コード例 #1
0
ファイル: SimplePlot2D.C プロジェクト: alexandertuna/MMFE8
void SimplePlot2D(){

  //string filename = "data/scan_CH1-64_unmasked.root";
  //string filename = "data/scan_CH1-50_masked.root";
  string filename = "test.root";
  string varXname = "VMM #";
  string varYname = "CH #";
  
  // delay count stuff
  int CH = 21;
  double delays[5];
  double count_tot[5];
  double count_right[5];
  for(int i = 0; i < 5; i++){
    delays[i] = double(i)*5.;
    count_tot[i] = 0.;
    count_right[i] = 0.;
  }
  
      

  ///////////////////////////////////////////////////////
  
  TChain* tree = new TChain("MMFE8","MMFE8");

  tree->AddFile(filename.c_str());

  MMFE8Base* base = new MMFE8Base(tree);

  int N = tree->GetEntries();

  TH2D* hist = new TH2D("hist","hist", 8, 0.5, 8.5, 64, 0.5,64.5);
  TH2D* histN = (TH2D*) hist->Clone("norm");
  TH2D* histchch = new TH2D("histchch","histchch", 64, 0.5, 64.5, 64, 0.5,64.5);
  TH2D* histDelay = new TH2D("histN","histN", 31, 9.5, 40.5, 5,-0.5, 4.5);	
  TH2D* histDelayD = new TH2D("histD","histD", 31, 9.5, 40.5, 5,-0.5, 4.5);

  for(int i = 0; i < N; i++){
    base->GetEntry(i);
    
    if(base->CHpulse == CH){
      //count_tot[base->Delay] += 1.;
      count_tot[(base->TPDAC-80)/20] += 1.;
      if(base->CHpulse == base->CHword)
	//count_right[base->Delay] += base->TDO;
      	count_right[(base->TPDAC-80)/20] += base->PDO;
    }

    //histDelayD->Fill(base->CHpulse,base->Delay);
    histDelayD->Fill(base->CHpulse,(base->TPDAC-80)/20);
    if(base->CHpulse == base->CHword)
      //histDelay->Fill(base->CHpulse,base->Delay,base->TDO);
      histDelay->Fill(base->CHpulse,(base->TPDAC-80)/20,base->PDO);

    if((base->CHpulse != base->CHword || true) &&
       base->VMM == 6)
      histchch->Fill(base->CHpulse,base->CHword);

    if(base->CHpulse != base->CHword)
      continue;

    hist->Fill(base->VMM,base->CHpulse,base->PDO);
    histN->Fill(base->VMM,base->CHpulse);
  
  }

  for(int x = 0; x < 8; x++){
    for(int y = 0; y < 64; y++){
      double v = hist->GetBinContent(x+1,y+1);
      double N = histN->GetBinContent(x+1,y+1);
      hist->SetBinContent(x+1,y+1,v/max(int(N),1));
    }
  }
  
  TLatex l;
  //l.NDC();

  TCanvas* can = new TCanvas("can","can",600,500);
  can->SetTopMargin(0.05);
  can->SetLeftMargin(0.12);
  can->SetRightMargin(0.15);
  gStyle->SetOptStat(0);
  gStyle->SetOptTitle(0);

  can->Draw();
  can->SetGridx();
  can->SetGridy();
  
  can->cd();

  hist->Draw("COLZ");
  
  hist->GetXaxis()->SetTitle(varXname.c_str());
  hist->GetXaxis()->CenterTitle();
  hist->GetYaxis()->SetTitle(varYname.c_str());
  hist->GetYaxis()->CenterTitle();
  hist->GetYaxis()->SetTitleOffset(1.4);
  hist->GetYaxis()->CenterTitle();
  //hist->GetYaxis()->SetRangeUser(0.,hist->GetMaximum()*1.1) ;

  TCanvas* canN = new TCanvas("canN","canN",600,500);
  canN->SetTopMargin(0.05);
  canN->SetLeftMargin(0.12);
  canN->SetRightMargin(0.15);

  canN->Draw();
  canN->SetGridx();
  canN->SetGridy();
  
  canN->cd();

  histN->Draw("COLZ");
  
  histN->GetXaxis()->SetTitle(varXname.c_str());
  histN->GetXaxis()->CenterTitle();
  histN->GetYaxis()->SetTitle(varYname.c_str());
  histN->GetYaxis()->CenterTitle();
  histN->GetYaxis()->SetTitleOffset(1.4);
  histN->GetYaxis()->CenterTitle();
			     
  TCanvas* canchch = new TCanvas("canchch","canchch",600,500);
  canchch->SetTopMargin(0.05);
  canchch->SetLeftMargin(0.12);
  canchch->SetRightMargin(0.15);

  canchch->Draw();
  canchch->SetGridx();
  canchch->SetGridy();
  
  canchch->cd();
  histchch->Draw("COLZ");
  
  histchch->GetXaxis()->SetTitle("CH pulsed");
  histchch->GetXaxis()->CenterTitle();
  histchch->GetYaxis()->SetTitle("CH data");
  histchch->GetYaxis()->CenterTitle();
  histchch->GetYaxis()->SetTitleOffset(1.4);
  histchch->GetYaxis()->CenterTitle();
  histchch->GetZaxis()->SetTitle("Number of data events");
  histchch->GetZaxis()->SetTitleOffset(1.4);
  histchch->GetZaxis()->CenterTitle();
 
  l.DrawLatex(.54,65.2,"VMM 2");

  TCanvas* can_delay = new TCanvas("can_delay","can_delay",600,500);
  can_delay->Draw();
  can_delay->cd();

  for(int i = 0; i < 5; i++)
    count_tot[i] = count_right[i]/count_tot[i];
  TGraph* gr = new TGraph(5,delays,count_tot);
  gr->SetMarkerSize(4);
  gr->SetMarkerStyle(5);
  gr->Draw("AP");

  histDelay->Divide(histDelayD);

  TCanvas* canDelay = new TCanvas("canDelay","canDelay",600,500);
  canDelay->SetTopMargin(0.05);
  canDelay->SetLeftMargin(0.12);
  canDelay->SetRightMargin(0.15);

  canDelay->Draw();
  canDelay->SetGridx();
  canDelay->SetGridy();
  
  canDelay->cd();
  histDelay->Draw("COLZ");
  
  histDelay->GetXaxis()->SetTitle("CH pulsed");
  histDelay->GetXaxis()->CenterTitle();
  histDelay->GetYaxis()->SetTitle("Delay Count");
  histDelay->GetYaxis()->CenterTitle();
  histDelay->GetYaxis()->SetTitleOffset(1.4);
  histDelay->GetYaxis()->CenterTitle();
  histDelay->GetZaxis()->SetTitle("Fraction zeroes");
  histDelay->GetZaxis()->SetTitleOffset(1.4);
  histDelay->GetZaxis()->CenterTitle();
}
コード例 #2
0
ファイル: drawPID.C プロジェクト: maszyman/PlotMacros
// infilename - root file with relevant histograms
// system - PP,APAP,PP
// status - Pass,Fail
// rWrite - 0-no,1-png,2-eps
// rPerformance - 0-no,1-yes (ALICE logo etc.)
// bin: 0 - all, 1- 0:5, 2- 5:10, etc
void drawPID(const char* infilename, const char* system, const char* status, Int_t rWrite, Int_t rPerformance, Int_t bin)
{


    TFile *f = new TFile(infilename, "read");

    // TPC dEdx
    TH2D* TPCdEdx =(TH2D*)f->Get(Form("TPCdEdxcut%s1%stpcM%i",status, system,0));

    if (!bin) {
        int minMultBin = 0;
        int maxMultBin = 6; // 8
    }
    else {
        int minMultBin = bin-1;
        int maxMultBin = bin; // 8
    }

    double EvMultall = 0;

    for (int i = minMultBin; i < maxMultBin; i++) {

        TH2D* TPCdEdxN =(TH2D*)f->Get(Form("TPCdEdxcut%s1%stpcM%i",status,system,i));
        TPCdEdx->Add(TPCdEdxN);

        cout << i << " " << TPCdEdxN->GetEntries() << endl;

        //delete hEvMult;
    }

    TCanvas *c2 = new TCanvas("TPC dEdx", "TPC dEdx");
    c2->SetGridx();
    c2->SetGridy();
    c2->SetFillColor(10);
    c2->SetRightMargin(1.9);
    c2->SetLogz();

    TPCdEdx->GetXaxis()->SetTitle("#it{p}_{T} (GeV/#it{c})");
    TPCdEdx->GetXaxis()->SetRangeUser(0.0,6.0);
    TPCdEdx->GetYaxis()->SetTitle("dE/dx");
    TPCdEdx->GetZaxis()->SetLabelSize(0.03);
    TPCdEdx->Draw("colz");

// 	double a1 = -3000.0; double b1 =  1280.0;
// 	double a2 = -312.5;  double b2 =  312.5;
// 	double a3 = -200.0;  double b3 =  240.0;

//    TF1 *fa1 = new TF1("fa1","-1800*x+940",0.3,0.4);
//   fa1->Draw("same");
//   TF1 *fa2 = new TF1("fa2","-500.0*x+420.0",0.4,0.6);
//   fa2->Draw("same");
// TF1 *fa3 = new TF1("fa3","-216.7*x+250.0",0.6,0.9);
//    fa3->Draw("same");
// TF1 *fa4 = new TF1("fa4","-566.7*x+570.0",0.6,0.75);
//    fa4->Draw("same");
// TF1 *fa5 = new TF1("fa5","-2076.92*x+1476.15",0.47,0.6);
//    fa5->Draw("same");
//   cout<<TPCdEdx->GetNbinsX()<<endl;
//   cout<<TPCdEdx->GetNbinsY()<<endl;
//   for (int ii=0;ii<TPCdEdx->GetNbinsX();ii++){

//     for (int jj=0;jj<TPCdEdx->GetNbinsY();jj++){

//       cout<<"binX: "<<ii<<endl;
//       cout<<"binY: "<<jj<<endl;
//       cout<<"val: "<<TPCdEdx->GetBinContent(ii,jj)<<endl;
//     }
//   }

// 	TH1D *py = TPCdEdx->ProjectionY("py", 230, 232); // where firstYbin = 0 and lastYbin = 9
// 	TCanvas *c22 = new TCanvas("TPC2", "TPC2");
// 	py->Draw();

    postprocess(c2,Form("TPCdEdx%s",status),rWrite,rPerformance,system);

    // TPC Nsigma
    TH2D* TPCNsigma =(TH2D*)f->Get(Form("TPCNSigmacut%s1%stpcM%i",status,system,0));

    // int minMultBin = 0;
    // int maxMultBin = 2;
    double EvMultall = 0;

    for(int i = minMultBin; i<maxMultBin; i++) {
        //all
        TH2D* TPCNsigmaN =(TH2D*)f->Get(Form("TPCNSigmacut%s1%stpcM%i",status,system,i));
        TPCNsigma->Add(TPCNsigmaN);
        //delete hEvMult;
    }

    TCanvas *c3 = new TCanvas("TPC Nsigma", "TPC Nsigma");
    c3->SetGridx();
    c3->SetGridy();
    c3->SetFillColor(10);
    c3->SetRightMargin(1.7);
    c3->SetLogz();

    TPCNsigma->GetXaxis()->SetTitle("#it{p}_{T} (GeV/#it{c})");
    TPCNsigma->GetXaxis()->SetRangeUser(0.0,5.0);
    TPCNsigma->GetYaxis()->SetTitle("number of sigmas");
    TPCNsigma->GetZaxis()->SetLabelSize(0.03);

    TPCNsigma->Draw("colz");

    postprocess(c3,Form("TPCNsigma%s",status),rWrite,rPerformance,system);

    // TOF Nsigma
    TH2D* TOFNsigma =(TH2D*)f->Get(Form("TOFNSigmacut%s1%stpcM%i",status,system,0));

    // int minMultBin = 1;
    // int maxMultBin = 1;
    double EvMultall = 0;

    for(int i = minMultBin; i<maxMultBin; i++) {
        //all
        TH2D* TOFNsigmaN =(TH2D*)f->Get(Form("TOFNSigmacut%s1%stpcM%i",status,system,i));
        TOFNsigma->Add(TOFNsigmaN);
        //delete hEvMult;
    }

    TCanvas *c4 = new TCanvas("TOF Nsigma", "TOF Nsigma");
    c4->SetGridx();
    c4->SetGridy();
    c4->SetFillColor(10);
    c4->SetRightMargin(1.7);
    c4->SetLogz();

    TOFNsigma->GetXaxis()->SetTitle("#it{p}_{T} (GeV/#it{c})");
    TOFNsigma->GetXaxis()->SetRangeUser(0.0,5.0);
    TOFNsigma->GetYaxis()->SetTitle("number of sigmas from TOF");
    TOFNsigma->GetZaxis()->SetLabelSize(0.03);
    TOFNsigma->Draw("colz");

    postprocess(c4,Form("TOFNsigma%s",status),rWrite,rPerformance,system);

    // TOF time
    TH2D* TOFTime =(TH2D*)f->Get(Form("TOFTimecut%s1%stpcM%i",status,system,0));

    // int minMultBin = 1;
    // int maxMultBin = 1;
    double EvMultall = 0;

    for(int i = minMultBin; i<maxMultBin; i++) {
        //all
        TH2D* TOFTimeN =(TH2D*)f->Get(Form("TOFTimecut%s1%stpcM%i",status,system,i));
        TOFTime->Add(TOFTimeN);
        //delete hEvMult;
    }

    TCanvas *c5 = new TCanvas("TOF Time", "TOF Time");
    c5->SetGridx();
    c5->SetGridy();
    c5->SetFillColor(10);
    c5->SetRightMargin(1.7);
    c5->SetLogz();

    TOFTime->GetXaxis()->SetTitle("#it{p}_{T} (GeV/#it{c})");
    TOFTime->GetYaxis()->SetTitle("GetTOFsignal - GetIntegratedTimes");
    TOFTime->GetYaxis()->SetTitleOffset(1.3);
    TOFTime->GetXaxis()->SetRangeUser(0,5);
    TOFTime->GetYaxis()->SetRangeUser(-7000,7000);
    //  TOFTime->GetZaxis()->SetLabelSize(0.03);
    TOFTime->Draw("colz");

    postprocess(c5,Form("TOFTime%s",status),rWrite,rPerformance,system);


    // TPC & TOF Nsigma
    TH2D* TPCTOFNsigma =(TH2D*)f->Get(Form("TPCTOFNSigmacut%s1%stpcM%i",status,system,0));

    int minMultBin = 1;
    int maxMultBin = 1;
    double EvMultall = 0;

    for(int i = minMultBin; i<maxMultBin; i++) {
        //all
        TH2D* TPCTOFNsigmaN =(TH2D*)f->Get(Form("TPCTOFNSigmacut%s1%stpcM%i",status,system,i));
        TOFNsigma->Add(TOFNsigmaN);
        //delete hEvMult;
    }

    TCanvas *c6 = new TCanvas("TOF Nsigma", "TOF Nsigma");
    c6->SetGridx();
    c6->SetGridy();
    c6->SetFillColor(10);
    c6->SetRightMargin(1.7);
    c6->SetLogz();

    TPCTOFNsigma->GetXaxis()->SetTitle("#it{p}_{T} (GeV/#it{c})");
    TPCTOFNsigma->GetXaxis()->SetRangeUser(0.0,5.0);
    TPCTOFNsigma->GetYaxis()->SetTitle("#sqrt{#frac{n#sigma_{TPC} + n#sigma_{TOF}}{2}}");
    TPCTOFNsigma->GetZaxis()->SetLabelSize(0.03);
    TPCTOFNsigma->Draw("colz");

    postprocess(c6,Form("TPCTOFNsigma%s",status),rWrite,rPerformance,system);

}
コード例 #3
0
ファイル: processors.cpp プロジェクト: soniafp/Judith_CERN
void residualAlignment(TH2D* residualX, TH2D* residualY, double& offsetX,
                       double& offsetY, double& rotation,
                       double relaxation, bool display)
{
  assert(residualX && residualY && "Processors: can't perform residual alignment without histograms");

  rotation = 0;
  offsetX = 0;
  offsetY = 0;
  double angleWeights = 0;
  double fitChi2 = 0;

  for (int axis = 0; axis < 2; axis++)
  {
    TH2D* hist = 0;
    if (axis) hist = residualX;
    else      hist = residualY;

    // Project the histogram and fit with a gaussian to center the sensor
    TH1D* project = hist->ProjectionX("ResidualProjetion", 1, hist->GetNbinsY());
    project->SetDirectory(0);

    double sigma = project->GetBinWidth(1);
    double mean = 0;
    fitGaussian(project, mean, sigma, false);

    if (axis) offsetX = mean;
    else      offsetY = mean;

    delete project;

    std::vector<double> ptsX;
    std::vector<double> ptsY;
    std::vector<double> ptsErr;

    const unsigned int numSlices = hist->GetNbinsY();

    for (Int_t row = 1; row <= (int)numSlices; row++)
    {
      TH1D* slice = hist->ProjectionX("ResidualSlice", row, row);
      slice->SetDirectory(0);

      double mean = 0;
      double sigma = 0;
      double factor = 0;
      double background = 0;

      if (slice->Integral() < 1) { delete slice; continue; }
      fitGaussian(slice, mean, sigma, factor, background, false);

      const double sliceMin = slice->GetBinCenter(1);
      const double sliceMax = slice->GetBinCenter(slice->GetNbinsX());
      delete slice;

      // Quality assurance

      // Sigma is contained in the slice's range
      if (sigma > (sliceMax - sliceMin)) continue;
      // Mean is contained in the slice's range
      if (mean > sliceMax || mean < sliceMin) continue;
      // Peak is contains sufficient events
      if (factor < 100) continue;
      // Sufficient signal to noise ratio
      if (factor / background < 10) continue;

      // Get the total number of events in the gaussian 1 sigma
      Int_t sigRangeLow = hist->FindBin(mean - sigma);
      Int_t sigRangeHigh = hist->FindBin(mean + sigma);

      double sigRangeTotal = 0;
      for (Int_t bin = sigRangeLow; bin <= sigRangeHigh; bin++)
        sigRangeTotal += hist->GetBinContent(bin);

      // 2 * 1 sigma integral shoudl give ~ area under gaussian
      sigma /= sqrt(2 * sigRangeTotal);

      ptsX.push_back(hist->GetYaxis()->GetBinCenter(row));
      ptsY.push_back(mean);
      ptsErr.push_back(sigma);
    }

    if (ptsX.size() < 3) continue;

    std::vector<double> yvals = ptsY;
    std::sort(yvals.begin(), yvals.end());
    const double median = yvals[yvals.size()/2];
    double avgDeviation = 0;
    for (unsigned int i = 0; i < yvals.size(); i++)
      avgDeviation += fabs(yvals[i] - median);
    avgDeviation /= (double)yvals.size();

    std::vector<double> ptsXGood;
    std::vector<double> ptsYGood;
    std::vector<double> ptsErrGood;

    for (unsigned int i = 0; i < ptsX.size(); i++)
    {
      if (fabs(ptsY[i] - median) > 1.5*avgDeviation) continue;
      ptsXGood.push_back(ptsX[i]);
      ptsYGood.push_back(ptsY[i]);
      ptsErrGood.push_back(ptsErr[i]);
    }

    if (ptsXGood.size() < 3) continue;

    TGraphErrors* graph = new TGraphErrors(ptsXGood.size(),
                                           &(ptsXGood.at(0)),
                                           &(ptsYGood.at(0)), 0,
                                           &(ptsErrGood.at(0)));

    TF1* fitFunc = new TF1("f1", "1 ++ x");
    TF1* result = 0;

    graph->Fit(fitFunc, "Q0E").Get();
    result = graph->GetFunction(fitFunc->GetName());

    // Weight the angle by the slope uncertainty and the inverse of the chi2 normalized
    double weight = result->GetParError(1);
    const double chi2 = result->GetChisquare() / (double)result->GetNDF();
    fitChi2 += chi2;
    weight *= chi2;
    if (weight > 10 * DBL_MIN) weight = 1.0 / weight;
    else weight = 1.0;

    if (axis)
    {
      rotation -= weight * atan(result->GetParameter(1));
      offsetX = result->GetParameter(0);
    }
    else
    {
      rotation += weight * atan(result->GetParameter(1));
      offsetY = result->GetParameter(0);
    }

    angleWeights += weight;

    if (display)
    {
      TCanvas* can = new TCanvas("ResidualAlignment", "Residual Alignment", 900, 600);
      can->Divide(2);
      can->cd(1);
      hist->Draw("COLZ");
      can->cd(2);
      result->SetLineColor(46);
      result->SetLineWidth(2);
      graph->Draw("ap");
      result->Draw("SAME");
      can->Update();
      can->WaitPrimitive();
    }

    delete fitFunc;
    delete graph;
  }

  if (angleWeights > 10 * DBL_MIN)
    rotation /= angleWeights;
  std::cout << "relaxation: " << relaxation << std::endl;
  rotation *= relaxation;
  offsetX *= relaxation;
  offsetY *= relaxation;
}
コード例 #4
0
void Factorization_eta_vn()
{
  const int nfiles = 16;
  TString filename[nfiles];

  double v2HF = 7.26962328031520721e-02; 

  filename[0] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg033_ptassallweight_etaass45_eff0_v24.root");
  filename[1] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg033_ptassallweight_etaass45_eff0_v24.root");
  filename[2] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg033_ptassallweight_etaass45_eff0_v24.root");
  filename[3] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg033_ptassallweight_etaass45_eff0_v24.root");
  filename[4] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[5] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg033_ptassallweight_etaass45_eff0_v24.root");
  filename[6] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg033_ptassallweight_etaass45_eff0_v24.root");
  filename[7] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg033_ptassallweight_etaass45_eff1_v24.root");

  filename[8] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg033_ptassallweight_etaass34_eff0_v24.root");
  filename[9] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg033_ptassallweight_etaass34_eff0_v24.root");
  filename[10] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg033_ptassallweight_etaass34_eff0_v24.root");
  filename[11] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg033_ptassallweight_etaass34_eff0_v24.root");
  filename[12] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg033_ptassallweight_etaass34_eff0_v24.root");
  filename[13] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg033_ptassallweight_etaass34_eff0_v24.root");
  filename[14] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg033_ptassallweight_etaass34_eff0_v24.root");
  filename[15] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg033_ptassallweight_etaass34_eff0_v24.root");
/*
  filename[8] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[9] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[10] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[11] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[12] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[13] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[14] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[15] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg053_ptassallweight_etaass45_eff0_v18.root");
*/
  const int ntrgbins = 20;
  const int ntrgbins1 = ntrgbins;
  const int ntrgbins2 = ntrgbins/2;
  TGraphErrors* gr_v2[nfiles][6];
  TGraphErrors* gr[nfiles][6];
  TGraphErrors* gr0[nfiles][6];
  TGraphErrors* gr1[nfiles][6];
  TGraphErrors* gr_ratio[nfiles][6];
  TGraph* gr_band[nfiles][6];
  TGraph* gr1_band[nfiles][6];
  TF1* fit[nfiles][6];
  TF1* fit_aver[nfiles][6];
  TF1* fit1_aver[nfiles][6];
  double slope[6][nfiles];
  double slope_err[6][nfiles];
  double slope1[6][nfiles];
  double slope1_err[6][nfiles];
  double eta[ntrgbins2] = {0.12,0.36,0.6,0.84,1.08,1.32,1.56,1.8,2.04,2.28};
//  double eta[ntrgbins2] = {0.1,0.3,0.5,0.7,0.9,1.1,1.3,1.5,1.7,1.9,2.1,2.3};  
//  double eta[ntrgbins2] = {0.15,0.45,0.75,1.05,1.35,1.65,1.95,2.25};
//  double eta[ntrgbins2] = {0.2,0.6,1.0,1.4,1.8,2.2};
  double eta_err[ntrgbins2] = {0.0};
  Color_t color[6] = {1,kBlue, kBlue, kBlue,1,1};

  TFile* fdiff[nfiles];
for(int jj=0;jj<nfiles;jj++)
{
  fdiff[jj] = new TFile(filename[jj].Data());

  TH2D* hsignal[ntrgbins];
  TH2D* hbackground[ntrgbins];
  TH2D* hsignal0[ntrgbins];
  TH2D* hbackground0[ntrgbins];
  TH2D* hsignal1[ntrgbins];
  TH2D* hbackground1[ntrgbins];
  TH1D* hsignal_1D[ntrgbins][6];
  TH1D* hbackground_1D[ntrgbins][6]; 
  TH1D* hsignal0_1D[ntrgbins][6];
  TH1D* hbackground0_1D[ntrgbins][6];
  TH1D* hsignal1_1D[ntrgbins][6];
  TH1D* hbackground1_1D[ntrgbins][6];

  double Vn[ntrgbins1][6];
  double VnError[ntrgbins1][6];
  double rn[ntrgbins1];
  double rn_err[ntrgbins1];
  double Vn0[ntrgbins1][6];
  double Vn0Error[ntrgbins1][6];
  double rn0[ntrgbins2];
  double rn0_err[ntrgbins2];
  double Vn1[ntrgbins1][6];
  double Vn1Error[ntrgbins1][6];
  double rn1[ntrgbins2];
  double rn1_err[ntrgbins2];
  double rn_ratio[ntrgbins2];
  double rn_ratio_err[ntrgbins2];

  for(int i=0;i<ntrgbins;i++)
  {
    hsignal0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfp/signalcosn_trg%d",i));
    hbackground0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfp/backgroundcosn_trg%d",i));
    hsignal1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfm/signalcosn_trg%d",i));
    hbackground1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfm/backgroundcosn_trg%d",i));
    hsignal[i] = (TH2D*)hsignal0[i]->Clone(Form("signalcosn_trg%d",i));
    hbackground[i] = (TH2D*)hbackground0[i]->Clone(Form("backgroundcosn_trg%d",i));
    hsignal[i]->Add(hsignal1[i]);
    hbackground[i]->Add(hbackground1[i]);

    for(int nbin=1;nbin<4;nbin++)
    {
      hsignal_1D[i][nbin] = (TH1D*)hsignal[i]->ProjectionX(Form("signal_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hsignal0_1D[i][nbin] = (TH1D*)hsignal0[i]->ProjectionX(Form("signal0_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hsignal1_1D[i][nbin] = (TH1D*)hsignal1[i]->ProjectionX(Form("signal1_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground_1D[i][nbin] = (TH1D*)hbackground[i]->ProjectionX(Form("background_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground0_1D[i][nbin] = (TH1D*)hbackground0[i]->ProjectionX(Form("background0_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground1_1D[i][nbin] = (TH1D*)hbackground1[i]->ProjectionX(Form("background1_1D_trg%d_%d",i,nbin),nbin,nbin,"e");

      Vn[i][nbin]=hsignal_1D[i][nbin]->GetMean()-hbackground_1D[i][nbin]->GetMean();
      VnError[i][nbin]=sqrt(hsignal_1D[i][nbin]->GetMeanError()*hsignal_1D[i][nbin]->GetMeanError()+hbackground_1D[i][nbin]->GetMeanError()*hbackground_1D[i][nbin]->GetMeanError());
      Vn0[i][nbin]=hsignal0_1D[i][nbin]->GetMean()-hbackground0_1D[i][nbin]->GetMean();
      Vn0Error[i][nbin]=sqrt(hsignal0_1D[i][nbin]->GetMeanError()*hsignal0_1D[i][nbin]->GetMeanError()+hbackground0_1D[i][nbin]->GetMeanError()*hbackground0_1D[i][nbin]->GetMeanError());
      Vn1[i][nbin]=hsignal1_1D[i][nbin]->GetMean()-hbackground1_1D[i][nbin]->GetMean();
      Vn1Error[i][nbin]=sqrt(hsignal1_1D[i][nbin]->GetMeanError()*hsignal1_1D[i][nbin]->GetMeanError()+hbackground1_1D[i][nbin]->GetMeanError()*hbackground1_1D[i][nbin]->GetMeanError());

      Vn[i][nbin]=Vn[i][nbin]/v2HF;
      VnError[i][nbin]=VnError[i][nbin]/v2HF;

if(jj==7 && nbin==1) cout<<"pos nbin="<<nbin<<" i="<<i<<" "<<hsignal0_1D[i][nbin]->GetMean()<<" "<<hbackground0_1D[i][nbin]->GetMean()<<" "<<Vn0[i][nbin]<<endl;
if(jj==7 && nbin==1) cout<<"neg nbin="<<nbin<<" i="<<i<<" "<<hsignal1_1D[i][nbin]->GetMean()<<" "<<hbackground1_1D[i][nbin]->GetMean()<<" "<<Vn1[i][nbin]<<endl;

      delete hsignal_1D[i][nbin];
      delete hsignal0_1D[i][nbin];
      delete hsignal1_1D[i][nbin];
      delete hbackground_1D[i][nbin];
      delete hbackground0_1D[i][nbin];
      delete hbackground1_1D[i][nbin];
    }
    delete hsignal0[i];
    delete hsignal1[i];
    delete hsignal[i];
    delete hbackground0[i];
    delete hbackground1[i];
    delete hbackground[i];
  }

  for(int nbin=1;nbin<4;nbin++)
  {
    for(int i=0;i<ntrgbins1;i++)
    {
      rn[i]=Vn[i][nbin];
      rn_err[i]=VnError[i][nbin];
    }

    gr_v2[jj][nbin] = new TGraphErrors(ntrgbins1,eta,rn,eta_err,rn_err);
    gr_v2[jj][nbin]->SetMarkerColor(color[nbin]);
  }
}

  TCanvas* c = new TCanvas("c","c",900,500);
  makeMultiPanelCanvas(c,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmp = new TH2D("htmp",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-2.4,2.4,100,0.0,0.2);
  fixedFontHist(htmp,1.8,2.2);
  htmp->GetXaxis()->CenterTitle();
  htmp->GetYaxis()->CenterTitle();
  htmp->GetYaxis()->SetTitleSize(htmp->GetYaxis()->GetTitleSize()*1.2);
  htmp->GetXaxis()->SetTitleSize(htmp->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<8;jj++)
  {
    c->cd(jj+1);
    htmp->Draw();
    gr_v2[jj][1]->SetMarkerStyle(21);
    gr_v2[jj][1]->Draw("Psame");
  }

return;
  TString histtitle[8] = {"0-0.2%","0-5%","5-10%","10-20%","20-30%","30-40%","40-50%","50-60%"};
  TLine* ll = new TLine(0,1.,5.0,1.);
  TCanvas* c = new TCanvas("c","c",900,500);
  makeMultiPanelCanvas(c,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmp = new TH2D("htmp",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.1,2.23,100,0.801,1.06);
  fixedFontHist(htmp,1.8,2.2);
  htmp->GetXaxis()->CenterTitle();
  htmp->GetYaxis()->CenterTitle();
  htmp->GetYaxis()->SetTitleSize(htmp->GetYaxis()->GetTitleSize()*1.2);
  htmp->GetXaxis()->SetTitleSize(htmp->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<8;jj++)
  {
    c->cd(jj+1);
    htmp->Draw();
    ll->Draw("Lsame");
    gr[jj][1]->SetMarkerStyle(21);
    gr[jj][1]->Draw("Psame");
    fit[jj][1]->Draw("Lsame");

    gr[jj+8][1]->SetMarkerStyle(25);
//    fit[jj+8][1]->SetLineStyle(5);
    gr[jj+8][1]->Draw("Psame");
//    fit[jj+8][1]->Draw("Lsame");
  }

  TLatex* latex2 = new TLatex();
  latex2->SetNDC();
  latex2->SetTextSize(1.5*latex2->GetTextSize());
  c->cd(1);
  latex2->DrawLatex(0.26,0.05,histtitle[0]);
  latex2->DrawLatex(0.24,0.865,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  c->cd(2);
  latex2->DrawLatex(0.08,0.05,histtitle[1]);
  latex2->DrawLatex(0.07,0.3,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex2->DrawLatex(0.07,0.18,"p_{T}^{b} > 0 GeV/c");
  c->cd(4);
  latex2->DrawLatex(0.08,0.05,histtitle[3]);
  c->cd(3);
  latex2->DrawLatex(0.08,0.05,histtitle[2]);
  c->cd(8);
  latex2->DrawLatex(0.08,0.24,histtitle[7]);
  c->cd(7);
  latex2->DrawLatex(0.08,0.24,histtitle[6]);
  c->cd(6);
  latex2->SetTextSize(0.96*latex2->GetTextSize());
  latex2->DrawLatex(0.08,0.24,histtitle[5]);
  c->cd(5);
  latex2->SetTextSize(0.85*latex2->GetTextSize());
  latex2->DrawLatex(0.26,0.24,histtitle[4]);

  TLegend* legend2 = new TLegend(0.24,0.14,0.51,0.38);
  legend2->SetFillStyle(0);
  legend2->AddEntry(gr[0][1],"4<#eta^{b}<5","P");
  legend2->AddEntry(gr[8][1],"3<#eta^{b}<4","P");
  c->cd(1);
  legend2->Draw("same");

  TCanvas* ccaa = new TCanvas("ccaa","ccaa",900,500);
  makeMultiPanelCanvas(ccaa,4,2,0.01,0.0,0.2,0.2,0.02);
  for(int jj=0;jj<8;jj++)
  {
    ccaa->cd(jj+1);
    htmp->Draw();
    ll->Draw("Lsame");
    gr0[jj][1]->SetMarkerStyle(21);
    gr0[jj][1]->Draw("Psame");
    gr1[jj][1]->SetMarkerStyle(25);
    gr1[jj][1]->Draw("Psame");
  }

  TCanvas* ccbb = new TCanvas("ccbb","ccbb",900,500);
  makeMultiPanelCanvas(ccbb,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmpaa = new TH2D("htmpaa",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.1,2.23,100,0.97,1.03);
  for(int jj=0;jj<8;jj++)
  {
    ccbb->cd(jj+1);
    htmpaa->Draw();
    ll->Draw("Lsame");
    gr_ratio[jj][1]->SetMarkerStyle(21);
    gr_ratio[jj][1]->Draw("Psame");
  }

  TCanvas* cc = new TCanvas("cc","cc",900,500);
  makeMultiPanelCanvas(cc,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmp1 = new TH2D("htmp1",";#eta^{a};r_{3}(#eta^{a},#eta^{b})",100,-0.1,2.23,100,0.801,1.06);
  fixedFontHist(htmp1,1.8,2.2);
  htmp1->GetXaxis()->CenterTitle();
  htmp1->GetYaxis()->CenterTitle();
  htmp1->GetYaxis()->SetTitleSize(htmp1->GetYaxis()->GetTitleSize()*1.2);
  htmp1->GetXaxis()->SetTitleSize(htmp1->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<8;jj++)
  {
    cc->cd(jj+1);
    htmp1->Draw();
    ll->Draw("Lsame");
    gr[jj][2]->SetMarkerStyle(21);
    gr[jj][2]->Draw("Psame");
    fit[jj][2]->Draw("Lsame");

    gr[jj+8][2]->SetMarkerStyle(25);
//    fit[jj+8][2]->SetLineStyle(5);
    gr[jj+8][2]->Draw("Psame");
//    fit[jj+8][2]->Draw("Lsame");
  }

  TLatex* latex3 = new TLatex();
  latex3->SetNDC();
  latex3->SetTextSize(1.5*latex3->GetTextSize());
  cc->cd(1);
  latex3->DrawLatex(0.26,0.05,histtitle[0]);
  latex3->DrawLatex(0.24,0.865,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  cc->cd(2);
  latex3->DrawLatex(0.08,0.05,histtitle[1]);
  latex3->DrawLatex(0.07,0.28,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex3->DrawLatex(0.07,0.18,"p_{T}^{b} > 0 GeV/c");
  cc->cd(4);
  latex3->DrawLatex(0.08,0.05,histtitle[3]);
  cc->cd(3);
  latex3->DrawLatex(0.08,0.05,histtitle[2]);
  cc->cd(8);
  latex3->DrawLatex(0.08,0.24,histtitle[7]);
  cc->cd(7);
  latex3->DrawLatex(0.08,0.24,histtitle[6]);
  cc->cd(6);
  latex3->SetTextSize(0.96*latex3->GetTextSize());
  latex3->DrawLatex(0.08,0.24,histtitle[5]);
  cc->cd(5);
  latex3->SetTextSize(0.85*latex3->GetTextSize());
  latex3->DrawLatex(0.26,0.24,histtitle[4]);

  TLegend* legend3 = new TLegend(0.24,0.14,0.51,0.38);
  legend3->SetFillStyle(0);
  legend3->AddEntry(gr[0][1],"4<#eta^{b}<5","P");
  legend3->AddEntry(gr[8][1],"3<#eta^{b}<4","P");
  cc->cd(1);
  legend3->Draw("same");
/*
  TCanvas* ccc = new TCanvas("ccc","ccc",900,500);
  makeMultiPanelCanvas(ccc,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmp2 = new TH2D("htmp2",";#eta^{a};r_{4}(#eta^{a},#eta^{b})",100,-0.1,2.23,100,0.801,1.06);
  fixedFontHist(htmp2,1.8,2.2);
  htmp2->GetXaxis()->CenterTitle();
  htmp2->GetYaxis()->CenterTitle();
  htmp2->GetYaxis()->SetTitleSize(htmp2->GetYaxis()->GetTitleSize()*1.2);
  htmp2->GetXaxis()->SetTitleSize(htmp2->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<8;jj++)
  {
    ccc->cd(jj+1);
    htmp2->Draw();
    ll->Draw("Lsame");
    gr[jj][3]->Draw("Psame");
    fit[jj][3]->Draw("Lsame");

    gr[jj+8][3]->Set_arkerStyle(25);
    fit[jj+8][3]->SetLineStyle(5);
    gr[jj+8][3]->Draw("Psame");
    fit[jj+8][3]->Draw("Lsame");
  }
*/
  TCanvas* c1 = new TCanvas("c1","c1",500,500);
  TH2D* htmp2 = new TH2D("htmp2",";Centrality;C",100,0,1.0,100,0.0,0.06);
  htmp2->Draw();
  htmp2->GetXaxis()->CenterTitle();
  htmp2->GetYaxis()->CenterTitle();
  gr_slope[1]->SetMarkerColor(1);
  gr_slope[2]->SetMarkerColor(1);
  gr_slope[1]->SetMarkerStyle(21);
  gr_slope[2]->SetMarkerStyle(22);
  gr_slope[1]->Draw("PESAME");
  gr_slope[2]->Draw("PESAME");
  gr1_slope[1]->SetMarkerColor(1);
  gr1_slope[2]->SetMarkerColor(1);
  gr1_slope[1]->SetMarkerStyle(25);
  gr1_slope[2]->SetMarkerStyle(26);
  gr1_slope[1]->Draw("PESAME");
  gr1_slope[2]->Draw("PESAME");

  TFile* f_slope_out = new TFile("gr_slope_v2v3.root","recreate");
  gr_slope[1]->Write();
  gr_slope[2]->Write();
  gr1_slope[1]->Write();
  gr1_slope[2]->Write();
  f_slope_out->Close();
return;
  SaveCanvas(c,"HI/FactBreak","epetadeco_HI_r2");
  SaveCanvas(cc,"HI/FactBreak","epetadeco_HI_r3");
  SaveCanvas(ccaa,"HI/FactBreak","epetadeco_HI_r2ratio");
//  SaveCanvas(c1,"HI/FactBreak","epetadeco_HI_C");
//  SaveCanvas(cc2,"HI/FactBreak","epetadeco_HI_cos");
}
コード例 #5
0
ファイル: MatrixSum.cpp プロジェクト: MirkoPitt/HGI
int main(int argc, char * argv[])
{
    int ChooseCamera;
    cout << "Set the camera you want to use: \n 0 -> Integrated one \n 1 -> USB one " << endl;
    cin >> ChooseCamera;
    VideoCapture cam(ChooseCamera); // with 1 -> choose the webcam if it's attached, otherwise choose the integrated one  
    
    if(!cam.isOpened()){  // Controllo di apertura della webcam
        cout << "Impossibile aprire lo stream della webcam. Il programma verrà terminato." << endl;
        return -1;
	}   
        
    //~ double MyWidth = 640; // Limiti 1280x720 copiati da Ave. Sono quelli propri della videocamera come mostrati da Cheese.
    //~ double MyHeight = 480;
    double MyWidth = 1280; // Limiti 1280x720 copiati da Ave. Sono quelli propri della videocamera come mostrati da Cheese.
    double MyHeight = 720;
    cam.set(CV_CAP_PROP_FRAME_WIDTH, MyWidth);  //Set frame width and height
    cam.set(CV_CAP_PROP_FRAME_HEIGHT, MyHeight);
    //~ system("v4l2-ctl --set-fmt-video=width=1280,height=720,pixelformat=1 -d /dev/video1"); //Set frame width and height through a system call
	cam.set(CV_CAP_PROP_FPS, 30); //Set the webcam frame rate
	
	// NB: per poter modificare i valori della frame Width and Height è necessario compilare le librerie OPENCV con
	// le librerie [ v4l2ucp, v4l-utils and libv4l-dev ] già installate nel computer 
	// (vedi: http://stackoverflow.com/questions/16287488/runtime-opencv-highgui-error-highgui-error-v4l-v4l2-vidioc-s-crop-opencv-c)
	
	
	if (ChooseCamera==1) {
		//~ system("v4l2-ctl --set-ctrl exposure_auto=1 -d /dev/video1"); 			//Alternative method to change v4l2 controls
		//~ system("v4l2-ctl --set-ctrl exposure_absolute=5 -d /dev/video1");
		system("v4l2-ctl -c exposure_auto=1 -d /dev/video1");				//system call to adjust the balance variables, sono necessarie le librerie v4l2
		system("v4l2-ctl -c exposure_absolute=5 -d /dev/video1");			//Le chiamate e le impostazioni le ho copiate da Ave, sperando che siano quelle giust
		// in general v4l2-ctl -c command -> comando per cambiare le immpostazioni, lista delle impostazioni possibili le leggi 
		// da bash dando $v4l2-ctl --list-ctrls 
		// documentazione completa delle v4l2 la trovi @ http://ivtvdriver.org/index.php/V4l2-ctl
		cout << "Sys call for camera #" << ChooseCamera << " done!\n";
		//system("say 'settings done baby'");
	}

	if (ChooseCamera==0) {
		//~ //Put here commands for set the integrated camera commands. Generally useless
		//~ system("v4l2-ctl -c exposure_auto=1 -d /dev/video0");				//system call to adjust the balance variables, sono necessarie le librerie v4l2
		//~ system("v4l2-ctl -c exposure_absolute=5 -d /dev/video0");			//Le chiamate e le impostazioni le ho copiate da Ave, sperando che siano quelle giust
		cout << "Sys call for camera #" << ChooseCamera << " done!\n";
	}


	//Controllo dimensionamento immagine acquisita:
	double RealWidth = cam.get(CV_CAP_PROP_FRAME_WIDTH); 				//This function get the Width (in pixels) of the output.
	double RealHeight = cam.get(CV_CAP_PROP_FRAME_HEIGHT);				//This function get the Height (in pixels) of the output.
	cout << " Setted Width: " << MyWidth << "		|| Real Width: " << RealWidth  << endl;
	cout << " Setted Height: " << MyHeight << "		|| Real Height: " << RealHeight  << endl;
	cout << "\n";
	
	
	//Creazione Root object used for analysis
	TApplication myapp("myapp", &argc,argv);
	
	//ROOT Canvas for the current image
	//~ TCanvas * C = new TCanvas ("C","",710,400);
	//~ TH2D * CurrentHisto = new TH2D ("h2d", " ", (int)MyWidth, -(MyWidth/2)+1 , (MyWidth/2), (int)MyHeight, -(MyHeight/2)+1 , (MyHeight/2) );
	//Canvas for the total image 
	TCanvas * C2 = new TCanvas ("C2","",710,400);
	TH2D * TotalHisto = new TH2D ("TotalHisto", " ", (int)MyWidth, -(MyWidth/2)+1 , (MyWidth/2), (int)MyHeight, -(MyHeight/2)+1 , (MyHeight/2) );
	//~ gStyle->SetPalette(1);
	TotalHisto->Draw("CONT");
	
	//~ double RootTempMatrix [int(MyWidth)][int(MyHeight)]; //declaration of a two dimansional array
	//~ int meanX;
	//~ int meanY;
	//~ double VarX;
	//~ double VarY;
	//~ double IntIntegral; 
	double alfa= 0.79; //IntensityCalibration


    namedWindow("Live_Video",WINDOW_NORMAL); 			//Crea una finestra di cui posso modificare le dimensioni (openCV method)
    resizeWindow("Live_Video", RealWidth, RealHeight); 	//Imposta la dimensione iniziale uguale alla dimensione del frame
    int k=0;
    float DisplayHeight = RealHeight / 2 ;
	float DisplayWidth = RealWidth / 2 ;
    Mat ImageBGR(Size(RealWidth, RealHeight), CV_16UC3);
    
    Vec3b intensity;
	//Definisco due array sui quali metto l'immagine istantanea e l'immagine totale
    double * MatIn = new double [int( MyWidth * MyHeight)];
    double * MatSum = new double [int( MyWidth * MyHeight)];
    
    for (int m=0; m < (MyWidth * MyHeight); m++){
		MatSum[m]=0.0;
		}
	
	for(int i=0; i< int(MyWidth); i++){			//Piazzo dentro i valori
		for(int j=0; j< int(MyHeight); j++){	
			TotalHisto->SetBinContent((MyWidth-i+1),(MyHeight-j+1),0);
		}
	}
        
	int IntensityGreen;
	double temp = 0;
    
    ofstream ofile;
    ofile.open("MatrixSumFondo.txt",ios::out);
    
    
		for(;;)
		{
			k++;
			Mat frame;	//non capisco la logica di rinizializzare il frame ad ogni ciclo...ma nel tutorial officiale opencv è così.. Lascio così che sia mai che vi potrebbero essere problemi con il buffer altrimenti
			cam >> frame; // get a new frame from camera
			imshow("Live_Video", frame);
			
			//MouseCallBack Function to get pixel intensity
			//For very good explaination and examples go at -> http://opencvexamples.blogspot.com/2014/01/detect-mouse-clicks-and-moves-on-image.html#.VWVpIs17h5Q
			setMouseCallback("Live_Video", mouseEvent, &frame);
			
			if( (k%10)==0){		//elabora un frame ogni 50 
				
				cam.retrieve(ImageBGR, 0); //Salva in una matrice la figura della webcam
				//~ cout << "\n--------    Inizio filling    --------" << endl;
				for(int i=0; i< int(MyWidth); i++){			//Piazzo dentro i valori
					for(int j=0; j< int(MyHeight); j++){	
						intensity = ImageBGR.at<Vec3b>(j, i);
						IntensityGreen = pow(intensity.val[1],(1.0/alfa));
						//cout << IntensityGreen << endl;
						//~ MatIn[Index(i,j,MyWidth)] = IntensityGreen;
						//~ CurrentHisto->SetBinContent((MyWidth-i+1),(MyHeight-j+1),IntensityGreen);
						MatSum[Index(i,j,MyWidth)] += IntensityGreen;
						if( (k%200)==0){
							TotalHisto->SetBinContent((MyWidth-i+1),(MyHeight-j+1),MatSum[Index(i,j,MyWidth)]);
						}
					}
				}
				
