y_jpsi)>rapMin && TMath::Abs(y_jpsi)<rapMax && lifetime>lMin && lifetime<lMax){
        						iRAPindex=iRAP;
        						iPTindex=iPT;
        						iLindex=iL;
        					}

        				}

        			}
        		}

        		double lifetimeErrRand = h_ctauerr_2011[iRAPindex][iPTindex][iLindex]->GetRandom();

        		lifetimeErr = lifetimeErrRand;
        		if (ientries%10000==0){
        			std::cout << "Test output: lifetimeErr " << lifetimeErr << " randomly drawn from from " << h_ctauerr_2011[iRAPindex][iPTindex][iLindex]->GetName() <<  std::endl;
        		}

        */

        if (
            M > chicMass->getMin() && M < chicMass->getMax()
            && pt > chicPt->getMin() && pt < chicPt->getMax()
            && y > chicRap->getMin() && y < chicRap->getMax()
            && M_jpsi > JpsiMass->getMin() && M_jpsi < JpsiMass->getMax()
            && pt_jpsi > JpsiPt->getMin() && pt_jpsi < JpsiPt->getMax()
            && y_jpsi > JpsiRap->getMin() && y_jpsi < JpsiRap->getMax()
            && lifetime > Jpsict->getMin() && lifetime < Jpsict->getMax()
            && lifetimeErr > JpsictErr->getMin() && lifetimeErr < JpsictErr->getMax()
        ) {

            chicPt      ->setVal(pt);
            chicRap     ->setVal(y);
            chicMass    ->setVal(M);
            JpsiMass    ->setVal(M_jpsi);
            JpsiPt    	->setVal(pt_jpsi);
            JpsiRap     ->setVal(y_jpsi);
            Jpsict      ->setVal(lifetime);
            JpsictErr   ->setVal(lifetimeErr);

            //cout<<"JpsiRap->getVal() "<<JpsiRap->getVal()<<endl;

            fullData->add(dataVars);
            numEntriesInAnalysis++;
        }
        else {
            numEntriesNotInAnalysis++;
            //if (M < chicMass->getMin() || M > chicMass->getMax()) cout << "M " << M << endl;
            //if (pt < chicPt->getMin() || pt > chicPt->getMax()) cout << "pt " << pt << endl;
            //if (y < chicRap->getMin() || y > chicRap->getMax()) cout << "y " << y << endl;
            //if (lifetime < Jpsict->getMin() || lifetime > Jpsict->getMax()) cout << "lifetime " << lifetime << endl;
            //if (lifetimeErr < JpsictErr->getMin() || lifetimeErr > JpsictErr->getMax()) cout << "lifetimeErr " << lifetimeErr << endl;
            //cout << "M " << M << endl;
            //cout << "pt " << pt << endl;
            //cout << "y " << y << endl;
            //cout << "lifetime " << lifetime << endl;
            //cout << "lifetimeErr " << lifetimeErr << endl;
            //cout << " " << endl;

        }

    }//ientries

    //infile->Close();

    cout << "entries entering all bins " << fullData->sumEntries() << endl;
    cout << "numEntriesTotal " << numEntriesTotal << endl;
    cout << "numEntriesInAnalysis " << numEntriesInAnalysis << endl;
    cout << "numEntriesNotInAnalysis " << numEntriesNotInAnalysis << endl;

    //------------------------------------------------------------------------------------------------------------------
    // Define workspace and import datasets

    ////Get datasets binned in pT an y

    for(int iRap = 0; iRap <= onia::kNbRapForPTBins; iRap++) {

        Double_t yMin;
        Double_t yMax;
        if(iRap==0) {
            yMin = onia::rapForPTRange[0];
            yMax = onia::rapForPTRange[onia::kNbRapForPTBins];
        } else {
            yMin = onia::rapForPTRange[iRap-1];
            yMax = onia::rapForPTRange[iRap];
        }

        for(int iPT = 0; iPT <= onia::kNbPTBins[iRap]; iPT++) {
            //for(int iPT = 0; iPT <= 0; iPT++)

            Double_t ptMin;
            Double_t ptMax;
            if(iPT==0) {
                ptMin = onia::pTRange[iRap][0];
                ptMax = onia::pTRange[iRap][onia::kNbPTBins[0]];
            } else {
                ptMin = onia::pTRange[iRap][iPT-1];
                ptMax = onia::pTRange[iRap][iPT];
            }

            // output file name and workspace
            std::stringstream outfilename;
            outfilename << "tmpFiles/backupWorkSpace/ws_createWorkspace_Chi_rap" << iRap << "_pt" << iPT << ".root";
            RooWorkspace* ws = new RooWorkspace(workspacename.c_str());