				//In questo modo stampo un asterisco ogni 20 immagini che si sommano
				if( (k%200)==0){
					temp = k/10;
					cout << "Numero di immagni sovraimposte: " << temp << endl;
				}				
				//~ 
				//~ if( (k%400)==0){
					//~ cout << "\n" << endl;
				//~ }
				//~ cout << "Fine filling:" << endl;
				
				//~ CurrentHisto->Draw("CONT");
				//~ C-> Update();
				//~ TotalHisto->Draw("CONT");
				C2 -> Modified();
				C2-> Update();

			}
			
			double px,py,pz;
			
			if (k==3000){
				for(int i=0; i< int(MyWidth); i++){
					for(int j=0; j< int(MyHeight); j++){
						pz=TotalHisto->GetBinContent((MyWidth-i+1),(MyHeight-j+1));
						px=MyHeight-j+1;
						py=MyWidth-i+1;
						
						ofile << px << "	" << py << "	" << pz << endl;
						
						}
					ofile << endl;
					}
					
					break;
				
				}
			

			if(waitKey(30) >= 0) break;
		} 
		// the camera will be deinitialized automatically in VideoCapture destructor
		ofile.close();
	myapp.Run();
    return 0;
}
コード例 #6
0
ファイル: DrawKinvarPlot.C プロジェクト: c-dilks/spinlong
void DrawKinvarPlot(TString filename="kinvarset/FMSOR_Pt_vs_run.root",
                    TString classname="pi0") {
  TFile * infile = new TFile(filename.Data(),"READ");

  char trig[32];
  char typ[32];
  char tmp[128];
  TString tmpstr = filename;
  tmpstr.ReplaceAll("_"," ");
  TRegexp re("^.*\/");
  tmpstr(re) = "";
  cout << tmpstr << endl;
  sscanf(tmpstr.Data(),"%s %s",trig,typ);
  printf("%s %s\n",trig,typ);

  TString hname = "h2_"+classname;
  TH2D * h = (TH2D*)infile->Get(hname.Data());
  TString gname = "g_"+classname;
  TGraphErrors * g = (TGraphErrors*)infile->Get(gname.Data());
  TString gtname = "gt_"+classname;
  TGraphErrors * gt;
  if(!strcmp(typ,"Pt")) gt = (TGraphErrors*)infile->Get(gtname.Data());
  
  char htitle[256];
  char hnewtitle[512];
  strcpy(htitle,h->GetTitle());
  sprintf(hnewtitle,"%s -- %s triggers",htitle,trig);
  h->SetTitle(hnewtitle);

  h->SetMinimum(0.001);

  if(!strcmp(typ,"Pt")) {
    gt->SetLineWidth(2);
    gt->SetLineColor(kBlack);
  };

  // temporary hack to cut out fluctuations of pt_thresh vs. run to 0
  Double_t xx,yy;
  Int_t gtn = gt->GetN();
  for(int ii=0; ii<gtn; ii++) {
    gt->GetPoint(ii,xx,yy);
    printf("xx=%f yy=%f\n",xx,yy);
    if(yy<0.001) gt->RemovePoint(ii);
  };
   
  // drawing range
  Float_t xmin = h->GetXaxis()->GetXmin();
  Float_t xmax = h->GetXaxis()->GetXmax();
  xmax = 515;
  if(xmax<gtn) { 
    fprintf(stderr,"\nWARNING: xmax < gt->GetN(); graphs will be cut off!\n\n");
  };
  
  TCanvas * c = new TCanvas("c","c",1500,700);
  c->Divide(1,2);
  gStyle->SetOptStat(0);
  for(int x=1; x<=2; x++) c->GetPad(x)->SetGrid(1,1);
  c->cd(1);
  c->GetPad(1)->SetLogz();
  h->GetXaxis()->SetRangeUser(xmin,xmax);
  h->Draw("colz");
  if(!strcmp(typ,"Pt")) gt->Draw("LX");
  c->cd(2);
  g->SetFillColor(kGray);
  printf("%f %f\n",xmin,xmax);
  g->GetXaxis()->SetLimits(xmin,xmax);
  g->GetXaxis()->SetRangeUser(xmin,xmax);
  /*
  g->Draw("A3");
  g->Draw("PLX");
  */
  g->Draw("APLX");
  
  TString outname = filename.ReplaceAll(".root"," "+classname);
  outname = outname+".png";
  c->Print(outname.Data(),"png");
};
コード例 #7
0
ファイル: DaviesCotton.C プロジェクト: ROBAST/ROBAST
void RayTrace(AOpticsManager* manager, TCanvas* can3D)
{
  const int kNdeg = 8;
  TH2D* h2[kNdeg];
  TGraph* graph = new TGraph();
  TCanvas* can = new TCanvas("can", "can", 900, 900);
  TCanvas* can2= new TCanvas("can2", "can2", 900, 900);
  can->Divide(3, 3, 1e-10, 1e-10);

  TH2D* hMirror = new TH2D("hMirror", ";X (mm);Y (mm)", 1000, -7, 7, 1000, -7, 7);

  for(int i = 0; i < kNdeg; i++){

    double deg = i*0.5;
    TGeoTranslation raytr("raytr", -2*kF*TMath::Sin(deg*TMath::DegToRad()), 0, 2*kF*TMath::Cos(deg*TMath::DegToRad()));
    TVector3 dir;
    dir.SetMagThetaPhi(1, TMath::Pi() - deg*TMath::DegToRad(), 0);
    double lambda = 400*nm; // dummy
    ARayArray* array = ARayShooter::Square(lambda, 14*m, 401, 0, &raytr, &dir);

    manager->TraceNonSequential(*array);

    h2[i] = new TH2D("", Form("#it{#theta} = %3.1f#circ;x (mm); y (mm)", deg), 200, -40, 100, 200, -70, 70);
    TH2D tmp("", "", 100, -1e5, 1e5, 100, -1e5, 1e5);

    TObjArray* focused = array->GetFocused();

    for(Int_t j = 0; j <= focused->GetLast(); j++){
      ARay* ray = (ARay*)(*focused)[j];
      Double_t p[4];
      ray->GetLastPoint(p);
      tmp.Fill(p[0], p[1]);

      if (i == 0) {
        int n = ray->FindNodeNumberStartWith("mirror");
        const double* pn = ray->GetPoint(n);
        hMirror->Fill(pn[0]/m, pn[1]/m);
      } // if

      if (i == kNdeg - 1 && gRandom->Uniform() < 0.001) {
        TPolyLine3D* pol = ray->MakePolyLine3D();
        pol->SetLineColor(2);
        can3D->cd();
        pol->Draw();
      } // if
    } // j

    double meanx = tmp.GetMean();

    for(Int_t j = 0; j <= focused->GetLast(); j++){
      ARay* ray = (ARay*)(*focused)[j];
      Double_t p[4];
      ray->GetLastPoint(p);
      h2[i]->Fill((p[0] - meanx)/mm, p[1]/mm);
    } // j

    can->cd(i + 1);
    h2[i]->Draw("colz");

    if(i == 0){
      can2->cd();
      hMirror->Draw("colz");
    } // i

    delete array;
  } // i
}
コード例 #8
0
ファイル: main.cpp プロジェクト: Kuenni/L1Analyzer
int main(int argc, char** argv){
	std::cout << "Starting application" << std::endl;
	TApplication* app = new TApplication("Analyse",&argc,argv);

	//Set plot style for own root design
	PlotStyle* s = new PlotStyle();

	CanvasManager* cManager = new CanvasManager("combinedPlots");

	//#######################
	//# Creating Trees and Analyse objects
	//#######################

	std::vector<AnalysisWrapper*> wrapperVect;

	wrapperVect.push_back(new AnalysisWrapper("deltaPhiGun/DeltaPhiGunPt100dPhi3_0/TrigTestDeltaPhiGun.root","DeltaPhiGunPt100dR3_0",10.,true));
//	wrapperVect.push_back(new AnalysisWrapper("deltaPhiGun/DeltaPhiGunPt100dPhi0_3/TrigTestDeltaPhiGun.root","DeltaPhiGunPt100dR0_3",10.,true));
//	wrapperVect.push_back(new AnalysisWrapper("deltaPhiGun/DeltaPhiGunPt100dPhi0_1/TrigTestDeltaPhiGun.root","DeltaPhiGunPt100dR0_1",10.,true));
//	wrapperVect.push_back(new AnalysisWrapper("deltaPhiGun/DeltaPhiGunPt100dPhi0_05/TrigTestDeltaPhiGun.root","DeltaPhiGunPt100dR0_05",10.,true));
//	wrapperVect.push_back(new AnalysisWrapper("deltaPhiGun/DeltaPhiGunPt100dPhi0_01/TrigTestDeltaPhiGun.root","DeltaPhiGunPt100dR0_01",10.,true));
//	wrapperVect.push_back(new AnalysisWrapper("deltaPhiGun/DeltaPhiGunPt100dPhi0_005/TrigTestDeltaPhiGun.root","DeltaPhiGunPt100dR0_005",10.,true));

	wrapperVect[0]->analyseBti();
	wrapperVect[0]->analyseTraco();
	wrapperVect[0]->analyseGenParticles();
	wrapperVect[0]->savePlots();

	//Create a vector with colors to access during scenario iterations
	std::vector<int> colorVector;
	colorVector.push_back(kBlack);
	colorVector.push_back(kBlue);
	colorVector.push_back(kViolet);
	colorVector.push_back(kRed);
	colorVector.push_back(kOrange);
	colorVector.push_back(kGreen);
	colorVector.push_back(kTeal);
	colorVector.push_back(kCyan - 1);

	//Create a vector with scenarios to access during scenario iterations
	std::vector<TString> legendNameVector;
	legendNameVector.push_back(TString("#Delta#Phi 3.0"));
	legendNameVector.push_back(TString("#Delta#Phi 0.3"));
	legendNameVector.push_back(TString("#Delta#Phi 0.1"));
	legendNameVector.push_back(TString("#Delta#Phi 0.05"));
	legendNameVector.push_back(TString("#Delta#Phi 0.01"));
	legendNameVector.push_back(TString("#Delta#Phi 0.005"));

	std::vector<std::vector<TH1*> > btiScenariosBestCase;
	std::vector<std::vector<TH1*> > btiScenariosHtrg;

	for(unsigned int i = 0 ; i < wrapperVect.size(); i++ ){
		btiScenariosBestCase.push_back(wrapperVect[i]->analyseBtiTrigPerStatAndSlBestCase());
		btiScenariosHtrg.push_back(wrapperVect[i]->analyseBtiTrigPerStatAndSlHtrg());
	}

	TCanvas* btiBestCaseCanvas = cManager->getDividedCanvas(1,1);
	btiBestCaseCanvas->SetName("btiTrigsPerStatAndSlTogetherBestCase");
	TCanvas* btiHtrgCanvas = cManager->getDividedCanvas(1,1);
	btiHtrgCanvas->SetName("btiTrigsPerStatAndSlTogetherHtrg");

	//Get the size of the first vector stored in the scenarios
	for (int i = 0 ; i < btiScenariosBestCase[0].size()/8. ; i++){
		int scenarioCounter = 0;
		TLegend* lBestCase = new TLegend(0.5,.525,0.7,0.9);
		TLegend* lBestCase2 = new TLegend(0.7,.525,0.9,0.9);
		TLegend* lHtrg = new TLegend(0.5,.525,0.7,0.9);
		TLegend* lHtrg2 = new TLegend(0.7,.525,0.9,0.9);

		btiBestCaseCanvas->cd(i+1)->SetLogy();
		//Build the frame
		TString frameName = "BTI Trigger (Best Case) f#ddot{u}r Station ";
		frameName += i+1;
		frameName += ";# BTI Trigger;Relative H#ddot{a}ufigkeit";

		TH2D* frame = new TH2D("frameBtiBestCase",frameName,1,-0.5,10.5,1,0.000001,1);
		frame->SetStats(kFALSE);
		frame->Draw();

		for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = btiScenariosBestCase.begin();
				scenarioIt != btiScenariosBestCase.end() ; scenarioIt++){

			//Loop over the scenarios
			scenarioIt->at(2*i)->SetLineColor(colorVector[scenarioCounter]);
			scenarioIt->at(2*i)->Scale(1/scenarioIt->at(2*i)->Integral());
			scenarioIt->at(2*i)->Draw("same");
			scenarioIt->at(2*i+1)->SetLineColor(colorVector[scenarioCounter]);
			scenarioIt->at(2*i+1)->SetLineStyle(2);
			scenarioIt->at(2*i+1)->Scale(1/scenarioIt->at(2*i+1)->Integral());
			scenarioIt->at(2*i+1)->Draw("same");

			lBestCase->AddEntry(scenarioIt->at(2*i),(legendNameVector[scenarioCounter] + " SL 1").Data());
			lBestCase2->AddEntry(scenarioIt->at(2*i+1),(legendNameVector[scenarioCounter] + " SL 3").Data());

			scenarioCounter++;
		}
		lBestCase->Draw();
		lBestCase2->Draw();

		btiBestCaseCanvas->Update();
		TString plotTitle("BTI Trigger (Best Case) f#ddot{u}r Station ");
		plotTitle += i+1;
		(new PlotTitle(plotTitle.Data()))->Draw();

		scenarioCounter = 0;

		btiHtrgCanvas->cd(i+1)->SetLogy();
		//Build the frame
		frameName = "BTI Trigger (HTRG) f#ddot{u}r Station ";
		frameName += i+1;
		frameName += ";# BTI Trigger;Relative H#ddot{a}ufigkeit";

		frame = new TH2D("frameBtiHtrg",frameName,1,-0.5,25.5,1,0.000001,1);
		frame->SetStats(kFALSE);
		frame->Draw();

		for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = btiScenariosHtrg.begin();
				scenarioIt != btiScenariosHtrg.end() ; scenarioIt++){

			//Loop over the scenarios
			scenarioIt->at(2*i)->SetLineColor(colorVector[scenarioCounter]);
			scenarioIt->at(2*i)->Scale(1/scenarioIt->at(2*i)->Integral());
			scenarioIt->at(2*i)->Draw("same");
			scenarioIt->at(2*i+1)->SetLineColor(colorVector[scenarioCounter]);
			scenarioIt->at(2*i+1)->SetLineStyle(2);
			scenarioIt->at(2*i+1)->Scale(1/scenarioIt->at(2*i+1)->Integral());
			scenarioIt->at(2*i+1)->Draw("same");

			lHtrg->AddEntry(scenarioIt->at(2*i),(legendNameVector[scenarioCounter] + " SL 1").Data());
			lHtrg2->AddEntry(scenarioIt->at(2*i+1),(legendNameVector[scenarioCounter] + " SL 3").Data());

			scenarioCounter++;
		}
		lHtrg->Draw();
		lHtrg2->Draw();

		btiHtrgCanvas->Update();

		plotTitle = "BTI Trigger (HTRG) f#ddot{u}r Station ";
		plotTitle += i+1;
		(new PlotTitle(plotTitle.Data()))->Draw();
	}

	cManager->addCanvas("btiTrigsPerStatAndSlTogetherBestCase",btiBestCaseCanvas);
	cManager->addCanvas("btiTrigsPerStatAndSlTogetherHtrg",btiHtrgCanvas);


	//################################
	//### plot TRACO triggers together
	//################################

	std::vector<std::vector<TH1*> > tracoScenariosBestCase;
	std::vector<std::vector<TH1*> > tracoScenariosHtrg;

	for(unsigned int i = 0 ; i < wrapperVect.size(); i++ ){
		tracoScenariosBestCase.push_back(wrapperVect[i]->analyseTracoTrigPerStationBestCase());
		tracoScenariosHtrg.push_back(wrapperVect[i]->analyseTracoTrigPerStationHtrig());
	}

	TCanvas* tracoBestCaseCanvas = cManager->getDividedCanvas(1,1);
	tracoBestCaseCanvas->SetName("tracoTrigsPerStatTogetherBestCase");
	TCanvas* tracoHtrgCanvas = cManager->getDividedCanvas(1,1);
	tracoHtrgCanvas->SetName("tracoTrigsPerStatTogetherHtrg");

	//Get the size of the first vector stored in the scenarios
	for (int i = 0 ; i < tracoScenariosBestCase[0].size()/4. ; i++){
		int scenarioCounter = 0;
		TLegend* lBestCase = new TLegend(0.75,.45,0.90,0.90);
		TLegend* lHtrg = new TLegend(0.75,.45,0.90,0.90);

		tracoBestCaseCanvas->cd(i+1)->SetLogy();
		//Build the frame
		TString frameName = "TRACO Trigger (Best Case) f#ddot{u}r Station ";
		frameName += i+1;
		frameName += ";# TRACO Trigger;Relative H#ddot{a}ufigkeit";

		TH2D* frame = new TH2D("frameTracoBestCase",frameName,1,-0.5,7.5,1,0.000001,1);
		frame->SetStats(kFALSE);
		frame->Draw();

		for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = tracoScenariosBestCase.begin();
				scenarioIt != tracoScenariosBestCase.end() ; scenarioIt++){

			//Loop over the scenarios
			scenarioIt->at(i)->SetLineColor(colorVector[scenarioCounter]);
			scenarioIt->at(i)->Scale(1/scenarioIt->at(i)->Integral());
			scenarioIt->at(i)->Draw("same");

			lBestCase->AddEntry(scenarioIt->at(i),legendNameVector[scenarioCounter]);

			scenarioCounter++;
		}
		lBestCase->Draw();

		tracoBestCaseCanvas->Update();
		TString plotTitle("TRACO Trigger (Best Case) f#ddot{u}r Station ");
		plotTitle += i+1;
		(new PlotTitle(plotTitle.Data()))->Draw();

		scenarioCounter = 0;
		tracoHtrgCanvas->cd(i+1)->SetLogy();
		//Build the frame
		frameName = "TRACO Trigger (HTRG) f#ddot{u}r Station ";
		frameName += i+1;
		frameName += ";# TRACO Trigger;Relative H#ddot{a}ufigkeit";

		frame = new TH2D("frameTracoHtrg",frameName,1,-0.5,7.5,1,0.000001,1);
		frame->SetStats(kFALSE);
		frame->Draw();
		for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = tracoScenariosHtrg.begin();
				scenarioIt != tracoScenariosHtrg.end() ; scenarioIt++){

			//Loop over the scenarios
			scenarioIt->at(i)->SetLineColor(colorVector[scenarioCounter]);
			scenarioIt->at(i)->Scale(1/scenarioIt->at(i)->Integral());
			scenarioIt->at(i)->Draw("same");

			lHtrg->AddEntry(scenarioIt->at(i),legendNameVector[scenarioCounter]);

			scenarioCounter++;
		}
		lHtrg->Draw();

		tracoHtrgCanvas->Update();
		plotTitle = "TRACO Trigger (HTRG) f#ddot{u}r Station ";
		plotTitle += i+1;
		(new PlotTitle(plotTitle.Data()))->Draw();

	}

	cManager->addCanvas("tracoTrigsPerStatTogetherBestCase",tracoBestCaseCanvas);
	cManager->addCanvas("tracoTrigsPerStatTogetherHtrg",tracoHtrgCanvas);

	cManager->storePlots();

	int scenarioCounter = 0;
	std::cout << "N Entries in bti Best case Scenarios:" << std::endl;
	for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = btiScenariosBestCase.begin();
			scenarioIt != btiScenariosBestCase.end() ; scenarioIt++) {
		std::cout << "\t" << legendNameVector[scenarioCounter] << ":\t\t" << scenarioIt->at(0)->GetEntries() << std::endl;
		scenarioCounter++;
	}
	std::cout << std::endl;
	scenarioCounter = 0;
	std::cout << "N Entries in bti HTRG Scenarios:" << std::endl;
	for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = btiScenariosHtrg.begin();
			scenarioIt != btiScenariosHtrg.end() ; scenarioIt++) {
		std::cout << "\t" << legendNameVector[scenarioCounter] << ":\t\t" << scenarioIt->at(0)->GetEntries() << std::endl;
		scenarioCounter++;
	}
	std::cout << std::endl;
	scenarioCounter = 0;
	std::cout << "N Entries in traco HTRIG Scenarios:" << std::endl;
	for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = tracoScenariosHtrg.begin();
			scenarioIt != tracoScenariosHtrg.end() ; scenarioIt++) {
//		std::cout << TString::Format("%s:\t%6d",legendNameVector[scenarioCounter].Data(),scenarioIt->at(0)->GetEntries()).Data() << std::endl;
		std::cout << "\t" << legendNameVector[scenarioCounter] << ":\t\t" << scenarioIt->at(0)->GetEntries() << std::endl;
		scenarioCounter++;
	}
	std::cout << std::endl;
	scenarioCounter = 0;
	std::cout << "N Entries in traco BestCase Scenarios:" << std::endl;
	for (std::vector<std::vector<TH1*> >::const_iterator scenarioIt = tracoScenariosBestCase.begin();
			scenarioIt != tracoScenariosBestCase.end() ; scenarioIt++) {
		std::cout << "\t" << legendNameVector[scenarioCounter] << ":\t\t" << scenarioIt->at(0)->GetEntries() << std::endl;
		scenarioCounter++;
	}
	std::cout << std::endl;
	delete btiBestCaseCanvas;
	delete btiHtrgCanvas;
	delete tracoBestCaseCanvas;
	delete tracoHtrgCanvas;

	std::cout << "All done!\nExit via ctrl+c..." << std::endl;
	//	app->Run();
	delete cManager;
	return 0;
}
コード例 #9
0
void Factorization_eta_pPb()
{
  const int nfiles = 15;
  TString filename[nfiles];
  filename[1] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n150185_pttrg033_ptassallweight_etaass445_eff1_all_v42.root");
  filename[2] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n185220_pttrg033_ptassallweight_etaass445_eff1_all_v42.root");
  filename[3] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n220260_pttrg033_ptassallweight_etaass445_eff1_all_v42.root");
  filename[4] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n260_pttrg033_ptassallweight_etaass445_eff1_all_v42.root");
  filename[0] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n120150_pttrg033_ptassallweight_etaass445_eff1_all_v42.root");

  filename[6] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n150185_pttrg033_ptassallweight_etaass34_eff1_all_v42.root");
  filename[7] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n185220_pttrg033_ptassallweight_etaass34_eff1_all_v42.root");
  filename[8] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n220260_pttrg033_ptassallweight_etaass34_eff1_all_v42.root");
  filename[9] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n260_pttrg033_ptassallweight_etaass34_eff1_all_v42.root");
  filename[5] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n120150_pttrg033_ptassallweight_etaass34_eff1_all_v42.root");

  filename[11] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n150185_pttrg033_ptassallweight_etaass45_eff1_all_v42.root");
  filename[12] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n185220_pttrg033_ptassallweight_etaass45_eff1_all_v42.root");
  filename[13] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n220260_pttrg033_ptassallweight_etaass45_eff1_all_v42.root");
  filename[14] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n260_pttrg033_ptassallweight_etaass45_eff1_all_v42.root");
  filename[10] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/PAData_Minbias_5TeV/merged/epetadeco_n120150_pttrg033_ptassallweight_etaass45_eff1_all_v42.root");


  const int ntrgbins = 16;
  const int ntrgbins1 = ntrgbins;
  const int ntrgbins2 = ntrgbins/2;
  TGraphErrors* gr[nfiles][6];
  TGraphErrors* gr1[nfiles][6];
  TGraphErrors* gr_tot[nfiles][6];
  TGraphErrors* gr_ratio[nfiles][6];
  TGraph* gr_band[nfiles][6];
  TGraph* gr1_band[nfiles][6];
  TF1* fit[nfiles][6];
  TF1* fit_aver[nfiles][6];
  TF1* fit1_aver[nfiles][6];
  double slope[6][nfiles];
  double slope_err[6][nfiles];
  double slope1[6][nfiles];
  double slope1_err[6][nfiles];

//  double eta[ntrgbins2] = {0.12,0.36,0.6,0.84,1.08,1.32,1.56,1.8,2.04,2.28};
//  double eta[ntrgbins2] = {0.1,0.3,0.5,0.7,0.9,1.1,1.3,1.5,1.7,1.9,2.1,2.3};    
  double eta[ntrgbins2] = {0.15,0.45,0.75,1.05,1.35,1.65,1.95,2.25};
//  double eta[ntrgbins2] = {0.2,0.6,1.0,1.4,1.8,2.2};
  double eta_err[ntrgbins2] = {0.0};
  Color_t color[6] = {1,kRed, kBlue, kGreen+2,1,1};

  TFile* fdiff[nfiles];
for(int jj=0;jj<nfiles;jj++)
{
  fdiff[jj] = new TFile(filename[jj].Data());

  TH2D* hsignal[ntrgbins];
  TH2D* hbackground[ntrgbins];
  TH2D* hsignal1[ntrgbins];
  TH2D* hbackground1[ntrgbins];
  TH1D* hsignal_1D[ntrgbins][6];
  TH1D* hbackground_1D[ntrgbins][6]; 
  TH1D* hsignal1_1D[ntrgbins][6];
  TH1D* hbackground1_1D[ntrgbins][6];

  for(int i=0;i<ntrgbins;i++)
  {
    hsignal[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfp/signalcosn_trg%d",i));
    hbackground[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfp/backgroundcosn_trg%d",i));
    hsignal1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfm/signalcosn_trg%d",i));
    hbackground1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfm/backgroundcosn_trg%d",i));
/*
    hsignal_1D[i] = (TH1D*)hsignal[i]->ProfileY(Form("signal_1D_trg%d",i),-1,-1,"e");
    hsignal1_1D[i] = (TH1D*)hsignal1[i]->ProfileY(Form("signal1_1D_trg%d",i),-1,-1,"e");
    hbackground_1D[i] = (TH1D*)hbackground[i]->ProfileY(Form("background_1D_trg%d",i),-1,-1,"e");
    hbackground1_1D[i] = (TH1D*)hbackground1[i]->ProfileY(Form("background1_1D_trg%d",i),-1,-1,"e");
*/
    for(int nbin=1;nbin<2;nbin++)
    {
      hsignal_1D[i][nbin] = (TH1D*)hsignal[i]->ProjectionX(Form("signal_1D_trg%d_%d",i,nbin),nbin,nbin,"i");
      hbackground_1D[i][nbin] = (TH1D*)hbackground[i]->ProjectionX(Form("background_1D_trg%d_%d",i,nbin),nbin,nbin,"i");
      hsignal1_1D[i][nbin] = (TH1D*)hsignal1[i]->ProjectionX(Form("signal1_1D_trg%d_%d",i,nbin),nbin,nbin,"i");
      hbackground1_1D[i][nbin] = (TH1D*)hbackground1[i]->ProjectionX(Form("background1_1D_trg%d_%d",i,nbin),nbin,nbin,"i");
    }
  }

  for(int nbin=1;nbin<2;nbin++)
  {
    double Vn[ntrgbins1];
    double VnError[ntrgbins1];
    double rn[ntrgbins2];
    double rn_err[ntrgbins2];
    double Vn1[ntrgbins1];
    double VnError1[ntrgbins1];
    double rn1[ntrgbins2];
    double rn1_err[ntrgbins2];
    double rn_tot[ntrgbins2];
    double rn_tot_err[ntrgbins2];
    double rn_ratio[ntrgbins2];
    double rn_ratio_err[ntrgbins2];

    for(int i=0;i<ntrgbins1;i++)
    {
if(nbin==1 && jj==3 ) cout<<nbin<<" "<<i<<" "<<hsignal1_1D[i][nbin]->GetMean()<<" "<<hsignal1_1D[i][nbin]->GetMeanError()<<" "<<hbackground1_1D[i][nbin]->GetMean()<<" "<<hbackground1_1D[i][nbin]->GetMeanError()<<endl;
/*
      Vn[i]=hsignal_1D[i]->GetBinContent(nbin)-hbackground_1D[i]->GetBinContent(nbin);
      VnError[i]=sqrt(hsignal_1D[i]->GetBinError(nbin)*hsignal_1D[i]->GetBinError(nbin)+hbackground_1D[i]->GetBinError(nbin)*hbackground_1D[i]->GetBinError(nbin));
      Vn1[i]=hsignal1_1D[i]->GetBinContent(nbin)-hbackground1_1D[i]->GetBinContent(nbin);
      VnError1[i]=sqrt(hsignal1_1D[i]->GetBinError(nbin)*hsignal1_1D[i]->GetBinError(nbin)+hbackground1_1D[i]->GetBinError(nbin)*hbackground1_1D[i]->GetBinError(nbin));
*/
      Vn[i]=hsignal_1D[i][nbin]->GetMean()-hbackground_1D[i][nbin]->GetMean();
      VnError[i]=sqrt(hsignal_1D[i][nbin]->GetMeanError()*hsignal_1D[i][nbin]->GetMeanError()+hbackground_1D[i][nbin]->GetMeanError()*hbackground_1D[i][nbin]->GetMeanError());
      Vn1[i]=hsignal1_1D[i][nbin]->GetMean()-hbackground1_1D[i][nbin]->GetMean();
      VnError1[i]=sqrt(hsignal1_1D[i][nbin]->GetMeanError()*hsignal1_1D[i][nbin]->GetMeanError()+hbackground1_1D[i][nbin]->GetMeanError()*hbackground1_1D[i][nbin]->GetMeanError());
    } 

    for(int i=0;i<ntrgbins2;i++)
    {
      rn[ntrgbins2-i-1]=Vn[i]/Vn[ntrgbins1-i-1];
      rn_err[ntrgbins2-i-1]=sqrt((VnError[ntrgbins1-i-1]/Vn[ntrgbins1-i-1])**2+(VnError[i]/Vn[i])**2);
      rn1[ntrgbins2-i-1]=Vn1[i]/Vn1[ntrgbins1-i-1];
      rn1_err[ntrgbins2-i-1]=sqrt((VnError1[ntrgbins1-i-1]/Vn1[ntrgbins1-i-1])**2+(VnError1[i]/Vn1[i])**2);
if(nbin==1 && jj==3 ) cout<<rn1[ntrgbins2-i-1]<<" "<<rn1_err[ntrgbins2-i-1]<<endl;
      rn_tot[ntrgbins2-i-1] = sqrt(rn[ntrgbins2-i-1]*rn1[ntrgbins2-i-1]);
      rn_tot_err[ntrgbins2-i-1] = rn_tot[ntrgbins2-i-1]*0.5*sqrt(rn_err[ntrgbins2-i-1]/rn[ntrgbins2-i-1]*rn_err[ntrgbins2-i-1]/rn[ntrgbins2-i-1]+rn1_err[ntrgbins2-i-1]/rn1[ntrgbins2-i-1]*rn1_err[ntrgbins2-i-1]/rn1[ntrgbins2-i-1]);

      rn_ratio[ntrgbins2-i-1] = sqrt(rn[ntrgbins2-i-1]/rn1[ntrgbins2-i-1]);
      rn_ratio_err[ntrgbins2-i-1] = rn_ratio[ntrgbins2-i-1]*sqrt(rn_err[ntrgbins2-i-1]/rn[ntrgbins2-i-1]*rn_err[ntrgbins2-i-1]/rn[ntrgbins2-i-1]+rn1_err[ntrgbins2-i-1]/rn1[ntrgbins2-i-1]*rn1_err[ntrgbins2-i-1]/rn1[ntrgbins2-i-1])*0.5;
    }

    gr[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn,eta_err,rn_err);
    gr[jj][nbin]->SetMarkerColor(color[nbin]);
    gr1[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn1,eta_err,rn1_err);
    gr1[jj][nbin]->SetMarkerColor(color[nbin]);
    gr_tot[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn_tot,eta_err,rn_tot_err);
    gr_tot[jj][nbin]->SetMarkerColor(color[nbin]);
//    gr_tot[jj][nbin]->SetMarkerSize(0.9*gr_tot[jj][nbin]->GetMarkerSize());
    gr_ratio[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn_ratio,eta_err,rn_ratio_err);
    gr_ratio[jj][nbin]->SetMarkerColor(color[nbin]); 
    if(jj<5) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"exp(2*[0]*(-x-4.6))/exp(2*[0]*(x-4.6))",0.0,2.5);
    else if(jj>=5 && jj<10) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"exp(2*[0]*(-x-3.5))/exp(2*[0]*(x-3.5))",0.0,1.1);
    else if(jj>=10) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"exp(2*[0]*(-x-4.6))/exp(2*[0]*(x-4.6))",0.0,2.06);
/*
    if(jj<4) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"(1-[1]+[1]*exp([0]*(-x-4.5)))/(1-[1]+[1]*exp([0]*(x-4.5)))",0.0,2.5);
    else if(jj>=4 && jj<8) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"(1-[1]+[1]*exp([0]*(-x-3.5)))/(1-[1]+[1]*exp([0]*(x-3.5)))",0.0,1.4);
    else if(jj>=8) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"(1-[1]+[1]*exp([0]*(-x-4.7)))/(1-[1]+[1]*exp([0]*(x-4.7)))",0.0,2.5);
*/
    fit[jj][nbin]->SetParameter(0,0.01);
    fit[jj][nbin]->SetParameter(1,0.1);
    fit[jj][nbin]->SetParLimits(1,0,0.2);
    gr_tot[jj][nbin]->Fit(Form("fit_%d_%d",nbin,jj),"RNO");
    fit[jj][nbin]->SetLineColor(color[nbin]);
    fit[jj][nbin]->SetLineStyle(9);
    fit[jj][nbin]->SetLineWidth(1);

    if(jj<5)
    {
      slope[nbin][jj] = fit[jj][nbin]->GetParameter(0);
      slope_err[nbin][jj] = fit[jj][nbin]->GetParError(0);
    }
    else
    {
      slope1[nbin][jj-10] = fit[jj][nbin]->GetParameter(0);
      slope1_err[nbin][jj-10] = fit[jj][nbin]->GetParError(0);
    }

//    fit1_aver[jj][nbin] = new TF1(Form("fit1_aver_%d_%d",nbin,jj),"[1]*exp(-[0]*x)+1-[1]",0,5.0);
    fit1_aver[jj][nbin] = new TF1(Form("fit1_aver_%d_%d",nbin,jj),"exp(-[0]*x)",0,5.0);
    fit1_aver[jj][nbin]->SetParameter(0,fit[jj][nbin]->GetParameter(0));
    fit1_aver[jj][nbin]->SetParError(0,fit[jj][nbin]->GetParError(0));
//    fit1_aver[jj][nbin]->SetParameter(1,fit[jj][nbin]->GetParameter(1));
//    fit1_aver[jj][nbin]->SetParError(1,fit[jj][nbin]->GetParError(1));
    fit1_aver[jj][nbin]->SetLineStyle(1);
    fit1_aver[jj][nbin]->SetLineColor(color[nbin]);
    gr1_band[jj][nbin] = new TGraph(53);
    for(int mm=0;mm<26;mm++) 
    {
      gr1_band[jj][nbin]->SetPoint(mm,0.2*mm,exp(-0.2*mm*(fit1_aver[jj][nbin]->GetParameter(0)+fit1_aver[jj][nbin]->GetParError(0))));
      gr1_band[jj][nbin]->SetPoint(51-mm,0.2*mm,exp(-0.2*mm*(fit1_aver[jj][nbin]->GetParameter(0)-fit1_aver[jj][nbin]->GetParError(0))));
    }
    gr1_band[jj][nbin]->SetPoint(52,0,1);
    gr1_band[jj][nbin]->SetFillColor(color[nbin]-10);
  }
}


  ofstream ff("r2_eta_pPb.txt");

  for(int nbin=1;nbin<2;nbin++) {
    cout<<"i="<<nbin+1<<endl;
    ff<<"i="<<nbin+1<<endl;
    for(int j=0;j<5;j++) { cout<<slope[nbin][j]<<" "; ff<<slope[nbin][j]<<", ";}
    cout<<endl;
    ff<<endl;
    for(int j=0;j<5;j++) { cout<<slope_err[nbin][j]<<" "; ff<<slope_err[nbin][j]<<", ";}
    cout<<endl;
    ff<<endl;
  }

  TString histtitle[5] = {"120 #leq N_{trk}^{offline} < 150", "150 #leq N_{trk}^{offline} < 185", "185 #leq N_{trk}^{offline} < 220", "220 #leq N_{trk}^{offline} < 260", "N_{trk}^{offline} #geq 260"};

  TLine* ll = new TLine(0,1.,2.65,1.);
  TCanvas* c = new TCanvas("c","c",530,500);
  makeMultiPanelCanvas(c,2,2,0.01,0.0,0.2,0.18,0.02);
  TH2D* htmp = new TH2D("htmp",";#eta^{a};#sqrt{r_{2}(-#eta^{a},-#eta^{b}) #times r_{2}(#eta^{a},#eta^{b})}",100,-0.1,2.5,100,0.601,1.06);
  fixedFontHist(htmp,1.8,2.1);
  htmp->GetXaxis()->CenterTitle();
  htmp->GetYaxis()->CenterTitle();
  htmp->GetYaxis()->SetTitleSize(htmp->GetYaxis()->GetTitleSize()*1.2);
  htmp->GetXaxis()->SetTitleSize(htmp->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<4;jj++)
  {
    c->cd(jj+1);
    htmp->Draw();
    ll->Draw("Lsame");

    gr_tot[jj][1]->SetMarkerStyle(25);
    gr_tot[jj][1]->Draw("Psame");
    fit[jj][1]->Draw("Lsame");

    gr_tot[jj+5][1]->SetMarkerStyle(24);
    gr_tot[jj+5][1]->Draw("Psame");

    gr_tot[jj+10][1]->SetMarkerStyle(28);
    gr_tot[jj+10][1]->SetMarkerColor(1);
    gr_tot[jj+10][1]->Draw("Psame");

/*
    gr_tot[jj+8][1]->SetMarkerStyle(28);
    fit[jj+8][1]->SetLineStyle(9);
    gr_tot[jj+8][1]->Draw("Psame");
    fit[jj+8][1]->Draw("Lsame");
*/
  }
  TLatex* latex = new TLatex();
  latex->SetNDC();
  latex->SetTextSize(1.3*latex->GetTextSize());
  c->cd(1);
  latex->DrawLatex(0.27,0.05,histtitle[0]);
//  latex->DrawLatex(0.58,0.74,"0.3 < p_{T}^{a} < 3 GeV/c");
//  latex->DrawLatex(0.58,0.65,"p_{T}^{b} > 0 GeV/c");
  latex->DrawLatex(0.24,0.885,"CMS pPb #sqrt{s_{NN}} = 5.02 TeV");
  latex->DrawLatex(0.68,0.7,"L_{int} = 35 nb^{-1}");
  c->cd(2);
  latex->DrawLatex(0.12,0.27,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex->DrawLatex(0.12,0.18,"p_{T}^{b} > 0 GeV/c");
  latex->DrawLatex(0.09,0.05,histtitle[1]);
  c->cd(4);
  latex->SetTextSize(0.9*latex->GetTextSize());
  latex->DrawLatex(0.09,0.22,histtitle[3]);
  latex->SetTextSize(latex->GetTextSize()/0.9);
  c->cd(3);
  latex->SetTextSize(0.85*latex->GetTextSize());
  latex->DrawLatex(0.27,0.22,histtitle[2]);

  TLegend* legend = new TLegend(0.25,0.18,0.62,0.39);
  legend->SetFillStyle(0);
//  legend->AddEntry(gr_tot[8][1],"4.4<#eta^{b}<5","P");
  legend->AddEntry(gr_tot[0][1],"4.4<#eta^{b}<5","P");
//  legend->AddEntry(fit[0][1],"Exponential fit","L");
  legend->AddEntry(gr_tot[10][1],"4<#eta^{b}<5","P");  
  legend->AddEntry(gr_tot[5][1],"3<#eta^{b}<4","P");
//  legend->AddEntry(fit[4][1],"Exponential fit","L");

  c->cd(1);  
  legend->Draw();

  TLine* ll = new TLine(0,1.,5.0,1.);
  TCanvas* ca = new TCanvas("ca","ca",560,500);
  makeMultiPanelCanvas(ca,2,2,0.02,0.0,0.27,0.18,0.02);
  TH2D* htmpa = new TH2D("htmpa",";#eta^{a};#frac{v_{2}(#eta^{a})}{v_{2}(-#eta^{a})} =  #sqrt{#frac{r_{2}(#eta^{a},#eta^{b})}{r_{2}(-#eta^{a},-#eta^{b})}}",100,-0.1,2.5,100,0.91,1.045);
  fixedFontHist(htmpa,1.8,2.7);
  htmpa->GetXaxis()->CenterTitle();
  htmpa->GetYaxis()->CenterTitle();
  htmpa->GetYaxis()->SetTitleSize(htmpa->GetYaxis()->GetTitleSize()*1.15);
  htmpa->GetXaxis()->SetTitleSize(htmpa->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<4;jj++)
  {
    ca->cd(jj+1);
    htmpa->Draw();
    ll->Draw("Lsame");
    gr_ratio[jj][1]->Draw("Psame");
    gr_ratio[jj+5][1]->SetMarkerStyle(24);
    gr_ratio[jj+5][1]->Draw("Psame");
  }
  TLatex* latex1 = new TLatex();
  latex1->SetNDC();
  latex1->SetTextSize(1.3*latex1->GetTextSize());
  ca->cd(1);
  latex1->DrawLatex(0.33,0.05,histtitle[0]);
  latex1->DrawLatex(0.31,0.88,"CMS pPb #sqrt{s_{NN}} = 5.02 TeV");
  latex1->DrawLatex(0.31,0.77,"L_{int} = 35 nb^{-1}");

  ca->cd(2);
  latex1->DrawLatex(0.075,0.05,histtitle[1]);
  latex1->DrawLatex(0.08,0.29,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex1->DrawLatex(0.08,0.19,"p_{T}^{b} > 0 GeV/c");
  ca->cd(4);
  latex1->SetTextSize(0.9*latex1->GetTextSize());
  latex1->DrawLatex(0.075,0.22,histtitle[3]);
  latex1->SetTextSize(latex1->GetTextSize()/0.9);
  ca->cd(3);
  latex1->SetTextSize(0.85*latex1->GetTextSize());
  latex1->DrawLatex(0.33,0.22,histtitle[2]);

  TLegend* legend1 = new TLegend(0.34,0.15,0.57,0.35);
  legend1->SetFillStyle(0);
  legend1->AddEntry(gr_ratio[0][1],"4.4<#eta^{b}<5","P");
  legend1->AddEntry(gr_ratio[5][1],"3<#eta^{b}<4","P");
  ca->cd(1);
  legend1->Draw();

  TCanvas* c2 = new TCanvas("c2","c2",810,400);
  makeMultiPanelCanvas(c2,4,2,0.016,0.0,0.24,0.2,0.02);
  TH2D* htmp2 = new TH2D("htmp2",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.1,2.5,100,0.61,1.06);
  fixedFontHist(htmp2,1.6,1.8);
  htmp2->GetXaxis()->CenterTitle();
  htmp2->GetYaxis()->CenterTitle();
  htmp2->GetYaxis()->SetTitleSize(htmp2->GetYaxis()->GetTitleSize()*1.3);
  htmp2->GetXaxis()->SetTitleSize(htmp2->GetXaxis()->GetTitleSize()*1.);
  TH2D* htmp2a = (TH2D*)htmp2->Clone("tmp2a"); 
  htmp2a->SetTitle(";#eta^{a};r_{2}(-#eta^{a},-#eta^{b})");
  for(int jj=0;jj<4;jj++)
  {
    c2->cd(jj+1);
    htmp2->Draw();
    ll->Draw("Lsame");
    gr[jj][1]->Draw("Psame");
    gr[jj+5][1]->SetMarkerStyle(24);
    gr[jj+5][1]->Draw("Psame");
    c2->cd(jj+5);
    htmp2a->Draw();
    ll->Draw("Lsame");
    gr1[jj][1]->Draw("Psame");
    gr1[jj+5][1]->SetMarkerStyle(24);
    gr1[jj+5][1]->Draw("Psame");
  } 
  TLatex* latex2 = new TLatex();
  latex2->SetNDC();
  latex2->SetTextSize(1.5*latex2->GetTextSize());
  c2->cd(1);
  latex2->DrawLatex(0.30,0.05,histtitle[0]);
  latex2->DrawLatex(0.28,0.865,"CMS pPb #sqrt{s_{NN}} = 5.02 TeV");
  c2->cd(2);
  latex2->DrawLatex(0.08,0.05,histtitle[1]);
  latex2->DrawLatex(0.07,0.3,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex2->DrawLatex(0.07,0.18,"p_{T}^{b} > 0 GeV/c");
  c2->cd(4);
  latex2->DrawLatex(0.08,0.05,histtitle[3]);
  c2->cd(3);
  latex2->DrawLatex(0.08,0.05,histtitle[2]);
  c2->cd(6);
  latex2->SetTextSize(0.96*latex2->GetTextSize());
  latex2->DrawLatex(0.08,0.24,histtitle[1]);
  c2->cd(8);
  latex2->DrawLatex(0.08,0.24,histtitle[3]);
  c2->cd(7);
  latex2->DrawLatex(0.08,0.24,histtitle[2]);
  c2->cd(5);
  latex2->SetTextSize(0.9*latex2->GetTextSize());
  latex2->DrawLatex(0.3,0.24,histtitle[0]);

  TLegend* legend2 = new TLegend(0.3,0.18,0.6,0.44);
  legend2->SetFillStyle(0);
  legend2->AddEntry(gr_ratio[0][1],"4.4<#eta^{b}<5","P");
  legend2->AddEntry(gr_ratio[5][1],"3<#eta^{b}<4","P");
  c2->cd(1);
  legend2->Draw();
/*
  TCanvas* cc2 = new TCanvas("cc2","cc2",530,500);
  makeMultiPanelCanvas(cc2,2,2,0.01,0.0,0.2,0.18,0.02);
  TH2D* htmp22 = new TH2D("htmp22",";|#eta^{a}-#eta^{b}|;cos[n(#Psi_{n}(#eta^{a})-#Psi_{n}(#eta^{b}))]",100,0,5,100,0.731,1.06);
  fixedFontHist(htmp22,1.8,2.2);
  htmp22->GetXaxis()->CenterTitle();
  htmp22->GetYaxis()->CenterTitle();
  htmp22->GetYaxis()->SetTitleSize(htmp22->GetYaxis()->GetTitleSize()*1.1);
  htmp22->GetXaxis()->SetTitleSize(htmp22->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<4;jj++)
  { 
    cc2->cd(jj+1);
    htmp22->Draw();
    ll->Draw("Lsame");
    gr1_band[jj][1]->Draw("Fsame");
    fit1_aver[jj][1]->Draw("Lsame");
  } 
  TLatex* latex3 = new TLatex();
  latex3->SetNDC();
  latex3->SetTextSize(1.4*latex3->GetTextSize());
  cc2->cd(1);
  latex3->DrawLatex(0.26,0.05,histtitle[0]);
  latex3->DrawLatex(0.24,0.865,"CMS pPb #sqrt{s_{NN}} = 5.02 TeV");
  cc2->cd(2);
  latex3->DrawLatex(0.075,0.05,histtitle[1]);
  cc2->cd(4);
  latex3->DrawLatex(0.075,0.22,histtitle[3]);
  cc2->cd(3);
  latex3->SetTextSize(0.85*latex3->GetTextSize());
  latex3->DrawLatex(0.24,0.22,histtitle[2]);
*/

  SaveCanvas(c,"HI/FactBreak","epetadeco_pPb_alletab_r2tot");
  SaveCanvas(c2,"HI/FactBreak","epetadeco_pPb_alletab_r2sep");
  SaveCanvas(ca,"HI/FactBreak","epetadeco_pPb_alletab_r2ratio");
//  SaveCanvas(cc2,"HI/FactBreak","epetadeco_pPb_cos");
}
コード例 #10
0
ファイル: RPCSeedValidator.C プロジェクト: hyteng/usercode
void RPCSeedValidator(string FileName) {

    gStyle->SetOptStat("");
    gStyle->SetOptTitle(0);
    if(debug) cout << FileName << endl;
    string theFileName = "../" + FileName;
    TFile* RootFile = TFile::Open(theFileName.c_str());
    string OutputPlotNameFix = ".eps";
    string FinalOutput = FileName + "_";

    unsigned int EventNumber;
    int SimTrackId;
    int SimTrackType;
    double SimTrackMomentum;
    double SimTrackDirectionPhi;
    int SimTrackCharge;
    int SimTrackvalid;
    bool PassSegmentFilter;
    double SimMomentumPtatRef;
    double SimDirectionPhiatRef;
    double SimDirectionEtaatRef;
    double SimBendingPhi;
    double SimBendingEntryPositionX;
    double SimBendingEntryPositionY;
    double SimBendingEntryPositionZ;
    double SimBendingLeavePositionX;
    double SimBendingLeavePositionY;
    double SimBendingLeavePositionZ;
    unsigned int SeedNumber;
    int SeedCharge;
    double SeedPurity;
    double SeedQuality;
    double RecMomentumPtatRef;
    double RecDirectionPhiatRef;
    double RecDirectionEtaatRef;
    double RecBendingPhi;
    double RecBendingEntryPositionX;
    double RecBendingEntryPositionY;
    double RecBendingEntryPositionZ;
    double RecBendingLeavePositionX;
    double RecBendingLeavePositionY;
    double RecBendingLeavePositionZ;
    double RecBendingLastPhi;

    TTree* T0 = (TTree*)RootFile->Get("ExTree");
    T0->SetBranchAddress("EventNumber", &EventNumber);
    T0->SetBranchAddress("SimTrackId", &SimTrackId);
    T0->SetBranchAddress("SimTrackType", &SimTrackType);
    T0->SetBranchAddress("SimTrackMomentum", &SimTrackMomentum);
    T0->SetBranchAddress("SimTrackDirectionPhi", &SimTrackDirectionPhi);
    T0->SetBranchAddress("SimTrackCharge", &SimTrackCharge);
    T0->SetBranchAddress("SimTrackValid", &SimTrackvalid);
    T0->SetBranchAddress("PassSegmentFilter", &PassSegmentFilter);
    T0->SetBranchAddress("SimMomentumPtatRef", &SimMomentumPtatRef);
    T0->SetBranchAddress("SimDirectionPhiatRef", &SimDirectionPhiatRef);
    T0->SetBranchAddress("SimDirectionEtaatRef", &SimDirectionEtaatRef);
    T0->SetBranchAddress("SimBendingPhi", &SimBendingPhi);
    T0->SetBranchAddress("SimBendingEntryPositionX", &SimBendingEntryPositionX);
    T0->SetBranchAddress("SimBendingEntryPositionY", &SimBendingEntryPositionY);
    T0->SetBranchAddress("SimBendingEntryPositionZ", &SimBendingEntryPositionZ);
    T0->SetBranchAddress("SimBendingLeavePositionX", &SimBendingLeavePositionX);
    T0->SetBranchAddress("SimBendingLeavePositionY", &SimBendingLeavePositionY);
    T0->SetBranchAddress("SimBendingLeavePositionZ", &SimBendingLeavePositionZ);
    T0->SetBranchAddress("SeedNumber", &SeedNumber);
    T0->SetBranchAddress("SeedCharge", &SeedCharge);
    T0->SetBranchAddress("SeedPurity", &SeedPurity);
    T0->SetBranchAddress("SeedQuality", &SeedQuality);
    T0->SetBranchAddress("RecMomentumPtatRef", &RecMomentumPtatRef);
    T0->SetBranchAddress("RecDirectionPhiatRef", &RecDirectionPhiatRef);
    T0->SetBranchAddress("RecDirectionEtaatRef", &RecDirectionEtaatRef);
    T0->SetBranchAddress("RecBendingPhi", &RecBendingPhi);
    T0->SetBranchAddress("RecBendingEntryPositionX", &RecBendingEntryPositionX);
    T0->SetBranchAddress("RecBendingEntryPositionY", &RecBendingEntryPositionY);
    T0->SetBranchAddress("RecBendingEntryPositionZ", &RecBendingEntryPositionZ);
    T0->SetBranchAddress("RecBendingLeavePositionX", &RecBendingLeavePositionX);
    T0->SetBranchAddress("RecBendingLeavePositionY", &RecBendingLeavePositionY);
    T0->SetBranchAddress("RecBendingLeavePositionZ", &RecBendingLeavePositionZ);
    T0->SetBranchAddress("RecBendingLastPhi", &RecBendingLastPhi);

    TH1D* SimTrackvalidHist = (TH1D*) new TH1D("SimTrackvalidHist", "SimTrackvalidHist", 2, 0, 2);
    TH1D* SeedPtforSimTrackvalidHist = (TH1D*) new TH1D("SeedPtforSimTrackvalidHist", "SeedPtforSimTrackvalidHist", 100, 0, 100);
    TH1D* SeeddeltaPtforSimTrackvalidHist = (TH1D*) new TH1D("SeeddeltaPtforSimTrackvalidHist", "SeeddeltaPtforSimTrackvalidHist", 150, -3., 3.);
    TH1D* SeeddeltaPhiforSimTrackvalidHist = (TH1D*) new TH1D("SeeddeltaPhiforSimTrackvalidHist", "SeeddeltaPhiforSimTrackvalidHist", 628, -3.14/6, 3.14/6);
    TH1D* SeeddeltaEtaforSimTrackvalidHist = (TH1D*) new TH1D("SeeddeltaEtaforSimTrackvalidHist", "SeeddeltaEtaforSimTrackvalidHist", 200, -1., 1.);
    TH1D* SeedPurityforSimTrackvalidHist = (TH1D*) new TH1D("SeedPurityforSimTrackvalidHist", "SeedPurityforSimTrackvalidHist", 20, 0, 2);
    TH1D* ChargeCheckforSimTrackvalidHist = (TH1D*) new TH1D("ChargeCheckforSimTrackvalidHist", "ChargeCheckforSimTrackvalidHist", 5, -2.5, 2.5);
    TH1D* SeedNumberforSimTrackvalidHist = (TH1D*) new TH1D("SeedNumberforSimTrackvalidHist", "SeedNumberforSimTrackvalidHist", 30, 0, 30);
    TH1D* SeedEfficiencyforSimTrackvalidHist = (TH1D*) new TH1D("SeedEfficiencyforSimTrackvalidHist", "SeedEfficiencyforSimTrackvalidHist", 2, 0, 2);
    TH1D* SeedNumberforSimTrackinvalidHist = (TH1D*) new TH1D("SeedNumberforSimTrackinvalidHist", "SeedNumberforSimTrackinvalidHist", 20, 0, 20);
    TH1D* SeedEfficiencyforSimTrackinvalidHist = (TH1D*) new TH1D("SeedEfficiencyforSimTrackinvalidHist", "SeedEfficiencyforSimTrackinvalidHist", 2, 0, 2);
    TH1D* RecBendingLastPhiHist = (TH1D*) new TH1D("RecBendingLastPhiHist", "RecBendingLastPhiHist", 628, -3.14/2, 3.14/2);
    TH1D* SeedEfficiencyHist = (TH1D*) new TH1D("SeedEfficiency", "SeedEfficiency", 2, 0, 2);
    TH2D* RecBendingPhi2PtHist = new TH2D("RecBendingPhi2PtHist", "RecBendingPhi2PtHist", 2000, -100, 100, 628, -3.14/4, 3.14/4);
    TH2D* PtRatoofRecBendingPhiHist = new TH2D("", "", 628, -3.14/4, 3.14/4, 2000, -100, 100);
    TObjArray* SimReverseBending = (TObjArray*) new TObjArray();

    unsigned int LastSeedNumber = -1;
    unsigned int LastSimTrackvalid = 0;
    bool LastPassSegmentFilter = false;
    bool LastPurityFull = false;
    int Nentries = T0->GetEntries();
    for(int i = 0; i < Nentries; i++) {
        T0->GetEntry(i);

        if(debug) cout << "SimTrackId: " << SimTrackId << ", SimTrackType: " << SimTrackType << ", PassSegmentFilter: " << PassSegmentFilter << ", SeedNumber: " << SeedNumber << ", SeedPurity: " << SeedPurity << ", SeedCharge: " << SeedCharge << ", SimTrackCharge: " << SimTrackCharge << ", SimBendingPhi: " << SimBendingPhi << ", RecBendingPhi: " << RecBendingPhi << ", RecBendingLastPhi: " << RecBendingLastPhi << ", RecMomentumPtatRef: " << RecMomentumPtatRef << ", SimMomentumPtatRef: " << SimMomentumPtatRef << ", LastSeedNumber: " << LastSeedNumber << endl;

        //if(SimTrackMomentum > 20.0)
            //continue;

        if(SeedNumber != 0) {
            if(SimTrackvalid == 1 && SeedPurity == 1. && PassSegmentFilter == true) {
                SeedPtforSimTrackvalidHist->Fill(RecMomentumPtatRef);
                SeeddeltaPtforSimTrackvalidHist->Fill((RecMomentumPtatRef-SimMomentumPtatRef)/SimMomentumPtatRef);
                SeeddeltaPhiforSimTrackvalidHist->Fill(RecDirectionPhiatRef-SimDirectionPhiatRef);
                SeeddeltaEtaforSimTrackvalidHist->Fill(RecDirectionEtaatRef-SimDirectionEtaatRef);
                RecBendingPhi2PtHist->Fill(SimMomentumPtatRef*SimTrackCharge, RecBendingPhi);
                double PtRato = SimMomentumPtatRef / RecMomentumPtatRef;
                if(debug) cout << "PtRato: " << PtRato << ", at RecBendingPhi: " << RecBendingPhi << endl;
                PtRatoofRecBendingPhiHist->Fill(RecBendingPhi, PtRato);
                RecBendingLastPhiHist->Fill((RecBendingLastPhi == 0. ? 0 : RecBendingLastPhi/fabs(RecBendingLastPhi))*SimTrackCharge);
                SeedPurityforSimTrackvalidHist->Fill(SeedPurity);
                ChargeCheckforSimTrackvalidHist->Fill(SeedCharge*SimTrackCharge);
                /*
                if(SeedPurity == 1) {
                    //SeedPtforSimTrackvalidHist->Fill(RecMomentumPtatRef);
                    //SeeddeltaPtforSimTrackvalidHist->Fill(RecMomentumPtatRef-SimMomentumPtatRef);
                    RecBendingPhi2PtHist->Fill(SimMomentumPtatRef*SimTrackCharge, RecBendingPhi);
                    double PtRato = SimMomentumPtatRef / RecMomentumPtatRef;
                    if(debug) cout << "PtRato: " << PtRato << ", at RecBendingPhi: " << RecBendingPhi << endl;
                    PtRatoofRecBendingPhiHist->Fill(RecBendingPhi, PtRato);
                    RecBendingLastPhiHist->Fill((RecBendingLastPhi == 0. ? 0 : RecBendingLastPhi/fabs(RecBendingLastPhi))*SimTrackCharge);
                }
                */
                if(SeedCharge*SimTrackCharge == -1) {
                    if(debug) cout << "R1: " << sqrt(SimBendingEntryPositionX*SimBendingEntryPositionX+SimBendingEntryPositionY*SimBendingEntryPositionY) << ", R2: " << sqrt(SimBendingLeavePositionX*SimBendingLeavePositionX+SimBendingLeavePositionY*SimBendingLeavePositionY) << endl;
                    TLine* SimSegment = new TLine(SimBendingEntryPositionX, SimBendingEntryPositionY, SimBendingLeavePositionX, SimBendingLeavePositionY);
                    SimReverseBending->AddLast(SimSegment);
                }
                LastPurityFull = true;
            }
        }
        else {
            if(LastSeedNumber != -1) {
                if(LastSimTrackvalid == 1 && LastPassSegmentFilter == true) {
                    if(debug) cout << "Filling valid track efficiency " << LastSeedNumber << endl;
                    SeedNumberforSimTrackvalidHist->Fill(LastSeedNumber);
                    SeedEfficiencyforSimTrackvalidHist->Fill(LastPurityFull==true?1:0);
                }
                else {
                    SeedNumberforSimTrackinvalidHist->Fill(LastSeedNumber);
                    SeedEfficiencyforSimTrackinvalidHist->Fill(LastPurityFull==true?1:0);
                }
                LastPurityFull = false;
            }
        }
        LastPassSegmentFilter = PassSegmentFilter;
        LastSeedNumber = SeedNumber;
        LastSimTrackvalid = SimTrackvalid;
    }
    if(LastSeedNumber != -1) {
        if(LastSimTrackvalid == 1 && LastPassSegmentFilter == true) {
            SeedNumberforSimTrackvalidHist->Fill(LastSeedNumber);
            SeedEfficiencyforSimTrackvalidHist->Fill(LastPurityFull==true?1:0);
        }
        else {
            SeedNumberforSimTrackinvalidHist->Fill(LastSeedNumber);
            SeedEfficiencyforSimTrackinvalidHist->Fill(LastPurityFull == true?1:0);
        }
    }

    TCanvas* SimTrackvalidCanvas = new TCanvas("SimTrackvalidCanvas", "SimTrackvalidCanvas", 800, 600);
    SimTrackvalidCanvas->cd();
    SimTrackvalidHist->Draw();
    string SimTrackvalidCanvasName = FinalOutput + "SimTrackvalid" + OutputPlotNameFix;
    SimTrackvalidCanvas->SaveAs(SimTrackvalidCanvasName.c_str());

    TCanvas* SeedPtforSimTrackvalidCanvas = new TCanvas("SeedPtforSimTrackvalidCanvas", "SeedPtforSimTrackvalidCanvas", 800, 600);
    SeedPtforSimTrackvalidCanvas->cd();
    SeedPtforSimTrackvalidHist->Draw();
    string SeedPtforSimTrackvalidCanvasName = FinalOutput + "SeedPtforSimTrackvalid" + OutputPlotNameFix;
    SeedPtforSimTrackvalidCanvas->SaveAs(SeedPtforSimTrackvalidCanvasName.c_str());

    TCanvas* SeeddeltaPtforSimTrackvalidCanvas = new TCanvas("SeeddeltaPtforSimTrackvalidCanvas", "SeeddeltaPtforSimTrackvalidCanvas", 800, 600);
    SeeddeltaPtforSimTrackvalidCanvas->cd();
    SeeddeltaPtforSimTrackvalidHist->SetStats(1);
    gStyle->SetOptFit(0111);
    //SeeddeltaPtforSimTrackvalidHist->Fit("gaus", "", "", -1., 1.);
    SeeddeltaPtforSimTrackvalidHist->GetXaxis()->SetTitle("(recPt-simPt)/simPt");
    SeeddeltaPtforSimTrackvalidHist->GetXaxis()->CenterTitle();
    SeeddeltaPtforSimTrackvalidHist->Draw();
    string SeeddeltaPtforSimTrackvalidCanvasName = FinalOutput + "SeeddeltaPtforSimTrackvalid" + OutputPlotNameFix;
    SeeddeltaPtforSimTrackvalidCanvas->SaveAs(SeeddeltaPtforSimTrackvalidCanvasName.c_str());

    TCanvas* SeeddeltaPhiforSimTrackvalidCanvas = new TCanvas("SeeddeltaPhiforSimTrackvalidCanvas", "SeeddeltaPhiforSimTrackvalidCanvas", 800, 600);
    SeeddeltaPhiforSimTrackvalidCanvas->cd();
    SeeddeltaPhiforSimTrackvalidHist->SetStats(1);
    SeeddeltaPhiforSimTrackvalidHist->GetXaxis()->SetTitle("(recPhi-simPhi)");
    SeeddeltaPhiforSimTrackvalidHist->GetXaxis()->CenterTitle();
    SeeddeltaPhiforSimTrackvalidHist->Draw();
    string SeeddeltaPhiforSimTrackvalidCanvasName = FinalOutput + "SeeddeltaPhiforSimTrackvalid" + OutputPlotNameFix;
    SeeddeltaPhiforSimTrackvalidCanvas->SaveAs(SeeddeltaPhiforSimTrackvalidCanvasName.c_str());

    TCanvas* SeeddeltaEtaforSimTrackvalidCanvas = new TCanvas("SeeddeltaEtaforSimTrackvalidCanvas", "SeeddeltaEtaforSimTrackvalidCanvas", 800, 600);
    SeeddeltaEtaforSimTrackvalidCanvas->cd();
    SeeddeltaEtaforSimTrackvalidHist->SetStats(1);
    SeeddeltaEtaforSimTrackvalidHist->GetXaxis()->SetTitle("(recEta-simEta)");
    SeeddeltaEtaforSimTrackvalidHist->GetXaxis()->CenterTitle();
    SeeddeltaEtaforSimTrackvalidHist->Draw();
    string SeeddeltaEtaforSimTrackvalidCanvasName = FinalOutput + "SeeddeltaEtaforSimTrackvalid" + OutputPlotNameFix;
    SeeddeltaEtaforSimTrackvalidCanvas->SaveAs(SeeddeltaEtaforSimTrackvalidCanvasName.c_str());


    TCanvas* SeedPurityforSimTrackvalidCanvas = new TCanvas("SeedPurityforSimTrackvalidCanvas", "SeedPurityforSimTrackvalidCanvas", 800, 600);
    SeedPurityforSimTrackvalidCanvas->cd();
    SeedPurityforSimTrackvalidHist->Draw();
    string SeedPurityforSimTrackvalidCanvasName = FinalOutput + "SeedPurityforSimTrackvalid" + OutputPlotNameFix;
    SeedPurityforSimTrackvalidCanvas->SaveAs(SeedPurityforSimTrackvalidCanvasName.c_str());

    TCanvas* ChargeCheckforSimTrackvalidCanvas = new TCanvas("ChargeCheckforSimTrackvalidCanvas", "ChargeCheckforSimTrackvalidCanvas", 800, 600);
    ChargeCheckforSimTrackvalidCanvas->cd();
    double HistEntries = ChargeCheckforSimTrackvalidHist->GetEntries() / 100.;
    ChargeCheckforSimTrackvalidHist->Scale(1./HistEntries);
    ChargeCheckforSimTrackvalidHist->GetXaxis()->SetTitle("simCharge*recCharge");
    ChargeCheckforSimTrackvalidHist->GetXaxis()->CenterTitle(1);
    ChargeCheckforSimTrackvalidHist->GetYaxis()->SetTitle("fraction %");
    ChargeCheckforSimTrackvalidHist->GetYaxis()->CenterTitle(1);
    ChargeCheckforSimTrackvalidHist->Draw();
    string ChargeCheckforSimTrackvalidCanvasName = FinalOutput + "ChargeCheckforSimTrackvalid" + OutputPlotNameFix;
    ChargeCheckforSimTrackvalidCanvas->SaveAs(ChargeCheckforSimTrackvalidCanvasName.c_str());

    TCanvas* SeedNumberforSimTrackvalidCanvas = new TCanvas("SeedNumberforSimTrackvalidCanvas", "SeedNumberforSimTrackvalidCanvas", 800, 600);
    SeedNumberforSimTrackvalidCanvas->cd();
    SeedNumberforSimTrackvalidHist->Draw();
    string SeedNumberforSimTrackvalidCanvasName = FinalOutput + "SeedNumberforSimTrackvalid" + OutputPlotNameFix;
    SeedNumberforSimTrackvalidCanvas->SaveAs(SeedNumberforSimTrackvalidCanvasName.c_str());

    TCanvas* SeedEfficiencyforSimTrackvalidCanvas = new TCanvas("SeedEfficiencyforSimTrackvalidCanvas", "SeedEfficiencyforSimTrackvalidCanvas", 800, 600);
    SeedEfficiencyforSimTrackvalidCanvas->cd();
    SeedEfficiencyforSimTrackvalidHist->Draw();
    string SeedEfficiencyforSimTrackvalidCanvasName = FinalOutput + "SeedEfficiencyforSimTrackvalid" + OutputPlotNameFix;
    SeedEfficiencyforSimTrackvalidCanvas->SaveAs(SeedEfficiencyforSimTrackvalidCanvasName.c_str());

    TCanvas* SeedNumberforSimTrackinvalidCanvas = new TCanvas("SeedNumberforSimTrackinvalidCanvas", "SeedNumberforSimTrackinvalidCanvas", 800, 600);
    SeedNumberforSimTrackinvalidCanvas->cd();
    SeedNumberforSimTrackinvalidHist->Draw();
    string SeedNumberforSimTrackinvalidCanvasName = FinalOutput + "SeedNumberforSimTrackinvalid" + OutputPlotNameFix;
    SeedNumberforSimTrackinvalidCanvas->SaveAs(SeedNumberforSimTrackinvalidCanvasName.c_str());

    TCanvas* SeedEfficiencyforSimTrackinvalidCanvas = new TCanvas("SeedEfficiencyforSimTrackinvalidCanvas", "SeedEfficiencyforSimTrackinvalidCanvas", 800, 600);
    SeedEfficiencyforSimTrackinvalidCanvas->cd();
    SeedEfficiencyforSimTrackinvalidHist->Draw();
    string SeedEfficiencyforSimTrackinvalidCanvasName = FinalOutput + "SeedEfficiencyforSimTrackinvalid" + OutputPlotNameFix;
    SeedEfficiencyforSimTrackinvalidCanvas->SaveAs(SeedEfficiencyforSimTrackinvalidCanvasName.c_str());

    double SeedEfficiencyforSimTrackinvalid = 100. * SeedEfficiencyforSimTrackinvalidHist->GetMean();
    double SeedEfficiencyforSimTrackvalid = 100. * SeedEfficiencyforSimTrackvalidHist->GetMean();
    SeedEfficiencyHist->SetBinContent(1, SeedEfficiencyforSimTrackinvalid);
    SeedEfficiencyHist->SetBinContent(2, SeedEfficiencyforSimTrackvalid);
    SeedEfficiencyHist->GetXaxis()->SetBinLabel(1, "for invalid simTrack");
    SeedEfficiencyHist->GetXaxis()->SetBinLabel(2, "for valid simTrack");
    TCanvas* SeedEfficiencyCanvas = new TCanvas("SeedEfficiencyCanvas", "SeedEfficiencyCanvas", 800, 600);
    SeedEfficiencyCanvas->cd();
    SeedEfficiencyHist->GetYaxis()->SetTitle("Efficiency %");
    SeedEfficiencyHist->GetYaxis()->CenterTitle(1);
    SeedEfficiencyHist->SetMarkerStyle(3);
    SeedEfficiencyHist->SetMarkerSize(3);
    SeedEfficiencyHist->Draw("P");
    string SeedEfficiencyCanvasName = FinalOutput + "SeedEfficiency" + OutputPlotNameFix;
    SeedEfficiencyCanvas->SaveAs(SeedEfficiencyCanvasName.c_str());

    TCanvas* RecBendingPhi2PtCanvas = new TCanvas("RecBendingPhi2PtCanvas", "RecBendingPhi2PtCanvas", 800, 600);
    RecBendingPhi2PtCanvas->cd();
    RecBendingPhi2PtHist->Draw();
    string RecBendingPhi2PtCanvasName = FinalOutput + "RecBendingPhi2Pt" + OutputPlotNameFix;
    RecBendingPhi2PtCanvas->SaveAs(RecBendingPhi2PtCanvasName.c_str());

    TCanvas* PtRatoofRecBendingPhiCanvas = new TCanvas("PtRatoofRecBendingPhiCanvas", "PtRatoofRecBendingPhiCanvas", 800, 600);
    PtRatoofRecBendingPhiCanvas->cd();
    PtRatoofRecBendingPhiHist->Draw();
    string PtRatoofRecBendingPhiCanvasName = FinalOutput + "PtRatoofRecBendingPhi" + OutputPlotNameFix;
    PtRatoofRecBendingPhiCanvas->SaveAs(PtRatoofRecBendingPhiCanvasName.c_str());

    TCanvas* RecBendingLastPhiCanvas = new TCanvas("RecBendingLastPhiCanvas", "RecBendingLastPhiCanvas", 800, 600);
    RecBendingLastPhiCanvas->cd();
    RecBendingLastPhiHist->Draw();
    string RecBendingLastPhiCanvasName = FinalOutput + "RecBendingLastPhi" + OutputPlotNameFix;
    RecBendingLastPhiCanvas->SaveAs(RecBendingLastPhiCanvasName.c_str());

    Int_t linsav = gStyle->GetLineWidth();
    gStyle->SetLineWidth(2);
    TCanvas* SimReverseBendingCanvas = new TCanvas("SimReverseBendingCanvas", "SimReverseBendingCanvas", 800, 800);
    SimReverseBendingCanvas->cd();
    TPad* SimReverseBendingPad = new TPad("SimReverseBendingPad", "SimReverseBendingPad", 0, 0, 1, 1);
    SimReverseBendingPad->Draw();
    SimReverseBendingPad->cd();
    SimReverseBendingPad->Range(-800, -800, 800, 800);
    unsigned int segmentNumber = SimReverseBending->GetEntries();
    cout << "Number of segments: " << segmentNumber << endl;
    for(unsigned int j = 0; j < segmentNumber; j++) {
        ((TLine*)(SimReverseBending->At(j)))->Print();
        ((TLine*)(SimReverseBending->At(j)))->Draw("SAME");
    }
    string SimReverseBendingCanvasName = FinalOutput + "SimReverseBending" + OutputPlotNameFix;
    SimReverseBendingCanvas->SaveAs(SimReverseBendingCanvasName.c_str());
}
コード例 #11
0
void toyV2Generator(const unsigned int numberEvents=300,
		    const unsigned int particlesPerEvent=500,	
		    const bool useFlow=true,
		    const float v2Factor=0.20,
		    const bool writeHistogramFile=true,
		    const bool readHistogramFile=false,
		    const unsigned int nBinsOneD=100,
		    const unsigned int nBinsX=40,
		    const unsigned int nBinsY=40,
		    const unsigned int iBinXMinPlot=3,
		    const unsigned int iBinYMinPlot=3,
		    const unsigned int iBinXMaxPlot=37,
		    const unsigned int iBinYMaxPlot=37) {

  if(readHistogramFile && writeHistogramFile) {
    cerr << "\n Cannot do a simultaneous read and write of the histogram file";
    cerr << endl;
    return;
  }

  const unsigned int particlesPerEventLessOne = particlesPerEvent - 1;
  float particleEta[particlesPerEvent];
  float particlePhi[particlesPerEvent];
  float particlePhiLab[particlesPerEvent];

  float particleEtaPreviousEvent[particlesPerEvent];
  float particlePhiLabPreviousEvent[particlesPerEvent];

  //
  // Function to provide azimuthal angles according to a v2 distribution
  //
  char flowFunction[200];
  sprintf(flowFunction, "1.0 + %4.2f*2.0*cos(2.0*x)", v2Factor);
  TF1 *v2Flow = new TF1("v2Flow", flowFunction, 0.0, 2.0*TMath::Pi());

  const float highEtaBin = 3.0;
  const float lowEtaBin = -3.0;
  const float highPhiBin = 1.5*TMath::Pi();
  const float lowPhiBin = -0.5*TMath::Pi();

  float mixedEventWeight = float(particlesPerEvent)*float(particlesPerEvent - 1)/(2.0*float(particlesPerEvent*particlesPerEvent));

  //
  // Single particle range in eta will be half the maximum for deltaEta
  //
  const float diffEta = 0.5*(highEtaBin - lowEtaBin);

  TH1D *particlePhiHistogram = 0;
  TH1D *particlePhiLabHistogram = 0;
  TH1D *particleEtaHistogram = 0;

  TH1D *pairDeltaPhiHistogram = 0;
  TH1D *pairDeltaPhiHistogramMixed = 0;
  TH1D *pairDeltaPhiHistogramNormalized = 0;

  TH1D *pairDeltaEtaHistogram = 0;
  TH1D *pairDeltaEtaHistogramMixed = 0;
  TH1D *pairDeltaEtaHistogramNormalized = 0;

  TH2D *pairDeltaEtaDeltaPhiHistogram = 0;
  TH2D *pairDeltaEtaDeltaPhiHistogramMixed = 0;
  TH2D *pairDeltaEtaDeltaPhiHistogramNormalized = 0;

  if(!readHistogramFile) {

    particlePhiHistogram = new TH1D("particlePhiHistogram", "Particle azimuthal distribution in reaction plane", nBinsOneD, 0.0, 2.0*TMath::Pi());
    particlePhiHistogram->SetXTitle("Particle azimuthal angle #phi (radians)");
    particlePhiHistogram->SetYTitle("Counts per 0.063 radians bin");

    particlePhiLabHistogram = new TH1D("particlePhiLabHistogram", "Particle azimuthal distribution in lab frame", nBinsOneD, 0.0, 2.0*TMath::Pi());
    particlePhiLabHistogram->SetXTitle("Particle azimuthal angle #phi (radians)");
    particlePhiLabHistogram->SetYTitle("Counts per 0.063 radians bin");

    particleEtaHistogram = new TH1D("particleEtaHistogram", "Particle azimuthal distribution", nBinsOneD, lowEtaBin, highEtaBin);
    particleEtaHistogram->SetXTitle("Particle #eta");
    particleEtaHistogram->SetYTitle("Counts per 0.015 bin");

    pairDeltaPhiHistogram = new TH1D("pairDeltaPhiHistogram", "#Delta #phi pairs in lab frame", nBinsOneD, lowPhiBin, highPhiBin);
    pairDeltaPhiHistogram->SetXTitle("#Delta #phi (radians)");
    pairDeltaPhiHistogram->SetYTitle("Counts");

    pairDeltaPhiHistogramMixed = new TH1D("pairDeltaPhiHistogramMixed", "#Delta #phi pairs in lab frame, mixed-event", nBinsOneD, lowPhiBin, highPhiBin);
    pairDeltaPhiHistogramMixed->SetXTitle("#Delta #phi (radians)");
    pairDeltaPhiHistogramMixed->SetYTitle("Counts");

    pairDeltaPhiHistogramNormalized = new TH1D("pairDeltaPhiHistogramNormalized", "Normalized #Delta #phi pairs in lab frame", nBinsOneD, lowPhiBin, highPhiBin);
    pairDeltaPhiHistogramNormalized->SetXTitle("#Delta #phi (radians)");
    pairDeltaPhiHistogramNormalized->SetYTitle("Counts");

    pairDeltaEtaHistogram = new TH1D("pairDeltaEtaHistogram", "#Delta #eta Pairs, Same Event", nBinsOneD, lowEtaBin, highEtaBin);
    pairDeltaEtaHistogram->SetXTitle("#Delta #eta (radians)");
    pairDeltaEtaHistogram->SetYTitle("Counts");

    pairDeltaEtaHistogramMixed = new TH1D("pairDeltaEtaHistogramMixed", "#Delta #eta Pairs, Mixed Event", nBinsOneD, lowEtaBin, highEtaBin);
    pairDeltaEtaHistogramMixed->SetXTitle("#Delta #eta (radians)");
    pairDeltaEtaHistogramMixed->SetYTitle("Counts");

    pairDeltaEtaHistogramNormalized = new TH1D("pairDeltaEtaHistogramNormalized", "#Delta #eta Pairs, Normalized Event", nBinsOneD, lowEtaBin, highEtaBin);
    pairDeltaEtaHistogramNormalized->SetXTitle("#Delta #eta (radians)");
    pairDeltaEtaHistogramNormalized->SetYTitle("Counts");
    
    pairDeltaEtaDeltaPhiHistogram = new TH2D("pairDeltaEtaDeltaPhiHistogram", "Angular Correlation Pairs", nBinsX, lowEtaBin, highEtaBin, nBinsY, lowPhiBin, highPhiBin);
    pairDeltaEtaDeltaPhiHistogram->SetXTitle("#Delta #eta");
    pairDeltaEtaDeltaPhiHistogram->SetYTitle("#Delta #phi");

    pairDeltaEtaDeltaPhiHistogramMixed = new TH2D("pairDeltaEtaDeltaPhiHistogramMixed", "Angular Correlation Pairs", nBinsX, lowEtaBin, highEtaBin, nBinsY, lowPhiBin, highPhiBin);
    pairDeltaEtaDeltaPhiHistogramMixed->SetXTitle("#Delta #eta");
    pairDeltaEtaDeltaPhiHistogramMixed->SetYTitle("#Delta #phi");

    pairDeltaEtaDeltaPhiHistogramNormalized = new TH2D("pairDeltaEtaDeltaPhiHistogramNormalized", "Normalized Angular Correlation Pairs", nBinsX, lowEtaBin, highEtaBin, nBinsY, lowPhiBin, highPhiBin);
    pairDeltaEtaDeltaPhiHistogramNormalized->SetXTitle("#Delta #eta");
    pairDeltaEtaDeltaPhiHistogramNormalized->SetYTitle("#Delta #phi");

    //
    // Random number generator object
    //
    TRandom1 *particleKinematics = new TRandom1();
    particleKinematics->SetSeed(1);
		
    unsigned int numberEvents10 = numberEvents/10;

    for(unsigned int kEvent=0; kEvent<numberEvents; kEvent++) {
			
      if(kEvent>0 && kEvent%numberEvents10==0) {
	cout << "\n At kEvent = " << kEvent;
      }
			
      //
      // Randomize the reaction plane angle in the lab frame
      //
      float reactionPlaneAngleThisEvent = 2.0*(particleKinematics->Rndm())*TMath::Pi();
			
      //
      // Loop over particles per event
      //
      for(unsigned int kParticle=0; kParticle<particlesPerEvent; kParticle++) {
	particleEta[kParticle] = lowEtaBin + diffEta*(0.5 - particleKinematics->Rndm());
	if(useFlow) {
	  particlePhi[kParticle] = v2Flow->GetRandom();
	  if(particlePhi[kParticle] > 2.0*TMath::Pi())
	    particlePhi[kParticle] -= 2.0*TMath::Pi();

	  particlePhiLab[kParticle] =  particlePhi[kParticle] + reactionPlaneAngleThisEvent;
	  if(particlePhiLab[kParticle] > 2.0*TMath::Pi())
	    particlePhiLab[kParticle] -= 2.0*TMath::Pi();
	}
	else {
	  particlePhi[kParticle] = 2.0*(particleKinematics->Rndm())*TMath::Pi();
	  particlePhiLab[kParticle] =  particlePhi[kParticle];
	}
	particleEtaHistogram->Fill(particleEta[kParticle]);
	particlePhiHistogram->Fill(particlePhi[kParticle]);
 	particlePhiLabHistogram->Fill(particlePhiLab[kParticle]);

      } // loop over particles

      if(kEvent > 0) {
	//
	// Fill the pair histograms for the same event
	//
	for(unsigned int kParticle=0; kParticle<particlesPerEventLessOne; kParticle++) {
	  float phi1 = particlePhiLab[kParticle];
	  float eta1 = particleEta[kParticle];
	  unsigned int jParticleStart = kParticle + 1;
	  for(unsigned int jParticle=jParticleStart; jParticle<particlesPerEvent; jParticle++) {
	    float phiDelta = deltaPhi(phi1, particlePhiLab[jParticle]);

	    //
	    // Change the phiDelta range for plot purposes
	    //
	    if(phiDelta < -0.5*TMath::Pi())
	      phiDelta = TMath::Pi() + TMath::Pi() + phiDelta;

	    float etaDelta = eta1 - particleEta[jParticle];
	    pairDeltaPhiHistogram->Fill(phiDelta);
	    pairDeltaEtaHistogram->Fill(etaDelta, 0.5);
	    pairDeltaEtaHistogram->Fill(-etaDelta, 0.5);
	    pairDeltaEtaDeltaPhiHistogram->Fill(etaDelta, phiDelta, 0.5);
	    pairDeltaEtaDeltaPhiHistogram->Fill(-etaDelta, phiDelta, 0.5);
	  } // loop over second particle in same event pair

	} // loop over first particle in same event pair

	//
	// Fill the pair histograms for the mixed event
	//
	for(unsigned int kParticle=0; kParticle<particlesPerEvent; kParticle++) {
	  float phi1 = particlePhiLab[kParticle];
	  float eta1 = particleEta[kParticle];
	  for(unsigned int jParticle=0; jParticle<particlesPerEvent; jParticle++) {
	    float phiDelta = deltaPhi(phi1, particlePhiLabPreviousEvent[jParticle]);

	    //
	    // Change the phiDelta range for plot purposes
	    //
	    if(phiDelta < -0.5*TMath::Pi())
	      phiDelta = TMath::Pi() + TMath::Pi() + phiDelta;

	    pairDeltaPhiHistogramMixed->Fill(phiDelta, mixedEventWeight);
	    float etaDelta = eta1 - particleEtaPreviousEvent[jParticle];
	    pairDeltaEtaHistogramMixed->Fill(etaDelta,0.5);
	    pairDeltaEtaHistogramMixed->Fill(-etaDelta,0.5);
	    pairDeltaEtaDeltaPhiHistogramMixed->Fill(etaDelta, phiDelta, 0.5);
	    pairDeltaEtaDeltaPhiHistogramMixed->Fill(-etaDelta, phiDelta, 0.5);

	  } // loop over particle in previous event

	} // loop over particle in current event


      } // check on beyond the first event

      //
      // Move particles from current event to previous event arrays
      //
      for(unsigned int kParticle=0; kParticle<particlesPerEvent; kParticle++) {
	particlePhiLabPreviousEvent[kParticle] = particlePhiLab[kParticle];
	particleEtaPreviousEvent[kParticle] = particleEta[kParticle];
      }

    } // loop over events
    cout << "\n Finished NTUPLE scan" << endl;

    //
    // Normalize the delta-phi histograms with the mixed-event yields
    //
    float sumSameEventPhi1D = 0.0;
    float sumMixedEventPhi1D = 0.0;
    for(unsigned int iBinX=1; iBinX<nBinsOneD; iBinX++) {
      sumSameEventPhi1D += pairDeltaPhiHistogram->GetBinContent(iBinX);
      sumMixedEventPhi1D += pairDeltaPhiHistogramMixed->GetBinContent(iBinX);
    }
    if(sumSameEventPhi1D > 0.0 && sumMixedEventPhi1D > 0.0) {
      float normalizationFactor1D = sumMixedEventPhi1D/sumSameEventPhi1D;
      for(unsigned int iBinX=0; iBinX<nBinsOneD; iBinX++) {
	pairDeltaPhiHistogramNormalized->SetBinContent(iBinX,0.0);
	float sameEventContent = pairDeltaPhiHistogram->GetBinContent(iBinX);
	float mixedEventContent = pairDeltaPhiHistogramMixed->GetBinContent(iBinX);
	if(mixedEventContent > 0.0) {
	  float normalizedYield = normalizationFactor1D*sameEventContent/mixedEventContent;
	  pairDeltaPhiHistogramNormalized->SetBinContent(iBinX, normalizedYield);
	} // check for non-zero denominator
      } // loop over phi bins
    } // check for non-zero totals
		
    //
    // Normalize the delta-eta histograms with the mixed-event yields
    //
    float sumSameEvent1D = pairDeltaEtaHistogram->GetEntries();
    float sumMixedEvent1D = pairDeltaEtaHistogramMixed->GetEntries();
    if(sumSameEvent1D > 0.0 && sumMixedEvent1D > 0.0) {
      float normalizationFactor1D = sumMixedEvent1D/sumSameEvent1D;
      for(unsigned int iBinX=0; iBinX<nBinsOneD; iBinX++) {
	pairDeltaEtaHistogramNormalized->SetBinContent(iBinX,0.0);
	float sameEventContent = pairDeltaEtaHistogram->GetBinContent(iBinX);
	float mixedEventContent = pairDeltaEtaHistogramMixed->GetBinContent(iBinX);
	if(mixedEventContent > 0.0) {
	  float normalizedYield = normalizationFactor1D*sameEventContent/mixedEventContent;
	  pairDeltaEtaHistogramNormalized->SetBinContent(iBinX, normalizedYield);
	} // check for non-zero denominator
      } // loop over eta bins
    } // check for non-zero totals
		
    float sumSameEvent2D = pairDeltaEtaDeltaPhiHistogram->GetEntries();
    float sumMixedEvent2D = pairDeltaEtaDeltaPhiHistogramMixed->GetEntries();

    if(sumSameEvent2D > 0.0 && sumMixedEvent2D > 0.0) {
      float normalizationFactor2D = sumMixedEvent2D/sumSameEvent2D;
      for(unsigned int iBinX=0; iBinX<nBinsX; iBinX++) {
	for(unsigned int iBinY=0; iBinY<nBinsY; iBinY++) {
	  pairDeltaEtaDeltaPhiHistogramNormalized->SetBinContent(iBinX, iBinY, 0.0);
	  if(iBinX<iBinXMinPlot || iBinX>iBinXMaxPlot ||
	     iBinY<iBinYMinPlot || iBinY>iBinYMaxPlot)
	    continue;  // limit the fiducial area of the plot because of possible low statistics

	  float sameEventContent = pairDeltaEtaDeltaPhiHistogram->GetBinContent(iBinX, iBinY);
	  float mixedEventContent = pairDeltaEtaDeltaPhiHistogramMixed->GetBinContent(iBinX, iBinY);
	  if(mixedEventContent > 0.0) {
	    float normalizedYield = normalizationFactor2D*sameEventContent/mixedEventContent;
	    pairDeltaEtaDeltaPhiHistogramNormalized->SetBinContent(iBinX, iBinY, normalizedYield);
	  } // check for non-zero mixed event content
	} // loop over phi bins
      } // loop over eta bins
    } // check for non-zero total counts

  } // check on not reading histogram file

  if(readHistogramFile) {

    char inputFileName[200];
    sprintf(inputFileName, "toyV2Generator%dEvents%dParticlesPerEvent%4.2fV2.root", numberEvents, particlesPerEvent, v2Factor);
    TFile *toyV2GeneratorFile = new TFile(inputFileName);
		
    if(!toyV2GeneratorFile) {
      cerr << "\n Unable to find ROOT file " <<  inputFileName << endl;
      return;
    }

    cout << "\n Using input ROOT file " << inputFileName << endl;
		
    particlePhiHistogram = (TH1D*)toyV2GeneratorFile->Get("particlePhiHistogram");
    if(!particlePhiHistogram) {
      cerr << "\n Cannot find particlePhiHistogram" << endl;
      return;
    }

    particlePhiLabHistogram = (TH1D*)toyV2GeneratorFile->Get("particlePhiLabHistogram");
    if(!particlePhiLabHistogram) {
      cerr << "\n Cannot find particlePhiLabHistogram" << endl;
      return;
    }

    particleEtaHistogram = (TH1D*)toyV2GeneratorFile->Get("particleEtaHistogram");
    if(!particleEtaHistogram) {
      cerr << "\n Cannot find particleEtaHistogram" << endl;
      return;
    }
		
    pairDeltaPhiHistogram = (TH1D*)toyV2GeneratorFile->Get("pairDeltaPhiHistogram");
    if(!pairDeltaPhiHistogram) {
      cerr << "\n Cannot find pairDeltaPhiHistogram" << endl;
      return;
    }		

    pairDeltaPhiHistogramMixed = (TH1D*)toyV2GeneratorFile->Get("pairDeltaPhiHistogramMixed");
    if(!pairDeltaPhiHistogramMixed) {
      cerr << "\n Cannot find pairDeltaPhiHistogramMixed" << endl;
      return;
    }

    pairDeltaPhiHistogramNormalized = (TH1D*)toyV2GeneratorFile->Get("pairDeltaPhiHistogramNormalized");
    if(!pairDeltaPhiHistogramNormalized) {
      cerr << "\n Cannot find pairDeltaPhiHistogramNormalized" << endl;
      return;
    }

    pairDeltaEtaHistogram = (TH1D*)toyV2GeneratorFile->Get("pairDeltaEtaHistogram");
    if(!pairDeltaEtaHistogram) {
      cerr << "\n Cannot find pairDeltaEtaHistogram" << endl;
      return;
    }

    pairDeltaEtaHistogramMixed = (TH1D*)toyV2GeneratorFile->Get("pairDeltaEtaHistogramMixed");
    if(!pairDeltaEtaHistogramMixed) {
      cerr << "\n Cannot find pairDeltaEtaHistogramMixed" << endl;
      return;
    }

    pairDeltaEtaHistogramNormalized = (TH1D*)toyV2GeneratorFile->Get("pairDeltaEtaHistogramNormalized");
    if(!pairDeltaEtaHistogramNormalized) {
      cerr << "\n Cannot find pairDeltaEtaHistogramNormalized" << endl;
      return;
    }

    pairDeltaEtaDeltaPhiHistogram = (TH2D*)toyV2GeneratorFile->Get("pairDeltaEtaDeltaPhiHistogram");
    if(!pairDeltaEtaDeltaPhiHistogram) {
      cerr << "\n Cannot find pairDeltaEtaDeltaPhiHistogram" << endl;
      return;
    }

    pairDeltaEtaDeltaPhiHistogramMixed = (TH2D*)toyV2GeneratorFile->Get("pairDeltaEtaDeltaPhiHistogramMixed");
    if(!pairDeltaEtaDeltaPhiHistogramMixed) {
      cerr << "\n Cannot find pairDeltaEtaDeltaPhiHistogramMixed" << endl;
      return;
    }

    pairDeltaEtaDeltaPhiHistogramNormalized = (TH2D*)toyV2GeneratorFile->Get("pairDeltaEtaDeltaPhiHistogramNormalized");
    if(!pairDeltaEtaDeltaPhiHistogramNormalized) {
      cerr << "\n Cannot find pairDeltaEtaDeltaPhiHistogramNormalized" << endl;
      return;
    }