            // define pt and y cuts on dataset
            std::stringstream cutString;

            if(onia::KinParticleChi && !onia::KinParticleChiButJpsiRap) {
                cutString << "(chicPt >= " << ptMin << " && chicPt < "<< ptMax << ") && "
                          << "(TMath::Abs(chicRap) >= " << yMin << " && TMath::Abs(chicRap) < " << yMax << ")";
            }
            if(!onia::KinParticleChi) {
                cutString << "(JpsiPt >= " << ptMin << " && JpsiPt < "<< ptMax << ") && "
                          << "(TMath::Abs(JpsiRap) >= " << yMin << " && TMath::Abs(JpsiRap) < " << yMax << ")";
            }
            if(onia::KinParticleChi && onia::KinParticleChiButJpsiRap) {
                cutString << "(chicPt >= " << ptMin << " && chicPt < "<< ptMax << ") && "
                          << "(TMath::Abs(JpsiRap) >= " << yMin << " && TMath::Abs(JpsiRap) < " << yMax << ")";
            }


            cout << "cutString: " << cutString.str().c_str() << endl;

            // get the dataset for the fit
            RooDataSet* binData = (RooDataSet*)fullData->reduce(cutString.str().c_str());
            std::stringstream name;
            name << "jpsi_data_rap" << iRap << "_pt" << iPT;
            binData->SetNameTitle(name.str().c_str(), "Data For Fitting");

            cout << "numEvents = " << binData->sumEntries() << endl;

            double chicMeanPt = binData->mean(*chicPt);
            RooRealVar var_chicMeanPt("var_chicMeanPt","var_chicMeanPt",chicMeanPt);
            if(!ws->var("var_chicMeanPt")) ws->import(var_chicMeanPt);
            else ws->var("var_chicMeanPt")->setVal(chicMeanPt);
            cout << "chicMeanPt = " << chicMeanPt << endl;

            double jpsiMeanPt = binData->mean(*JpsiPt);
            RooRealVar var_jpsiMeanPt("var_jpsiMeanPt","var_jpsiMeanPt",jpsiMeanPt);
            if(!ws->var("var_jpsiMeanPt")) ws->import(var_jpsiMeanPt);
            else ws->var("var_jpsiMeanPt")->setVal(jpsiMeanPt);
            cout << "jpsiMeanPt = " << jpsiMeanPt << endl;

            std::stringstream cutStringPosRapChic;
            cutStringPosRapChic << "chicRap > 0";
            RooDataSet* binDataPosRapChic = (RooDataSet*)binData->reduce(cutStringPosRapChic.str().c_str());
            double chicMeanAbsRap = binDataPosRapChic->mean(*chicRap);
            cout << "chicMeanAbsRap = " << chicMeanAbsRap << endl;
            RooRealVar var_chicMeanAbsRap("var_chicMeanAbsRap","var_chicMeanAbsRap",chicMeanAbsRap);
            if(!ws->var("var_chicMeanAbsRap")) ws->import(var_chicMeanAbsRap);
            else ws->var("var_chicMeanAbsRap")->setVal(chicMeanAbsRap);

            std::stringstream cutStringPosRapJpsi;
            cutStringPosRapJpsi << "JpsiRap > 0";
            RooDataSet* binDataPosRapJpsi = (RooDataSet*)binData->reduce(cutStringPosRapJpsi.str().c_str());
            double jpsiMeanAbsRap = binDataPosRapJpsi->mean(*JpsiRap);
            cout << "jpsiMeanAbsRap = " << jpsiMeanAbsRap << endl;
            RooRealVar var_jpsiMeanAbsRap("var_jpsiMeanAbsRap","var_jpsiMeanAbsRap",jpsiMeanAbsRap);
            if(!ws->var("var_jpsiMeanAbsRap")) ws->import(var_jpsiMeanAbsRap);
            else ws->var("var_jpsiMeanAbsRap")->setVal(jpsiMeanAbsRap);

            // Import variables to workspace
            ws->import(*binData);
            ws->writeToFile(outfilename.str().c_str());
        }//iPT
    }//iRap

    ////---------------------------------------------------------------
    ////--Integrating rapidity and pt bins, in +/- 3*sigma mass window
    ////---------------------------------------------------------------
    if(drawRapPt2D) {
        double yMin = onia::rapForPTRange[0];
        double yMax = 1.6;//onia::rapForPTRange[onia::kNbRapForPTBins];
        double ptMin =  onia::pTRange[0][0];
        double ptMax =  onia::pTRange[0][onia::kNbPTBins[0]];

        std::stringstream cutRapPt;
        cutRapPt << "(chicPt > " << ptMin << " && chicPt < "<< ptMax << ") && "
                 << "(TMath::Abs(chicRap) > " << yMin << " && TMath::Abs(chicRap) < " << yMax << ")";
        cout<<"cutRapPt: "<<cutRapPt.str().c_str()<<endl;

        RooDataSet* rapPtData = (RooDataSet*)fullData->reduce(cutRapPt.str().c_str());
        std::stringstream nameRapPt;
        nameRapPt << "data_rap0_pt0";
        rapPtData->SetNameTitle(nameRapPt.str().c_str(), "Data For full rap and pt");