  } // check on readHistogramFile

  TCanvas *c1 = new TCanvas("c1", "Plotting Pair Events", 200, 10, 700, 500);
  //
  // Use ROOT's gStyle function to set up plot options
  //
  gStyle->SetOptStat(1110);
  gStyle->SetStatTextColor(kBlue);
  gStyle->SetFuncColor(kBlue);
  gStyle->SetFuncWidth(2);
  gStyle->SetOptFit(1111);
  gStyle->SetFitFormat("6.5g");
	
  c1->SetFillColor(kWhite);

  c1->Divide(2,2);

  c1->cd(1);
  
  if(useFlow) {
    particlePhiHistogram->SetStats(0);
    particlePhiHistogram->SetMinimum(0);
    float fMaximum = particlePhiHistogram->GetMaximum();
    int iMaximum = 1.5*fMaximum;
    particlePhiHistogram->SetMaximum(iMaximum);
		
    particlePhiHistogram->SetLineColor(4);
    particlePhiHistogram->Draw();
    particlePhiLabHistogram->SetLineColor(1);
    particlePhiLabHistogram->Draw("same");
		
    char labelBufferTitle[200];
    sprintf(labelBufferTitle, "Events = %d, Particles/Event = %d, V2 factor = %4.2f", numberEvents, particlesPerEvent, v2Factor);
    TLatex *text1 = new TLatex(0.5, 0.90*iMaximum, labelBufferTitle);
    text1->SetTextColor(4);
    text1->SetTextSize(0.045);
    text1->Draw();
		
    char labelBuffer2[200];
    sprintf(labelBuffer2, "Blue: azimuthal distribution relative to reaction plane");
    TLatex *text2 = new TLatex(0.5, 0.20*iMaximum, labelBuffer2);
    text2->SetTextColor(4);
    text2->SetTextSize(0.035);
    text2->Draw();
		
    char labelBuffer3[200];
    sprintf(labelBuffer3, "Black: azimuthal distribution relative to lab frame");
    TLatex *text3 = new TLatex(0.5, 0.10*iMaximum, labelBuffer3);
    text3->SetTextColor(1);
    text3->SetTextSize(0.035);
    text3->Draw();
		
  }
  else {
    particlePhiLabHistogram->SetStats(0);
    float fMaximum = particlePhiLabHistogram->GetMaximum();
    int iMaximum = 1.5*fMaximum;
    particlePhiLabHistogram->SetMaximum(iMaximum);
    particlePhiLabHistogram->SetMinimum(0);
    particlePhiLabHistogram->Draw();
		
    char labelBufferTitle[200];
    sprintf(labelBufferTitle, "Events = %d, Particles/Event = %d, No Flow", numberEvents, particlesPerEvent);
    TLatex *text1 = new TLatex(0.5, 0.90*iMaximum, labelBufferTitle);
    text1->SetTextColor(4);
    text1->SetTextSize(0.045);
    text1->Draw();
		
  }

  c1->cd(2);
  //pairDeltaPhiHistogramNormalized->SetStats(0);
  pairDeltaPhiHistogramNormalized->SetMaximum(1.3);
  pairDeltaPhiHistogramNormalized->SetMinimum(0.7);
  pairDeltaPhiHistogramNormalized->SetLineColor(2);

  TF1* fitFcnV2 = new TF1("fitFcnV2", v2Fit, -0.5*TMath::Pi(), 1.5*TMath::Pi(), 1);
  fitFcnV2->SetParameters(0, 0.20);
  fitFcnV2->SetParName(0, "Coeff");

  pairDeltaPhiHistogramNormalized->Fit("fitFcnV2", "", "",  -0.5*TMath::Pi(), 1.5*TMath::Pi());

  char labelBuffer12[200];
  sprintf(labelBuffer12, "Blue: fit with 1.0 + 2.0*Coeff*cos(2#Delta#phi), Coeff = %4.3f", fitFcnV2->GetParameter(0));
  TLatex *text12 = new TLatex(-0.5, 0.83, labelBuffer12);
  text12->SetTextColor(4);
  text12->SetTextSize(0.035);
  text12->Draw();

  char labelBuffer22[200];
  sprintf(labelBuffer22, "Red: normalized pair #Delta#phi distribution in lab frame");
  TLatex *text22 = new TLatex(-0.5, 0.77, labelBuffer22);
  text22->SetTextColor(2);
  text22->SetTextSize(0.035);
  text22->Draw();

  c1->cd(3);
  pairDeltaEtaHistogramNormalized->SetStats(0);
  pairDeltaEtaHistogramNormalized->SetMaximum(1.5);
  pairDeltaEtaHistogramNormalized->SetMinimum(0);
  pairDeltaEtaHistogramNormalized->Draw();
	
  c1->cd(4);
  pairDeltaEtaDeltaPhiHistogramNormalized->SetStats(0);
  pairDeltaEtaDeltaPhiHistogramNormalized->SetMaximum(1.3);
  pairDeltaEtaDeltaPhiHistogramNormalized->SetMinimum(0.7);
  pairDeltaEtaDeltaPhiHistogramNormalized->Draw("surf1");

  if(writeHistogramFile) {
    TFile *toyV2GeneratorFile;
		
    char outputFileName[200];
    sprintf(outputFileName, "toyV2Generator%dEvents%dParticlesPerEvent%4.2fV2.root", numberEvents, particlesPerEvent, v2Factor);
    char outputFileTitle[200];
    sprintf(outputFileTitle, "Toy V2 Generator with %d Events, %d Particles/Event, and V2 = %4.2f", numberEvents, particlesPerEvent, v2Factor);
    toyV2GeneratorFile = new TFile(outputFileName, "recreate", outputFileTitle);

    particlePhiHistogram->Write();
    particlePhiLabHistogram->Write();
    particleEtaHistogram->Write();

    pairDeltaPhiHistogram->Write();
    pairDeltaPhiHistogramMixed->Write();
    pairDeltaPhiHistogramNormalized->Write();

    pairDeltaEtaHistogram->Write();
    pairDeltaEtaHistogramMixed->Write();
    pairDeltaEtaHistogramNormalized->Write();

    pairDeltaEtaDeltaPhiHistogram->Write();
    pairDeltaEtaDeltaPhiHistogramMixed->Write();
    pairDeltaEtaDeltaPhiHistogramNormalized->Write();
		
    toyV2GeneratorFile->Write();
    toyV2GeneratorFile->Close();

  }

  return;

}
コード例 #12
0
void clusterGaussReso() {

  TFile* file = new TFile("complete.root");

  TTree* tree = (TTree *)file->Get("Signal");

  int nEvents = tree->GetEntries();

  double addresses[121] = {};
  for (int k=0; k<121; k++){
    std::stringstream ss2;
    ss2 << k; 
    string str = "Crystal_"+ss2.str();
    const char* charstr = str.c_str(); 
    tree->SetBranchAddress(charstr, &addresses[k]);
  }

  TH1D* energyResoG = new TH1D("energyResoG", "Gauss_Energy_Resolution",
			      100, -10, 10);

  TH2D* posResoG = new TH2D("posResoG", "Gauss_Pos_Resolution", 
			    11, -5, 5, 11, -5, 5);

  double energyThresHi = 50.; //set energy threshold to start looking for bumps
  double energyThresLo = .5; //energy lower bound


  //Going through each scan of the calorimeter
  for (int k=0; k<nEvents; k++)
    {
      tree->GetEntry(k);

      pair<int, double> bump(0, 0.); 
      vector<pair<int, double> > geant;
      vector<pair<int, double> > hitMap;

      for(int i=0; i<121; i++)
	{
	  pair<int, double> hit(i, addresses[i]);
	  geant.push_back(hit);
	  if (addresses[i] > energyThresHi)
	    { hitMap.push_back(hit);}
	  if (hit.second>bump.second)
	    { bump = hit;}
	}

      gaussFit(bump, geant, energyResoG, posResoG);


    } //end of event

 TCanvas* canvas = new TCanvas("canvas", "canvas", 700,700);
 canvas->Divide(2, 1);
 TF1* g1d = new TF1("g1d", "gaus", -10, 10);
 TF2* g2d2 = new TF2("g2d2", Gaus2D, -10, 10, -10, 10, 6);
 g2d2->SetParameters(0., 0., 1., 1., 0., 100000);
 g2d2->FixParameter(4, 0.);
 energyResoG->Fit(g1d);
canvas->cd(1); energyResoG->Draw();
 posResoG->Fit(g2d2);
canvas->cd(2); posResoG->Draw("BOX");

}
コード例 #13
0
void plot_eff_NoErrors(const string& fInputFile, const string& fPlot, const double fOP, const string& fTitle, const string& fXAxisTitle, const string& fYAxisTitle, const string& fOutputFile,
                       const double fYmin=0., const double fYmax=1.0, const Int_t fLogy=0, const Double_t fTitleOffsetX=1.0, const Double_t fTitleOffsetY=1.0,
                       const Double_t fLeftMargin=0.12, const Double_t fTopMargin=0.07, const Double_t fPlotWidth=0.8)
{
  gROOT->SetBatch(kTRUE);
  setEXOStyle();
  gStyle->SetGridColor(kGray);
  gStyle->SetOptStat(kFALSE);
  gStyle->SetPadTopMargin(fTopMargin);
  gStyle->SetPadBottomMargin(1.-fTopMargin-fPlotWidth);
  gStyle->SetPadLeftMargin(fLeftMargin);
  gStyle->SetPadRightMargin(1.-fLeftMargin-fPlotWidth);
  gROOT->ForceStyle();

  TFile *file = new TFile(fInputFile.c_str());

  TH1D *h1_total = new TH1D("h1_total","h1_total",4,0.,0.8);
  TH1D *h1_subjet1 = new TH1D("h1_subjet1","h1_subjet1",4,0.,0.8);
  TH1D *h1_subjet2 = new TH1D("h1_subjet2","h1_subjet2",4,0.,0.8);
  TH1D *h1_subjet12 = new TH1D("h1_subjet12","h1_subjet12",4,0.,0.8);

  string bin_strings[4] = {"0to0p2", "0p2to0p4", "0p4to0p6", "0p6to0p8"};

  for(int i=0; i<4; ++i)
  {
     TH2D *h2 = (TH2D*)file->Get((fPlot + bin_strings[i]).c_str());

     int bin = h2->GetXaxis()->FindBin(fOP);

     h1_total->SetBinContent(   i+1,h2->Integral(0,101,0,101));
     h1_subjet1->SetBinContent( i+1,h2->Integral(bin,101,0,101));
     h1_subjet2->SetBinContent( i+1,h2->Integral(0,101,bin,101));
     h1_subjet12->SetBinContent(i+1,h2->Integral(bin,101,bin,101));
  }

  TCanvas *c = new TCanvas("c", "",1000,800);
  c->cd();

  TH2D *bkg = new TH2D("bkg","",100,0.,0.8,100,fYmin,fYmax);
  bkg->GetXaxis()->SetTitle(fXAxisTitle.c_str());
  bkg->GetYaxis()->SetTitle(fYAxisTitle.c_str());
  bkg->SetTitleOffset(fTitleOffsetX,"X");
  bkg->SetTitleOffset(fTitleOffsetY,"Y");
  bkg->Draw();
  c->SetGridx();
  c->SetGridy();

  TGraph *g_eff_subjet1 = new TGraph(4);
  g_eff_subjet1->SetMarkerStyle(20);
  g_eff_subjet1->SetMarkerColor(kBlue+1);
  g_eff_subjet1->SetLineColor(kBlue+1);
  g_eff_subjet1->SetLineStyle(2);
  for(int i=0; i<4; ++i)
    g_eff_subjet1->SetPoint(i,h1_total->GetBinCenter(i+1),h1_subjet1->GetBinContent(i+1)/h1_total->GetBinContent(i+1));

  TGraph *g_eff_subjet2 = new TGraph(4);
  g_eff_subjet2->SetMarkerStyle(21);
  g_eff_subjet2->SetMarkerColor(kGreen+1);
  g_eff_subjet2->SetLineColor(kGreen+1);
  g_eff_subjet2->SetLineStyle(2);
  for(int i=0; i<4; ++i)
    g_eff_subjet2->SetPoint(i,h1_total->GetBinCenter(i+1),h1_subjet2->GetBinContent(i+1)/h1_total->GetBinContent(i+1));

  TGraph *g_eff_subjet12 = new TGraphAsymmErrors(4);
  g_eff_subjet12->SetMarkerStyle(22);
  g_eff_subjet12->SetMarkerColor(kBlack);
  g_eff_subjet12->SetLineColor(kBlack);
  g_eff_subjet12->SetLineStyle(2);
  for(int i=0; i<4; ++i)
    g_eff_subjet12->SetPoint(i,h1_total->GetBinCenter(i+1),h1_subjet12->GetBinContent(i+1)/h1_total->GetBinContent(i+1));

  TGraph *g_eff_subjet12_prod = new TGraph(4);
  g_eff_subjet12_prod->SetMarkerStyle(26);
  g_eff_subjet12_prod->SetMarkerColor(kRed);
  g_eff_subjet12_prod->SetLineColor(kRed);
  g_eff_subjet12_prod->SetLineStyle(2);
  for(int i=0; i<4; ++i)
    g_eff_subjet12_prod->SetPoint(i,h1_total->GetBinCenter(i+1),(h1_subjet1->GetBinContent(i+1)*h1_subjet2->GetBinContent(i+1))/(h1_total->GetBinContent(i+1)*h1_total->GetBinContent(i+1)));

  g_eff_subjet1->Draw("PLsame");
  g_eff_subjet2->Draw("PLsame");
  g_eff_subjet12->Draw("PLsame");
  g_eff_subjet12_prod->Draw("PLsame");

  TLegend *legend = new TLegend(.6,.3,.85,.55);
  legend->SetBorderSize(0);
  legend->SetFillColor(0);
  legend->SetFillStyle(0);
  legend->SetTextFont(42);
  legend->SetTextSize(0.05);
  legend->AddEntry(g_eff_subjet1, "#varepsilon_{1}","lp");
  legend->AddEntry(g_eff_subjet2, "#varepsilon_{2}","lp");
  legend->AddEntry(g_eff_subjet12, "#varepsilon_{1 & 2}","lp");
  legend->AddEntry(g_eff_subjet12_prod, "#varepsilon_{1} #times #varepsilon_{2}","lp");
  legend->Draw();

  TLatex l1;
  l1.SetTextAlign(13);
  l1.SetTextFont(42);
  l1.SetTextSize(0.045);
  l1.SetNDC();
  l1.DrawLatex(fLeftMargin+0.03,0.91, fTitle.c_str());

  l1.SetTextAlign(12);
  l1.SetTextSize(0.05);
  l1.SetTextFont(62);
  l1.DrawLatex(fLeftMargin,0.97, "CMS Simulation Preliminary, #sqrt{s} = 8 TeV");

  c->SetLogy(fLogy);
  c->SaveAs(fOutputFile.c_str());
}
コード例 #14
0
ファイル: alignTracking.cpp プロジェクト: CeF3TB/H4_2015
float fitAndDraw( const std::string& outputdir, TH1F* h1 ) {


  float returnConst=0.;

  TCanvas* c1 = new TCanvas("c1", "", 600, 600);
  c1->cd();

  float xMin = h1->GetXaxis()->GetXmin();
  float xMax = h1->GetXaxis()->GetXmax();
  float yMax = 1.1*h1->GetMaximum();


  TH2D* axes = new TH2D( "axes", "", 10, xMin, xMax, 10, 0., yMax );
  axes->SetXTitle("Cluster Position [mm]");
  //  axes->SetXTitle(h1->GetName());
  axes->SetYTitle("Events");
  axes->Draw();

  h1->SetFillColor(29);
  h1->Draw("same");

  int opt=2;

  if( opt==1 ) { // gaussian fit

    float maxPos = h1->GetBinCenter(h1->GetMaximumBin());

    TF1* f1 = new TF1(Form("f1_%s", h1->GetName()), "gaus", -10., 10.);
    
    f1->SetParameter( 1, maxPos );
    h1->Fit(f1, "QRN");
    
    for( int i=0; i<4; ++i ) {

      float m = f1->GetParameter(1);
      float s = f1->GetParameter(2);
      float nSigmas = 1.2;
      f1->SetRange( m-nSigmas*s, m+nSigmas*s );
      if( i==3 ) 
        h1->Fit(f1, "RQ");
      else
        h1->Fit(f1, "RNQ");

    }


    f1->SetLineColor(kRed);
    returnConst = f1->GetParameter(1);

  } else if( opt==2 ) { // average of high bins

    float maximum = h1->GetMaximum();
    float thresh = 0.25*maximum;

    float total=0.;
    float denom = 0.;
    
    int nBins = h1->GetNbinsX();
    TH1F* h1_usedBins = new TH1F( Form("usedBins_%s", h1->GetName()), "", nBins, xMin, xMax );

    for( int ibin=1; ibin<nBins; ++ibin ) {

      if( h1->GetBinContent(ibin)<thresh ) continue;

      h1_usedBins->SetBinContent( ibin, h1->GetBinContent(ibin) );
  
      // average:
      total += h1->GetBinCenter(ibin)*h1->GetBinContent(ibin);
      denom += h1->GetBinContent(ibin);

      //// weighted average:
      //total += h1->GetBinCenter(ibin)*h1->GetBinContent(ibin);
      //denom += h1->GetBinContent(ibin);

    }

    TLine* lineThresh = new TLine( xMin, thresh, xMax, thresh );
    lineThresh->SetLineStyle(2);
    lineThresh->Draw("same");

    returnConst = total/denom;
    h1_usedBins->SetFillColor(kOrange);
    h1_usedBins->Draw("same");


  } else if( opt==3 ) { // maximum

    float maxBinCenter = h1->GetBinCenter(h1->GetMaximumBin());

    returnConst = maxBinCenter;

  }


  TLine* lineOffset = new TLine( returnConst, 0., returnConst, yMax );
  lineOffset->SetLineColor(kRed);
  lineOffset->SetLineWidth(3);
  lineOffset->Draw("same");

  TPaveText* offsetText = new TPaveText( 0.65, 0.7, 0.9, 0.9, "brNDC");
  offsetText->SetFillColor(0);
  offsetText->SetTextSize(0.035);
  if( returnConst>0. )
    offsetText->AddText( Form("offset = +%.1f mm", returnConst) );
  else
    offsetText->AddText( Form("offset = %.1f mm", returnConst) );
  offsetText->Draw("same");
  
  
  gPad->RedrawAxis();

  TPaveText* labelTop = DrawTools::getLabelTop();
  labelTop->Draw("same");

  c1->SaveAs(Form("%s/%s.eps", outputdir.c_str(), h1->GetName()));
  c1->SaveAs(Form("%s/%s.png", outputdir.c_str(), h1->GetName()));
  c1->SaveAs(Form("%s/%s.pdf", outputdir.c_str(), h1->GetName()));

  delete c1;
  delete axes;

  return returnConst;

}
コード例 #15
0
ファイル: drawScanY.C プロジェクト: Nabarun21/H4DQM
void run() {


  TGraphErrors* gr0 = new TGraphErrors(0);
  TGraphErrors* gr1 = new TGraphErrors(0);
  TGraphErrors* gr2 = new TGraphErrors(0);
  TGraphErrors* gr3 = new TGraphErrors(0);

  TGraphErrors* gr23 = new TGraphErrors(0);

  TGraphErrors* gr_cef3 = new TGraphErrors(0);
  gr_cef3->SetName("cef3");

  std::vector< std::pair<int, float> > run_pos;
  run_pos.push_back( std::pair< int, float>(225, 250.0) );
  run_pos.push_back( std::pair< int, float>(226, 251.0) );
  run_pos.push_back( std::pair< int, float>(227, 252.0) );
  run_pos.push_back( std::pair< int, float>(228, 253.0) );
  run_pos.push_back( std::pair< int, float>(229, 254.0) );
  run_pos.push_back( std::pair< int, float>(230, 248.0) );
  run_pos.push_back( std::pair< int, float>(231, 247.0) );
  run_pos.push_back( std::pair< int, float>(232, 246.0) );
  run_pos.push_back( std::pair< int, float>(233, 245.0) );
  run_pos.push_back( std::pair< int, float>(234, 244.0) );
  run_pos.push_back( std::pair< int, float>(235, 243.0) );
  run_pos.push_back( std::pair< int, float>(236, 242.0) );
  run_pos.push_back( std::pair< int, float>(237, 249.0) );
  run_pos.push_back( std::pair< int, float>(238, 255.0) );
  run_pos.push_back( std::pair< int, float>(239, 256.0) );
  run_pos.push_back( std::pair< int, float>(240, 257.0) );
  run_pos.push_back( std::pair< int, float>(241, 258.0) );
  run_pos.push_back( std::pair< int, float>(242, 259.0) );
  run_pos.push_back( std::pair< int, float>(243, 260.0) );
  run_pos.push_back( std::pair< int, float>(246, 261.0) );
  run_pos.push_back( std::pair< int, float>(247, 262.0) );
  run_pos.push_back( std::pair< int, float>(248, 263.0) );
  run_pos.push_back( std::pair< int, float>(249, 264.0) );
  run_pos.push_back( std::pair< int, float>(250, 265.0) );
  run_pos.push_back( std::pair< int, float>(251, 266.0) );
  run_pos.push_back( std::pair< int, float>(252, 267.0) );
  run_pos.push_back( std::pair< int, float>(253, 268.0) );
  run_pos.push_back( std::pair< int, float>(254, 270.0) );
  //run_pos.push_back( std::pair< int, float>(255, 272.5) );
  run_pos.push_back( std::pair< int, float>(244, 275.0) );

  for( unsigned i=0; i<run_pos.size(); ++i ) {

    hodoScan p(run_pos[i].first);
    std::vector<float> eff = p.Loop();
    gr0->SetPoint( i, run_pos[i].second, eff[0] );
    gr1->SetPoint( i, run_pos[i].second, eff[1] );
    gr2->SetPoint( i, run_pos[i].second, eff[2] );
    gr3->SetPoint( i, run_pos[i].second, eff[3] );
    
    gr23->SetPoint( i, run_pos[i].second, 0.5*(eff[3]+eff[2]) );
    
    cef3Scan c(run_pos[i].first);
    TH1F* h1_cef3 = c.Loop();
    
    //TF1* f1 = new TF1(Form("f1_%d", run_pos[i].first), "gaus", 3000., 6000.);
    //h1_cef3->Fit( f1, "RQL" );
    //for( unsigned j=0; j<4; ++j ) {
    //  float mu = f1->GetParameter(1);
    //  float sigma = f1->GetParameter(2);
    //  f1->SetRange( mu-sigma, mu+sigma );
    //  h1_cef3->Fit( f1, "RQL" );
    //}

    //TCanvas* c2 = new TCanvas("c2", "", 600, 600);
    //c2->cd();
    //h1_cef3->Draw();
    //c2->SaveAs(Form("provaY/%d.png", run_pos[i].first));
    //delete c2;
    //gr_cef3->SetPoint( i, run_pos[i].second, f1->GetParameter(1) );
    //gr_cef3->SetPointError( i, 0., f1->GetParError(1) );
  

    gr_cef3->SetPoint( i, run_pos[i].second, h1_cef3->GetBinCenter(h1_cef3->GetMaximumBin()));
    
  }

  TCanvas* c1 = new TCanvas("c1", "", 600, 600);
  c1->cd();

  TH2D* axes = new TH2D("axes", "", 10, 200., 300., 10, 0., 0.15 );
  axes->SetXTitle("Y Position [mm]");
  axes->SetYTitle("Efficiency");
  axes->Draw();

  gr0->SetMarkerStyle(20);
  gr0->SetMarkerColor(46);
  gr0->SetMarkerSize(1.);

  gr1->SetMarkerStyle(21);
  gr1->SetMarkerColor(29);
  gr1->SetMarkerSize(1.);

  gr2->SetMarkerStyle(22);
  gr2->SetMarkerColor(38);
  gr2->SetMarkerSize(1.);

  gr3->SetMarkerStyle(23);
  gr3->SetMarkerColor(kGreen+2);
  gr3->SetMarkerSize(1.);

  gr23->SetMarkerStyle(20);
  gr23->SetMarkerColor(kBlack);
  gr23->SetMarkerSize(1.);

  gr2->Draw("Psame");
  gr3->Draw("Psame");

  gr23->Draw("Psame");

  TLegend* legend = new TLegend(0.2, 0.6, 0.55, 0.9);
  legend->SetFillColor(0);
  legend->SetTextSize(0.035);
  legend->AddEntry( gr2, "2", "P" );
  legend->AddEntry( gr3, "3", "P" );
  legend->AddEntry( gr23, "2+3", "P" );
  legend->Draw("same");

  c1->SaveAs("posScanY.eps");
  c1->SaveAs("posScanY.png");

  TFile* file = TFile::Open("scanY.root", "recreate");

  file->cd();
  gr_cef3->Write();
  file->Close();

}
コード例 #16
0
ファイル: analyze.C プロジェクト: CmsHI/CVS_SavedFMa
void analyze(){

  int ifiles = 0;

  bool MC = false;
  bool correct = true;
  double drMax = 0.2;

  double ptMin = 0.3;
  double ptMax = 15;

  double jetPtMin = 7.;
  double jetEtaMax = 2.;
  double jetEMFMin = 0.01;

  const int nEtBins = 8;

  // === input ===
  TChain* tree = new TChain("Events");
  tree->Add("/d100/data/MinimumBias-ReReco/Jan29ReReco-v2/bambu/BSCNOBEAMHALO_000_*.root");
  //tree->Add("/d100/data/MinimumBias-ReReco/Jan29ReReco-v2/bambu/BSCNOBEAMHALO_000_1.root");
  
  // === ana config ===
  double etBinsArray[nEtBins] = {0,5,10,15,20,30,70,120};
  vector<double> etBins(etBinsArray,etBinsArray+nEtBins);

  string JECLevels = "L2:L3";
  //string JECTag = "900GeV_L2Relative_IC5Calo:900GeV_L3Absolute_IC5Calo";
  string JECTag = "900GeV_L2Relative_AK5Calo:900GeV_L3Absolute_AK5Calo";
  CombinedJetCorrector *JEC = new CombinedJetCorrector(JECLevels,JECTag);

  // === setup output ===
  char* outname = Form("hists.root",ifiles);
  TFile* outf = new TFile(outname,"recreate");
  TH1::SetDefaultSumw2();

  TH1D* hptTr[nEtBins+1];
  TH1D* hptGen[nEtBins+1];
  
  TTree * tree_ = new TTree("dijetTree","dijet tree");
  TreeDiJetEventData jd_;
  jd_.SetTree(tree_);
  jd_.SetBranches();

  for(int ih = 0; ih < nEtBins+1; ++ih){
    hptTr[ih] =  new TH1D(Form("hptTr%d",ih),Form("Tracks in cone |#Delta R| < %f; p_{T}^{track}; N_{track}/N_{jet}",drMax),250,ptMin,ptMax);
    hptGen[ih] =  new TH1D(Form("hptGen%d",ih),Form("Charged Particles in cone |#Delta R| < %f; p_{T}^{chg}; N_{chg}/N_{jet}",drMax),250,ptMin,ptMax);
  }

  TH1D* hptJet = new TH1D("hptJet",";p_{T} [GeV];jets",100,0,20);
  TH2D* hptCor = new TH2D("hptCor",";p_{T}^{raw} [GeV];p_{T}^{corrected} [GeV]",100,0,20,100,0,20);
  TH1D* hDR = new TH1D("hDR",";#Delta R;tracks",100,0,3.2);
  TH1D* hFFz = new TH1D("hFFz","",100,0,1.2);
  TH1D* hXi = new TH1D("hXi","",100,-2,8);
  TH1D* hFFzGen = new TH1D("hFFzGen","",100,0,1.2);
  TH1D* hXiGen = new TH1D("hXiGen","",100,-2,8);


  // === setup branches
  mithep::Array<mithep::CaloJet> *jets;
  mithep::Array<mithep::Track> *tracks;
  mithep::Array<mithep::Vertex> *vertices;
  mithep::L1TriggerMask *L1T;
  mithep::L1TriggerMask *L1A;
  mithep::Array<mithep::MCParticle> *genparticles;
  mithep::Array<mithep::GenJet> *genjets;
  mithep::EventHeader *evInfo;

  //tree->SetBranchAddress("ItrCone5Jets",&jets);
  tree->SetBranchAddress("AKt5Jets",&jets);
  tree->SetBranchAddress("Tracks",&tracks);
  tree->SetBranchAddress("PrimaryVertexes",&vertices);
  tree->SetBranchAddress("L1TechBitsBeforeMask",&L1T);
  tree->SetBranchAddress("L1AlgoBitsBeforeMask",&L1A);
  tree->SetBranchAddress("EventHeader",&evInfo);

  /*
  if(MC){
    tree->SetBranchAddress("MCParticles",&genparticles);
    tree->SetBranchAddress("IC5GenJets",&genjets);
  }
  */

  int nevents = tree->GetEntries();
  int nevtrig = 0;
  double njet[nEtBins] = {0.,0.,0.,0.,0.,0.,0.,0.};
  double ngenjet[nEtBins] = {0.,0.,0.,0.,0.,0.,0.,0.};

  //  nevents = 50;  
  for(int iev = 0; iev < nevents; ++iev){
    tree->GetEntry(iev);

    // clear jet data
    jd_.ClearCounters();

    // trigger info
    bool A0 = L1A->Get().TestBit(0);

    // run level
    UInt_t runNum=evInfo->RunNum();
    //  - good runs -
    if (!MC &&
	runNum!=123596 &&
	runNum!=123615 &&
	runNum!=123732 &&
	runNum!=123815 &&
	runNum!=123818 &&
	runNum!=123906 &&
	runNum!=123908 &&
	runNum!=124008 &&
	runNum!=124009 &&
	runNum!=124020 &&
	runNum!=124022 &&
	runNum!=124023 &&
	runNum!=124024 &&
	runNum!=124025 &&
	runNum!=124027 &&
	runNum!=124030 
       )
      continue;

    // print out info (out of good runs) before any filters
    cout << "Run #: " << runNum << " Event: " << evInfo->EvtNum() << " Lumi: " << evInfo->LumiSec() << " PhysDeclared?: " << evInfo->IsPhysDec()
      << " L1A0?: " << A0 << endl;

    // Filter on phys declared
    if (!MC && (!evInfo->IsPhysDec() || !A0)) continue;

    // === Event Level ===
    // if no vertex nothing to do
    if(vertices->GetEntries() < 1) continue;

    // there is a vertex
    const mithep::Vertex * vtx = (Vertex*)vertices->At(0);
    bool goodVertex = vtx->Ndof()> 4 && TMath::Abs(vtx->Z() < 15.);
    cout << " EventInfo - nvtx: " << vertices->GetEntries() << " vtxndof: " << vtx->Ndof() << endl;
    //  - save event info
    jd_.run_ = runNum;
    jd_.event_ = evInfo->EvtNum();
    jd_.vtxdof_ = vtx->Ndof();
    jd_.vz_ = vtx->Z();

    if(!goodVertex) { tree_->Fill(); continue; }

    //  - got good event vertex -
    nevtrig++;

    // === Jet Level ===
    int njets = jets->GetEntries();
    int nGoodJets = 0;
    double awayEtMax=-99;
    double ptljet[2] = {-99,-99};
    for(int i = 0; i < njets; ++i){
      CaloJet* jet = (CaloJet*)jets->At(i);

      jet->DisableCorrections();
      double ptjet = jet->Pt();
      double etajet = jet->Eta();
      double phijet = jet->Phi();
      if (ptjet>3) cout << "  raw jet "<<i<<": Pt|eta|phi: " << ptjet <<"|"<< etajet << "|" << phijet << endl;

      double emf = jet->EnergyFractionEm();

      bool goodJet = TMath::Abs(etajet) < jetEtaMax && emf > jetEMFMin;
      if(!goodJet) continue;

      double energy = jet->E();

      int jetbin = getBin(ptjet,etBins)+1;
      njet[jetbin] += 1.;

      hptJet->Fill(ptjet);


      double corpt = ptjet*JEC->getCorrection(ptjet,etajet,energy);
      hptCor->Fill(ptjet,corpt);

      if(correct) ptjet = corpt;

      if(ptjet< jetPtMin) continue;
      //cout << " jet" << i << " Good . corr"<<correct<<"Pt|eta|phi: " << ptjet <<"|"<< etajet << "|" << phijet << endl;
    }
    
    // === Dijet Ana ===
    if (njets<2) {
      // nothing to do for dijet ana, fill some inclusive track info
      int ntracks = tracks->GetEntries();
      int nHP = 0;
      for(int it = 0; it < ntracks; ++it){
	Track* track		       = (Track*)(tracks->At(it));
	mithep::TrackQuality& quality  = track->Quality();
	bool highPurity		       = quality.QualityMask().TestBit(2);
	jd_.trkNHits_[it]	       = track->NHits();
	jd_.trkHP_[it]		       = highPurity;
	jd_.ppt_[it]		       = track->Pt();
	jd_.peta_[it]		       = track->Eta();
	jd_.pphi_[it]		       = track->Phi();
	if (highPurity) ++nHP;
      }
      jd_.evtnp_		 = ntracks;
      jd_.fracHP_		 = (double)nHP/(double)ntracks;
      tree_->Fill();
      continue;
    }

    // there are 2 jets
    CaloJet* jet0 = (CaloJet*)jets->At(0);
    CaloJet* jet1 = (CaloJet*)jets->At(1);
    // apply corrections
    jet0->DisableCorrections();
    jet1->DisableCorrections();
    double ptjet0 = jet0->Pt();
    double ptjet1 = jet1->Pt();
    double etajet0 = jet0->Eta();
    double etajet1 = jet1->Eta();
    double phijet0 = jet0->Phi();
    double phijet1 = jet1->Phi();
    FourVectorM jet0p4 = jet0->RawMom();
    FourVectorM jet1p4 = jet1->RawMom();
    if(correct) {
      double scale = JEC->getCorrection(ptjet0,etajet0,jet0->E());
      ptjet0 *= scale;
      jet0p4 *= scale;
    }
    if(correct) {
      double scale = JEC->getCorrection(ptjet1,etajet1,jet1->E());
      ptjet1 *= scale;
      jet1p4 *= scale;
    }
    // cut jet
    //bool goodDiJet = ptjet0>1 && ptjet1>1;
    //if (!goodDiJet) continue;
    cout << " jet 0 corr"<<correct<<"Pt|eta|phi: " << ptjet0 <<"|"<< etajet0 << "|" << phijet0 << " p4: " << jet0p4 << endl;
    cout << " jet 1 corr"<<correct<<"Pt|eta|phi: " << ptjet1 <<"|"<< etajet1 << "|" << phijet1 << " p4: " << jet1p4 << endl;
    double ljdphi = TMath::Abs(reco::deltaPhi(phijet0,phijet1));
    cout << "   leading jets dphi: " << ljdphi << endl;
    // -- Fill jet info --
    // fill dijet info
    jd_.jdphi_	       = ljdphi;
    jd_.mass_	       = (jet0p4+jet1p4).M();

    // near/away info
    jd_.nljet_         = ptjet0;
    jd_.nljeta_	       = etajet0;
    jd_.nljphi_        = phijet0;
    jd_.nljemf_        = jet0->EnergyFractionEm();

    jd_.aljet_         = ptjet1;
    jd_.aljeta_	       = etajet1;
    jd_.aljphi_        = phijet1;
    jd_.aljemf_        = jet1->EnergyFractionEm();

    // === Track Level ===
    int ntracks = tracks->GetEntries();
    int nHP = 0;
    int selTrkCt = 0;
    for(int j = 0; j < ntracks; ++j){
      Track* track = (Track*)(tracks->At(j));

      double pttrack = track->Pt();
      double etatrack = track->Eta();
      double phitrack = track->Phi();


      mithep::TrackQuality& quality = track->Quality();

      if(0){
	double d0err = track->D0Err();
	double sigXY = sqrt(d0err*d0err + 0.04*0.04);
	double qope = track->QOverPErr();
	double lambdaerr = track->LambdaErr();
	double pz = track->Pz();
	int chg = track->Charge();
      }

      bool highPurity = quality.QualityMask().TestBit(2);
      //cout << "highPurity?: " << quality.QualityMask().TestBit(2) << endl;
      bool goodTrack = highPurity;
      if (highPurity) ++nHP;

      //if(!goodTrack) continue;
      //cout << "sel track: " << selTrkCt << " pt eta phi: " << pttrack << "|" << etatrack << "|" << phitrack << endl;

      // -- Fill Tracks --
      // fill frag candidates basic info
      jd_.trkNHits_[selTrkCt]      = track->NHits();
      jd_.trkHP_[selTrkCt]      = highPurity;
      jd_.ppt_[selTrkCt]      = pttrack;
      jd_.peta_[selTrkCt]     = etatrack;
      jd_.pphi_[selTrkCt]     = phitrack;

      // Relations to jet
      jd_.pndphi_[selTrkCt]   = TMath::Abs(reco::deltaPhi(phitrack,phijet0));
      jd_.pndeta_[selTrkCt]   = etatrack - etajet0;
      jd_.pndr_[selTrkCt]     = reco::deltaR(etatrack,phitrack,etajet0,phijet0);

      jd_.padphi_[selTrkCt]   = TMath::Abs(reco::deltaPhi(phitrack,phijet1));
      jd_.padeta_[selTrkCt]   = etatrack - etajet1;
      jd_.padr_[selTrkCt]     = reco::deltaR(etatrack,phitrack,etajet1,phijet1);

      //  - background variables-
      jd_.pndrbg_[selTrkCt]	  = reco::deltaR(etatrack,phitrack,etajet0,phijet0+TMath::Pi()/2);
      jd_.padrbg_[selTrkCt]	= reco::deltaR(etatrack,phitrack,etajet1,phijet1+TMath::Pi()/2);

      // jet cone info
      if (pttrack>0.3 && pttrack<60 && highPurity && track->NHits()>=8 && jd_.pndr_[selTrkCt]<0.5) ++jd_.nljCone5NP_;

      // fragmentation variables
      jd_.zn_[selTrkCt]	= pttrack/ptjet0;
      jd_.za_[selTrkCt] = pttrack/ptjet1;

      // save counter
      ++selTrkCt;


      /*
      double dr = reco::deltaR(etatrack,phitrack,etajet,phijet);
      hDR->Fill(dr);

      if(dr > drMax) continue;

      hptTr[0]->Fill(pttrack);
      hptTr[jetbin]->Fill(pttrack);

      if(pttrack < ptMin) continue;

      double ffz = pttrack/ptjet;
      double xi = -log(ffz);

      hFFz->Fill(ffz);
      hXi->Fill(xi);
      */
    } // tracks
    jd_.evtnp_		 = selTrkCt;
    jd_.fracHP_		 = (double)nHP/(double)ntracks;


    // mc input
    /*
    if(MC){
      int ngenjets = genjets->GetEntries();
      for(int i = 0; i < ngenjets; ++i){
	GenJet* jet = (GenJet*)genjets->At(i);

	double ptjet = jet->Pt();
	double etajet = jet->Eta();
	double phijet = jet->Phi();

	double energy = jet->E();

	int jetbin = getBin(ptjet,etBins)+1;
	ngenjet[jetbin] += 1.;

	int nparticles = genparticles->GetEntries();
	for(int j = 0; j < nparticles; ++j){
	  MCParticle* p = (MCParticle*)(genparticles->At(j));

	  int chg = p->Charge();

	  if(chg == 0 || chg < -10) continue;

	  double ptpar = p->Pt();
	  double etapar = p->Eta();
	  double phipar = p->Phi();

	  double dr = reco::deltaR(etapar,phipar,etapar,phipar);

	  if(dr > drMax) continue;

	  if(ptpar < ptMin) continue;
	  double ffz = ptpar/ptjet;
	  double xi = -log(ffz);
	  hFFzGen->Fill(ffz);
	  hXiGen->Fill(xi);


	}
      }

    }
    */

    // all done!
    tree_->Fill();
  } // event end

  hptJet->Draw();

  TCanvas* c2 = new TCanvas();
  hptCor->Draw("colz");

  TCanvas* c3 = new TCanvas();
  c3->Divide(2,2);
  c3->cd(1);
  hDR->Draw();

  c3->cd(2);
  hFFz->Draw();
  c3->cd(3);
  hXi->Draw();


  /*
  if(MC){
    TCanvas* c4 = new TCanvas();
    c4->Divide(2,2);
    c4->cd(1);

    c4->cd(2);
    hFFzGen->Draw();
    c4->cd(3);
    hXiGen->Draw();
  }
  */



  /*
  for(int is = 0; is < nEtBins; ++is){
    hptTr[is]->Write();
    hptGen[is]->Write();
  }

  hDR->Write();
  hFFz->Write();
  hXi->Write();
  */

  outf->Write();
  outf->Close();

  cout<<"---------------------------------------"<<endl;
  cout<<"Total Number of Events used : "<<nevtrig<<endl;
  cout<<"---------------------------------------"<<endl;
}
コード例 #17
0
ファイル: calcFOM_t2tt.C プロジェクト: laramaktub/STOP
void make2Dplot_MAX(TString setup, TString dir, int num, int MLSP,TString opt){

          gStyle->SetOptStat(0);
          gStyle->SetCanvasColor(0);
          gStyle->SetPadColor(0);
          gStyle->SetMarkerStyle(15);
          gStyle->SetMarkerSize(0.25);
          gStyle->SetTextFont(42);
          gStyle->SetMarkerColor(37);
	  if (num <3) {gStyle->SetPaintTextFormat("4.1f");}
	  
	  TString BDT ="";
	  
	  
	char cadena[128];
   // Crea un fichero de salida
   ofstream fs(setup+".txt"); 

   fs.setf(ios::fixed);
   fs.precision(1);
   

              TH2D* TwoDPlot = new TH2D("","",26,157.5, 812.5, 28, 12.5,712.5);

 	 
              for(int x=175; x<=800; x+=25){
           //   for(int x=175; x<=225; x+=25){

	
    	               for(int y=25; y<=700; y+=25){
		       
			       if (x - y > 99){ 
			       
			       
			               BDT = signalregiont2tt(x,y);
				       
				       cout << BDT << endl;
 
					
					double array[1] = {
							   FOM(setup,BDT,dir,x,y,num) 
							  
							   };
							   
				        double arraycut[1]= {
							   FOM(setup,BDT,dir,x,y,1) 
							  
							   };
					                                  
					


					double temp = 0.;
					int mvaval = 0;
					double tempcut=0.;

						// Get the maximum of each point for all MVAs
						  for(int i=0;i<1;i++){

							if(arraycut[i]>temp){ 

								temp	= arraycut[i]; 
								mvaval 	= i; 
								tempcut=array[i];
								
							}  
						  }
						  
						
						  
			
	
								if (num ==1) {TwoDPlot->Fill(x,y,temp);}
								if (num ==2) {TwoDPlot->Fill(x,y,tempcut);}
								if (num ==3) {
								if (BDT=="BDT1") mvaval=1;
								if (BDT=="BDT3") mvaval=3;
								if (BDT=="BDT4") mvaval=4;
								TwoDPlot->Fill(x,y,mvaval);}
								//	createTableCLs(x,y,temp);
								
			       }	
              	        }
			
			
			
	   }
	   
	                                                     
	   
	   fs.close();


           TCanvas c1("c1","c1",800,600);
	   c1.SetLeftMargin(0.1706731);
	   c1.SetRightMargin(0.1983173);
	   c1.SetTopMargin(0.04895105);
	   c1.SetBottomMargin(0.1416084);
	   c1.Range(-289.7381,-191.8196,1334.643,1074.487);
           TwoDPlot->SetMarkerSize(1.); 
           TwoDPlot->SetMarkerColor(kWhite); 
           TwoDPlot->Draw("COLZ TEXT");

           TwoDPlot->GetYaxis()->SetTitle("LSP mass"); 
           TwoDPlot->GetXaxis()->SetTitle("Stop mass");  
           if (num==0) {TwoDPlot->GetZaxis()->SetTitle("Entries"); TwoDPlot->GetZaxis()->SetRangeUser(0,5000);}
           if (num==1) {TwoDPlot->GetZaxis()->SetTitle("FOM"); TwoDPlot->GetZaxis()->SetRangeUser(0,15);}
           if (num==2) {TwoDPlot->GetZaxis()->SetTitle("Optimal cut point"); TwoDPlot->GetZaxis()->SetRangeUser(0,1);}
           if (num==3) {TwoDPlot->GetZaxis()->SetTitle("Best performing BDT training"); TwoDPlot->GetZaxis()->SetRangeUser(0,6);}
	   
	                                             
                                                                
	                                                        TFile* f = new TFile(dir+"_"+opt+".root","RECREATE");
	                                                        TwoDPlot->Write("twodplot");
	                                                        f->Write();
	                                                        f->Close();

           TLatex l1;
           l1.SetTextAlign(12);
           l1.SetTextSize(0.04);
           l1.SetNDC();
           l1.DrawLatex(0.155, 0.98, "CMS Simulation, 20 fb^{-1}");
           l1.DrawLatex(0.7, 0.98, "#sqrt{s} = 8 TeV");
           l1.SetTextSize(0.03);
	   
	   
	   
	
	 
	 	
	   
	   
	   if (num==3){
	   
	   
       tex = new TLatex(0.7449749,0.8251748,"BDT1");
tex->SetNDC();
   tex->SetTextAlign(12);
   tex->SetTextFont(42);
   tex->SetTextSize(0.03);
   tex->SetTextAngle(41.15586);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.7449749,0.7097902,"BDT2");
tex->SetNDC();
   tex->SetTextAlign(12);
   tex->SetTextFont(42);
   tex->SetTextSize(0.03);
   tex->SetTextAngle(41.15586);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.7437186,0.5891608,"BDT3");
tex->SetNDC();
   tex->SetTextAlign(12);
   tex->SetTextFont(42);
   tex->SetTextSize(0.03);
   tex->SetTextAngle(41.15586);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.7424623,0.4755245,"BDT4");
tex->SetNDC();
   tex->SetTextAlign(12);
   tex->SetTextFont(42);
   tex->SetTextSize(0.03);
   tex->SetTextAngle(41.15586);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.7424623,0.3583916,"BDT5");
tex->SetNDC();
   tex->SetTextAlign(12);
   tex->SetTextFont(42);
   tex->SetTextSize(0.03);
   tex->SetTextAngle(41.15586);
   tex->SetLineWidth(2);
   tex->Draw();
      tex = new TLatex(0.7424623,0.2447552,"BDT6");
tex->SetNDC();
   tex->SetTextAlign(12);
   tex->SetTextFont(42);
   tex->SetTextSize(0.03);
   tex->SetTextAngle(41.15586);
   tex->SetLineWidth(2); 
     tex->Draw();
   
   }
	    
	    
TString dataset_name;
TString datasetnombre;
          if (dir == "T2bw025") {dataset_name = "t2bw_025";}
          if (dir == "T2bw050") {dataset_name = "t2bw_050";}
          if (dir == "T2bw075") {dataset_name = "t2bw_075";}
	if (dir == "T2tt") {dataset_name = "t2tt_all";}
	  if (dir == "T2tt") {datasetnombre = "t2tt_half";} 
	  
//if (num==0) c1.Print("~/www/STOP/BDTTraining/08TeV/"+dataset_name+"/"+setup+"/Entries_Lara.png");
//if (num==1) c1.Print("~/www/STOP/BDTTraining/08TeV/"+dataset_name+"/"+setup+"/FOM_Lara.png");
//if (num==2) c1.Print("~/www/STOP/BDTTraining/08TeV/"+dataset_name+"/"+setup+"/OptimalCut_Lara.png");
//if (num==3) c1.Print("~/www/STOP/BDTTraining/08TeV/"+dataset_name+"/"+setup+"/BestBDT_Lara.png");

if (num==0) c1.Print("~/www/STOP/BDTTraining/8TeV/"+datasetnombre+"/BestSet/Entries_Lara_SR_fixcut.png");
if (num==1) c1.Print("~/www/STOP/BDTTraining/8TeV/"+datasetnombre+"/BestSet/FOM_Lara_SR_fixcut.png");
if (num==2) c1.Print("~/www/STOP/BDTTraining/8TeV/"+datasetnombre+"/BestSet/OptimalCut_Lara_SR_fixcut.png");
if (num==3) c1.Print("~/www/STOP/BDTTraining/8TeV/"+datasetnombre+"/BestSet/BestBDT_Lara_SR_fixcut.png");


}
コード例 #18
0
ファイル: ShowSPDConfiguration.C プロジェクト: alisw/AliRoot
void ShowSPDConfiguration(Int_t runNb=0, const char *ocdblocation="local://$ALICE_ROOT/OCDB", bool grid=kFALSE,bool threed=kFALSE){


  gStyle->SetOptStat(0);

  if(grid){
    TGrid::Connect("alien://");
    if(!gGrid){
      printf("no grid connection is available, exiting.\n");
      return;
    }
  }
  AliITSOnlineCalibrationSPDhandler *h = new AliITSOnlineCalibrationSPDhandler();
  h->ReadDeadFromDB(runNb,ocdblocation);
  AliCDBManager::Instance();
  AliCDBManager::Instance()->SetRun(runNb);
  AliCDBManager::Instance()->SetDefaultStorage(ocdblocation);
  AliGeomManager::LoadGeometry();

  if(threed) {
    Draw3D(h);  
    return;
  }

  Double_t nact[2]={0.,0.};

  TCanvas *c = new TCanvas("c","Active Modules ",500,700);
  c->Divide(1,2);
  c->cd(1);
  TH2D *hPhiZInner = new TH2D("hPhiZInner","Inner layer Active Modules ",200,-20,20,3,0,2*TMath::Pi());
  hPhiZInner->SetXTitle("Z (cm)");
  hPhiZInner->SetYTitle("#varphi (rad)");
  hPhiZInner->Draw();

  for(Int_t i=0; i<80; i++){
    if((h->GetNrBad(i))<1) {
      TGeoHMatrix matrix;
      int vid = AliITSAlignMille2Module::GetVolumeIDFromIndex(i);
      AliITSAlignMille2Module::SensVolMatrix(vid,&matrix);
      Double_t local0[3],local1[3],local2[3],local3[3]; // local position of the four angles
      local0[0]=-0.6375; local0[1]=0; local0[2]= 3.48; 
      local1[0]=-0.6375; local1[1]=0; local1[2]= -3.48; 
      local2[0]=0.6375; local2[1]=0; local2[2]= -3.48; 
      local2[0]=0.6375; local3[1]=0; local3[2]= 3.48; 
      Double_t global0[3],global1[3],global2[3],global3[3];
      matrix.LocalToMaster(local0,global0);
      matrix.LocalToMaster(local1,global1);
      matrix.LocalToMaster(local2,global2);
      matrix.LocalToMaster(local3,global3);
      Double_t phiUp = atan2(global0[1],global0[0]);
      if(phiUp<0) phiUp+=2*TMath::Pi();
      Double_t phiDown = atan2(global2[1],global2[0]);
      if(phiDown<0) phiDown+=2*TMath::Pi();
      TLine *lhor1 = new TLine(global0[2],phiDown,global1[2],phiDown); lhor1->Draw("same");
      lhor1->SetLineColor(kBlue);
      lhor1->SetLineWidth(3); 
      TLine *lver1 = new TLine(global1[2],phiDown,global2[2],phiUp); lver1->Draw("same");
      lver1->SetLineColor(kBlue);
      lver1->SetLineWidth(3); 
      TLine *lhor2 = new TLine(global2[2],phiUp,global3[2],phiUp); lhor2->Draw("same");
      lhor2->SetLineColor(kBlue);
      lhor2->SetLineWidth(3); 
      TLine *lver2 = new TLine(global3[2],phiUp,global0[2],phiDown); lver2->Draw("same");
      lver2->SetLineColor(kBlue);
      lver2->SetLineWidth(3); 
      nact[0]++;
    } 
  }
  c->cd(2);

  TH2D *hPhiZOuter = new TH2D("hPhiZOuter","Outer layer Active Modules ",200,-20,20,3,0,2*TMath::Pi());
  hPhiZOuter->SetXTitle("Z (cm)");
  hPhiZOuter->SetYTitle("#varphi (rad)");
  hPhiZOuter->Draw();
  for(Int_t i=80; i<240; i++){
    TGeoHMatrix matrix;
    int vid = AliITSAlignMille2Module::GetVolumeIDFromIndex(i);
    AliITSAlignMille2Module::SensVolMatrix(vid,&matrix);
    Double_t local[4][3]; // local position of the four angles
    local[0][0]=0.6375; local[0][1]=0; local[0][2]= -3.48;
    local[1][0]=0.6375; local[1][1]=0; local[1][2]= 3.48;
    local[2][0]=-0.6375; local[2][1]=0; local[2][2]= 3.48;
    local[2][0]=-0.6375; local[3][1]=0; local[3][2]= -3.48;
    Double_t global[4][3];
    for(Int_t j=0; j<4; j++){
      matrix.LocalToMaster(local[j],global[j]);
    }
    Double_t phiUp = atan2(global[0][1],global[0][0]);
    if(phiUp<0) phiUp+=2*TMath::Pi();
    Double_t phiDown = atan2(global[2][1],global[2][0]);
    if(phiDown<0) phiDown+=2*TMath::Pi();
    if(i>235) if(phiUp < 0.1) phiUp = TMath::Pi()*2;
    //  printf("module %i  -   phiDown %f   phiUp %f \n",i,phiDown,phiUp); 
    if((h->GetNrBad(i))<1) {
      TLine *lhor1 = new TLine(global[0][2],phiUp,global[1][2],phiUp); lhor1->Draw("same");
      lhor1->SetLineColor(kBlue);
      lhor1->SetLineWidth(2); 
      TLine *lver1 = new TLine(global[1][2],phiUp,global[2][2],phiDown); lver1->Draw("same");
      lver1->SetLineColor(kBlue);
      lver1->SetLineWidth(2); 
      TLine *lhor2 = new TLine(global[2][2],phiDown,global[3][2],phiDown); lhor2->Draw("same");
      lhor2->SetLineColor(kBlue);
      lhor2->SetLineWidth(2); 
      TLine *lver2 = new TLine(global[3][2],phiDown,global[0][2],phiUp); lver2->Draw("same");
      lver2->SetLineColor(kBlue);
      lver2->SetLineWidth(2); 
      nact[1]++; 
    } 
  }
  printf("  \n   Number of Active SPD modules (->Total)  : inner %3.0f (80) %f   -  outer %3.0f (160)  %f \n",nact[0],nact[0]/80.,nact[1],nact[1]/160.);
  c->SaveAs(Form("active%i.png",runNb));
}
コード例 #19
0
ファイル: ExclusionPlot.C プロジェクト: SusyRa2b/NtupleTools
void CommandMSUGRA(TString plotName_,Int_t tanBeta_, Bool_t plotLO_){
  gROOT->SetStyle("CMS");//jmt specific
  gROOT->ForceStyle();

  gStyle->SetOptTitle(0);
  gStyle->SetOptStat(0);
  gStyle->SetPalette(1); 
  gStyle->SetTextFont(42);
  gStyle->SetFrameBorderMode(0);

  //convert tanb value to string
  std::stringstream tmp;
  tmp << tanBeta_;
  TString tanb( tmp.str() );
  
  
  // Output file
  std::cout << " create " << plotName_ << std::endl;
  TFile* output = new TFile( plotName_, "RECREATE" );
  if ( !output || output->IsZombie() ) { std::cout << " zombie alarm output is a zombie " << std::endl; }
  

  //set old exclusion Limits
  TGraph* LEP_ch = set_lep_ch(tanBeta_);
  TGraph* LEP_sl = set_lep_sl(tanBeta_);//slepton curve
  TGraph* TEV_sg_cdf = set_tev_sg_cdf(tanBeta_);//squark gluino cdf
  TGraph* TEV_sg_d0 = set_tev_sg_d0(tanBeta_);//squark gluino d0
  //  TGraph* TEV_tlp_cdf = set_tev_tlp_cdf(tanBeta_);//trilepton cdf
  //  TGraph* TEV_tlp_d0 = set_tev_tlp_d0(tanBeta_);//trilepton d0
  TGraph* stau   = set_tev_stau(tanBeta_);//stau 
  TGraph* NoEWSB = set_NoEWSB(tanBeta_); 

  TGraph* TEV_sn_d0_1 = set_sneutrino_d0_1(tanBeta_);
  TGraph* TEV_sn_d0_2 = set_sneutrino_d0_2(tanBeta_);

  int nPoints = nSusyGridPoints();
  double m0[nPoints],m12[nPoints],squarkMass[nPoints],gluinoMass[nPoints];

  susyGrid(m0,m12,squarkMass,gluinoMass);

  TGraph2D* squarkMasses = new TGraph2D("squarkMasses","",nPoints,m0,m12,squarkMass);
  TGraph2D* gluinoMasses = new TGraph2D("gluinoMasses","",nPoints,m0,m12,gluinoMass);

  TH2D* gluinoMassPlot = gluinoMasses->GetHistogram();
  TH2D* squarkMassPlot = squarkMasses->GetHistogram();

  //constant ssqquark and gluino lines
  TF1* lnsq[15];
  TF1* lngl[15];

  TGraph* lnsq_40[15];
  TGraph* lngl_40[15];
  
  TLatex* sq_text[15];
  TLatex* gl_text[15];

  TLatex* sq_40_text[15];
  TLatex* gl_40_text[15];

  for(int i = 1; i < 15; i++){
    //lnsq[i] = constant_squark(tanBeta_,i);
    //sq_text[i] = constant_squark_text(i,*lnsq[i],tanBeta_);
    //lngl[i] = constant_gluino(tanBeta_,i);
    //gl_text[i] = constant_gluino_text(i,*lngl[i]);
    lnsq_40[i] = constant_mass(i*250,squarkMasses);
    lngl_40[i] = constant_mass(i*250,gluinoMasses);
    sq_40_text[i] = constant_squark_text_tanBeta40(i*250,lnsq_40[i]);
    gl_40_text[i] = constant_gluino_text_tanBeta40(i*250,lngl_40[i]);;
  }


  //Legends
  TLegend* legst  = makeStauLegend(0.05,tanBeta_);
  TLegend* legNoEWSB  = makeNoEWSBLegend(0.05,tanBeta_);
  TLegend* legexp = makeExpLegend( *TEV_sg_cdf,*TEV_sg_d0,*LEP_ch,*LEP_sl,*TEV_sn_d0_1,0.035,tanBeta_);
  
 
  //make Canvas
  TCanvas* cvsSys = new TCanvas("cvsnm","cvsnm",0,0,800,600);
  gStyle->SetOptTitle(0);
  cvsSys->SetFillColor(0);
  cvsSys->GetPad(0)->SetRightMargin(0.07);
  cvsSys->Range(-120.5298,26.16437,736.0927,750);
  //  cvsSys->Range(-50.5298,26.16437,736.0927,500);
  cvsSys->SetFillColor(0);
  cvsSys->SetBorderMode(0);
  cvsSys->GetPad(0)->SetBorderMode(0);
  cvsSys->GetPad(0)->SetBorderSize(2);
  cvsSys->GetPad(0)->SetLeftMargin(0.1407035);
  cvsSys->GetPad(0)->SetTopMargin(0.08);
  cvsSys->GetPad(0)->SetBottomMargin(0.13);

  cvsSys->SetTitle("tan#beta="+tanb);
 
  output->cd();
  
//and now  the exclusion limits


  TGraph* SSdilep;
  TGraphErrors* OSdilep;
  TGraphErrors* RA1;

  TGraphErrors* RA1_old;
  TGraphErrors* RA5_old;
  TGraphErrors* RA6_old;

  TGraph* RA2b_1b_loose;
  TGraph* RA2b_1b_tight;
  TGraph* RA2b_2b_loose;
  TGraph* RA2b_2b_tight;

  TGraph* RA2b_1b_loose_exp;
  TGraph* RA2b_1b_tight_exp;
  TGraph* RA2b_2b_loose_exp;
  TGraph* RA2b_2b_tight_exp;

  TGraph* RA2b_1b_loose_exp_p;
  TGraph* RA2b_1b_tight_exp_p;
  TGraph* RA2b_2b_loose_exp_p;
  TGraph* RA2b_2b_tight_exp_p;

  TGraph* RA2b_1b_loose_exp_m;
  TGraph* RA2b_1b_tight_exp_m;
  TGraph* RA2b_2b_loose_exp_m;
  TGraph* RA2b_2b_tight_exp_m;

  TGraph* RA2b_1b_loose_shade;
  TGraph* RA2b_1b_tight_shade;
  TGraph* RA2b_2b_loose_shade;
  TGraph* RA2b_2b_tight_shade;

  TSpline3* RA1_tb40 =getCLs1080ObsNLOtb40();

  if (tanBeta_ == 10) {
    SSdilep = SSdilep_NLO();
    OSdilep = OSdilep_NLO();
    RA1 = RA1_NLO();

    RA1_old = getRA1Observed_NLO_tanBeta10();
    RA5_old = getRA5Observed_NLO_tanBeta10();
    RA6_old = getRA6Observed_NLO_tanBeta10();

  }
  if(tanBeta_ == 40)
    {
//       RA2b_1b_loose = RA2b_limit("an-scanplot-unblind-tb40-withcontam-ge1b-loose.root", "hsusyscanExcluded");
//       RA2b_2b_loose = RA2b_limit("an-scanplot-unblind-tb40-withcontam-ge2b-loose.root", "hsusyscanExcluded");
//       RA2b_1b_tight = RA2b_limit("an-scanplot-unblind-tb40-withcontam-ge1b-tight.root", "hsusyscanExcluded");
//       RA2b_2b_tight = RA2b_limit("an-scanplot-unblind-tb40-withcontam-ge2b-tight.root", "hsusyscanExcluded");
//       RA2b_1b_loose = RA2b_limit("/afs/cern.ch/user/o/owen/public/RA2b/clsplots-tb40-ge1bloose.root", "hcls");
//       RA2b_2b_loose = RA2b_limit("/afs/cern.ch/user/o/owen/public/RA2b/clsplots-tb40-ge2bloose.root", "hcls");
//       RA2b_1b_tight = RA2b_limit("/afs/cern.ch/user/o/owen/public/RA2b/clsplots-tb40-ge1btight.root", "hcls");
//       RA2b_2b_tight = RA2b_limit("/afs/cern.ch/user/o/owen/public/RA2b/clsplots-tb40-ge2btight.root", "hcls");

/* 
     TString ra2bfile= "RA2b_tb40_exclusion.25Sep.root";
      RA2b_1b_loose = RA2b_limit(ra2bfile,"curve4_ge1bloose");
      RA2b_1b_tight = RA2b_limit(ra2bfile,"curve4_ge1btight");
      RA2b_2b_loose = RA2b_limit(ra2bfile,"curve4_ge2bloose");
      RA2b_2b_tight = RA2b_limit(ra2bfile,"curve4_ge2btight");

      RA2b_1b_loose_exp = RA2b_limit(ra2bfile,"curve4_1bloose_exp");
      RA2b_1b_tight_exp = RA2b_limit(ra2bfile,"curve4_1btight_exp");
      RA2b_2b_loose_exp = RA2b_limit(ra2bfile,"curve4_2bloose_exp");
      RA2b_2b_tight_exp = RA2b_limit(ra2bfile,"curve4_2btight_exp");

      RA2b_1b_loose_exp_p = RA2b_limit(ra2bfile,"curve4_1bloose_exp_plus");
      RA2b_1b_tight_exp_p = RA2b_limit(ra2bfile,"curve4_1btight_exp_plus");
      RA2b_2b_loose_exp_p = RA2b_limit(ra2bfile,"curve4_2bloose_exp_plus");
      RA2b_2b_tight_exp_p = RA2b_limit(ra2bfile,"curve4_2btight_exp_plus");

      RA2b_1b_loose_exp_m = RA2b_limit(ra2bfile,"curve4_1bloose_exp_minus");
      RA2b_1b_tight_exp_m = RA2b_limit(ra2bfile,"curve4_1btight_exp_minus");
      RA2b_2b_loose_exp_m = RA2b_limit(ra2bfile,"curve4_2bloose_exp_minus");
      RA2b_2b_tight_exp_m = RA2b_limit(ra2bfile,"curve4_2btight_exp_minus");
*/
      RA2b_1b_loose = get_RA2b_1bloose();
      RA2b_1b_tight = get_RA2b_1btight();
      RA2b_2b_loose = get_RA2b_2bloose();
      RA2b_2b_tight = get_RA2b_2btight();

      RA2b_1b_loose_exp = get_RA2b_1bloose_exp();
      RA2b_1b_tight_exp = get_RA2b_1btight_exp();
      RA2b_2b_loose_exp = get_RA2b_2bloose_exp();
      RA2b_2b_tight_exp = get_RA2b_2btight_exp();
    
      RA2b_1b_loose_exp_p = get_RA2b_1bloose_exp_p();
      RA2b_1b_tight_exp_p = get_RA2b_1btight_exp_p();
      RA2b_2b_loose_exp_p = get_RA2b_2bloose_exp_p();
      RA2b_2b_tight_exp_p = get_RA2b_2btight_exp_p();

      RA2b_1b_loose_exp_m = get_RA2b_1bloose_exp_m();
      RA2b_1b_tight_exp_m = get_RA2b_1btight_exp_m();
      RA2b_2b_loose_exp_m = get_RA2b_2bloose_exp_m();
      RA2b_2b_tight_exp_m = get_RA2b_2btight_exp_m();
   
      cout<<"Getting the shaded regions"<<endl;
      RA2b_1b_loose_shade = getShadedRegion(RA2b_1b_loose_exp_p,RA2b_1b_loose_exp_m);
      RA2b_1b_tight_shade = getShadedRegion(RA2b_1b_tight_exp_p,RA2b_1b_tight_exp_m);
      RA2b_2b_loose_shade = getShadedRegion(RA2b_2b_loose_exp_p,RA2b_2b_loose_exp_m);
      RA2b_2b_tight_shade = getShadedRegion(RA2b_2b_tight_exp_p,RA2b_2b_tight_exp_m);
      cout<<"DONE Getting the shaded regions"<<endl;
    }



  double m0min = 0;
  if (tanBeta_ == 40) m0min=400; 
  TH2D* hist = new TH2D("h","h",100,m0min,2000,100,120,700);
  hist->Draw();  
  hist->GetXaxis()->SetTitle("m_{0} [GeV]");
  hist->GetYaxis()->SetTitle("m_{1/2} [GeV]");
  hist->GetXaxis()->SetTitleOffset(.9);
  hist->GetXaxis()->SetTitleSize(0.06);
  hist->GetYaxis()->SetTitleOffset(1.0);
  hist->GetYaxis()->SetTitleSize(0.06);

  hist->GetXaxis()->SetNdivisions(506);
  //  if (tanBeta_ == 50)  hist->GetXaxis()->SetNdivisions(504);
  hist->GetYaxis()->SetNdivisions(506);

  int col[]={2,3,4};

  //SSdilep->SetLineColor(kGreen+2);
  //SSdilep->SetLineStyle(1);
  //SSdilep->SetLineWidth(3);
  //
  //OSdilep->SetLineColor(kCyan+2);
  //OSdilep->SetLineStyle(1);
  //OSdilep->SetLineWidth(3);
  //
  //RA1->SetLineColor(kRed+2);
  //RA1->SetLineStyle(1);
  //RA1->SetLineWidth(3);
  RA1_tb40->SetLineColor(kBlack);
  RA1_tb40->SetLineStyle(7);
  RA1_tb40->SetLineWidth(3);
  RA1_tb40->SetName("RA1_tb40");
  //
  //TSpline3 *sRA1 = new TSpline3("sRA1",RA1_old);
  //sRA1->SetLineColor(kRed+2);
  ////sRA1->SetLineStyle(5);
  //sRA1->SetLineStyle(2);
  //sRA1->SetLineWidth(3);
  //
  //RA5_old->SetLineColor(kGreen+2);
  ////RA5_old->SetLineStyle(5);
  //RA5_old->SetLineStyle(2);
  //RA5_old->SetLineWidth(3);
  //
  //RA6_old->SetLineColor(kCyan+2);
  ////RA6_old->SetLineStyle(1);
  //RA6_old->SetLineStyle(2);
  //RA6_old->SetLineWidth(3);

  if (RA2bmode.Contains("all")) {
  RA2b_1b_loose->SetLineColor(kRed+2);
  RA2b_1b_loose->SetLineStyle(2);
  RA2b_1b_loose->SetLineWidth(3);
         
  RA2b_1b_tight->SetLineColor(kRed+2);
  RA2b_1b_tight->SetLineStyle(1);
  RA2b_1b_tight->SetLineWidth(3);
         
  RA2b_2b_loose->SetLineColor(kGreen+2);
  RA2b_2b_loose->SetLineStyle(2);
  RA2b_2b_loose->SetLineWidth(3);
         
  RA2b_2b_tight->SetLineColor(kGreen+2);
  RA2b_2b_tight->SetLineStyle(1);
  RA2b_2b_tight->SetLineWidth(3);
  }
  else {
  RA2b_1b_loose->SetLineColor(kRed);
  RA2b_1b_loose->SetLineStyle(1);
  RA2b_1b_loose->SetLineWidth(3);
         
  RA2b_1b_tight->SetLineColor(kRed);
  RA2b_1b_tight->SetLineStyle(1);
  RA2b_1b_tight->SetLineWidth(3);
         
  RA2b_2b_loose->SetLineColor(kRed);
  RA2b_2b_loose->SetLineStyle(1);
  RA2b_2b_loose->SetLineWidth(3);
         
  RA2b_2b_tight->SetLineColor(kRed);
  RA2b_2b_tight->SetLineStyle(1);
  RA2b_2b_tight->SetLineWidth(3);

  RA2b_1b_loose_exp->SetLineColor(kBlue);
  RA2b_2b_loose_exp->SetLineColor(kBlue);
  RA2b_1b_tight_exp->SetLineColor(kBlue);
  RA2b_2b_tight_exp->SetLineColor(kBlue);

  RA2b_1b_loose_exp->SetLineStyle(5);
  RA2b_2b_loose_exp->SetLineStyle(5);
  RA2b_1b_tight_exp->SetLineStyle(5);
  RA2b_2b_tight_exp->SetLineStyle(5);

  RA2b_1b_loose_exp->SetLineWidth(3);
  RA2b_2b_loose_exp->SetLineWidth(3);
  RA2b_1b_tight_exp->SetLineWidth(3);
  RA2b_2b_tight_exp->SetLineWidth(3);

  int acolor=kCyan+2;
  RA2b_1b_loose_exp_p->SetLineColor(acolor);
  RA2b_2b_loose_exp_p->SetLineColor(acolor);
  RA2b_1b_tight_exp_p->SetLineColor(acolor);
  RA2b_2b_tight_exp_p->SetLineColor(acolor);

  RA2b_1b_loose_exp_p->SetLineStyle(1);
  RA2b_2b_loose_exp_p->SetLineStyle(1);
  RA2b_1b_tight_exp_p->SetLineStyle(1);
  RA2b_2b_tight_exp_p->SetLineStyle(1);

  RA2b_1b_loose_exp_p->SetLineWidth(3);
  RA2b_2b_loose_exp_p->SetLineWidth(3);
  RA2b_1b_tight_exp_p->SetLineWidth(3);
  RA2b_2b_tight_exp_p->SetLineWidth(3);

  RA2b_1b_loose_exp_m->SetLineColor(acolor);
  RA2b_2b_loose_exp_m->SetLineColor(acolor);
  RA2b_1b_tight_exp_m->SetLineColor(acolor);
  RA2b_2b_tight_exp_m->SetLineColor(acolor);

  RA2b_1b_loose_exp_m->SetLineStyle(1);
  RA2b_2b_loose_exp_m->SetLineStyle(1);
  RA2b_1b_tight_exp_m->SetLineStyle(1);
  RA2b_2b_tight_exp_m->SetLineStyle(1);

  RA2b_1b_loose_exp_m->SetLineWidth(3);
  RA2b_2b_loose_exp_m->SetLineWidth(3);
  RA2b_1b_tight_exp_m->SetLineWidth(3);
  RA2b_2b_tight_exp_m->SetLineWidth(3);

  RA2b_1b_tight_shade->SetFillStyle(fillstyle);
  RA2b_1b_tight_shade->SetFillColor(acolor);

  RA2b_1b_loose_shade->SetFillStyle(fillstyle);
  RA2b_1b_loose_shade->SetFillColor(acolor);

  RA2b_2b_tight_shade->SetFillStyle(fillstyle);
  RA2b_2b_tight_shade->SetFillColor(acolor);

  RA2b_2b_loose_shade->SetFillStyle(fillstyle);
  RA2b_2b_loose_shade->SetFillColor(acolor);

  }
  
  TLegend* myleg;

  float leg_x1=0.39+0.23;
  float leg_y1=0.65+0.05;
  float leg_x2= 0.55+0.25;
  float leg_y2= 0.84+0.05;

  if (RA2bmode.Contains("all")) {
    leg_y1 -= 0.1;
  }

  if( plotLO_ ) myleg = new TLegend(0.3,0.65,0.65,0.8,NULL,"brNDC");
  else          myleg = new TLegend(leg_x1,leg_y1,leg_x2,leg_y2,NULL,"brNDC");


  myleg->SetFillColor(0); 
  myleg->SetShadowColor(0);
  myleg->SetTextSize(0.04);
  myleg->SetBorderSize(0);

  TLegendEntry *entry=0;
//   entry= myleg->AddEntry("ge1bLoose","LEP2 #tilde{#chi}_{1}^{#pm}","f");

//   entry->SetFillColor(3);
//   entry->SetLineColor(3);
//   entry->SetFillStyle(1001);


  if (RA2bmode.Contains("all")) {
    entry= myleg->AddEntry("ge1bLoose","#geq 1b Loose","l");
    entry->SetLineColor(1);
    entry->SetLineStyle(2);
    entry->SetLineWidth(3);
    entry->SetLineColor(kRed+2);
    entry->SetTextColor(kRed+2);
    
    entry=myleg->AddEntry("ge2bLoose","#geq 2b Loose","l");
    entry->SetLineColor(1);
    entry->SetLineStyle(2);
    entry->SetLineWidth(3);
    entry->SetLineColor(kGreen+2);
    entry->SetTextColor(kGreen+2);
    
    entry=myleg->AddEntry("ge1bTight","#geq 1b Tight","l");
    entry->SetLineColor(1);
    entry->SetLineStyle(1);
    entry->SetLineWidth(3);
    entry->SetLineColor(kRed+2);
    entry->SetTextColor(kRed+2);
    
    entry=myleg->AddEntry("ge2bTight","#geq 2b Tight","l");
    entry->SetLineColor(1);
    entry->SetLineStyle(1);
    entry->SetLineWidth(3);
    entry->SetLineColor(kGreen+2);
    entry->SetTextColor(kGreen+2);
  }
  else if (RA2bmode.Contains("ge")) {
    entry=myleg->AddEntry("ge1bTight","Observed Limit","l");
    entry->SetLineStyle(1);
    entry->SetLineWidth(3);
    entry->SetLineColor(kRed);
    entry->SetTextColor(kBlack);

    entry=myleg->AddEntry("ge1bTight_exp","Expected Limit #pm 1#sigma","lf");
    entry->SetFillStyle (fillstyle);
    entry->SetFillColor (kCyan+2);
    entry->SetLineStyle(5);
    entry->SetLineWidth(3);
    entry->SetLineColor(kBlue);
    entry->SetTextColor(kBlack);


  }
  
   if (RA2bmode=="allPlusRA1") {
    entry=myleg->AddEntry("RA1_tb40","CMS #alpha_{T}","l");
    entry->SetLineColor(kBlack);
    entry->SetLineStyle(7);
    entry->SetLineWidth(3);
    entry->SetTextColor(kBlack);
   }  

  //constant squark and gluino mass contours
  for (int it=2;it<9;it++) {  
    if(it<7){
      if(lngl_40[it]!=0)lngl_40[it]->Draw("samec");   
      if(gl_40_text[it]!=0)gl_40_text[it]->Draw();
    }
      if(lnsq_40[it]!=0)lnsq_40[it]->Draw("samec");
    if(it<6){
      if(sq_40_text[it]!=0)sq_40_text[it]->Draw();
    }
  }
  //SSdilep->Draw("samec");
  //OSdilep->Draw("samec");
  //RA1->Draw("samec");
  //
  //sRA1->Draw("same"); 
  //RA5_old->Draw("c same");
  //RA6_old->Draw("c same");
  TString drawopt="samel"; //default choice
  if (RA2bmode.Contains("all"))  RA2b_1b_loose->Draw(drawopt);
  if (RA2bmode.Contains("all")) RA2b_2b_loose->Draw(drawopt);
  if (RA2bmode.Contains("all")) RA2b_1b_tight->Draw(drawopt);
  if (RA2bmode.Contains("all")) RA2b_2b_tight->Draw(drawopt);
  if (RA2bmode=="allPlusRA1") RA1_tb40->Draw(drawopt);

  if (RA2bmode=="ge1btight") {
    RA2b_1b_tight_shade->Draw("f");
    RA2b_1b_tight_exp_p->Draw(drawopt);
    RA2b_1b_tight_exp_m->Draw(drawopt);
    RA2b_1b_tight_exp->Draw(drawopt);
    RA2b_1b_tight->Draw(drawopt);
  }
  else if (RA2bmode=="ge1bloose") {
    RA2b_1b_loose_shade->Draw("f");
    RA2b_1b_loose_exp_p->Draw(drawopt);
    RA2b_1b_loose_exp_m->Draw(drawopt);
    RA2b_1b_loose_exp->Draw(drawopt);
    RA2b_1b_loose->Draw(drawopt);
  }
  else if (RA2bmode=="ge2bloose") {
    RA2b_2b_loose_shade->Draw("f");
    RA2b_2b_loose_exp_p->Draw(drawopt);
    RA2b_2b_loose_exp_m->Draw(drawopt);
    RA2b_2b_loose_exp->Draw(drawopt);
    RA2b_2b_loose->Draw(drawopt);
  }
  else if (RA2bmode=="ge2btight") {
    RA2b_2b_tight_shade->Draw("f");
    RA2b_2b_tight_exp_p->Draw(drawopt);
    RA2b_2b_tight_exp_m->Draw(drawopt);
    RA2b_2b_tight_exp->Draw(drawopt);
    RA2b_2b_tight->Draw(drawopt);
  }
  //
  //
  //TLatex* RA1label = new TLatex(670,430.,"#alpha_{T}");
  ////TLatex* RA1label = new TLatex(80,288.,"#alpha_{T}");
  //RA1label->SetTextFont(42);
  //RA1label->SetTextSize(0.05);
  //RA1label->SetTextColor(kRed+2);
  //RA1label->Draw("same");

  TLatex* RA2blabel_2b=0;
  TLatex* RA2blabel_1b=0;
  if (false) {
    RA2blabel_2b = new TLatex(1150,330.,"#geq 2 b-tags");
    RA2blabel_2b->SetTextFont(42);
    RA2blabel_2b->SetTextSize(0.05);
    RA2blabel_2b->SetTextColor(kGreen+2);
    RA2blabel_2b->Draw("same");
    
    RA2blabel_1b = new TLatex(1150,430.,"#geq 1 b-tags");
    RA2blabel_1b->SetTextFont(42);
    RA2blabel_1b->SetTextSize(0.05);
    RA2blabel_1b->SetTextColor(kRed+2);
    RA2blabel_1b->Draw("same");
  }
  //
  //TLatex* RA5label = new TLatex(400,370.,"SS Dilepton");
  //RA5label->SetTextFont(42);
  ////RA5label->SetTextAngle(20);
  //RA5label->SetTextSize(0.04);
  //RA5label->SetTextColor(kGreen+2);
  //RA5label->Draw("same");
  //
  //TLatex* RA6label = new TLatex(650,215.,"OS Dilepton");
  //RA6label->SetTextFont(42);
  ////RA6label->SetTextAngle(8);
  //RA6label->SetTextSize(0.04);
  //RA6label->SetTextColor(kCyan+2);
  //RA6label->Draw("same");
  
  
  //exclusion limits previous experiments
  if(tanBeta_ == 3){
    TEV_sn_d0_1->Draw("fsame");
    TEV_sn_d0_2->Draw("fsame");
  }
  //  LEP_ch->Draw("fsame");
  if (tanBeta_ != 40) LEP_sl->Draw("fsame");

  //remove CDF/D0 excluded regions
  //  TEV_sg_cdf->Draw("fsame");
  //  TEV_sg_d0->Draw("same");  
  //  TEV_sg_d0->Draw("fsame");


  //other labels
  Double_t xpos = 0;
  Double_t xposi = 0;
  Double_t ypos = 0;
  if(tanBeta_ == 40) xposi = 180+160;
  if(tanBeta_ == 40) xpos = 400;//240;
  if(tanBeta_ == 40) ypos = -10;
  
  //TLatex* lumilabel = new TLatex(750 +xposi + 100,767.-154,"#sqrt{s} = 7 TeV, #scale[0.65]{#int}Ldt = 0.98 fb^{-1}");
  TLatex* lumilabel = new TLatex(925+xpos-50,767.-154+105,"#sqrt{s} = 7 TeV, L_{int} = 1.1 fb^{-1}");
  TLatex* integral_symbol = new TLatex(1287 +xposi + 100-85,767.-145+95,"#int");

  lumilabel->SetTextSize(0.05);
  integral_symbol->SetTextSize(0.03);
  lumilabel->Draw("same");
  //  integral_symbol->Draw("same");

  TLatex* cmslabel = new TLatex(10.+xpos,767.-154+105,"CMS Preliminary");
  cmslabel->SetTextSize(0.05);
  cmslabel->Draw("same");

  TString text_tanBeta;
  text_tanBeta =  "tan#beta = "+tanb+",  A_{0} = -500 GeV,  #mu > 0";
  TLatex* cmssmpars = new TLatex(/*530.+xpos,690.+ypos-130*/150+xpos,660,text_tanBeta);

  cmssmpars->SetTextSize(0.04);
  cmssmpars->Draw("same");

  TLatex* lep_chargino = new TLatex(250,135,"LEP2 #tilde{#chi}_{1}^{#pm}");
  lep_chargino->SetTextSize(0.03);
  lep_chargino->SetTextFont(42);
  //    lep_chargino->Draw("same");

  TLatex* lep_slepton = new TLatex(26,190,"LEP2 #tilde{#font[12]{l}}^{#pm}");
  lep_slepton->SetTextSize(0.03);
  lep_slepton->SetTextAngle(-83);
  lep_slepton->SetTextFont(42);
  //  lep_slepton->Draw("same");



  //LM points
  TMarker* LM0 = new TMarker(200.,160.,20);
  TMarker* LM1 = new TMarker(60.,250.,20);
  TMarker* LM3 = new TMarker(330.,240.,20);
  TMarker* LM6 = new TMarker(80.,400.,20);
    
  LM0->SetMarkerSize(1.2);
  LM1->SetMarkerSize(1.2);
    
  TLatex* tLM0 = new TLatex(205.,160.," LM0");
  tLM0->SetTextSize(0.035);
    
  TLatex* tLM1 = new TLatex(80.,245.,"LM1");
  tLM1->SetTextSize(0.035);
  
  //TLatex* tLM3 = new TLatex(350.,235.,"LM3 (tan#beta=20)");
  TLatex* tLM3 = new TLatex(350.,235.,"LM3");
  tLM3->SetTextSize(0.035);
  
  TLatex* tLM6 = new TLatex(100.,395.,"LM6");
  tLM6->SetTextSize(0.035);
  
  //  if (tanBeta_ != 50){
  //  LM0->Draw("same");   
  //  tLM0->Draw("same");
  //  LM1->Draw("same");   
  //  tLM1->Draw("same");
  // }

  /*
  if (tanBeta_ == 10){ 
    LM1->Draw("same");
    tLM1->Draw("same");
    LM3->Draw("same");
    tLM3->Draw("same");
    LM6->Draw("same");
    tLM6->Draw("same");
  }
  */



  //stau=LSP contour
  stau->Draw("fsame");
  //  NoEWSB->Draw("fsame");
 
  //legends
  //  legexp->Draw();
  //  legst->Draw();
  //legNoEWSB->Draw();
    myleg->Draw();

  hist->Draw("sameaxis");
  cvsSys->RedrawAxis();
  cvsSys->Update();
  cvsSys->Write();
  
  if( plotLO_ ){
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+"_LO.pdf");
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+"_LO.png");
  }else{
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+"_"+RA2bmode+".eps");
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+"_"+RA2bmode+".pdf");
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+"_"+RA2bmode+".png");
  }
  
  output->Write();
  //output->Close();
  //delete output; 
  
}
コード例 #20
0
void plotAngResVsSnr2(){

  TChain* cLdb = new TChain("angResTree");
  TChain* cSnrLdb = new TChain("snrTree");  

  TChain* cWais = new TChain("angResTree");
  TChain* cSnrWais = new TChain("snrTree");  
  
  // cLdb->Add("filterOffs/phaseCenter/generateAngularResolutionTreeVPOLPlots_*");
  // cSnrLdb->Add("filterOffs/phaseCenter/generateSignalToNoiseRatioTreeVPOLPlots_*");

  // cWais->Add("filterOffs/phaseCenter/generateAngularResolutionTreePlots_*");
  // cSnrWais->Add("filterOffs/phaseCenter/generateSignalToNoiseRatioTreePlots_*");

  cLdb->Add("extremeFilter/phaseCenter/generateAngularResolutionTreeVPOLPlots_*");
  cSnrLdb->Add("extremeFilter/phaseCenter/generateSignalToNoiseRatioTreeVPOLPlots_*");
  
  cWais->Add("filterOns/phaseCenter/generateAngularResolutionTreePlots_*");
  cSnrWais->Add("filterOns/phaseCenter/generateSignalToNoiseRatioTreePlots_*");
  
  Double_t deltaPhiDegLdb = 0;
  cLdb->SetBranchAddress("deltaPhiDeg", &deltaPhiDegLdb);
  Double_t deltaThetaDegLdb = 0;
  cLdb->SetBranchAddress("deltaThetaDeg", &deltaThetaDegLdb);
  UInt_t eventNumber = 0;
  cLdb->SetBranchAddress("eventNumber", &eventNumber);
  
  
  Double_t phiExpected = 0;
  cLdb->SetBranchAddress("phiExpected", &phiExpected);

  Double_t snr0Ldb = 0;
  cSnrLdb->SetBranchAddress("snr0", &snr0Ldb);

  Long64_t nEntries = cSnrLdb->GetEntries();
  Long64_t maxEntry = 0; //5; //1000; //10000;
  Long64_t startEntry = 0;
  if(maxEntry<=0 || maxEntry > nEntries) maxEntry = nEntries;
  std::cout << "Processing " << maxEntry << " of " << nEntries << " entries." << std::endl;
  ProgressBar p(maxEntry-startEntry);

  double dPhi = 0.05;
  double phiRange = 6;

  double dTheta = 0.05;
  double thetaRange = 6;
  double rebin = 2;

  const int nBinsPhi = 32;
  
  std::vector<double> theSnrBinsLdb = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 18, 21};//, 22, 23, 24, 25};

  TH2D* hSnrVsPhiExpectedLdb = new TH2D("hSnrVsPhiExpectedLdb", "SNR vs. #phi_{LDB}; #phi_{LDB} (Degrees); SNR (no units); Events per bin", nBinsPhi, 0, 360, theSnrBinsLdb.size()-1, &theSnrBinsLdb[0]);


  TH1D* hDeltaPhiLdb = new TH1D("hDeltaPhiLdb", "#delta#phi_{LDB}; #delta#phi (Degrees); Events per bin", phiRange/(dPhi*rebin), -phiRange/2 - dPhi/2, phiRange/2 - dPhi/2);
  // TH2D* hDeltaPhiLdb2 = new TH2D("hDeltaPhiLdb2", "#delta#phi_{LDB} vs. SNR; SNR (no units); #delta#phi (Degrees); Events per bin", nBinsSnr, minSnr, maxSnr, phiRange/dPhi, -phiRange/2 - dPhi/2, phiRange/2 - dPhi/2);
  TH2D* hDeltaPhiLdb2 = new TH2D("hDeltaPhiLdb2", "#delta#phi_{LDB} vs. SNR; SNR (no units); #delta#phi (Degrees); Events per bin", theSnrBinsLdb.size()-1, &theSnrBinsLdb[0], phiRange/dPhi, -phiRange/2 - dPhi/2, phiRange/2 - dPhi/2);  

  TH1D* hDeltaThetaLdb = new TH1D("hDeltaThetaLdb", "#delta#theta_{LDB}; #delta#theta (Degrees); Events per bin", thetaRange/dTheta, -thetaRange/2 - dTheta/2, thetaRange/2 - dTheta/2);
  // TH2D* hDeltaThetaLdb2 = new TH2D("hDeltaThetaLdb2", "#delta#theta_{LDB} vs. SNR; SNR (no units); #delta#theta (Degrees); Events per bin", nBinsSnr, minSnr, maxSnr, thetaRange/dTheta, -thetaRange/2 - dTheta/2, thetaRange/2 - dTheta/2);
  TH2D* hDeltaThetaLdb2 = new TH2D("hDeltaThetaLdb2", "#delta#theta_{LDB} vs. SNR; SNR (no units); #delta#theta (Degrees); Events per bin", theSnrBinsLdb.size()-1, &theSnrBinsLdb[0], thetaRange/dTheta, -thetaRange/2 - dTheta/2, thetaRange/2 - dTheta/2);  

  double lowestSnr = 9999;
  double highestSnr = -9999;
  UInt_t lowEventNumber;
  UInt_t highEventNumber;  
  
  const double phiCut = 3;  
  for(Long64_t entry = startEntry; entry < maxEntry; entry++){
    cLdb->GetEntry(entry);
    cSnrLdb->GetEntry(entry);    
    // cLdbOff->GetEntry(entry);

    if(TMath::Abs(deltaPhiDegLdb) < phiCut){

      hSnrVsPhiExpectedLdb->Fill(phiExpected, snr0Ldb);
	
      // if(snr0Ldb > 6){
      hDeltaPhiLdb->Fill(deltaPhiDegLdb);
      hDeltaPhiLdb2->Fill(snr0Ldb, deltaPhiDegLdb);

      hDeltaThetaLdb->Fill(deltaThetaDegLdb);
      hDeltaThetaLdb2->Fill(snr0Ldb, deltaThetaDegLdb);
      // }

      if(snr0Ldb < lowestSnr){
	lowestSnr = snr0Ldb;
	lowEventNumber = eventNumber;
      }
      if(snr0Ldb > highestSnr){
	highestSnr = snr0Ldb;	
	highEventNumber = eventNumber;
      }
    }
    
    p.inc(entry, maxEntry);
  }

  std::cout << "LDB: " << std::endl;
  std::cout << lowEventNumber << "\t" << lowestSnr << std::endl;
  std::cout << highEventNumber << "\t" << highestSnr << std::endl;

  auto c0 = new TCanvas();
  hSnrVsPhiExpectedLdb->Draw("colz");
  
  TObjArray* tArrLdbPhi =  new TObjArray();
  hDeltaPhiLdb2->FitSlicesY(NULL, 1, hDeltaPhiLdb2->GetNbinsY(), 0, "QNR", tArrLdbPhi);
  TH1D* hResolutionVsSnrPhiLdb = NULL;
  for(int i=0; i < tArrLdbPhi->GetEntries(); i++){
    auto h = (TH1D*)tArrLdbPhi->At(i);
    // auto c0 = new TCanvas();
    // TString opt = i==0? "" : "same";
    // h->Draw(opt);
    if(i==2){
      hResolutionVsSnrPhiLdb = h;
      hResolutionVsSnrPhiLdb->SetTitle("VPOL #delta#phi_{LDB}");      
    }
    new TCanvas();
    h->Draw();    
  }
  
  TObjArray* tArrLdbTheta =  new TObjArray();
  hDeltaThetaLdb2->FitSlicesY(NULL, 1, hDeltaThetaLdb2->GetNbinsY(), 0, "QNR", tArrLdbTheta);
  TH1D* hResolutionVsSnrThetaLdb = NULL;
  for(int i=0; i < tArrLdbTheta->GetEntries(); i++){
    auto h = (TH1D*)tArrLdbTheta->At(i);
    // auto c0 = new TCanvas();    
    // TString opt = i==0? "" : "same";
    // h->Draw(opt);
    if(i==2){
      hResolutionVsSnrThetaLdb = h;
      hResolutionVsSnrThetaLdb->SetTitle("VPOL #delta#theta_{LDB}");
    }
    new TCanvas();
    h->Draw();
    
  }

  Double_t deltaPhiDegWais = 0;
  cWais->SetBranchAddress("deltaPhiDeg", &deltaPhiDegWais);
  Double_t deltaThetaDegWais = 0;
  cWais->SetBranchAddress("deltaThetaDeg", &deltaThetaDegWais);
  
  phiExpected = 0;
  cWais->SetBranchAddress("phiExpected", &phiExpected);

  Double_t snr0Wais = 0;
  cSnrWais->SetBranchAddress("snr0", &snr0Wais);

  std::vector<double> theSnrBinsWais = {0, 1, 2, 3, 4, 5, 6, 7, 8, 10, 11, 12, 13, 14, 15, 16, 18, 21};//, 22, 23, 24, 25};


  TH2D* hSnrVsPhiExpectedWais = new TH2D("hSnrVsPhiExpectedWais", "SNR vs. #phi_{WAIS}; #phi_{WAIS} (Degrees); SNR (no units); Events per bin", nBinsPhi, 0, 360, theSnrBinsWais.size()-1, &theSnrBinsWais[0]);

    
  TH1D* hDeltaPhiWais = new TH1D("hDeltaPhiWais", "#delta#phi_{WAIS}; #delta#phi (Degrees); Events per bin", phiRange/(dPhi*rebin), -phiRange/2 - dPhi/2, phiRange/2 - dPhi/2);
  TH2D* hDeltaPhiWais2 = new TH2D("hDeltaPhiWais2", "#delta#phi_{WAIS} vs. SNR; SNR (no units); #delta#phi (Degrees); Events per bin", theSnrBinsWais.size()-1, &theSnrBinsWais[0], phiRange/dPhi, -phiRange/2 - dPhi/2, phiRange/2 - dPhi/2);