        // output file name and workspace
        std::stringstream outfilename;
        outfilename << "tmpFiles/backupWorkSpace/ws_createWorkspace_Chi_rap0_pt0.root";
        RooWorkspace* ws_RapPt = new RooWorkspace(workspacename.c_str());
        //Import variables to workspace
        ws_RapPt->import(*rapPtData);
        ws_RapPt->writeToFile(outfilename.str().c_str());

        TH2D* rapPt;
        TH1D* rap1p2;
        double MassMin;
        double MassMax;

        rap1p2 = new TH1D("rap1p2","rap1p2",30,1.2, 1.8);
        if(nState==4) {
            rapPt = new TH2D( "rapPt", "rapPt", 52,-1.3,1.3,144,0,72);
            MassMin=3.011;//massPsi1S-onia::nSigMass*sigma1S;
            MassMax=3.174;//massPsi1S+onia::nSigMass*sigma1S;
            // sigma  27.2 MeV
            // mean 3.093 GeV
        }
        if(nState==5) {
            rapPt = new TH2D( "rapPt", "rapPt", 64,-1.6,1.6,144,0,72); //  rap<1.5
            //rapPt = new TH2D( "rapPt", "rapPt", 52,-1.3,1.3,144,0,72); //  rap<1.2
            MassMin=3.576;//massPsi2S-onia::nSigMass*sigma2S;
            MassMax=3.786;//massPsi2S+onia::nSigMass*sigma2S;
            // sigma 34.9 MeV // pT > 7
            // sigma 34.3 MeV // pT > 10
            // mean 3.681 GeV
        }

        cout<<"Plotting rap-Pt for Psi"<<nState-3<<"S"<<endl;
        cout<<"MassMin for rap-Pt plot = "<<MassMin<<endl;
        cout<<"MassMax for rap-Pt plot = "<<MassMax<<endl;

        TTree *rapPtTree = (TTree*)rapPtData->tree();
        std::stringstream cutMass;
        cutMass<<"(chicMass > " << MassMin << " && chicMass < "<< MassMax << ")";
        //following two methods can only be used in root_v30, 34 does not work
        rapPtTree->Draw("chicPt:chicRap>>rapPt",cutMass.str().c_str(),"colz");
        cout<<"debug"<<endl;
        rapPtTree->Draw("TMath::Abs(chicRap)>>rap1p2",cutMass.str().c_str());

        TCanvas* c2 = new TCanvas("c2","c2",1200,1500);
        rapPt->SetYTitle("p_{T}(#mu#mu) [GeV]");
        rapPt->SetXTitle("y(#mu#mu)");
        gStyle->SetPalette(1);
        gPad->SetFillColor(kWhite);
        rapPt->SetTitle(0);
        rapPt->SetStats(0);
        gPad->SetLeftMargin(0.15);
        gPad->SetRightMargin(0.17);
        rapPt->GetYaxis()->SetTitleOffset(1.5);

        rapPt->Draw("colz");

        TLine* rapPtLine;

        for(int iRap=0; iRap<onia::kNbRapForPTBins+1; iRap++) {
            rapPtLine= new TLine( -onia::rapForPTRange[iRap], onia::pTRange[0][0], -onia::rapForPTRange[iRap], onia::pTRange[0][onia::kNbPTBins[iRap]] );
            rapPtLine->SetLineWidth( 2 );
            rapPtLine->SetLineStyle( 1 );
            rapPtLine->SetLineColor( kWhite );
            rapPtLine->Draw();
            rapPtLine= new TLine( onia::rapForPTRange[iRap], onia::pTRange[0][0], onia::rapForPTRange[iRap], onia::pTRange[0][onia::kNbPTBins[iRap]] );
            rapPtLine->SetLineWidth( 2 );
            rapPtLine->SetLineStyle( 1 );
            rapPtLine->SetLineColor( kWhite );
            rapPtLine->Draw();

            int pTBegin = 0;
            if(nState==5) pTBegin = 1;
            for(int iPt=pTBegin; iPt<onia::kNbPTBins[iRap+1]+1; iPt++) {
                rapPtLine= new TLine( -onia::rapForPTRange[onia::kNbRapForPTBins], onia::pTRange[0][iPt], onia::rapForPTRange[onia::kNbRapForPTBins], onia::pTRange[0][iPt] );
                rapPtLine->SetLineWidth( 2 );
                rapPtLine->SetLineStyle( 1 );
                rapPtLine->SetLineColor( kWhite );
                rapPtLine->Draw();
            }
        }

        char savename[200];
        sprintf(savename,"Figures/rapPt_Chi.pdf");
        c2->SaveAs(savename);

        TCanvas* c3 = new TCanvas("c3","c3",1500,1200);
        rap1p2->SetYTitle("Events");
        rap1p2->SetXTitle("y(#mu#mu)");
        rap1p2->SetTitle(0);
        rap1p2->SetStats(0);
        rap1p2->GetYaxis()->SetTitleOffset(1.2);
        rap1p2->Draw();
        sprintf(savename,"Figures/rap_Chi_1p2.pdf");
        c3->SaveAs(savename);
    }

    f->Close();
}