  TH1D* hDeltaThetaWais = new TH1D("hDeltaThetaWais", "#delta#theta_{WAIS}; #delta#theta (Degrees); Events per bin", thetaRange/dTheta, -thetaRange/2 - dTheta/2, thetaRange/2 - dTheta/2);
  TH2D* hDeltaThetaWais2 = new TH2D("hDeltaThetaWais2", "#delta#theta_{WAIS} vs. SNR; SNR (no units); #delta#theta (Degrees); Events per bin", theSnrBinsWais.size()-1, &theSnrBinsWais[0], thetaRange/dTheta, -thetaRange/2 - dTheta/2, thetaRange/2 - dTheta/2);

  Long64_t nEntries2 = cSnrWais->GetEntries();
  Long64_t maxEntry2 = 0; //5; //1000; //10000;
  Long64_t startEntry2 = 0;
  if(maxEntry2<=0 || maxEntry2 > nEntries2) maxEntry2 = nEntries2;
  std::cout << "Processing " << maxEntry2 << " of " << nEntries2 << " entries." << std::endl;
  ProgressBar p2(maxEntry2-startEntry2);
  
  for(Long64_t entry = startEntry2; entry < maxEntry2; entry++){
    cWais->GetEntry(entry);
    cSnrWais->GetEntry(entry);    

    if(TMath::Abs(deltaPhiDegWais) < phiCut){
      hSnrVsPhiExpectedWais->Fill(phiExpected, snr0Wais);
      hDeltaPhiWais->Fill(deltaPhiDegWais);
      hDeltaPhiWais2->Fill(snr0Wais, deltaPhiDegWais);

      hDeltaThetaWais->Fill(deltaThetaDegWais);
      hDeltaThetaWais2->Fill(snr0Wais, deltaThetaDegWais);
    }
    
    p2.inc(entry, maxEntry2);
  }  


  TObjArray* tArrWaisPhi =  new TObjArray();
  hDeltaPhiWais2->FitSlicesY(NULL, 1, hDeltaPhiWais2->GetNbinsY(), 0, "QNR", tArrWaisPhi);
  TH1D* hResolutionVsSnrPhiWais = NULL;
  for(int i=0; i < tArrWaisPhi->GetEntries(); i++){
    auto h = (TH1D*)tArrWaisPhi->At(i);
    // auto c0 = new TCanvas();
    // TString opt = i==0? "" : "same";
    // h->Draw(opt);
    if(i==2){
      hResolutionVsSnrPhiWais = h;
      hResolutionVsSnrPhiWais->SetTitle("HPOL #delta#phi_{WAIS}");
    }
    new TCanvas();
    h->Draw();
    
  }
  
  TObjArray* tArrWaisTheta =  new TObjArray();
  hDeltaThetaWais2->FitSlicesY(NULL, 1, hDeltaThetaWais2->GetNbinsY(), 0, "QNR", tArrWaisTheta);
  TH1D* hResolutionVsSnrThetaWais = NULL;
  for(int i=0; i < tArrWaisTheta->GetEntries(); i++){
    auto h = (TH1D*)tArrWaisTheta->At(i);
    // auto c0 = new TCanvas();    
    // TString opt = i==0? "" : "same";
    // h->Draw(opt);
    if(i==2){
      hResolutionVsSnrThetaWais = h;
      hResolutionVsSnrThetaWais->SetTitle("HPOL #delta#theta_{WAIS}");      
    }
    new TCanvas();
    h->Draw();
  }
  
  
  auto c0a = new TCanvas();
  hSnrVsPhiExpectedWais->Draw("colz");
  return;
  
  auto c1 = new TCanvas();
  hDeltaPhiWais2->Draw("colz");

  auto c1a = new TCanvas();
  hDeltaPhiLdb2->Draw("colz");

  auto c2 = new TCanvas();
  hDeltaThetaWais2->Draw("colz");
  
  auto c2a = new TCanvas();
  hDeltaThetaLdb2->Draw("colz");

  // auto c3 = new TCanvas();
  // // hResolutionVsSnrPhiLdb->SetLineColor(kRed);
  // // hResolutionVsSnrThetaLdb->SetLineColor(kBlue);
  // hResolutionVsSnrPhiLdb->Draw();
  // hResolutionVsSnrThetaLdb->Draw("same");

  // auto c3a = new TCanvas();
  // // hResolutionVsSnrPhiWais->SetLineColor(kRed);
  // // hResolutionVsSnrThetaWais->SetLineColor(kBlue);
  // hResolutionVsSnrPhiWais->Draw();
  // hResolutionVsSnrThetaWais->Draw("same");

  auto c4 = new TCanvas();
  hResolutionVsSnrPhiWais->SetLineColor(kRed);
  hResolutionVsSnrPhiLdb->SetLineColor(kBlue);
  hResolutionVsSnrThetaWais->SetLineColor(kMagenta);
  hResolutionVsSnrThetaLdb->SetLineColor(kCyan);

  hResolutionVsSnrPhiWais->SetMarkerSize(0);
  hResolutionVsSnrPhiLdb->SetMarkerSize(0);
  hResolutionVsSnrThetaWais->SetMarkerSize(0);
  hResolutionVsSnrThetaLdb->SetMarkerSize(0);
  
  hResolutionVsSnrPhiLdb->Draw();
  hResolutionVsSnrThetaLdb->Draw("same");  
  hResolutionVsSnrPhiWais->Draw("same");
  hResolutionVsSnrThetaWais->Draw("same");

  
  auto l4 = c4->BuildLegend();
  // l1->SetNColumns(2);
  l4->Draw();
  // hs[0]->SetMaximum(0.13);

  hResolutionVsSnrPhiLdb->SetTitle("Angular Resolution vs. SNR; SNR; Angular Resolution (Degrees)");
  hResolutionVsSnrPhiLdb->SetMaximum(1);
  hResolutionVsSnrPhiLdb->SetMinimum(0);  
  
  //hDeltaPhiDegPhaseLdb->SetTitle("ANITA Angular Resolution Using Fitted Phase Centres; #delta#theta or #delta#phi (Degrees); Fraction of events per bin");

  
}
コード例 #21
0
ファイル: draw_22Na_v2.C プロジェクト: lab305itep/digi
void draw_Src(TChain *tMc, TChain *tExpA, TChain *tExpB, const char *name, const char *fname, double kSP = 0.5, double kRndm = 0.0)
{
	char str[256];
	double rAB;
	long NA, NB;
	
	gStyle->SetOptStat("i");
	gStyle->SetOptFit(1);
//	gStyle->SetOptStat(0);
//	gStyle->SetOptFit(0);
	gStyle->SetTitleXSize(0.05);
	gStyle->SetTitleYSize(0.05);
	gStyle->SetLabelSize(0.05);
	gStyle->SetPadLeftMargin(0.15);
	gStyle->SetPadBottomMargin(0.15);
//	gStyle->SetLineWidth(4);
	
	sprintf(str, "Monte Carlo energy deposit in %s decay;E, MeV", name);
	TH1D *hMc = new TH1D("hMc", str, 70, 0, 7);
	sprintf(str, "Monte Carlo SiPM energy deposit in %s decay;E, MeV", name);
	TH1D *hMcSiPM = new TH1D("hMcSiPM", str, 35, 0, 7);
	sprintf(str, "Monte Carlo PMT energy deposit in %s decay;E, MeV", name);
	TH1D *hMcPMT = new TH1D("hMcPMT", str, 35, 0, 7);
	sprintf(str, "Monte Carlo energy deposit in %s decay with random %2.0f%%;E, MeV", name, kRndm*100);
	TH1D *hMcR = new TH1D("hMcR", str, 70, 0, 7);
	sprintf(str, "Monte Carlo number of hits from %s decay", name);
	TH1D *hMcHits = new TH1D("hMcHits", str, 20, 0, 20);
	TH2D *hXY = new TH2D("hXY", "XY distribution of gamma flash center;X, cm;Y, cm", 25, 0, 100, 25, 0, 100);
	sprintf(str, "DANSS energy deposit in %s decay;E, MeV", name);
	TH1D *hExpA = new TH1D("hExpA", str, 70, 0, 7);
	TH1D *hExpB = new TH1D("hExpB", str, 70, 0, 7);
	TH1D *hExpC = new TH1D("hExpC", str, 70, 0, 7);
	sprintf(str, "SiPM energy deposit in %s decay;E, MeV", name);
	TH1D *hExpSiPMA = new TH1D("hExpSiPMA", str, 70, 0, 7);
	TH1D *hExpSiPMB = new TH1D("hExpSiPMB", str, 70, 0, 7);
	TH1D *hExpSiPMC = new TH1D("hExpSiPMC", str, 70, 0, 7);
	sprintf(str, "PMT energy deposit in %s decay;E, MeV", name);
	TH1D *hExpPMTA = new TH1D("hExpPMTA", str, 70, 0, 7);
	TH1D *hExpPMTB = new TH1D("hExpPMTB", str, 70, 0, 7);
	TH1D *hExpPMTC = new TH1D("hExpPMTC", str, 70, 0, 7);
	sprintf(str, "Number of hits from %s decay", name);
	TH1D *hHitsA = new TH1D("hHitsA", str, 20, 0, 20);
	TH1D *hHitsB = new TH1D("hHitsB", str, 20, 0, 20);
	TH1D *hHitsC = new TH1D("hHitsC", str, 20, 0, 20);
	
	TH1D *hTmpA = new TH1D("hTmpA", "Normalization counts A", 100, 0, 1000);
	TH1D *hTmpB = new TH1D("hTmpB", "Normalization counts B", 100, 0, 1000);

	TCut cxyz("NeutronX[0] >= 0 && NeutronX[1] >= 0 && NeutronX[2] >= 0");
	TCut cz50("(NeutronX[2] - 49.5) * (NeutronX[2] - 49.5) < 100");
	TCut ccc("(NeutronX[0] - 48) * (NeutronX[0] - 48) + (NeutronX[1] - 48) * (NeutronX[1] - 48) + (NeutronX[2] - 49.5) * (NeutronX[2] - 49.5) < 400");
	TCut cVeto("VetoCleanHits < 2 && VetoCleanEnergy < 4");
	TCut cn("SiPmCleanHits > 5");
	
	sprintf(str, "%6.4f*SiPmCleanEnergy+%6.4f*PmtCleanEnergy", kSP, 1-kSP);
	tMc->Project("hMc", str, cxyz && ccc && cVeto && cn);
	tMc->Project("hMcSiPM", "SiPmCleanEnergy", cxyz && ccc && cVeto && cn);
	tMc->Project("hMcPMT", "PmtCleanEnergy", cxyz && ccc && cVeto && cn);
	sprintf(str, "MyRandom::GausAdd(%6.4f*SiPmCleanEnergy+%6.4f*PmtCleanEnergy, %6.4f)", kSP, 1-kSP, kRndm);
	tMc->Project("hMcR", str, cxyz && ccc && cVeto && cn);
	tMc->Project("hMcHits", "SiPmCleanHits", cxyz && ccc && cVeto);
	
	sprintf(str, "%6.4f*SiPmCleanEnergy+%6.4f*PmtCleanEnergy", kSP, 1-kSP);
	tExpA->Project("hXY", "NeutronX[1]+2:NeutronX[0]+2", cxyz && cz50 && cVeto && cn);
	tExpA->Project("hExpA", str, cxyz && ccc && cVeto && cn);
	tExpB->Project("hExpB", str, cxyz && ccc && cVeto && cn);
	tExpA->Project("hExpSiPMA", "SiPmCleanEnergy", cxyz && ccc && cVeto && cn);
	tExpB->Project("hExpSiPMB", "SiPmCleanEnergy", cxyz && ccc && cVeto && cn);
	tExpA->Project("hExpPMTA", "PmtCleanEnergy", cxyz && ccc && cVeto && cn);
	tExpB->Project("hExpPMTB", "PmtCleanEnergy", cxyz && ccc && cVeto && cn);
	tExpA->Project("hHitsA", "SiPmCleanHits", cxyz && ccc && cVeto);
	tExpB->Project("hHitsB", "SiPmCleanHits", cxyz && ccc && cVeto);
	NA = tExpA->Project("hTmpA", "SiPmCleanEnergy", "(SiPmCleanEnergy + PmtCleanEnergy) / 2 > 100");
	NB = tExpB->Project("hTmpB", "SiPmCleanEnergy", "(SiPmCleanEnergy + PmtCleanEnergy) / 2 > 100");
	
	rAB = 1.0 * NA / NB;
	printf("NA = %ld    NB = %ld    rAB = %f\n", NA, NB, rAB);
	
	hMc->Sumw2();
	hMcSiPM->Sumw2();
	hMcPMT->Sumw2();
	hMcR->Sumw2();
	hMcHits->Sumw2();
	hExpA->Sumw2();
	hExpB->Sumw2();
	hExpSiPMA->Sumw2();
	hExpSiPMB->Sumw2();
	hExpPMTA->Sumw2();
	hExpPMTB->Sumw2();
	hHitsA->Sumw2();
	hHitsB->Sumw2();
	
	hExpC->Add(hExpA, hExpB, 1.0, -rAB);
	hExpSiPMC->Add(hExpSiPMA, hExpSiPMB, 1.0, -rAB);
	hExpPMTC->Add(hExpPMTA, hExpPMTB, 1.0, -rAB);
	hHitsC->Add(hHitsA, hHitsB, 1.0, -rAB);
	hMcHits->Scale(hHitsC->Integral() / hMcHits->Integral());
	hMcR->Scale(hExpC->Integral() / hMcR->Integral());

	hMc->GetYaxis()->SetLabelSize(0.05);
	hMcSiPM->GetYaxis()->SetLabelSize(0.05);
	hMcPMT->GetYaxis()->SetLabelSize(0.05);
	hMcR->GetYaxis()->SetLabelSize(0.05);
	hMcR->SetLineColor(kRed);
	hMcHits->GetYaxis()->SetLabelSize(0.05);
	hMcHits->SetLineColor(kRed);
	hMcHits->SetMarkerColor(kRed);
	hMcHits->SetMarkerStyle(kFullCircle);
	hXY->GetXaxis()->SetLabelSize(0.045);
	hXY->GetYaxis()->SetLabelSize(0.045);
	hXY->GetZaxis()->SetLabelSize(0.045);
	hExpC->GetYaxis()->SetLabelSize(0.05);
	hExpC->SetLineWidth(2);
	hExpC->SetLineColor(kBlue);
	hExpSiPMC->GetYaxis()->SetLabelSize(0.05);
	hExpPMTC->GetYaxis()->SetLabelSize(0.05);
	hHitsC->GetYaxis()->SetLabelSize(0.05);
	hHitsC->SetLineColor(kBlue);
	hHitsC->SetMarkerColor(kBlue);
	hHitsC->SetMarkerStyle(kFullSquare);

	hMcHits->SetStats(0);
	hHitsC->SetStats(0);
	
	TLegend *lg = new TLegend(0.65, 0.8, 0.95, 0.93);
	lg->AddEntry(hMcHits, "Monte Carlo", "L");
	lg->AddEntry(hHitsC,  "DANSS", "LP");
	lg->SetTextSize(0.035);
	
	TCanvas *cMc = new TCanvas("cMc", "Monte Carlo", 1200, 800);
	cMc->Divide(2, 2);
	cMc->cd(1);
	hMc->Fit("gaus", "", "", 1.5, 3.5);
	cMc->cd(2);
	hMcSiPM->Fit("gaus", "", "", 1.5, 3.5);
	cMc->cd(3);
	hMcPMT->Fit("gaus", "", "", 1.5, 3.5);
	cMc->cd(4);
	hMcR->Fit("gaus", "", "", 1.5, 3.5);
	sprintf(str, "%s.pdf(", fname);
	cMc->SaveAs(str);
	
	TCanvas *cExp = new TCanvas("cExp", "Data", 1200, 800);
	cExp->Divide(2, 2);
	cExp->cd(1);
	hExpC->Fit("gaus", "", "", 1.5, 3.5);
	cExp->cd(2);
	hExpSiPMC->Fit("gaus", "", "", 1.5, 3.5);
	cExp->cd(3);
	hExpPMTC->Fit("gaus", "", "", 1.5, 3.5);
	cExp->cd(4);
	hXY->Draw("colz");
	sprintf(str, "%s.pdf", fname);
	cExp->SaveAs(str);

	TCanvas *cHits = new TCanvas("cHits", "Hits", 1200, 800);
	cHits->Divide(2, 1);
	cHits->cd(1);
	hHitsC->Draw();
	hMcHits->Draw("same,hist");
	lg->Draw();
	cHits->cd(2);
	hExpC->Draw();
	hMcR->Draw("same,hist");
	cHits->Update();
	sprintf(str, "%s.pdf)", fname);
	cHits->SaveAs(str);

	sprintf(str, "%s.root", fname);
	TFile *f = new TFile(str, "RECREATE");
	if (f->IsOpen()) {
		f->cd();
		hMc->Write();
		hMcSiPM->Write();
		hMcPMT->Write();
		hMcR->Write();
		hMcHits->Write();
		hXY->Write();
		hExpA->Write();
		hExpB->Write();
		hExpC->Write();
		hExpSiPMA->Write();
		hExpSiPMB->Write();
		hExpSiPMC->Write();
		hExpPMTA->Write();
		hExpPMTB->Write();
		hExpPMTC->Write();
		hHitsA->Write();
		hHitsB->Write();
		hHitsC->Write();
		f->Close();
	}
	
	TCanvas *cPRL = new TCanvas("PRL", "PRL", 800, 800);
	cPRL->SetLeftMargin(0.17);
	cPRL->SetRightMargin(0.03);
	cPRL->SetTopMargin(0.03);
	cPRL->SetBottomMargin(0.10);
	hExpC->SetLineColor(kBlack);
	hExpC->GetXaxis()->SetRange(0, 50);
	hExpC->SetTitle(";E, MeV;Events/100 keV");
	hExpC->SetStats(0);
	hExpC->GetYaxis()->SetTitleOffset(1.7);
	hExpC->Draw();
	hMcR->Draw("hits,same");
	lg->Draw();
	sprintf(str, "%s-prl.pdf", fname);
	cPRL->SaveAs(str);
}
コード例 #22
0
ファイル: ExclusionPlot.C プロジェクト: wa01/usercode
void CommandMSUGRA(TString plotName,Int_t tanBeta_, Bool_t plotLO_, Bool_t tb40_plotExpected) {
  
  gStyle->SetOptTitle(0);
  gStyle->SetOptStat(0);
  gStyle->SetPalette(1); 
  gStyle->SetTextFont(42);
  gStyle->SetFrameBorderMode(0);

  //convert tanb value to string
  std::stringstream tmp;
  tmp << tanBeta_;
  TString tanb( tmp.str() );
  
  
  // Output file
  std::cout << " create " << plotName << std::endl;
  TFile* output = new TFile( plotName, "RECREATE" );
  if ( !output || output->IsZombie() ) { std::cout << " zombie alarm output is a zombie " << std::endl; }
  

  //set old exclusion Limits
  TGraph* LEP_ch = set_lep_ch(tanBeta_);
  TGraph* LEP_sl = set_lep_sl(tanBeta_);//slepton curve
  TGraph* TEV_sg_cdf = set_tev_sg_cdf(tanBeta_);//squark gluino cdf
  TGraph* TEV_sg_d0 = set_tev_sg_d0(tanBeta_);//squark gluino d0
  //  TGraph* TEV_tlp_cdf = set_tev_tlp_cdf(tanBeta_);//trilepton cdf
  //  TGraph* TEV_tlp_d0 = set_tev_tlp_d0(tanBeta_);//trilepton d0
  TGraph* stau   = set_tev_stau(tanBeta_);//stau 
  TGraph* NoEWSB = set_NoEWSB(tanBeta_); 

  TGraph* TEV_sn_d0_1 = set_sneutrino_d0_1(tanBeta_);
  TGraph* TEV_sn_d0_2 = set_sneutrino_d0_2(tanBeta_);

  //some tan beta 40 stuff (load the squark and gluino mass lines)
  TGraph2D* squarkMasses=0;
  TGraph2D* gluinoMasses=0;
  if (tanBeta_==40) {
    const int nPoints = nSusyGridPoints();
    double m0[nPoints],m12[nPoints],squarkMass[nPoints],gluinoMass[nPoints];
    
    susyGrid(m0,m12,squarkMass,gluinoMass);
    
    squarkMasses = new TGraph2D("squarkMasses","",nPoints,m0,m12,squarkMass);
    gluinoMasses = new TGraph2D("gluinoMasses","",nPoints,m0,m12,gluinoMass);
    
    gluinoMasses->GetHistogram();
    squarkMasses->GetHistogram();
  }
  // end of tan beta 40 stuff

  //constant squark and gluino lines
  TF1* lnsq[10];
  TF1* lngl[10];
  TLatex* sq_text[10];
  TLatex* gl_text[10];

  //versions for tan beta 40
  TGraph* lnsq_40[15];
  TGraph* lngl_40[15];
  TLatex* sq_40_text[15];
  TLatex* gl_40_text[15];

  int loopmax = 6;
  if (tanBeta_==40) loopmax=15;
  for(int i = 0; i < loopmax; i++){
    if (tanBeta_==10) {
      lnsq[i] = constant_squark(tanBeta_,i);
      sq_text[i] = constant_squark_text(i,*lnsq[i],tanBeta_);
      lngl[i] = constant_gluino(tanBeta_,i);
      gl_text[i] = constant_gluino_text(i,*lngl[i]);
    }
    else if (tanBeta_==40) {
      lnsq_40[i] = constant_mass(i*250,squarkMasses);
      lngl_40[i] = constant_mass(i*250,gluinoMasses);
      sq_40_text[i] = constant_squark_text_tanBeta40(i*250,lnsq_40[i]);
      gl_40_text[i] = constant_gluino_text_tanBeta40(i*250,lngl_40[i]);;
    }
  }
  

  //Legends
  TLegend* legst  = makeStauLegend(0.05,tanBeta_);
//   TLegend* legNoEWSB  = makeNoEWSBLegend(0.05,tanBeta_);
  TLegend* legexp = makeExpLegend( *TEV_sg_cdf,*TEV_sg_d0,*LEP_ch,*LEP_sl,*TEV_sn_d0_1,0.035,tanBeta_);
  
 
  //make Canvas
  TCanvas* cvsSys = new TCanvas("cvsnm","cvsnm",0,0,800,600);
  gStyle->SetOptTitle(0);
  cvsSys->SetFillColor(0);
  cvsSys->GetPad(0)->SetRightMargin(0.07);
  cvsSys->Range(-120.5298,26.16437,736.0927,750);
  //  cvsSys->Range(-50.5298,26.16437,736.0927,500);
  cvsSys->SetFillColor(0);
  cvsSys->SetBorderMode(0);
  cvsSys->GetPad(0)->SetBorderMode(0);
  cvsSys->GetPad(0)->SetBorderSize(2);
  cvsSys->GetPad(0)->SetLeftMargin(0.1407035);
  cvsSys->GetPad(0)->SetTopMargin(0.08);
  cvsSys->GetPad(0)->SetBottomMargin(0.13);

  cvsSys->SetTitle("tan#beta="+tanb);
 
  output->cd();
  
  TDirectory* curDir = gDirectory;
//   TFile* f = new TFile("limits_binc_ht1000_met350-contours.root");
//   TFile* f = new TFile("limits_msugraNLO_multibtag_ht1000_met250_m12_0-550_HN_comb-contours.root");
  TFile* f = ContourFile;
  TGraph* ra4VieObs = (TGraph*)f->Get("gObs");
  TGraph* ra4VieExpM2 = (TGraph*)f->Get("gExpMinus2");
  TGraph* ra4VieExpM1 = (TGraph*)f->Get("gExpMinus1");
  TGraph* ra4VieExp = (TGraph*)f->Get("gExpMedian");
  TGraph* ra4VieExpP1 = (TGraph*)f->Get("gExpPlus1");
  TGraph* ra4VieExpP2 = (TGraph*)f->Get("gExpPlus2");
  TGraph* ra4VieExpArea(0);

  TGraph* ra4VieObsThM(0);
  TGraph* ra4VieExpThM(0);
  if ( ContourFileM ) {
    ra4VieObsThM = (TGraph*)ContourFileM->Get("gObs");
    ra4VieExpThM = (TGraph*)ContourFileM->Get("gExpMedian");
  }
  TGraph* ra4VieObsThP(0);
  TGraph* ra4VieExpThP(0);
  if ( ContourFileP ) {
    ra4VieObsThP = (TGraph*)ContourFileP->Get("gObs");
    ra4VieExpThP = (TGraph*)ContourFileP->Get("gExpMedian");
  }

  curDir->cd();


  double m0min = 0;
  double m0max=1600;
//   double m0max=1800;
  double xscale = m0max-m0min;
  if (tanBeta_ == 50) m0min=200;
  if (tanBeta_ == 40) {m0min=400;  m0max=2000;}
  xscale = (m0max-m0min)/xscale;
  TH2D* hist = new TH2D("h","h",100,m0min,m0max,100,120,700);
  hist->Draw();  
  hist->GetXaxis()->SetTitle("m_{0} (GeV/c^{2})");
  hist->GetYaxis()->SetTitle("m_{1/2} (GeV/c^{2})");
  hist->GetXaxis()->SetTitleOffset(.9);
  hist->GetXaxis()->SetTitleSize(0.06);
  hist->GetYaxis()->SetTitleOffset(1.0);
  hist->GetYaxis()->SetTitleSize(0.06);

  hist->GetXaxis()->SetNdivisions(506);
  //  if (tanBeta_ == 50)  hist->GetXaxis()->SetNdivisions(504);
  hist->GetYaxis()->SetNdivisions(506);

  int col[]={2,3,4};

  TSpline3 *sRA4_LP =0;
  TSpline3 *sRA1 = 0;
  TSpline3 *sRA2 = 0;
  TSpline3 *sRA4_old =0;
  TSpline3 *sRAZ =0;

  if (tanBeta_==10) {
    ra4VieObs->SetLineWidth(3);
    ra4VieObs->SetLineColor(2);
    ra4VieExp->SetLineWidth(3);
//     ra4VieExp->SetLineStyle(2);
    ra4VieExp->SetLineColor(4);
//     ra4VieObs->RemovePoint(0);
//     ra4VieObs->RemovePoint(0);
//     double x,y;
//     ra4VieObs->GetPoint(36,x,y);
//     std::cout << x << " " << y << std::endl;
//     ra4VieObs->RemovePoint(37);
//     ra4VieObs->RemovePoint(37);
//     ra4VieObs->RemovePoint(37);
    if ( ra4VieExpM1 && ra4VieExpP1 ) {
      ra4VieExpArea = new TGraph();
      int np(0);
      double* xExp = ra4VieExpM1->GetX();
      double* yExp = ra4VieExpM1->GetY();
      for ( int i=0; i<ra4VieExpM1->GetN(); ++i ) 
	ra4VieExpArea->SetPoint(np++,xExp[i],yExp[i]);
      xExp = ra4VieExpP1->GetX();
      yExp = ra4VieExpP1->GetY();
      for ( int i=ra4VieExpP1->GetN()-1; i>=0; --i ) 
	ra4VieExpArea->SetPoint(np++,xExp[i],yExp[i]);
      ra4VieExpArea->SetLineColor(7);
      ra4VieExpArea->SetFillColor(7);
      ra4VieExpArea->Draw("F");
      ra4VieExpM1->SetLineWidth(1);
      ra4VieExpM1->SetLineStyle(3);
      ra4VieExpM1->SetLineColor(4);
      ra4VieExpP1->SetLineWidth(1);
      ra4VieExpP1->SetLineStyle(3);
      ra4VieExpP1->SetLineColor(4);
      ra4VieExpM1->Draw();
      ra4VieExpP1->Draw();
    }
    if ( ra4VieObsThM && ra4VieObsThP ) {
      ra4VieObsThM->SetLineWidth(2);
      ra4VieObsThM->SetLineColor(2);
      ra4VieObsThM->SetLineStyle(2);
      ra4VieObsThM->Draw();
      ra4VieObsThP->SetLineWidth(2);
      ra4VieObsThP->SetLineColor(2);
      ra4VieObsThP->SetLineStyle(2);
      ra4VieObsThP->Draw();
      
      ra4VieExpThM->SetLineWidth(2);
      ra4VieExpThM->SetLineColor(4);
      ra4VieExpThM->SetLineStyle(2);
      ra4VieExpThM->Draw();
      ra4VieExpThP->SetLineWidth(2);
      ra4VieExpThP->SetLineColor(4);
      ra4VieExpThP->SetLineStyle(2);
      ra4VieExpThP->Draw();
      
    }
    ra4VieExp->Draw();
    ra4VieObs->Draw();
//     if ( ra4VieExpM2 && ra4VieExpP2 ) {
//       ra4VieExpM2->SetLineWidth(2);
//       ra4VieExpM2->SetLineStyle(3);
//       ra4VieExpM2->SetLineColor(4);
//       ra4VieExpP2->SetLineWidth(2);
//       ra4VieExpP2->SetLineStyle(3);
//       ra4VieExpP2->SetLineColor(4);
//       ra4VieExpM2->Draw();
//       ra4VieExpP2->Draw();
//     }
  }
  else if (tanBeta_==40 ) {

  }
  
  TLegend* myleg;

  float leg_x1=0.39+0.23;
  float leg_y1=0.65+0.05;
  float leg_x2= 0.55+0.25;
  float leg_y2= 0.84+0.05;

  if( plotLO_ ) {
    if ( ContourFileM && ContourFileP )
      myleg = new TLegend(0.3,0.55,0.6,0.7,NULL,"brNDC");
//       myleg = new TLegend(0.3,0.55,0.6,0.8,NULL,"brNDC");
    else
      myleg = new TLegend(0.3,0.65,0.6,0.7,NULL,"brNDC");
  }
  else if (tb40_plotExpected) myleg = new TLegend(0.25,0.76,0.44,0.91,NULL,"brNDC"); // copied from else block below
  else if (tanBeta_==40) myleg = new TLegend(leg_x1,leg_y1,leg_x2,leg_y2,NULL,"brNDC");
  else          myleg = new TLegend(0.25,0.76,0.44,0.91,NULL,"brNDC");


  myleg->SetFillColor(0); 
  myleg->SetShadowColor(0);
  myleg->SetTextSize(0.03);
  myleg->SetBorderSize(0);

  TLegendEntry *entry=0;

  if (tanBeta_ == 10 ) {
//     myleg->SetHeader("RA4Tmpl, (NLO, exp. unc.)");
    myleg->SetHeader("95% CL exclusion limits");
    myleg->AddEntry(ra4VieObs,"observed","l");
    myleg->AddEntry(ra4VieExp,"median expected","l");
    if ( ra4VieExpM1 && ra4VieExpP1 ) {
//       myleg->AddEntry(ra4VieExpP1,"exp #pm 1#sigma","l");
      myleg->AddEntry(ra4VieExpArea,"expected #pm 1#sigma exp.","f");
    }
    if ( ra4VieObsThM && ra4VieObsThP ) {
      myleg->AddEntry(ra4VieObsThM,"observed / sig.cont.","l");
      myleg->AddEntry(ra4VieExpThM,"expected / sig.cont.","l");
//       myleg->AddEntry(ra4VieObsThM,"observed #pm 1#sigma theor.","l");
//       myleg->AddEntry(ra4VieExpThM,"expected #pm 1#sigma theor.","l");
    }
    //     entry=myleg->AddEntry("RA1","2011 Limits","l");
    //     entry->SetLineColor(1);
    //     entry->SetLineStyle(1);
    //     entry->SetLineWidth(3);
    
    //     entry=myleg->AddEntry("sRA1","2010 Limits","l");
    //     entry->SetLineColor(1);
    //     entry->SetLineStyle(2);
    //     entry->SetLineWidth(3);
  }
  else if (tanBeta_==40) {

    //     entry=myleg->AddEntry("obs","Observed Limit","l");
    //     entry->SetLineColor(1);
    //     entry->SetLineStyle(1);
    //     entry->SetLineWidth(3);
    //     entry->SetTextColor(1);

    //     entry=myleg->AddEntry("exp","Expected Limit #pm 1#sigma","lf");
    //     entry->SetFillColor(kGray);
    //     entry->SetTextColor(1);
    //     entry->SetLineColor(1);
    //     entry->SetLineStyle(7);
    //     entry->SetLineWidth(3);
    //     entry->SetFillStyle(3002);


  }
  
  //constant squark and gluino mass contours
  if (tanBeta_==10) {
    for (int it=0;it<5;it++) {   
      lngl[it]->Draw("same");   
      lnsq[it]->Draw("same");
      sq_text[it]->Draw();
      gl_text[it]->Draw();
    }
  }
  else if (tanBeta_==40) {
    for (int it=2;it<9;it++) {  
      if(it<7){
	if(lngl_40[it]!=0)lngl_40[it]->Draw("samec");   
	if(gl_40_text[it]!=0)gl_40_text[it]->Draw();
      }
      if(lnsq_40[it]!=0)lnsq_40[it]->Draw("samec");
      if(it<6){
	if(sq_40_text[it]!=0)sq_40_text[it]->Draw();
      }
    }
  }

  if (tanBeta_==10) {
    //     SSdilep->Draw("samec");
    //     OSdilep->Draw("samec");
    //     Multilep->Draw("samec");
    //     RA1->Draw("samec");
    //     RA2->Draw("samec");
    //     MT2->Draw("samec");
    //     sRA4_LP->Draw("samec");
    // 	RAZ->Draw("samec");
    
    //     sRA1->Draw("same"); 
    //     sRA2->Draw("same"); 
    //     sRA4_old->Draw("samec");
    // 	sRAZ->Draw("samec");
    //     RA5_old->Draw("c same");
    //     RA6_old->Draw("c same");
  }
  else if (tanBeta_==40) {

    //     //expected curves and errors bands
    //     if ( tb40_plotExpected) {
    //       //not drawing the expected curves for better legibility
    // //       RA1_tb40_exp_p->Draw("samel");
    // //       RA1_tb40_exp_m->Draw("samel");
    // //       RA2b_1b_tight_exp_p->Draw("samel");
    // //       RA2b_1b_tight_exp_m->Draw("samel");
    // //keep the expected +/-1 sigma band
    //       RA1_tb40_exp_band->Draw("f") ;
    //       RA2b_1b_tight_exp_band->Draw("f") ;

    //       //important to draw lines after fill
    //       RA1_tb40_exp->Draw("samel");
    //       RA2b_1b_tight_exp->Draw("samel") ;

  }

  //     RA2b_1b_tight->Draw("samel");
  //     RA1_tb40->Draw("samel");

  // }
  
  TLegend* leg2=0;
  if (tanBeta_==10) {
    //     TLatex* RA1label = new TLatex(670,370.,"#alpha_{T}");
    //     RA1label->SetTextFont(42);
    //     RA1label->SetTextSize(0.05);
    //     RA1label->SetTextColor(kRed+2);
    //     RA1label->Draw("same");
    
    //     TLatex* RA2label = new TLatex(640,465.,"Jets+MHT");
    //     RA2label->SetTextFont(42);
    //     RA2label->SetTextSize(0.04);
    //     RA2label->SetTextColor(kBlue+2);
    //     RA2label->Draw("same");
	  
    //     TLatex* RAZlabel = new TLatex(740,415.,"Razor (0.8 fb^{-1})");
    //     RAZlabel->SetTextFont(42);
    //     RAZlabel->SetTextSize(0.04);
    //     RAZlabel->SetTextColor(kMagenta+1);
    //     RAZlabel->Draw("same");
    
    //     TLatex* RA5label = new TLatex(300,350.,"SS Dilepton");
    //     RA5label->SetTextFont(42);
    //     //RA5label->SetTextAngle(-10);
    //     RA5label->SetTextSize(0.04);
    //     RA5label->SetTextColor(kGreen+2);
    //     RA5label->Draw("same");
    
    //     //TLatex* RA6label = new TLatex(400,280.,"OS Dilepton");
    //     TLatex* RA6label = new TLatex(355,285.,"OS Dilepton");
    //     RA6label->SetTextFont(42);
    //     //RA6label->SetTextAngle(-15);
    //     RA6label->SetTextSize(0.04);
    //     RA6label->SetTextColor(kCyan+2);
    //     RA6label->Draw("same");

    //     TLatex* RA7label = new TLatex(338,215.,"Multi-Lepton");
    //     RA7label->SetTextFont(42);
    //     RA7label->SetTextSize(0.04);
    //     RA7label->SetTextColor(kYellow+2);
    //     RA7label->Draw("same");
    //     TLatex* RA7lumi = new TLatex(450,185.,"(2.1 fb^{-1})");
    //     RA7lumi->SetTextFont(42);
    //     RA7lumi->SetTextSize(0.04);
    //     RA7lumi->SetTextColor(kYellow+2);
    //     RA7lumi->Draw("same");

    
    //     TLatex* MT2label = new TLatex(400,440.,"MT2");
    //     MT2label->SetTextFont(42);
    //     MT2label->SetTextSize(0.04);
    //     MT2label->SetTextColor(kRed);
    //     MT2label->Draw("same");
    
    //     TLatex* RA4label = new TLatex(250,400.,"1 Lepton");
    //     RA4label->SetTextFont(42);
    //     RA4label->SetTextSize(0.04);
    //     RA4label->SetTextColor(kBlue);
    //     RA4label->Draw("same");
  }
  else if (tanBeta_==40  && !tb40_plotExpected) {
    //     int xposRA1 = 480;
    //     int yposRA1 = 510;

    //     int xposRA2b=450;
    //     int yposRA2b=275;

    //     TLatex* RA1label = new TLatex(xposRA1,yposRA1,"#alpha_{T}");
    //     RA1label->SetTextFont(42);
    //     RA1label->SetTextSize(0.05);
    //     RA1label->SetTextColor(kRed+2);
    //     RA1label->Draw("same");

    //     TLatex* RA2blabel = new TLatex(xposRA2b,yposRA2b,"Jets+MET+b");
    //     RA2blabel->SetTextFont(42);
    //     RA2blabel->SetTextSize(0.05);
    //     RA2blabel->SetTextColor(kBlue+1);
    //     RA2blabel->Draw("same");
    //   }
    //   else if (tanBeta_==40 && tb40_plotExpected) {

    //     leg2 = new TLegend(0.63,0.76,0.94,0.91,NULL,"brNDC");
    //     leg2->SetFillColor(0); 
    //     leg2->SetShadowColor(0);
    //     leg2->SetTextSize(0.04);
    //     leg2->SetBorderSize(0);
    
    //     entry=leg2->AddEntry("RA1_tb40","#alpha_{T}","l");
    //     entry->SetLineColor(kRed+2);
    //     entry->SetLineStyle(1);
    //     entry->SetLineWidth(3);
    //     entry->SetTextColor(kRed+2);

    //     entry=leg2->AddEntry("RA2b_1btight","Jets+MET+b","l");
    //     entry->SetLineColor(kBlue+1);
    //     entry->SetLineStyle(1);
    //     entry->SetLineWidth(3);
    //     entry->SetTextColor(kBlue+1);

  }

  //exclusion limits previous experiments
  if(tanBeta_ == 3){
    TEV_sn_d0_1->Draw("fsame");
    TEV_sn_d0_2->Draw("fsame");
  }
  if (tanBeta_==10)   LEP_ch->Draw("fsame");
  if (tanBeta_ != 50 && tanBeta_!=40) LEP_sl->Draw("fsame");

//   //remove CDF/D0 excluded regions
//   if (tanBeta_==10) {
//     TEV_sg_cdf->Draw("fsame");
//     TEV_sg_d0->Draw("same");  
//     TEV_sg_d0->Draw("fsame");
//   }

  //other labels
  Double_t xpos = 0;
  Double_t xposi = 0;
  Double_t ypos = 0;
  if(tanBeta_ == 50) xposi = 100;
  if(tanBeta_ == 50) xpos = 200;
  if(tanBeta_ == 50) ypos = -10;

  if(tanBeta_ == 40) xposi = 180+160;
  if(tanBeta_ == 40) xpos = 400;//240;
  if(tanBeta_ == 40) ypos = 100;

 
  //TLatex* lumilabel = new TLatex(750 +xposi + 100,767.-154,"#sqrt{s} = 7 TeV, #scale[0.65]{#int}Ldt = 0.98 fb^{-1}");
  TLatex* lumilabel = new TLatex(450*xscale+xpos,767.-154+100,"#sqrt{s} = 7 TeV,   Ldt 4.98 fb^{ -1}");
  TLatex* integral_symbol = new TLatex((577+100)*xscale+xpos,767.-145+100,"#int");

  lumilabel->SetTextSize(0.03);
  integral_symbol->SetTextSize(0.015);
  lumilabel->Draw("same");
  integral_symbol->Draw("same");

  TLatex* cmslabel = new TLatex(10.+xpos,767.-154+100,"CMS Preliminary");
  cmslabel->SetTextSize(0.03);
  cmslabel->Draw("same");

  TString text_tanBeta;
  TString a0str="0";
  if (tanBeta_==40) a0str = "-500 GeV";
  text_tanBeta =  "tan#beta = "+tanb+",  A_{0} = "+a0str+",  #mu > 0";
  int anotherOffset = (tb40_plotExpected && tanBeta_==40) ? -100 : 0;
//   TLatex* cmssmpars = new TLatex(/*530.+xpos,690.+ypos-130*/120+xpos,555+ypos+anotherOffset,text_tanBeta);
//   TLatex* cmssmpars = new TLatex(0.61,0.60,text_tanBeta);
  TLatex* cmssmpars = new TLatex(0.61,0.70,text_tanBeta);
  cmssmpars->SetNDC(1);

  cmssmpars->SetTextSize(0.04);
  cmssmpars->Draw("same");

  TLatex* lep_chargino = new TLatex(250,135,"LEP2 #tilde{#chi}_{1}^{#pm}");
  lep_chargino->SetTextSize(0.03);
  lep_chargino->SetTextFont(42);
  //  lep_chargino->Draw("same");

  TLatex* lep_slepton = new TLatex(26,190,"LEP2 #tilde{#font[12]{l}}^{#pm}");
  lep_slepton->SetTextSize(0.03);
  lep_slepton->SetTextAngle(-83);
  lep_slepton->SetTextFont(42);
  //  lep_slepton->Draw("same");



  //LM points
  TMarker* LM0 = new TMarker(200.,160.,20);
  TMarker* LM1 = new TMarker(60.,250.,20);
  TMarker* LM3 = new TMarker(330.,240.,20);
  TMarker* LM6 = new TMarker(80.,400.,20);
    
  LM0->SetMarkerSize(1.2);
  LM1->SetMarkerSize(1.2);
    
  TLatex* tLM0 = new TLatex(205.,160.," LM0");
  tLM0->SetTextSize(0.035);
    
  TLatex* tLM1 = new TLatex(80.,245.,"LM1");
  tLM1->SetTextSize(0.035);
  
  //TLatex* tLM3 = new TLatex(350.,235.,"LM3 (tan#beta=20)");
  TLatex* tLM3 = new TLatex(350.,235.,"LM3");
  tLM3->SetTextSize(0.035);
  
  TLatex* tLM6 = new TLatex(100.,395.,"LM6");
  tLM6->SetTextSize(0.035);
  
  //  if (tanBeta_ != 50){
  //  LM0->Draw("same");   
  //  tLM0->Draw("same");
  //  LM1->Draw("same");   
  //  tLM1->Draw("same");
  // }

  /*
    if (tanBeta_ == 10){ 
    LM1->Draw("same");
    tLM1->Draw("same");
    LM3->Draw("same");
    tLM3->Draw("same");
    LM6->Draw("same");
    tLM6->Draw("same");
    }
  */



  //stau=LSP contour
  if (tanBeta_==10) {
    stau->Draw("fsame");
//     NoEWSB->Draw("fsame");
    
    //legends
    legexp->Draw();
    legst->Draw();
    //legNoEWSB->Draw();
  }
  if (tanBeta_!=40 || tb40_plotExpected)  myleg->Draw();
  if (tanBeta_==40 && tb40_plotExpected) leg2->Draw();

  hist->Draw("sameaxis");
  cvsSys->RedrawAxis();
  cvsSys->Update();
  cvsSys->Write();
  
  if( plotLO_ ){
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+"_LO.pdf");
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+"_LO.png");
  }else{
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+".eps");
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+".ps");
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+".pdf");
    cvsSys->SaveAs("ExclusionLimit_tanb"+tanb+".png");
  }
  
  output->Write();

  //output->Close();
  //delete output; 

}
コード例 #23
0
void draw_survey()
{
  TFile * infile = new TFile("geotr.root","READ");
  TTree * tr = (TTree*) infile->Get("geotr");
  Int_t nstb,row,col;
  tr->SetBranchAddress("nstb",&nstb);
  tr->SetBranchAddress("row",&row);
  tr->SetBranchAddress("col",&col);

  const Double_t large_width = 58.0; // large cell width
  const Double_t small_width = 38.0; // small cell width

  Double_t x,y,z,x1,y1,x2,y2;
  Int_t it=0;
  Int_t color;
  TLine * cell[4][1264];

  for(Int_t i=0; i<tr->GetEntries(); i++)
  {
    tr->GetEntry(i);
    switch(nstb)
    {
      case 1:
        x = -24.0 - 25.0 - 58.6 * col;
        y = 965.5 - 58.5 * row;
        z = 7208;
        color = (Int_t) kMagenta;
        break;
      case 2:
        x = -24.0 - 8.0 + 66.6 + 58.4 * col; //new position May 5 2015
        y = 965.1 - 58.6 * row;
        z = 7188;
        color = (Int_t) kRed;
        break;
      case 3:
        if(row>16.5)
        {
          x = -22.0 - 17.7 - 38.2 * col;
          y = 422.7 - 37.9 * row;
          z = 7208;
          color = (Int_t) kBlue;
        }
        else
        {
          x = -22.0 - 17.7 - 38.2 * col;
          y = 4.75 + 438.9 - 39.0 * row;
          z = 7204;
          color = (Int_t) kCyan;
        };
        break;
      case 4:
        x = -22.0 - 8.0 + 60. + 38.4 * col; // new position May 5 2015
        y = 444. - 38.7 * row;
        z = 7188;
        color = (Int_t) kGreen+2;
        break;
    };

    if(nstb<=2) 
    {
      x1 = x - large_width/2.0;
      x2 = x + large_width/2.0;
      y1 = y - large_width/2.0;
      y2 = y + large_width/2.0;
    }
    else
    {
      x1 = x - small_width/2.0;
      x2 = x + small_width/2.0;
      y1 = y - small_width/2.0;
      y2 = y + small_width/2.0;
    };

    cell[0][it] = new TLine(x1,y1,x2,y1); //t
    cell[1][it] = new TLine(x1,y2,x2,y2); //b
    cell[2][it] = new TLine(x1,y1,x1,y2); //l
    cell[3][it] = new TLine(x2,y1,x2,y2); //r
    for(Int_t j=0; j<4; j++) cell[j][it]->SetLineColor(color);
    it++;
  };

  Double_t md = 1200;
  Int_t factor = 1; // bins per millimeter... set this too high and you'll get a memory leak!
  factor *= 2;
  TH2D * bg = new TH2D("survey","FMS cells survey [mm]",factor*md,-1*md,md,factor*md,-1*md,md);
  TCanvas * survey = new TCanvas("survey","survey",700,700);
  gStyle->SetOptStat(0);
  bg->Draw();
  for(Int_t i=0; i<1264; i++) for(Int_t j=0; j<4; j++) cell[j][i]->Draw();
};
コード例 #24
0
void createWorkspace(const std::string &infilename, int nState, bool correctCtau, bool drawRapPt2D, bool drawPtCPM2D){
	gROOT->SetStyle("Plain");
	gStyle->SetTitleBorderSize(0);

	// 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* jpsi = new TLorentzVector;
	tree->SetBranchAddress("JpsiP",&jpsi);
	double CPMval = 0;
	tree->SetBranchAddress("CPM",&CPMval);
	double massErr = 0;
	tree->SetBranchAddress("JpsiMassErr",&massErr);
	double Vprob = 0;
	tree->SetBranchAddress("JpsiVprob",&Vprob);
	double lifetime = 0;
	tree->SetBranchAddress("Jpsict",&lifetime);
	double lifetimeErr = 0;
	tree->SetBranchAddress("JpsictErr",&lifetimeErr);

	// define variables necessary for J/Psi(Psi(2S)) mass,lifetime fit
	RooRealVar* JpsiMass =
		new RooRealVar("JpsiMass", "M [GeV]", onia::massMin, onia::massMax);
	RooRealVar* JpsiMassErr =
		new RooRealVar("JpsiMassErr", "#delta M [GeV]", 0, 5);
	RooRealVar* JpsiRap =
		new RooRealVar("JpsiRap", "y", -onia::rap, onia::rap);
	RooRealVar* JpsiPt =
		new RooRealVar("JpsiPt", "p_{T} [GeV]", 0. ,100.);
	RooRealVar* JpsiCPM =
		new RooRealVar("JpsiCPM", "N_{ch}", 0. ,100.);		
	RooRealVar* Jpsict =
		new RooRealVar("Jpsict", "lifetime [mm]", -1., 2.5);
	RooRealVar* JpsictErr =
		new RooRealVar("JpsictErr", "Error on lifetime [mm]", 0.0001, 1);
	RooRealVar* JpsiVprob =
		new RooRealVar("JpsiVprob", "", 0.01, 1.);

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

	// The list of data variables    
	RooArgList dataVars(*JpsiMass,*JpsiMassErr,*JpsiRap,*JpsiPt,*JpsiCPM,*Jpsict,*JpsictErr,*JpsiVprob);

	// 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;

	// loop through events in tree and save them to dataset
	for (int ientries = 0; ientries < entries; ientries++) {
	
		if (ientries%100000==0) std::cout << "event " << ientries << " of " << entries <<  std::endl;

		tree->GetEntry(ientries);

		double M =jpsi->M();
		double y=jpsi->Rapidity();
		double pt=jpsi->Pt();
		double cpm=CPMval;


		if (M > JpsiMass->getMin() && M < JpsiMass->getMax()
				&& massErr > JpsiMassErr->getMin() && massErr < JpsiMassErr->getMax()
				&& pt > JpsiPt->getMin() && pt < JpsiPt->getMax()
				&& cpm > JpsiCPM->getMin() && cpm < JpsiCPM->getMax()
				&& y > JpsiRap->getMin() && y < JpsiRap->getMax()
				&& lifetime > Jpsict->getMin() && lifetime < Jpsict->getMax()
				&& lifetimeErr > JpsictErr->getMin() && lifetimeErr < JpsictErr->getMax()
				&& Vprob > JpsiVprob->getMin() && Vprob < JpsiVprob->getMax()
			 ){

			JpsiPt      ->setVal(pt); 
			JpsiCPM		->setVal(cpm);
			JpsiRap     ->setVal(y); 
			JpsiMass    ->setVal(M);
			JpsiMassErr ->setVal(massErr);
			JpsiVprob   ->setVal(Vprob);

			//cout<<"before lifetime correction \n"
			//	<<"Jpsict: "<<lifetime<<" JpsictErr: "<<lifetimeErr<<endl;

			if(correctCtau){
				lifetime    = lifetime    * onia::MpsiPDG / M ;
				lifetimeErr = lifetimeErr * onia::MpsiPDG / M ;
				Jpsict    ->setVal(lifetime);
				JpsictErr ->setVal(lifetimeErr);
				//cout<<"MpsiPDG: "<<onia::MpsiPDG<<endl;
				//cout<<"after lifetime correction \n"
				//	<<"Jpsict: "<<lifetime<<" JpsictErr: "<<lifetimeErr<<endl;
			}
			else{
				Jpsict    ->setVal(lifetime);
				JpsictErr ->setVal(lifetimeErr);
			}

			fullData->add(dataVars);
		}
	}//ientries


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

	////Get datasets binned in pT, cpm, and y

		for(int iRap = 1; 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 = 1; 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];
			}
			
		  for(int iCPM = 1; iCPM <= onia::NchBins; iCPM++){
		  
		  
	  	    Double_t cpmMin;
			Double_t cpmMax;
			if(iCPM==0){
				cpmMin = onia::cpmRange[0];
				cpmMax = onia::cpmRange[onia::NchBins];
			} else{
				cpmMin = onia::cpmRange[iCPM-1];
				cpmMax = onia::cpmRange[iCPM];
			}

			// output file name and workspace
			std::stringstream outfilename;
			outfilename << "tmpFiles/backupWorkSpace/fit_Psi" << nState-3 << "S_rap" << iRap << "_pt" << iPT << "_cpm" << iCPM << ".root";
//			outfilename << "tmpFiles/fit_Psi" << nState-3 << "S_rap" << iRap << "_pt" << iPT << ".root";			
			RooWorkspace* ws = new RooWorkspace(workspacename.c_str());

			// define pt and y cuts on dataset
			std::stringstream cutString;
			cutString << "(JpsiCPM > " << cpmMin << " && JpsiCPM < "<< cpmMax << ") && " << "(JpsiPt >= " << ptMin << " && JpsiPt < "<< 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 << "data_rap" << iRap << "_pt" << iPT << "_cpm" << iCPM;;
			binData->SetNameTitle(name.str().c_str(), "Data For Fitting");    

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

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

		std::stringstream cutRapPt;
		cutRapPt << "(JpsiCPM > " << cpmMin << " && JpsiCPM < "<< cpmMax << ") && "
			<< "(JpsiPt > " << ptMin << " && JpsiPt < "<< ptMax << ") && "
			<< "(TMath::Abs(JpsiRap) > " << yMin << " && TMath::Abs(JpsiRap) < " << yMax << ")";
		cout<<"cutRapPt: "<<cutRapPt.str().c_str()<<endl;

		RooDataSet* rapPtData = (RooDataSet*)fullData->reduce(cutRapPt.str().c_str());
		std::stringstream nameRapPt;
		nameRapPt << "data_rap0_pt0_cpm0";
		rapPtData->SetNameTitle(nameRapPt.str().c_str(), "Data For full rap and pt");

		// output file name and workspace
		std::stringstream outfilename;
		outfilename << "tmpFiles/backupWorkSpace/fit_Psi" << nState-3 << "S_rap0_pt0_cpm0.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",30,0, 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<<"(JpsiMass > " << MassMin << " && JpsiMass < "<< MassMax << ")";
		//following two methods can only be used in root_v30, 34 does not work
		rapPtTree->Draw("JpsiPt:JpsiRap>>rapPt",cutMass.str().c_str(),"colz");
		cout<<"debug"<<endl;
		rapPtTree->Draw("TMath::Abs(JpsiRap)>>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;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,"Fit/rapPt_Psi%dS.pdf",nState-3);
		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,"Fit/rapDimuon_1p2_Psi%dS.pdf",nState-3);
		c3->SaveAs(savename);
	}
	
	if(drawPtCPM2D){
		double yMin = onia::rapForPTRange[0];
		double yMax = onia::rapForPTRange[onia::kNbRapForPTBins];
		double ptMin =  onia::pTRange[0][0];
		double ptMax =  onia::pTRange[0][onia::kNbPTBins[0]];
		double cpmMin =  onia::cpmRange[0];
		double cpmMax =  onia::cpmRange[onia::NchBins];		

		std::stringstream cutRapPt;
		cutRapPt << "(JpsiCPM > " << cpmMin << " && JpsiCPM < "<< cpmMax << ") && "
			<< "(JpsiPt > " << ptMin << " && JpsiPt < "<< ptMax << ") && "
			<< "(TMath::Abs(JpsiRap) > " << yMin << " && TMath::Abs(JpsiRap) < " << yMax << ")";
		cout<<"cutRapPt: "<<cutRapPt.str().c_str()<<endl;

		RooDataSet* rapPtData = (RooDataSet*)fullData->reduce(cutRapPt.str().c_str());
		std::stringstream nameRapPt;
		nameRapPt << "data_rap0_pt0_cpm0";
		rapPtData->SetNameTitle(nameRapPt.str().c_str(), "Data For full rap and pt");

		// output file name and workspace
		std::stringstream outfilename;
		outfilename << "tmpFiles/backupWorkSpace/fit_Psi" << nState-3 << "S_rap0_pt0_cpm0.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* PtCPM;
		double MassMin;
		double MassMax;

		if(nState==4){
			PtCPM = new TH2D( "PtCPM", "PtCPM", 100,0,50,200,0,100);
			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){
			PtCPM = new TH2D( "PtCPM", "PtCPM", 100,0,50,200,0,100); //  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 Pt-CPM for Psi"<<nState-3<<"S"<<endl;
		cout<<"MassMin for Pt-CPM plot = "<<MassMin<<endl;
		cout<<"MassMax for Pt-CPM plot = "<<MassMax<<endl;

		TTree *rapPtTree = (TTree*)rapPtData->tree();
		std::stringstream cutMass;
		cutMass<<"(JpsiMass > " << MassMin << " && JpsiMass < "<< MassMax << ")";
		//following two methods can only be used in root_v30, 34 does not work
		rapPtTree->Draw("JpsiCPM:JpsiPt>>PtCPM",cutMass.str().c_str(),"colz");
		cout<<"debug"<<endl;

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

		TLine* PtCPMLine;

		int iRap=0;
		for(int iPt=0;iPt<onia::kNbPTMaxBins+1;iPt++){
		int cpmBegin = 0;
			if(nState==5) cpmBegin = 1;
			for(int icpm=cpmBegin;icpm<onia::NchBins+1;icpm++){
			
			PtCPMLine= new TLine( onia::pTRange[iRap][0], onia::cpmRange[icpm], onia::pTRange[iRap][onia::kNbPTMaxBins], onia::cpmRange[icpm] );
			PtCPMLine->SetLineWidth( 2 );
			PtCPMLine->SetLineStyle( 1 );
			PtCPMLine->SetLineColor( kWhite );
			PtCPMLine->Draw();
			PtCPMLine= new TLine( onia::pTRange[iRap][iPt], onia::cpmRange[0], onia::pTRange[iRap][iPt], onia::cpmRange[onia::NchBins] );
			PtCPMLine->SetLineWidth( 2 );
			PtCPMLine->SetLineStyle( 1 );
			PtCPMLine->SetLineColor( kWhite );
			PtCPMLine->Draw();

			
//				PtCPMLine= new TLine( onia::pTRange[0][onia::kNbPTMaxBins], onia::cpmRange[icpm], onia::pTRange[0][onia::kNbPTMaxBins], onia::cpmRange[icpm] );
//				PtCPMLine->SetLineWidth( 2 );
//				PtCPMLine->SetLineStyle( 1 );
//				PtCPMLine->SetLineColor( kWhite );
//				PtCPMLine->Draw();
			}
		}

		char savename[200];
		sprintf(savename,"Fit/PtCPM_Psi%dS.pdf",nState-3);
		c2->SaveAs(savename);
	}

	f->Close();
}
コード例 #25
0
ファイル: talk.C プロジェクト: bainbrid/usercode
// -----------------------------------------------------------------------------
//
void talk() {
  
  time_t start = TTimeStamp().GetSec();

  bool draw = true;
  bool debug = true;
  
  // Binning
  int xbins = 100;
  int ybins = 100;
  double xmin = 0.0;
  double xmax = 1.0;
  double ymin = 0.0;
  double ymax = 1.0;
  double xbin_centre = ( ( xmax - xmin ) / xbins ) / 2.;
  double ybin_centre = ( ( ymax - ymin ) / ybins ) / 2.;
  
  // AlphaT values
  const int nat = 1;
  double at[nat];
  for ( int ii = 0; ii < nat; ++ii ) { at[ii] = 0.55 + ii * 0.001; } 
  
  // HT regions
  const int nht = 3;
  double ht_min[nht] = { 250., 300., 350. };

  // Jet pT thresholds
  double pt1_min[nht] = { 71.4, 85.7, 100. };
  double pt2_min[nht] = { 71.4, 85.7, 100. };
  double pt3_min[nht] = { 35.7, 42.9., 50. };

  // x fractions
  double x1_min[nht];
  double x2_min[nht];
  double x3_max[nht];
  for ( int ii = 0; ii < nht; ++ii ) { x1_min[ii] = ( 2. * pt1_min[ii]) / ( ht_min[ii] + pt3_min[ii] ); }
  for ( int ii = 0; ii < nht; ++ii ) { x2_min[ii] = ( 2. * pt2_min[ii]) / ( ht_min[ii] + pt3_min[ii] ); }
  for ( int ii = 0; ii < nht; ++ii ) { x3_max[ii] = ( 2. * pt3_min[ii]) / ( ht_min[ii] + pt3_min[ii] ); }
  
  // Loop through bins 
  int loop = 0;
  int nloops = nht;
  for ( int iht = 0; iht < nht; ++iht ) {
    std::cout << "Completed " 
	      << 100.*float(loop)/float(nloops) 
	      << "%..." 
	      << std::endl; 
    loop++;
    
    // Labeling
    std::stringstream ss;
    ss << "HT" << int(ht_min[iht]);
	  
    // New canvas for plots
    TCanvas* c1 = 0;
    if (draw) c1 = new TCanvas( TString("Canvas"+ss.str()), "" );
	  
    // Pad for cross-section plot
    TPad* pad = 0;
    if (draw) pad = new TPad(TString("Pad"+ss.str()),"",0.,0.,1.,1.);
    if (pad) {
      pad->SetGrid();
      pad->Draw();
      pad->cd();
      pad->SetLogz();
    }
    TH1F* hr = 0;
    if (draw) hr = pad->DrawFrame(0.,0.,1.,1.);

    // Histo title
    if (hr) {
      std::stringstream sss;
      sss << "H_{T}=" << ht_min[iht]
	  << "(p_{T1},p_{T2},p_{T3})=" 
	  << pt1_min[iht] << ","
	  << pt2_min[iht] << ","
	  << pt3_min[iht] << ")"
	  << ", (x_{1},x_{2},x_{3})=" 
	  << x1_min[iht] << ","
	  << x2_min[iht] << ","
	  << x3_max[iht] << ")";
      hr->SetTitle( sss.str().c_str() );
      hr->GetXaxis()->SetTitle( "x_{2}" );
      hr->GetYaxis()->SetTitle( "x_{1}" );
    }
	  
    // Create 2D cross-section plot
    TH2D* his = 0;
    if (draw) his = new TH2D(TString("Histo"+ss.str()),"",
			     xbins,xmin,xmax,
			     ybins,ymin,ymax);
	  
    // Fill 2D cross-section plot
    for ( int xbin = 0; xbin < xbins; ++xbin ) { 
      for ( int ybin = 0; ybin < ybins; ++ybin ) { 
	double x2 = ( ( xmax - xmin ) / xbins ) * xbin + xmin;
	double x1 = ( ( ymax - ymin ) / ybins ) * ybin + ymin;
	double val = ( x1*x1 + x2*x2 ) / ( ( 1 - x1 ) * ( 1 - x2 ) ); 
	      
	if ( !constrain( x1, x2, x3 ) ) { continue; }
	      
	if ( x1 < x1_cut[ix1] ) { continue; }
	      
	double alpha_t =  x2 / ( 2 * sqrt(x1+x2-1) );
	if (his) his->Fill( x2+xbin_centre, x1+ybin_centre, val ); 
      }
    }
	  
    // Draw 2D cross-section plot
    gStyle->SetPalette(1);
    if (his) {
      his->SetMaximum( his->GetMaximum() );
      his->SetMinimum( his->GetMinimum(1.e-12) );
      his->Draw("COLZsame");
    }

    // Pad for AlphaT contours
    if (c1) c1->cd();
    TPad* overlay = 0;
    if (draw) overlay = new TPad(TString("Overlay"+ss.str()),"",0.,0.,1.,1.);
    if (overlay) {
      overlay->SetFillStyle(4000);
      overlay->SetFillColor(0);
      overlay->SetFrameFillStyle(4000);
      overlay->Draw();
      overlay->cd();
    }
    TH1F* hframe = 0;
    if (draw) overlay->DrawFrame(pad->GetUxmin(),
				 pad->GetUymin(),
				 pad->GetUxmax(),
				 pad->GetUymax());
	  
    // Graphs of AlphaT contours
    TMultiGraph* mg = 0;
    if (draw) {
      mg = new TMultiGraph();
      for ( Int_t iat = 0; iat < nat; iat++ ) {
	Double_t alpha_t = at[iat];
	const Int_t n_ = 100;
	Double_t x1_[n_];
	Double_t x2_[n_];
	for ( Int_t j = 0; j < 100; j++ ) {
	  x2_[j] = j*0.01;
	  Double_t temp = ( x2_[j] - 2. * alpha_t * alpha_t ) / ( 2. * alpha_t );
	  x1_[j] = temp * temp + 1 - alpha_t * alpha_t;
	}
	TGraph* gr = new TGraph(n_,x2_,x1_);
	mg->Add(gr,"l");
      }
      mg->Draw();
    }
	  
    if (c1) c1->cd();
    if (c1) c1->SaveAs(TString(ss.str()+".png"));
	  
  }

}
コード例 #26
0
ファイル: hPYphocalc.C プロジェクト: XuQiao/HI
void hPYphocalc(){
	gStyle->SetOptStat(kFALSE);
	const int maxNpart = 100;
	int sth=0, Gth=0;
        TFile *f = TFile::Open(outG);
        if(sth==0){TString dirname = "std";}
        else if(sth==1){TString dirname ="Gri055";}
        else {TString dirname ="Gri101";}
        TObjString* dataname = (TObjString*)f->Get(Form("dataname"));
        TObjString* histoname = (TObjString*)f->Get(Form("histoname"));
	TFile *fdata = TFile::Open(dataname->GetName());
                TString name;
        if(Gth==0)
                name = "G0";
        else if(Gth<nGlau)
                name = Form("Glau_%d",Gth);
        else
                name = Form("bin_%d",Gth-nGlau+1);
        TObjString* Glaubername = (TObjString*)f->Get(Form("%s/%s/Glaubername",dirname.Data(),name.Data()));
        TVectorD* k0 = (TVectorD*)f->Get(Form("%s/%s/k0",dirname.Data(),name.Data()));
        TVectorD* theta0 = (TVectorD*)f->Get(Form("%s/%s/theta0",dirname.Data(),name.Data()));
        TVectorD* xmin = (TVectorD*)f->Get(Form("%s/%s/xmin",dirname.Data(),name.Data()));
        TVectorD* xmax = (TVectorD*)f->Get(Form("%s/%s/xmax",dirname.Data(),name.Data()));
        TVectorD* thetabest = (TVectorD*)f->Get(Form("%s/%s/thetabest",dirname.Data(),name.Data()));
        TVectorD* kbest = (TVectorD*)f->Get(Form("%s/%s/kbest",dirname.Data(),name.Data()));
	TVectorD* kpoint = (TVectorD*)f->Get(Form("%s/%s/kpoint",dirname.Data(),name.Data()));
        TVectorD* NcollAver = (TVectorD*)f->Get(Form("%s/%s/NcollAver",dirname.Data(),name.Data()));
	TVectorD* centbin = (TVectorD*)f->Get(Form("%s/%s/centbin",dirname.Data(),name.Data()));

        TFile *fGlauber = TFile::Open(Glaubername->GetName());
        //(*k0)[0]=1.39;  (*kbest)[0]=0.425;
        //(*theta0)[0]=3.41;      (*thetabest)[0]=1.30;
        TF1 *gammafun[maxNpart];
        TF1 *gammafunevt[maxNpart];
        TF1 *gammafunnucl[maxNpart];
        TF1 *gammafunnuclNcoll[maxNpart];
        double kevt = (*k0)[0]-(*kbest)[0];
        for(int iNpart=0;iNpart<maxNpart;iNpart++){
        	gammafun[iNpart] = new TF1("gammafun","TMath::GammaDist(x,[0],0,[1])",0,200);
		gammafunevt[iNpart] = new TF1("gammafunevt","TMath::GammaDist(x,[0],0,[1])",0,200);
	        gammafunnucl[iNpart] = new TF1("gammafunnucl","TMath::GammaDist(x,[0],0,[1])",0,200);
        	gammafunnuclNcoll[iNpart] = new TF1("gammafunnuclNcoll","TMath::GammaDist(x,[0],0,[1])",0,200);
                double k_=(*k0)[0]+(*kbest)[0]*(iNpart-2);
                double theta_=(*theta0)[0]+(*thetabest)[0]*TMath::Log(iNpart-1);
                gammafun[iNpart]->SetParameter(0,k_);   //[1]: k value
                gammafun[iNpart]->SetParameter(1,theta_);       //[2]: theta value
		gammafunevt[iNpart]->SetParameter(0,kevt);
		gammafunevt[iNpart]->SetParameter(1,theta_);
		gammafunnucl[iNpart]->SetParameter(0,(*kbest)[0]);
		gammafunnucl[iNpart]->SetParameter(1,theta_);
		gammafunnuclNcoll[iNpart]->SetParameter(0,(*kbest)[0]*(iNpart-1));
		gammafunnuclNcoll[iNpart]->SetParameter(1,theta_);
		if(iNpart==2){
			gammafunnuclNcoll[iNpart]->SetNpx(1e4);
			gammafunnuclNcoll[iNpart]->SetRange(1e-11,200);
		}
       }

        TTree *t = (TTree*)fGlauber->Get("nt_p_Pb");
        Float_t Ncoll, Npart, B;        Long_t Nevent;
        t->SetBranchAddress("Ncoll",&Ncoll);
        t->SetBranchAddress("Npart",&Npart);
        t->SetBranchAddress("B",&B);

        Nevent = (Long_t) t->GetEntries();
        Long_t Ev;      Int_t Bino;     Double_t Para, Para_nucl, Para_p, Para_evt, Bi_Para_nucl, Bi_Para_evt;			

	double yUCM[8]={};
	double yPCM[8]={};
	double yVCM[8]={};
	double yUCM_[200]={};
	double yPCM_[200]={};
	double yVCM_[200]={};
	double C=1e-4;
	double PNcoll[maxNpart]={};
	TH1D *histo_obs = (TH1D*)fdata->Get(histoname->GetName());
        TH1D *histo_obs_norm = (TH1D*)histo_obs->Clone();
        histo_obs_norm->Scale(1/histo_obs->Integral());
	TH1D* hUCM = new TH1D("hUCM","hUCM",200,0,200);
	TH1D* hPCM = new TH1D("hPCM","hPCM",200,0,200);
	TH1D* hVCM = new TH1D("hVCM","hVCM",200,0,200);
	TH2D* NcollvsET = new TH2D("NcollvsET","NcollvsET",100,0,100,2000,0,400);
	for(Ev=0;Ev<Nevent;Ev++){
		t->GetEntry(Ev);
		PNcoll[(int)Ncoll]++;
	}
	for(int i=0;i<maxNpart;i++){
		PNcoll[i]/=Nevent;
		cout<<PNcoll[i]<<"\t";
	}
		cout<<endl;
	for(Ev=0;Ev<Nevent;Ev++){
		if(Ev%100000==0)	cout<<"\t"<<"Have run "<<Ev<<" events"<<endl;
		t->GetEntry(Ev);
		Para = gammafun[(int)Npart]->GetRandom();
		Para_nucl = gammafunnuclNcoll[(int)Npart]->GetRandom();
		Para_p = gammafunnuclNcoll[(int)Npart]->GetRandom();
		Para_evt = 0;
		for(int i=0;i<N-1;i++)
			if(Para>=(*kpoint)[i] && Para<(*kpoint)[i+1])
				int ibin = i;
		for(int Bino=0;Bino<Ncoll;Bino++){
			Bi_Para_evt = gammafunevt[(int)Npart]->GetRandom();
			Para_evt += Bi_Para_evt;
		}	
		double PNcollET = gammafun[(int)Npart]->Eval(Para);
//		double k = gammafun[(int)Npart]->GetParameter(0);
                double theta=(*theta0)[0]+(*thetabest)[0]*TMath::Log(Npart-1);
		double YNcollUCM = C*Ncoll;
		double YNcollPCM = C/1.0/(*kbest)[0]/theta*(Para_nucl);
		double YNcollVCM = C/2.0*(Para_nucl/(*kbest)[0]/theta+Ncoll);
		yUCM[ibin] += PNcoll[(int)Ncoll]*PNcollET*YNcollUCM;
		yPCM[ibin] += PNcoll[(int)Ncoll]*PNcollET*YNcollPCM;
		yVCM[ibin] += PNcoll[(int)Ncoll]*PNcollET*YNcollVCM;
		yUCM_[(int)Para] += PNcoll[(int)Ncoll]*PNcollET*YNcollUCM;
		yPCM_[(int)Para] += PNcoll[(int)Ncoll]*PNcollET*YNcollPCM;
		yVCM_[(int)Para] += PNcoll[(int)Ncoll]*PNcollET*YNcollVCM;

		NcollvsET->Fill(Ncoll,Para);
	}
	for(int ibin=1;ibin<hUCM->GetNbinsX();ibin++){
		hUCM->SetBinContent(ibin,yUCM_[ibin-1]);			
		hPCM->SetBinContent(ibin,yPCM_[ibin-1]);			
		hVCM->SetBinContent(ibin,yVCM_[ibin-1]);
	}
	TCanvas *c1 = new TCanvas();
	TCanvas *c2 = new TCanvas();
	c1->SetLogy();
	c2->SetLogx();
	c2->SetLogy();
	c2->SetLogz();
	c1->cd();
	TH1D* hFrame = new TH1D("","",200,0,200);
	hFrame->SetTitle("");
	hFrame->GetXaxis()->SetTitle("HF #Sigma E_{T} |#eta|>4");
	hFrame->GetYaxis()->SetTitle("Yield no units");
	hFrame->GetXaxis()->SetRangeUser(0,150);
	hFrame->GetYaxis()->SetRangeUser(1e-6,1);
	hFrame->Draw();
	histo_obs_norm->SetMarkerStyle(20);
	histo_obs_norm->SetMarkerSize(1.0);
	histo_obs_norm->SetMarkerColor(1);
	histo_obs_norm->Draw("Psame");
	hUCM->SetMarkerStyle(24);
	hUCM->SetMarkerSize(1.0);
	hUCM->SetMarkerColor(2);
        hPCM->SetMarkerStyle(29);
        hPCM->SetMarkerSize(1.0);
        hPCM->SetMarkerColor(4);
        hVCM->SetMarkerStyle(34);
        hVCM->SetMarkerSize(1.0);
        hVCM->SetMarkerColor(5);
	hUCM->Draw("Psame");
	hPCM->Draw("Psame");
	hVCM->Draw("Psame");
	TLegend *leg = new TLegend(0.1,0.2,0.5,0.45);	
        leg->SetFillColor(0);
        leg->SetFillStyle(0);
        leg->SetBorderSize(0);
        leg->SetTextFont(42);
        leg->SetTextSize(0.03);
	leg->AddEntry(histo_obs_norm,"minimum bias events","lp");
	leg->AddEntry(hUCM,"hard scattering events(UCM)","lp");
	leg->AddEntry(hPCM,"hard scattering events(PCM)","lp");
	leg->AddEntry(hVCM,"hard scattering events(VCM)","lp");
	leg->Draw("same");
	c1->Print("paperfig3_CMS.png");
	c2->cd();
	gStyle->SetOptStat("nemr");
	NcollvsET->GetXaxis()->SetTitle("Ncoll");
	NcollvsET->GetYaxis()->SetTitle("HF #Sigma E_{T} |#eta|>4");
	NcollvsET->Draw("colz");
	c2->Print("NcollvsET2D.png");
	ofstream fstr("result_CMS.dat");
	fstr<<"i"<<"\t"<<"centbin"<<"\t"<<"kpoint"<<"\t"<<"NcollAver"<<"\t"<<"UCM"<<"\t"<<"PCM"<<"\t"<<"VCM"<<"\t"<<"pho1"<<"\t"<<"pho2"<<"\t"<<"MB"<<endl;
	for(int i=0;i<N-1;i++){
		fstr<<i<<"\t"<<(*centbin)[i]*100<<"% to "<<(*centbin)[i+1]*100<<"% \t"<<(*kpoint)[i]<<" to "<<(*kpoint)[i+1]<<"\t"<<(*NcollAver)[i]<<"\t"<<yUCM[i]<<"\t"<<yPCM[i]<<"\t"<<yVCM[i]<<"\t"<<yPCM[i]/yUCM[i]<<"\t"<<yVCM[i]/yUCM[i]<<"\t"<<"undetermined"<<endl;
	}
}
コード例 #27
0
ファイル: Fourier.C プロジェクト: CmsHI/CVS_CmsHi
void Fourier()
{
/*
  TString dataname = "HIData_Minbias_2760GeV";
  TString datatag = "PPRereco_INCLEFF1v4";
*/
  TString dataname = "PAData_Minbias_5TeV";
  TString datatag = "HM_Express_INCLEFF1v5";
//  TString datatag = "MB_INCLEFF1v4";

  int nmin=220;
  int nmax=260;
  const int ntrgptbins=11;
  const int nassptbins=11;

  TH1D ***hdata = compare_flow_pp_phi_multipad_pt<TH1D**>(dataname.Data(),datatag.Data(),nmin,nmax,-1,-1,2.0,4.0,ntrgptbins,nassptbins,-2.4,2.4,-2.4,2.4);
  TH1D* hdata_zyam[ntrgptbins][nassptbins];
  TF1* fitfunc_vn[ntrgptbins][nassptbins];

  for(int itrg = 0; itrg<ntrgptbins; itrg++)
  {
    for(int jass = 0; jass<nassptbins; jass++)
    {
      fitfunc_vn[itrg][jass] = FitVnFunc(hdata[itrg][jass]);
    }
  }

  int bin_ref=1;
  double V2_ref = fitfunc_vn[bin_ref][bin_ref]->GetParameter(2);
  double V3_ref = fitfunc_vn[bin_ref][bin_ref]->GetParameter(3);
  double V2_ref_err = fitfunc_vn[bin_ref][bin_ref]->GetParError(2);
  double V3_ref_err = fitfunc_vn[bin_ref][bin_ref]->GetParError(3);

  double v2[ntrgptbins];
  double v3[ntrgptbins];
  double v2_err[ntrgptbins];
  double v3_err[ntrgptbins];
  double pttrg[ntrgptbins] = {0.0};
  double pttrg_err[ntrgptbins] = {0.0};

  TH1D* hpt[ntrgptbins];
  for(int itrg = 0; itrg<ntrgptbins; itrg++)
  {
    TString filename = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/%s/merged/%s_%s_nmin%d_nmax%d_etatrg%.1f-%.1f_etaass%.1f-%.1f_centmin%d_centmax%d.root",dataname.Data(),dataname.Data(),datatag.Data(),nmin,nmax,-1,-1,-2.4,2.4,-2.4,2.4);    
    hpt[itrg] = (TH1D*)GetHist(filename,Form("ptcorr_signal_trg_%d",itrg));
    pttrg[itrg] = hpt[itrg]->GetMean();
  }

  for(int itrg = 0; itrg<ntrgptbins; itrg++)
  {
    v2[itrg] = fitfunc_vn[itrg][bin_ref]->GetParameter(2)/sqrt(fabs(V2_ref));
    v3[itrg] = fitfunc_vn[itrg][bin_ref]->GetParameter(3)/sqrt(fabs(V3_ref));
    v2_err[itrg] = fitfunc_vn[itrg][bin_ref]->GetParError(2)/fitfunc_vn[itrg][bin_ref]->GetParameter(2)*v2[itrg];
    v3_err[itrg] = fitfunc_vn[itrg][bin_ref]->GetParError(3)/fitfunc_vn[itrg][bin_ref]->GetParameter(3)*v3[itrg];
  }

  ofstream fcout(Form("data/%s_%s_nmin%d_nmax%d_centmin%d_centmax%d_ptass%d.txt",dataname.Data(),datatag.Data(),nmin,nmax,-1,-1,bin_ref));
  fcout << "pT    v_2    v_2 err." << endl;
  for(int itrg = 0; itrg<ntrgptbins; itrg++) fcout << pttrg[itrg] << " "<< v2[itrg] << " " << v2_err[itrg] <<endl;
  fcout<<endl<<endl;
  fcout << "pT    v_3    v_3 err." << endl;
  for(int itrg = 0; itrg<ntrgptbins; itrg++) fcout << pttrg[itrg] << " "<< v3[itrg] << " " << v3_err[itrg] <<endl;
  fcout<<endl<<endl;

  TGraphErrors* g_v2 = new TGraphErrors(ntrgptbins,pttrg,v2,pttrg_err,v2_err);
  TGraphErrors* g_v3 = new TGraphErrors(ntrgptbins,pttrg,v3,pttrg_err,v3_err);
  g_v3->SetMarkerStyle(24);

  TCanvas* cv = new TCanvas("cv","cv",600,550);
  TH2D* hdummy = new TH2D("dummy",";p_{T} (GeV/c);v_{2}",100,0,12.0,100,0,0.25);
  hdummy->Draw();
  g_v2->Draw("PESAME");
  g_v3->Draw("PESAME");
}
コード例 #28
0
void Factorization_eta_mc()
{
  const int nfiles = 24;
  TString filename[nfiles];

  filename[0] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent020_pttrg033_ptassallweight_etaass445_eff0_v42.root");
  filename[1] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent2040_pttrg033_ptassallweight_etaass445_eff0_v42.root");
  filename[2] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent4060_pttrg033_ptassallweight_etaass445_eff0_v42.root");
  filename[3] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent020_pttrg033_ptassallweight_etaass34_pixel_eff0_v42.root");
  filename[4] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent2040_pttrg033_ptassallweight_etaass34_pixel_eff0_v42.root");
  filename[5] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent4060_pttrg033_ptassallweight_etaass34_pixel_eff0_v42.root");
  filename[6] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent5060_pttrg053_ptassallweight_etaass45_eff0_v42.root");
  filename[7] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_mc_cent5060_pttrg053_ptassallweight_etaass45_eff0_v42.root");

//  filename[8] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent020_pttrg033_ptassallweight_etaass445_eff0_v42.root");
  filename[8] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HijingReco_Minbias_2760GeV/merged/epetadeco_gen_n2500_pttrg033_ptassallweight_etaass445_eff0_v42.root");
  filename[9] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HijingReco_Minbias_2760GeV/merged/epetadeco_gen_n5001200_pttrg033_ptassallweight_etaass445_eff0_v42.root");
  filename[10] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HijingReco_Minbias_2760GeV/merged/epetadeco_gen_n0160_pttrg033_ptassallweight_etaass445_eff0_v42.root");

/*
  filename[9] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent2040_pttrg033_ptassallweight_etaass445_eff0_v42.root");
  filename[10] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent4060_pttrg033_ptassallweight_etaass445_eff0_v42.root");
*/
  filename[11] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HijingReco_Minbias_2760GeV/merged/epetadeco_gen_n2500_pttrg033_ptassallweight_etaass34_eff0_v42.root");
  filename[12] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HijingReco_Minbias_2760GeV/merged/epetadeco_gen_n5001200_pttrg033_ptassallweight_etaass34_eff0_v42.root");
  filename[13] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HijingReco_Minbias_2760GeV/merged/epetadeco_gen_n0160_pttrg033_ptassallweight_etaass34_eff0_v42.root");
/*
  filename[11] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent020_pttrg033_ptassallweight_etaass34_eff0_v42.root");
  filename[12] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent2040_pttrg033_ptassallweight_etaass34_eff0_v42.root");
  filename[13] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent4060_pttrg033_ptassallweight_etaass34_eff0_v42.root");
*/
  filename[14] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent5060_pttrg053_ptassallweight_etaass34_eff0_v42.root");
  filename[15] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HydjetReco_Minbias_2760GeV/merged/epetadeco_gen_cent5060_pttrg053_ptassallweight_etaass34_eff0_v42.root");

  filename[16] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent020_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[17] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2040_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[18] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4060_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[19] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent020_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[20] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2040_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[21] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4060_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[22] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg033_ptassallweight_etaass34_eff0_v42.root");
  filename[23] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg033_ptassallweight_etaass34_eff0_v42.root");

/*
  filename[8] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[9] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[10] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[11] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[12] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[13] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[14] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg053_ptassallweight_etaass45_eff0_v18.root");
  filename[15] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg053_ptassallweight_etaass45_eff0_v18.root");
*/
  const int ntrgbins = 16;
  const int ntrgbins1 = ntrgbins;
  const int ntrgbins2 = ntrgbins/2;
  TGraphErrors* gr[nfiles][6];
  TGraphErrors* gr0[nfiles][6];
  TGraphErrors* gr1[nfiles][6];
  TGraphErrors* gr_ratio[nfiles][6];
  TGraphErrors* gr_total[nfiles][6];
  TGraph* gr_band[nfiles][6];
  TGraph* gr1_band[nfiles][6];
  TF1* fit[nfiles][6];
  TF1* fit_aver[nfiles][6];
  TF1* fit1_aver[nfiles][6];
  double slope[6][nfiles];
  double slope_err[6][nfiles];
  double slope1[6][nfiles];
  double slope1_err[6][nfiles];
//  double eta[ntrgbins2] = {0.12,0.36,0.6,0.84,1.08,1.32,1.56,1.8,2.04,2.28};
//  double eta[ntrgbins2] = {0.1,0.3,0.5,0.7,0.9,1.1,1.3,1.5,1.7,1.9,2.1,2.3};  
  double eta[ntrgbins2] = {0.15,0.45,0.75,1.05,1.35,1.65,1.95,2.25};
//  double eta[ntrgbins2] = {0.2,0.6,1.0,1.4,1.8,2.2};
  double eta_err[ntrgbins2] = {0.0};
  Color_t color[6] = {1,kBlue, kBlue, kBlue,1,1};

  TFile* fdiff[nfiles];
for(int jj=0;jj<nfiles;jj++)
{
  fdiff[jj] = new TFile(filename[jj].Data());

  TH2D* hsignal[ntrgbins];
  TH2D* hbackground[ntrgbins];
  TH2D* hsignal0[ntrgbins];
  TH2D* hbackground0[ntrgbins];
  TH2D* hsignal1[ntrgbins];
  TH2D* hbackground1[ntrgbins];
  TH1D* hsignal_1D[ntrgbins][6];
  TH1D* hbackground_1D[ntrgbins][6]; 
  TH1D* hsignal0_1D[ntrgbins][6];
  TH1D* hbackground0_1D[ntrgbins][6];
  TH1D* hsignal1_1D[ntrgbins][6];
  TH1D* hbackground1_1D[ntrgbins][6];

  double Vn[ntrgbins1][6];
  double VnError[ntrgbins1][6];
  double rn[ntrgbins2];
  double rn_err[ntrgbins2];
  double Vn0[ntrgbins1][6];
  double Vn0Error[ntrgbins1][6];
  double rn0[ntrgbins2];
  double rn0_err[ntrgbins2];
  double Vn1[ntrgbins1][6];
  double Vn1Error[ntrgbins1][6];
  double rn1[ntrgbins2];
  double rn1_err[ntrgbins2];
  double rn_ratio[ntrgbins2];
  double rn_ratio_err[ntrgbins2];
  double rn_total[ntrgbins2];
  double rn_total_err[ntrgbins2];

  for(int i=0;i<ntrgbins;i++)
  {
    hsignal0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfp/signalcosn_trg%d",i));
    hbackground0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfp/backgroundcosn_trg%d",i));
    hsignal1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfm/signalcosn_trg%d",i));
    hbackground1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfm/backgroundcosn_trg%d",i));
    hsignal[i] = (TH2D*)hsignal0[i]->Clone(Form("signalcosn_trg%d",i));
    hbackground[i] = (TH2D*)hbackground0[i]->Clone(Form("backgroundcosn_trg%d",i));
    hsignal[i]->Add(hsignal1[i]);
    hbackground[i]->Add(hbackground1[i]);

    for(int nbin=1;nbin<4;nbin++)
    {
      hsignal_1D[i][nbin] = (TH1D*)hsignal[i]->ProjectionX(Form("signal_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hsignal0_1D[i][nbin] = (TH1D*)hsignal0[i]->ProjectionX(Form("signal0_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hsignal1_1D[i][nbin] = (TH1D*)hsignal1[i]->ProjectionX(Form("signal1_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground_1D[i][nbin] = (TH1D*)hbackground[i]->ProjectionX(Form("background_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground0_1D[i][nbin] = (TH1D*)hbackground0[i]->ProjectionX(Form("background0_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground1_1D[i][nbin] = (TH1D*)hbackground1[i]->ProjectionX(Form("background1_1D_trg%d_%d",i,nbin),nbin,nbin,"e");

      Vn[i][nbin]=hsignal_1D[i][nbin]->GetMean()-hbackground_1D[i][nbin]->GetMean();
      VnError[i][nbin]=sqrt(hsignal_1D[i][nbin]->GetMeanError()*hsignal_1D[i][nbin]->GetMeanError()+hbackground_1D[i][nbin]->GetMeanError()*hbackground_1D[i][nbin]->GetMeanError());
      Vn0[i][nbin]=hsignal0_1D[i][nbin]->GetMean()-hbackground0_1D[i][nbin]->GetMean();
      Vn0Error[i][nbin]=sqrt(hsignal0_1D[i][nbin]->GetMeanError()*hsignal0_1D[i][nbin]->GetMeanError()+hbackground0_1D[i][nbin]->GetMeanError()*hbackground0_1D[i][nbin]->GetMeanError());
      Vn1[i][nbin]=hsignal1_1D[i][nbin]->GetMean()-hbackground1_1D[i][nbin]->GetMean();
      Vn1Error[i][nbin]=sqrt(hsignal1_1D[i][nbin]->GetMeanError()*hsignal1_1D[i][nbin]->GetMeanError()+hbackground1_1D[i][nbin]->GetMeanError()*hbackground1_1D[i][nbin]->GetMeanError());

if(jj==7 && nbin==1) cout<<"pos nbin="<<nbin<<" i="<<i<<" "<<hsignal0_1D[i][nbin]->GetMean()<<" "<<hbackground0_1D[i][nbin]->GetMean()<<" "<<Vn0[i][nbin]<<endl;
if(jj==7 && nbin==1) cout<<"neg nbin="<<nbin<<" i="<<i<<" "<<hsignal1_1D[i][nbin]->GetMean()<<" "<<hbackground1_1D[i][nbin]->GetMean()<<" "<<Vn1[i][nbin]<<endl;

      delete hsignal_1D[i][nbin];
      delete hsignal0_1D[i][nbin];
      delete hsignal1_1D[i][nbin];
      delete hbackground_1D[i][nbin];
      delete hbackground0_1D[i][nbin];
      delete hbackground1_1D[i][nbin];
    }
    delete hsignal0[i];
    delete hsignal1[i];
    delete hsignal[i];
    delete hbackground0[i];
    delete hbackground1[i];
    delete hbackground[i];
  }

  for(int nbin=1;nbin<4;nbin++)
  {
    for(int i=0;i<ntrgbins2;i++)
    {
      rn[ntrgbins2-i-1]=Vn[i][nbin]/Vn[ntrgbins1-i-1][nbin];
      rn_err[ntrgbins2-i-1]=sqrt((VnError[ntrgbins1-i-1][nbin]/Vn[ntrgbins1-i-1][nbin])**2+(VnError[i][nbin]/Vn[i][nbin])**2);
      rn0[ntrgbins2-i-1]=Vn0[i][nbin]/Vn0[ntrgbins1-i-1][nbin];
      rn0_err[ntrgbins2-i-1]=sqrt((Vn0Error[ntrgbins1-i-1][nbin]/Vn0[ntrgbins1-i-1][nbin])**2+(Vn0Error[i][nbin]/Vn0[i][nbin])**2);
      rn1[ntrgbins2-i-1]=Vn1[i][nbin]/Vn1[ntrgbins1-i-1][nbin];
      rn1_err[ntrgbins2-i-1]=sqrt((Vn1Error[ntrgbins1-i-1][nbin]/Vn1[ntrgbins1-i-1][nbin])**2+(Vn1Error[i][nbin]/Vn1[i][nbin])**2);
      rn_ratio[ntrgbins2-i-1] = rn0[ntrgbins2-i-1]/rn1[ntrgbins2-i-1];
      rn_ratio_err[ntrgbins2-i-1] = sqrt(rn0_err[ntrgbins2-i-1]*rn0_err[ntrgbins2-i-1]+rn1_err[ntrgbins2-i-1]*rn1_err[ntrgbins2-i-1]);
      rn_total[ntrgbins2-i-1] = sqrt(rn0[ntrgbins2-i-1]*rn1[ntrgbins2-i-1]);
      rn_total_err[ntrgbins2-i-1] = sqrt(rn0_err[ntrgbins2-i-1]*rn0_err[ntrgbins2-i-1]/rn0[ntrgbins2-i-1]/rn0[ntrgbins2-i-1]+rn1_err[ntrgbins2-i-1]*rn1_err[ntrgbins2-i-1]/rn1[ntrgbins2-i-1]/rn1[ntrgbins2-i-1])*0.5*rn_total[ntrgbins2-i-1];

if(jj==7 && nbin==1) cout<<"pos nbin="<<nbin<<" i="<<i<<" "<<Vn0[i][nbin]<<" "<<Vn0[ntrgbins1-i-1][nbin]<<" "<<rn0[ntrgbins2-i-1]<<endl;
if(jj==7 && nbin==1) cout<<"neg nbin="<<nbin<<" i="<<i<<" "<<Vn1[i][nbin]<<" "<<Vn1[ntrgbins1-i-1][nbin]<<" "<<rn1[ntrgbins2-i-1]<<endl;

    }

    gr[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn,eta_err,rn_err);
    gr[jj][nbin]->SetMarkerColor(color[nbin]);
    gr0[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn0,eta_err,rn0_err);
    gr0[jj][nbin]->SetMarkerColor(color[nbin]);
    gr1[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn1,eta_err,rn1_err);
    gr1[jj][nbin]->SetMarkerColor(color[nbin]);
    gr_ratio[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn_ratio,eta_err,rn_ratio_err);
    gr_ratio[jj][nbin]->SetMarkerColor(color[nbin]);
    gr_total[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn_total,eta_err,rn_total_err);
    gr_total[jj][nbin]->SetMarkerColor(color[nbin]);
/*
    gr[jj][nbin]->SetMarkerSize(gr[jj][1]->GetMarkerSize()*0.8);
    gr0[jj][nbin]->SetMarkerSize(gr0[jj][1]->GetMarkerSize()*0.8);
    gr1[jj][nbin]->SetMarkerSize(gr1[jj][1]->GetMarkerSize()*0.8);
    gr_ratio[jj][nbin]->SetMarkerSize(gr_ratio[jj][1]->GetMarkerSize()*0.8);
*/
//    fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"(1+[0]*(-x-4.5)*(-x-4.5))/(1+[0]*(x-4.5)*(x-4.5))",0,3.0);
//    fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"(1+[0]*(-x-4.5))/(1+[0]*(x-4.5))",0,3.0);
    if(jj<8) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"exp([0]*(-x-4.6))/exp([0]*(x-4.6))",0.0,2.5);
    else fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"exp([0]*(-x-3.5))/exp([0]*(x-3.5))",0.0,1.1);
    fit[jj][nbin]->SetParameter(0,0.01);
    gr[jj][nbin]->Fit(Form("fit_%d_%d",nbin,jj),"RNO");
    fit[jj][nbin]->SetLineColor(color[nbin]);
    fit[jj][nbin]->SetLineStyle(9);
    fit[jj][nbin]->SetLineWidth(1);
    if(jj<8)
    {    
      slope[nbin][jj] = fit[jj][nbin]->GetParameter(0);
      slope_err[nbin][jj] = fit[jj][nbin]->GetParError(0);
    }
    else
    {
      slope1[nbin][jj-8] = fit[jj][nbin]->GetParameter(0);
      slope1_err[nbin][jj-8] = fit[jj][nbin]->GetParError(0);
    }     

//    fit1_aver[jj][nbin] = new TF1(Form("fit1_aver_%d_%d",nbin,jj),"(1+[0]*(-x-4.5))/(1-4.5*[0])",0,4.5);
    fit1_aver[jj][nbin] = new TF1(Form("fit1_aver_%d_%d",nbin,jj),"exp(-[0]*x)",0,5);
    fit1_aver[jj][nbin]->SetParameter(0,fit[jj][nbin]->GetParameter(0));
    fit1_aver[jj][nbin]->SetParError(0,fit[jj][nbin]->GetParError(0));    
    fit1_aver[jj][nbin]->SetLineStyle(1);
    fit1_aver[jj][nbin]->SetLineColor(color[nbin]);
    gr1_band[jj][nbin] = new TGraph(53);
    for(int mm=0;mm<26;mm++) 
    {
      gr1_band[jj][nbin]->SetPoint(mm,0.2*mm,exp(-0.2*mm*(fit1_aver[jj][nbin]->GetParameter(0)+fit1_aver[jj][nbin]->GetParError(0))));
      gr1_band[jj][nbin]->SetPoint(51-mm,0.2*mm,exp(-0.2*mm*(fit1_aver[jj][nbin]->GetParameter(0)-fit1_aver[jj][nbin]->GetParError(0))));
    }
    gr1_band[jj][nbin]->SetPoint(52,0,1);
    gr1_band[jj][nbin]->SetFillColor(color[nbin]-10);
  }
}

  ofstream ff("r2r3_eta_mc.txt");

  double cent[8]={0.01,0.025,0.075,0.15,0.25,0.35,0.45,0.55};
  double cent_err[8]={0};
  TGraphErrors* gr_slope[6];
  TGraphErrors* gr1_slope[6];
  for(int nbin=1;nbin<4;nbin++) {
    gr_slope[nbin] = new TGraphErrors(8,cent,slope[nbin],cent_err,slope_err[nbin]);
    gr_slope[nbin]->SetName(Form("gr_slope_%d",nbin));
    cout<<"i="<<nbin+1<<endl;
    ff<<"i="<<nbin+1<<endl;
    for(int j=0;j<8;j++) { cout<<slope[nbin][j]<<" "; ff<<slope[nbin][j]<<", ";}
    cout<<endl;
    ff<<endl;
    for(int j=0;j<8;j++) { cout<<slope_err[nbin][j]<<" "; ff<<slope_err[nbin][j]<<", ";}
    cout<<endl;
    ff<<endl;
  }
  for(int nbin=1;nbin<4;nbin++) {
    gr1_slope[nbin] = new TGraphErrors(8,cent,slope1[nbin],cent_err,slope1_err[nbin]);
    gr1_slope[nbin]->SetName(Form("gr1_slope_%d",nbin));
  }

  ff.close();

  TString histtitle[8] = {"0-0.2%","0-5%","5-10%","10-20%","20-30%","30-40%","40-50%","50-60%"};
  TLine* ll = new TLine(0,1.,5.0,1.);
  TCanvas* c = new TCanvas("c","c",850,500);
  makeMultiPanelCanvas(c,3,2,0.01,0.0,0.2,0.2,0.02);
//  TH2D* htmp = new TH2D("htmp",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.1,2.5,100,0.905,1.019);
  TH2D* htmp = new TH2D("htmp",";#eta^{a};#sqrt{r_{2}(#eta^{a},#eta^{b}) #times r_{2}(-#eta^{a},-#eta^{b})}",100,-0.1,2.5,100,0.905-0.8,1.019+0.5);
  fixedFontHist(htmp,1.8,2.2);
  htmp->GetXaxis()->CenterTitle();
  htmp->GetYaxis()->CenterTitle();
  htmp->GetYaxis()->SetTitleSize(htmp->GetYaxis()->GetTitleSize()*1.2);
  htmp->GetXaxis()->SetTitleSize(htmp->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<6;jj++)
  {
    c->cd(jj+1);
    htmp->Draw();
    ll->Draw("Lsame");
/*
    gr_total[jj][1]->SetMarkerStyle(34);
    gr_total[jj][1]->SetMarkerColor(1);
    gr_total[jj][1]->Draw("Psame");

    gr[jj][1]->SetMarkerStyle(28);
    gr[jj][1]->SetMarkerColor(1);
    gr[jj][1]->Draw("Psame");
*/
    gr_total[jj+8][1]->SetMarkerStyle(21);
    gr_total[jj+8][1]->SetMarkerColor(4);
    gr_total[jj+8][1]->Draw("Psame");
  }

  TLatex* latex2 = new TLatex();
  latex2->SetNDC();
  latex2->SetTextSize(1.5*latex2->GetTextSize());
  c->cd(1);
  latex2->DrawLatex(0.26,0.05,"0-20%");
  latex2->DrawLatex(0.24,0.865,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  latex2->DrawLatex(0.6,0.1,"4.4 < #eta^{b} < 5");
  c->cd(2);
  latex2->DrawLatex(0.08,0.05,"20-40%");
  latex2->DrawLatex(0.07,0.3,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex2->DrawLatex(0.07,0.18,"p_{T}^{b} > 0 GeV/c");
  c->cd(3);
  latex2->DrawLatex(0.08,0.05,"40-60%");
  c->cd(6);
  latex2->SetTextSize(0.92*latex2->GetTextSize());
  latex2->DrawLatex(0.08,0.24,"40-60%");
  c->cd(5);
  latex2->SetTextSize(0.95*latex2->GetTextSize());
  latex2->DrawLatex(0.08,0.24,"20-40%");
  c->cd(4);
  latex2->SetTextSize(latex2->GetTextSize());
  latex2->DrawLatex(0.26,0.24,"0-20%");
  latex2->DrawLatex(0.6,0.3,"3 < #eta^{b} < 4");

  TLegend* legend2 = new TLegend(0.2,0.24,0.7,0.54);
  legend2->SetFillStyle(0);
  legend2->AddEntry(gr_total[16][1],"Data","P");
  legend2->AddEntry(gr_total[8][1],"Hydjet, gen-level","P");
  legend2->AddEntry(gr_total[0][1],"Hydjet, reco-level","P");
  c->cd(1);
  legend2->Draw("same");

//  SaveCanvas(c,"HI/FactBreak","epetadeco_HI_MCcompareTotal_r2");

return;
  TCanvas* ccaa = new TCanvas("ccaa","ccaa",900,500);
  makeMultiPanelCanvas(ccaa,4,2,0.01,0.0,0.2,0.2,0.02);
  for(int jj=0;jj<8;jj++)
  {
    ccaa->cd(jj+1);
    htmp->Draw();
    ll->Draw("Lsame");
    gr0[jj][1]->SetMarkerStyle(21);
    gr0[jj][1]->Draw("Psame");
    gr1[jj][1]->SetMarkerStyle(25);
    gr1[jj][1]->Draw("Psame");
  }

  TCanvas* ccbb = new TCanvas("ccbb","ccbb",900,500);
  makeMultiPanelCanvas(ccbb,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmpaa = new TH2D("htmpaa",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.1,2.23,100,0.97,1.03);
  for(int jj=0;jj<8;jj++)
  {
    ccbb->cd(jj+1);
    htmpaa->Draw();
    ll->Draw("Lsame");
    gr_ratio[jj][1]->SetMarkerStyle(21);
    gr_ratio[jj][1]->Draw("Psame");
  }

  TCanvas* cc = new TCanvas("cc","cc",900,500);
  makeMultiPanelCanvas(cc,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmp1 = new TH2D("htmp1",";#eta^{a};r_{3}(#eta^{a},#eta^{b})",100,-0.1,2.5,100,0.831,1.06);
  fixedFontHist(htmp1,1.8,2.2);
  htmp1->GetXaxis()->CenterTitle();
  htmp1->GetYaxis()->CenterTitle();
  htmp1->GetYaxis()->SetTitleSize(htmp1->GetYaxis()->GetTitleSize()*1.2);
  htmp1->GetXaxis()->SetTitleSize(htmp1->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<8;jj++)
  {
    cc->cd(jj+1);
    htmp1->Draw();
    ll->Draw("Lsame");
    gr[jj][2]->SetMarkerStyle(21);
    gr[jj][2]->Draw("Psame");
    fit[jj][2]->Draw("Lsame");

    gr[jj+8][2]->SetMarkerStyle(25);
//    fit[jj+8][2]->SetLineStyle(5);
    gr[jj+8][2]->Draw("Psame");
//    fit[jj+8][2]->Draw("Lsame");
  }

  TLatex* latex3 = new TLatex();
  latex3->SetNDC();
  latex3->SetTextSize(1.5*latex3->GetTextSize());
  cc->cd(1);
  latex3->DrawLatex(0.26,0.05,histtitle[0]);
  latex3->DrawLatex(0.24,0.865,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  cc->cd(2);
  latex3->DrawLatex(0.08,0.05,histtitle[1]);
  latex3->DrawLatex(0.07,0.28,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex3->DrawLatex(0.07,0.18,"p_{T}^{b} > 0 GeV/c");
  cc->cd(4);
  latex3->DrawLatex(0.08,0.05,histtitle[3]);
  cc->cd(3);
  latex3->DrawLatex(0.08,0.05,histtitle[2]);
  cc->cd(8);
  latex3->DrawLatex(0.08,0.24,histtitle[7]);
  cc->cd(7);
  latex3->DrawLatex(0.08,0.24,histtitle[6]);
  cc->cd(6);
  latex3->SetTextSize(0.96*latex3->GetTextSize());
  latex3->DrawLatex(0.08,0.24,histtitle[5]);
  cc->cd(5);
  latex3->SetTextSize(0.85*latex3->GetTextSize());
  latex3->DrawLatex(0.26,0.24,histtitle[4]);

  TLegend* legend3 = new TLegend(0.24,0.14,0.51,0.38);
  legend3->SetFillStyle(0);
  legend3->AddEntry(gr[0][1],"4.4<#eta^{b}<5","P");
  legend3->AddEntry(gr[8][1],"3<#eta^{b}<4","P");
  cc->cd(1);
  legend3->Draw("same");
/*
  TCanvas* ccc = new TCanvas("ccc","ccc",900,500);
  makeMultiPanelCanvas(ccc,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmp2 = new TH2D("htmp2",";#eta^{a};r_{4}(#eta^{a},#eta^{b})",100,-0.1,2.23,100,0.801,1.06);
  fixedFontHist(htmp2,1.8,2.2);
  htmp2->GetXaxis()->CenterTitle();
  htmp2->GetYaxis()->CenterTitle();
  htmp2->GetYaxis()->SetTitleSize(htmp2->GetYaxis()->GetTitleSize()*1.2);
  htmp2->GetXaxis()->SetTitleSize(htmp2->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<8;jj++)
  {
    ccc->cd(jj+1);
    htmp2->Draw();
    ll->Draw("Lsame");
    gr[jj][3]->Draw("Psame");
    fit[jj][3]->Draw("Lsame");

    gr[jj+8][3]->Set_arkerStyle(25);
    fit[jj+8][3]->SetLineStyle(5);
    gr[jj+8][3]->Draw("Psame");
    fit[jj+8][3]->Draw("Lsame");
  }
*/
  TCanvas* c1 = new TCanvas("c1","c1",500,500);
  TH2D* htmp2 = new TH2D("htmp2",";Centrality;C",100,0,1.0,100,0.0,0.06);
  htmp2->Draw();
  htmp2->GetXaxis()->CenterTitle();
  htmp2->GetYaxis()->CenterTitle();
  gr_slope[1]->SetMarkerColor(1);
  gr_slope[2]->SetMarkerColor(1);
  gr_slope[1]->SetMarkerStyle(21);
  gr_slope[2]->SetMarkerStyle(22);
  gr_slope[1]->Draw("PESAME");
  gr_slope[2]->Draw("PESAME");
  gr1_slope[1]->SetMarkerColor(1);
  gr1_slope[2]->SetMarkerColor(1);
  gr1_slope[1]->SetMarkerStyle(25);
  gr1_slope[2]->SetMarkerStyle(26);
  gr1_slope[1]->Draw("PESAME");
  gr1_slope[2]->Draw("PESAME");
return;
  TFile* f_slope_out = new TFile("gr_slope_v2v3.root","recreate");
  gr_slope[1]->Write();
  gr_slope[2]->Write();
  gr1_slope[1]->Write();
  gr1_slope[2]->Write();
  f_slope_out->Close();
return;
  SaveCanvas(c,"HI/FactBreak","epetadeco_HI_r2");
  SaveCanvas(cc,"HI/FactBreak","epetadeco_HI_r3");
  SaveCanvas(ccaa,"HI/FactBreak","epetadeco_HI_r2ratio");
//  SaveCanvas(c1,"HI/FactBreak","epetadeco_HI_C");
//  SaveCanvas(cc2,"HI/FactBreak","epetadeco_HI_cos");
}
コード例 #29
0
void diaphragm_spectrum()
{
    gROOT->Reset();
    TFile * tfin = new TFile("data/kaon_mcraytracing.root");
    TH2D * hphotons;
    tfin->GetObject( "CedarMCTester/Photons/RayTracing/Diaphragm", hphotons );

    TCanvas c("c","c", 600, 600 );
    c.cd();
    gStyle->SetOptStat(0);
    gStyle->SetGridColor( kGray);
    c.SetRightMargin(0.15);
    c.SetLeftMargin(0.12);
    c.SetGrid();

    plot_diaphragm_spectrum( hphotons);

    c.Print("output/diaphragm_photons.pdf", "pdf" );

    TH2D * hphotoelectrons;
    tfin->GetObject( "CedarMCTester/Photoelectrons/RayTracing/Diaphragm", hphotoelectrons );
    plot_diaphragm_spectrum( hphotoelectrons);

    c.Print("output/diaphragm_photoelectrons.pdf", "pdf" );

    TCanvas * c2 = new TCanvas( "c2", "c2", 900, 300 );
    c2->cd();
    TFile * tfinpion = new TFile("data/pion_mcraytracing.root");
    TH2D * hpepion;
    tfinpion->GetObject( "CedarMCTester/Photoelectrons/RayTracing/Diaphragm", hpepion );

    gROOT->GetColor( kRed+2)->SetAlpha(0.02);
    hphotoelectrons->SetMarkerColor( kRed+2 );
    hphotoelectrons->Draw();
    hphotoelectrons->GetXaxis()->SetRangeUser(98, 104 );
    gROOT->GetColor( kBlue+2)->SetAlpha(0.02);
    hpepion->SetMarkerColor( kBlue+2 );
    hpepion->Draw("same");


    c2->SetGrid();
    c2->Print("output/diaphragm_pionvskaon.pdf", "pdf" );

    TImage * img = TImage::Create();
    img->FromPad(c2);
    img->WriteImage( "output/diaphragm_pionvskaon.png" );

    TH1D * hkaon = hphotoelectrons->ProjectionX( "hkaon", 0, -1 );
    TH1D * hpion = hpepion->ProjectionX( "hpion", 0, -1 );

    TCanvas * c3 = new TCanvas( "c2", "c2", 900, 500 );
    c3->cd();
    gROOT->GetColor( kRed+2)->SetAlpha(1);
    gROOT->GetColor( kBlue+2)->SetAlpha(1);
    hkaon->SetLineColor( kRed+2);
    hkaon->Scale(1.0/11.0);
    hpion->SetLineColor( kBlue+2);
    hpion->GetXaxis()->SetRangeUser(98,104);
    hpion->SetBit( TH1::kNoTitle, true );
    hpion->Draw();
    hkaon->SetBit( TH1::kNoTitle, true );
    hkaon->Draw("same");
    c3->SetGrid();
    c3->Print("output/diaphragm_pkcomp.pdf", "pdf" );
}
コード例 #30
0
void Factorization_eta_v2v3_paper()
{
  const int nfiles = 24;
  TString filename[nfiles];

  filename[0] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[1] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[2] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[3] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[4] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[5] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[6] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg033_ptassallweight_etaass445_eff1_v42.root");
  filename[7] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg033_ptassallweight_etaass445_eff1_v42.root");
/*
  filename[0] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
  filename[1] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
  filename[2] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
  filename[3] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
  filename[4] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
  filename[5] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
  filename[6] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
  filename[7] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg053_ptassallweight_etaass445_eff0_general_v45.root");
*/
  filename[8] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[9] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[10] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[11] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[12] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[13] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[14] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg033_ptassallweight_etaass34_eff1_v42.root");
  filename[15] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg033_ptassallweight_etaass34_eff1_v42.root");

  filename[16] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent002_pttrg033_ptassallweight_etaass45_eff1_v42.root");
  filename[17] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent05_pttrg033_ptassallweight_etaass45_eff1_v42.root");
  filename[18] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent510_pttrg033_ptassallweight_etaass45_eff1_v42.root");
  filename[19] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent1020_pttrg033_ptassallweight_etaass45_eff1_v42.root");
  filename[20] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent2030_pttrg033_ptassallweight_etaass45_eff1_v42.root");
  filename[21] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent3040_pttrg033_ptassallweight_etaass45_eff1_v42.root");
  filename[22] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent4050_pttrg033_ptassallweight_etaass45_eff1_v42.root");
  filename[23] = Form("/net/hisrv0001/home/davidlw/scratch1/DiHadronCorrelations/outputs_312/HIData_Minbias_2760GeV/merged/epetadeco_cent5060_pttrg033_ptassallweight_etaass45_eff1_v42.root");

  const int ntrgbins = 16;
  const int ntrgbins1 = ntrgbins;
  const int ntrgbins2 = ntrgbins/2;
  TGraphErrors* gr[nfiles][6];
  TGraphErrors* gr0[nfiles][6];
  TGraphErrors* gr1[nfiles][6];
  TGraphErrors* gr_ratio[nfiles][6];
  TGraph* gr_band[nfiles][6];
  TGraph* gr1_band[nfiles][6];
  TF1* fit[nfiles][6];
  TF1* fit_aver[nfiles][6];
  TF1* fit1_aver[nfiles][6];
  double slope[6][nfiles];
  double slope_err[6][nfiles];
  double slope1[6][nfiles];
  double slope1_err[6][nfiles];
//  double eta[ntrgbins2] = {0.12,0.36,0.6,0.84,1.08,1.32,1.56,1.8,2.04,2.28};
//  double eta[ntrgbins2] = {0.1,0.3,0.5,0.7,0.9,1.1,1.3,1.5,1.7,1.9,2.1,2.3};  
  double eta[ntrgbins2] = {0.15,0.45,0.75,1.05,1.35,1.65,1.95,2.25};
//  double eta[ntrgbins2] = {0.2,0.6,1.0,1.4,1.8,2.2};
  double eta_err[ntrgbins2] = {0.0};
  Color_t color[6] = {1,kBlue, kBlue, kBlue,1,1};

  TFile* fdiff[nfiles];
for(int jj=0;jj<nfiles;jj++)
{
  fdiff[jj] = new TFile(filename[jj].Data());

  TH2D* hsignal[ntrgbins];
  TH2D* hbackground[ntrgbins];
  TH2D* hsignal0[ntrgbins];
  TH2D* hbackground0[ntrgbins];
  TH2D* hsignal1[ntrgbins];
  TH2D* hbackground1[ntrgbins];
  TH1D* hsignal_1D[ntrgbins][6];
  TH1D* hbackground_1D[ntrgbins][6]; 
  TH1D* hsignal0_1D[ntrgbins][6];
  TH1D* hbackground0_1D[ntrgbins][6];
  TH1D* hsignal1_1D[ntrgbins][6];
  TH1D* hbackground1_1D[ntrgbins][6];

  double Vn[ntrgbins1][6];
  double VnError[ntrgbins1][6];
  double rn[ntrgbins2];
  double rn_err[ntrgbins2];
  double Vn0[ntrgbins1][6];
  double Vn0Error[ntrgbins1][6];
  double rn0[ntrgbins2];
  double rn0_err[ntrgbins2];
  double Vn1[ntrgbins1][6];
  double Vn1Error[ntrgbins1][6];
  double rn1[ntrgbins2];
  double rn1_err[ntrgbins2];
  double rn_ratio[ntrgbins2];
  double rn_ratio_err[ntrgbins2];

  for(int i=0;i<ntrgbins;i++)
  {
    hsignal0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfp/signalcosn_trg%d",i));
    hbackground0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfp/backgroundcosn_trg%d",i));
    hsignal1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfm/signalcosn_trg%d",i));
    hbackground1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_HI_hfm/backgroundcosn_trg%d",i));
/*
    if(jj==6 || jj==7)
    {
      hsignal0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfp/signalcosn_trg%d",i));
      hbackground0[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfp/backgroundcosn_trg%d",i));
      hsignal1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfm/signalcosn_trg%d",i));
      hbackground1[i] = (TH2D*)fdiff[jj]->Get(Form("epetadeco_ana_pPb_hfm/backgroundcosn_trg%d",i));
    }
*/
    hsignal[i] = (TH2D*)hsignal0[i]->Clone(Form("signalcosn_trg%d",i));
    hbackground[i] = (TH2D*)hbackground0[i]->Clone(Form("backgroundcosn_trg%d",i));
    hsignal[i]->Add(hsignal1[i]);
    hbackground[i]->Add(hbackground1[i]);

    for(int nbin=1;nbin<4;nbin++)
    {
      hsignal_1D[i][nbin] = (TH1D*)hsignal[i]->ProjectionX(Form("signal_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hsignal0_1D[i][nbin] = (TH1D*)hsignal0[i]->ProjectionX(Form("signal0_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hsignal1_1D[i][nbin] = (TH1D*)hsignal1[i]->ProjectionX(Form("signal1_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground_1D[i][nbin] = (TH1D*)hbackground[i]->ProjectionX(Form("background_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground0_1D[i][nbin] = (TH1D*)hbackground0[i]->ProjectionX(Form("background0_1D_trg%d_%d",i,nbin),nbin,nbin,"e");
      hbackground1_1D[i][nbin] = (TH1D*)hbackground1[i]->ProjectionX(Form("background1_1D_trg%d_%d",i,nbin),nbin,nbin,"e");

      Vn[i][nbin]=hsignal_1D[i][nbin]->GetMean()-hbackground_1D[i][nbin]->GetMean();
      VnError[i][nbin]=sqrt(hsignal_1D[i][nbin]->GetMeanError()*hsignal_1D[i][nbin]->GetMeanError()+hbackground_1D[i][nbin]->GetMeanError()*hbackground_1D[i][nbin]->GetMeanError());
      Vn0[i][nbin]=hsignal0_1D[i][nbin]->GetMean()-hbackground0_1D[i][nbin]->GetMean();
      Vn0Error[i][nbin]=sqrt(hsignal0_1D[i][nbin]->GetMeanError()*hsignal0_1D[i][nbin]->GetMeanError()+hbackground0_1D[i][nbin]->GetMeanError()*hbackground0_1D[i][nbin]->GetMeanError());
      Vn1[i][nbin]=hsignal1_1D[i][nbin]->GetMean()-hbackground1_1D[i][nbin]->GetMean();
      Vn1Error[i][nbin]=sqrt(hsignal1_1D[i][nbin]->GetMeanError()*hsignal1_1D[i][nbin]->GetMeanError()+hbackground1_1D[i][nbin]->GetMeanError()*hbackground1_1D[i][nbin]->GetMeanError());

if(jj==7 && nbin==1) cout<<"pos nbin="<<nbin<<" i="<<i<<" "<<hsignal0_1D[i][nbin]->GetMean()<<" "<<hbackground0_1D[i][nbin]->GetMean()<<" "<<Vn0[i][nbin]<<endl;
if(jj==7 && nbin==1) cout<<"neg nbin="<<nbin<<" i="<<i<<" "<<hsignal1_1D[i][nbin]->GetMean()<<" "<<hbackground1_1D[i][nbin]->GetMean()<<" "<<Vn1[i][nbin]<<endl;

      delete hsignal_1D[i][nbin];
      delete hsignal0_1D[i][nbin];
      delete hsignal1_1D[i][nbin];
      delete hbackground_1D[i][nbin];
      delete hbackground0_1D[i][nbin];
      delete hbackground1_1D[i][nbin];
    }
    delete hsignal0[i];
    delete hsignal1[i];
    delete hsignal[i];
    delete hbackground0[i];
    delete hbackground1[i];
    delete hbackground[i];
  }

  for(int nbin=1;nbin<4;nbin++)
  {
    for(int i=0;i<ntrgbins2;i++)
    {
      rn[ntrgbins2-i-1]=Vn[i][nbin]/Vn[ntrgbins1-i-1][nbin];
      rn_err[ntrgbins2-i-1]=sqrt((VnError[ntrgbins1-i-1][nbin]/Vn[ntrgbins1-i-1][nbin])**2+(VnError[i][nbin]/Vn[i][nbin])**2);
      rn0[ntrgbins2-i-1]=Vn0[i][nbin]/Vn0[ntrgbins1-i-1][nbin];
      rn0_err[ntrgbins2-i-1]=sqrt((Vn0Error[ntrgbins1-i-1][nbin]/Vn0[ntrgbins1-i-1][nbin])**2+(Vn0Error[i][nbin]/Vn0[i][nbin])**2);
      rn1[ntrgbins2-i-1]=Vn1[i][nbin]/Vn1[ntrgbins1-i-1][nbin];
      rn1_err[ntrgbins2-i-1]=sqrt((Vn1Error[ntrgbins1-i-1][nbin]/Vn1[ntrgbins1-i-1][nbin])**2+(Vn1Error[i][nbin]/Vn1[i][nbin])**2);
      rn_ratio[ntrgbins2-i-1] = rn0[ntrgbins2-i-1]/rn1[ntrgbins2-i-1];
      rn_ratio_err[ntrgbins2-i-1] = sqrt(rn0_err[ntrgbins2-i-1]*rn0_err[ntrgbins2-i-1]+rn1_err[ntrgbins2-i-1]*rn1_err[ntrgbins2-i-1]);

if(jj==7 && nbin==1) cout<<"pos nbin="<<nbin<<" i="<<i<<" "<<Vn0[i][nbin]<<" "<<Vn0[ntrgbins1-i-1][nbin]<<" "<<rn0[ntrgbins2-i-1]<<endl;
if(jj==7 && nbin==1) cout<<"neg nbin="<<nbin<<" i="<<i<<" "<<Vn1[i][nbin]<<" "<<Vn1[ntrgbins1-i-1][nbin]<<" "<<rn1[ntrgbins2-i-1]<<endl;

    }

    gr[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn,eta_err,rn_err);
    gr[jj][nbin]->SetMarkerColor(color[nbin]);
    gr0[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn0,eta_err,rn0_err);
    gr0[jj][nbin]->SetMarkerColor(color[nbin]);
    gr1[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn1,eta_err,rn1_err);
    gr1[jj][nbin]->SetMarkerColor(color[nbin]);
    gr_ratio[jj][nbin] = new TGraphErrors(ntrgbins2,eta,rn_ratio,eta_err,rn_ratio_err);
    gr_ratio[jj][nbin]->SetMarkerColor(color[nbin]);
/*
    gr[jj][nbin]->SetMarkerSize(gr[jj][1]->GetMarkerSize()*0.8);
    gr0[jj][nbin]->SetMarkerSize(gr0[jj][1]->GetMarkerSize()*0.8);
    gr1[jj][nbin]->SetMarkerSize(gr1[jj][1]->GetMarkerSize()*0.8);
    gr_ratio[jj][nbin]->SetMarkerSize(gr_ratio[jj][1]->GetMarkerSize()*0.8);
*/
//    fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"(1+[0]*(-x-4.5)*(-x-4.5))/(1+[0]*(x-4.5)*(x-4.5))",0,3.0);
//    fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"(1+[0]*(-x-4.5))/(1+[0]*(x-4.5))",0,3.0);
    if(jj<8) fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"exp([0]*(-x-4.6))/exp([0]*(x-4.6))",0.0,2.4);
    else fit[jj][nbin] = new TF1(Form("fit_%d_%d",nbin,jj),"exp([0]*(-x-3.5))/exp([0]*(x-3.5))",0.0,1.1);
    fit[jj][nbin]->SetParameter(0,0.01);
    gr[jj][nbin]->Fit(Form("fit_%d_%d",nbin,jj),"RNO");
    fit[jj][nbin]->SetLineColor(color[nbin]);
    fit[jj][nbin]->SetLineStyle(7);
    fit[jj][nbin]->SetLineWidth(1);
    if(jj<8)
    {    
      slope[nbin][jj] = fit[jj][nbin]->GetParameter(0);
      slope_err[nbin][jj] = fit[jj][nbin]->GetParError(0);
    }
    else
    {
      slope1[nbin][jj-8] = fit[jj][nbin]->GetParameter(0);
      slope1_err[nbin][jj-8] = fit[jj][nbin]->GetParError(0);
    }     

//    fit1_aver[jj][nbin] = new TF1(Form("fit1_aver_%d_%d",nbin,jj),"(1+[0]*(-x-4.5))/(1-4.5*[0])",0,4.5);
    fit1_aver[jj][nbin] = new TF1(Form("fit1_aver_%d_%d",nbin,jj),"exp(-[0]*x)",0,5);
    fit1_aver[jj][nbin]->SetParameter(0,fit[jj][nbin]->GetParameter(0));
    fit1_aver[jj][nbin]->SetParError(0,fit[jj][nbin]->GetParError(0));    
    fit1_aver[jj][nbin]->SetLineStyle(1);
    fit1_aver[jj][nbin]->SetLineColor(color[nbin]);
    gr1_band[jj][nbin] = new TGraph(53);
    for(int mm=0;mm<26;mm++) 
    {
      gr1_band[jj][nbin]->SetPoint(mm,0.2*mm,exp(-0.2*mm*(fit1_aver[jj][nbin]->GetParameter(0)+fit1_aver[jj][nbin]->GetParError(0))));
      gr1_band[jj][nbin]->SetPoint(51-mm,0.2*mm,exp(-0.2*mm*(fit1_aver[jj][nbin]->GetParameter(0)-fit1_aver[jj][nbin]->GetParError(0))));
    }
    gr1_band[jj][nbin]->SetPoint(52,0,1);
    gr1_band[jj][nbin]->SetFillColor(color[nbin]-10);
  }
}

  ofstream ff("r2r3_eta.txt");

  double cent[8]={0.01,0.025,0.075,0.15,0.25,0.35,0.45,0.55};
  double cent_err[8]={0};
  TGraphErrors* gr_slope[6];
  TGraphErrors* gr1_slope[6];
  for(int nbin=1;nbin<4;nbin++) {
    gr_slope[nbin] = new TGraphErrors(8,cent,slope[nbin],cent_err,slope_err[nbin]);
    gr_slope[nbin]->SetName(Form("gr_slope_%d",nbin));
    cout<<"i="<<nbin+1<<endl;
    ff<<"i="<<nbin+1<<endl;
    for(int j=0;j<8;j++) { cout<<slope[nbin][j]<<" "; ff<<slope[nbin][j]<<", ";}
    cout<<endl;
    ff<<endl;
    for(int j=0;j<8;j++) { cout<<slope_err[nbin][j]<<" "; ff<<slope_err[nbin][j]<<", ";}
    cout<<endl;
    ff<<endl;
  }
  for(int nbin=1;nbin<4;nbin++) {
    gr1_slope[nbin] = new TGraphErrors(8,cent,slope1[nbin],cent_err,slope1_err[nbin]);
    gr1_slope[nbin]->SetName(Form("gr1_slope_%d",nbin));
  }

  ff.close();

  TString histtitle[8] = {"0-0.2% centrality","0-5%","5-10%","10-20%","20-30%","30-40%","40-50%","50-60%"};
  TLine* ll = new TLine(-0.12,1.,2.49,1.);
  TCanvas* c = new TCanvas("c","c",920,500);
  makeMultiPanelCanvas(c,4,2,0.01,0.0,0.25,0.2,0.02);
  TH2D* htmp = new TH2D("htmp",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.12,2.49,100,0.831-0.02,1.06-0.02);
  fixedFontHist(htmp,1.8,2.8);
  htmp->GetXaxis()->CenterTitle();
  htmp->GetYaxis()->CenterTitle();
  htmp->GetYaxis()->SetTitleSize(htmp->GetYaxis()->GetTitleSize()*1.2);
  htmp->GetXaxis()->SetTitleSize(htmp->GetXaxis()->GetTitleSize()*1.);
  htmp->GetXaxis()->SetLabelSize(htmp->GetXaxis()->GetLabelSize()*0.95);
  htmp->GetXaxis()->SetNdivisions(510);

  for(int jj=0;jj<8;jj++)
  {
    c->cd(jj+1);
    htmp->Draw();
    ll->Draw("Lsame");
    gr[jj][1]->SetMarkerStyle(21);
    gr[jj][1]->Draw("Psame");
    fit[jj][1]->Draw("Lsame");
    cout<<fit[jj][1]->GetChisquare()/fit[jj][1]->GetNDF()<<endl;

    gr[jj+8][1]->SetMarkerStyle(25);
//    fit[jj+8][1]->SetLineStyle(5);
    gr[jj+8][1]->Draw("Psame");
//    fit[jj+8][1]->Draw("Lsame");
/*
    gr[jj+16][1]->SetMarkerStyle(28);
    gr[jj+16][1]->SetMarkerColor(1);
    gr[jj+16][1]->Draw("Psame");
*/
  }

  TLatex* latex2 = new TLatex();
  latex2->SetNDC();
  latex2->SetTextSize(1.5*latex2->GetTextSize());
  c->cd(1);
  latex2->DrawLatex(0.31,0.05,histtitle[0]);
  latex2->DrawLatex(0.29,0.865,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  c->cd(2);
  latex2->DrawLatex(0.08,0.05,histtitle[1]);
  latex2->SetTextSize(0.98*latex2->GetTextSize());
  latex2->DrawLatex(0.1,0.285,"0.3 < p_{T}^{a} < 3.0 GeV/c");
  latex2->DrawLatex(0.1,0.18,"p_{T}^{b} > 0 GeV/c");
  latex2->SetTextSize(latex2->GetTextSize()/0.98);
  c->cd(4);
  latex2->DrawLatex(0.08,0.05,histtitle[3]);
  c->cd(3);
  latex2->DrawLatex(0.08,0.05,histtitle[2]);
  c->cd(8);
  latex2->DrawLatex(0.08,0.24,histtitle[7]);
  c->cd(7);
  latex2->DrawLatex(0.08,0.24,histtitle[6]);
  c->cd(6);
  latex2->SetTextSize(0.96*latex2->GetTextSize());
  latex2->DrawLatex(0.08,0.24,histtitle[5]);
  c->cd(5);
  latex2->SetTextSize(0.85*latex2->GetTextSize());
  latex2->DrawLatex(0.31,0.24,histtitle[4]);

  TLegend* legend2 = new TLegend(0.26,0.16,0.78,0.46);
  legend2->SetFillStyle(0);
  legend2->AddEntry(gr[0][1],"4.4 < #eta^{b} < 5.0","P");
  legend2->AddEntry(gr[8][1],"3.0 < #eta^{b} < 4.0","P");
  legend2->AddEntry(fit[0][1],"Exponential fits","L");
  c->cd(1);
  legend2->Draw("same");

  TCanvas* ccaa = new TCanvas("ccaa","ccaa",900,500);
  makeMultiPanelCanvas(ccaa,4,2,0.01,0.0,0.2,0.2,0.02);
  for(int jj=0;jj<8;jj++)
  {
    ccaa->cd(jj+1);
    htmp->Draw();
    ll->Draw("Lsame");
    gr0[jj][1]->SetMarkerStyle(21);
    gr0[jj][1]->Draw("Psame");
    gr1[jj][1]->SetMarkerStyle(25);
    gr1[jj][1]->Draw("Psame");
  }

  TCanvas* ccbb = new TCanvas("ccbb","ccbb",900,500);
  makeMultiPanelCanvas(ccbb,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmpaa = new TH2D("htmpaa",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.1,2.5,100,0.97,1.03);
  for(int jj=0;jj<8;jj++)
  {
    ccbb->cd(jj+1);
    htmpaa->Draw();
    ll->Draw("Lsame");
    gr_ratio[jj][1]->SetMarkerStyle(21);
    gr_ratio[jj][1]->Draw("Psame");
  }

  TCanvas* cc = new TCanvas("cc","cc",920,500);
  makeMultiPanelCanvas(cc,4,2,0.01,0.0,0.25,0.2,0.02);
  TH2D* htmp1 = new TH2D("htmp1",";#eta^{a};r_{3}(#eta^{a},#eta^{b})",100,-0.12,2.49,100,0.831-0.02,1.06-0.02);
  fixedFontHist(htmp1,1.8,2.8);
  htmp1->GetXaxis()->CenterTitle();
  htmp1->GetYaxis()->CenterTitle();
  htmp1->GetYaxis()->SetTitleSize(htmp1->GetYaxis()->GetTitleSize()*1.2);
  htmp1->GetXaxis()->SetTitleSize(htmp1->GetXaxis()->GetTitleSize()*1.);
  htmp1->GetXaxis()->SetLabelSize(htmp1->GetXaxis()->GetLabelSize()*0.95);
  htmp1->GetXaxis()->SetNdivisions(510);

  for(int jj=0;jj<8;jj++)
  {
    cc->cd(jj+1);
    htmp1->Draw();
    ll->Draw("Lsame");
    gr[jj][2]->SetMarkerStyle(21);
    gr[jj][2]->Draw("Psame");
    fit[jj][2]->Draw("Lsame");
    cout<<fit[jj][2]->GetChisquare()/fit[jj][2]->GetNDF()<<endl;

    gr[jj+8][2]->SetMarkerStyle(25);
//    fit[jj+8][2]->SetLineStyle(5);
    gr[jj+8][2]->Draw("Psame");
//    fit[jj+8][2]->Draw("Lsame");
/*
    gr[jj+16][2]->SetMarkerStyle(28);
    gr[jj+16][2]->SetMarkerColor(1);
    gr[jj+16][2]->Draw("Psame");
    fit[jj+16][2]->Draw("Lsame");
*/
  }

  TLatex* latex3 = new TLatex();
  latex3->SetNDC();
  latex3->SetTextSize(1.5*latex3->GetTextSize());
  cc->cd(1);
  latex3->DrawLatex(0.31,0.05,histtitle[0]);
  latex3->DrawLatex(0.29,0.865,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  cc->cd(2);
  latex3->DrawLatex(0.08,0.05,histtitle[1]);
  latex3->SetTextSize(0.98*latex3->GetTextSize());
  latex3->DrawLatex(0.1,0.285,"0.3 < p_{T}^{a} < 3.0 GeV/c");
  latex3->DrawLatex(0.1,0.18,"p_{T}^{b} > 0 GeV/c");
  latex3->SetTextSize(latex3->GetTextSize()/0.98);
  cc->cd(4);
  latex3->DrawLatex(0.08,0.05,histtitle[3]);
  cc->cd(3);
  latex3->DrawLatex(0.08,0.05,histtitle[2]);
  cc->cd(8);
  latex3->DrawLatex(0.08,0.24,histtitle[7]);
  cc->cd(7);
  latex3->DrawLatex(0.08,0.24,histtitle[6]);
  cc->cd(6);
  latex3->SetTextSize(0.96*latex3->GetTextSize());
  latex3->DrawLatex(0.08,0.24,histtitle[5]);
  cc->cd(5);
  latex3->SetTextSize(0.85*latex3->GetTextSize());
  latex3->DrawLatex(0.31,0.24,histtitle[4]);

  TLegend* legend3 = new TLegend(0.26,0.16,0.78,0.46);
  legend3->SetFillStyle(0);
  legend3->AddEntry(gr[0][1],"4.4 < #eta^{b} < 5.0","P");
//  legend3->AddEntry(gr[16][1],"4<#eta^{b}<5","P");
  legend3->AddEntry(gr[8][1],"3.0 < #eta^{b} < 4.0","P");
  legend3->AddEntry(fit[0][1],"Exponential fits","L");
  cc->cd(1);
  legend3->Draw("same");
/*
  TCanvas* ccc = new TCanvas("ccc","ccc",900,500);
  makeMultiPanelCanvas(ccc,4,2,0.01,0.0,0.2,0.2,0.02);
  TH2D* htmp2 = new TH2D("htmp2",";#eta^{a};r_{4}(#eta^{a},#eta^{b})",100,-0.1,2.23,100,0.801,1.06);
  fixedFontHist(htmp2,1.8,2.2);
  htmp2->GetXaxis()->CenterTitle();
  htmp2->GetYaxis()->CenterTitle();
  htmp2->GetYaxis()->SetTitleSize(htmp2->GetYaxis()->GetTitleSize()*1.2);
  htmp2->GetXaxis()->SetTitleSize(htmp2->GetXaxis()->GetTitleSize()*1.);
  for(int jj=0;jj<8;jj++)
  {
    ccc->cd(jj+1);
    htmp2->Draw();
    ll->Draw("Lsame");
    gr[jj][3]->Draw("Psame");
    fit[jj][3]->Draw("Lsame");

    gr[jj+8][3]->Set_arkerStyle(25);
    fit[jj+8][3]->SetLineStyle(5);
    gr[jj+8][3]->Draw("Psame");
    fit[jj+8][3]->Draw("Lsame");
  }
*/
  SaveCanvas(c,"HI/FactBreak","epetadeco_HI_r2");
  SaveCanvas(cc,"HI/FactBreak","epetadeco_HI_r3");
return;
  TCanvas* c1 = new TCanvas("c1","c1",500,500);
  TH2D* htmp2 = new TH2D("htmp2",";Centrality;C",100,0,1.0,100,0.0,0.06);
  htmp2->Draw();
  htmp2->GetXaxis()->CenterTitle();
  htmp2->GetYaxis()->CenterTitle();
  gr_slope[1]->SetMarkerColor(1);
  gr_slope[2]->SetMarkerColor(1);
  gr_slope[1]->SetMarkerStyle(21);
  gr_slope[2]->SetMarkerStyle(22);
  gr_slope[1]->Draw("PESAME");
  gr_slope[2]->Draw("PESAME");
  gr1_slope[1]->SetMarkerColor(1);
  gr1_slope[2]->SetMarkerColor(1);
  gr1_slope[1]->SetMarkerStyle(25);
  gr1_slope[2]->SetMarkerStyle(26);
  gr1_slope[1]->Draw("PESAME");
  gr1_slope[2]->Draw("PESAME");

  TFile* f_slope_out = new TFile("gr_slope_v2v3.root","recreate");
  gr_slope[1]->Write();
  gr_slope[2]->Write();
  gr1_slope[1]->Write();
  gr1_slope[2]->Write();
  f_slope_out->Close();

  double c2th_05[4] = {1,0.961347696746,0.880663601763,0.754486161464};
  double c2th_05_err[4] = {0,0.000356333410703,0.000338330912667,0.000274987058522};
  double c2th_510[4] = {1,0.972713667246,0.915076778092,0.833525975859};
  double c2th_510_err[4] = {0,0.000405999641418,0.000387338629763,0.000306789774481};
  double c2th_2025[4] = {1,0.984223594381,0.952359517332,0.902163004038};
  double c2th_2025_err[4] = {0,0.00034410202865,0.000327502849547,0.000264412975357};

  double c3th_05[4] = {1,0.969266017011,0.906673110779,0.811457263278};
  double c3th_05_err[4] = {0,0.000169783126377,0.000162733412441,0.000127976935994};
  double c3th_510[4] = {1,0.967235903665,0.902375220756,0.794138304113};
  double c3th_510_err[4] = {0,0.000140808705408,0.000136143144565,0.000110350606241};
  double c3th_2025[4] = {1,0.969550353187,0.904351369862,0.80580447205};
  double c3th_2025_err[4] = {0,9.57789409787e-05,9.14453396096e-05,7.07914090744e-05};

  double etath[4] = {0,0.5,1,2};
  double etath_err[4] = {0};

  TGraphErrors* gr_c2th_05 = new TGraphErrors(4,etath,c2th_05,etath_err,c2th_05_err);
  TGraphErrors* gr_c2th_510 = new TGraphErrors(4,etath,c2th_510,etath_err,c2th_510_err);
  TGraphErrors* gr_c2th_2025 = new TGraphErrors(4,etath,c2th_2025,etath_err,c2th_2025_err);
  TGraphErrors* gr_c3th_05 = new TGraphErrors(4,etath,c3th_05,etath_err,c3th_05_err);
  TGraphErrors* gr_c3th_510 = new TGraphErrors(4,etath,c3th_510,etath_err,c3th_510_err);
  TGraphErrors* gr_c3th_2025 = new TGraphErrors(4,etath,c3th_2025,etath_err,c3th_2025_err);
  gr_c2th_05->SetMarkerStyle(31);
  gr_c2th_510->SetMarkerStyle(31);
  gr_c2th_2025->SetMarkerStyle(31);
  gr_c3th_05->SetMarkerStyle(31);
  gr_c3th_510->SetMarkerStyle(31);
  gr_c3th_2025->SetMarkerStyle(31);

  TCanvas* cth = new TCanvas("cth","",900,330);
  makeMultiPanelCanvas(cth,3,1,0.01,0.0,0.2,0.17,0.02);
  TH2D* htmp8 = new TH2D("htmp8",";#eta^{a};r_{2}(#eta^{a},#eta^{b})",100,-0.1,2.5,100,0.67,1.06);
  fixedFontHist(htmp8,0.9,1.3);
  htmp8->GetXaxis()->CenterTitle();
  htmp8->GetYaxis()->CenterTitle();
  htmp8->GetYaxis()->SetTitleSize(htmp8->GetYaxis()->GetTitleSize()*1.4);
  htmp8->GetXaxis()->SetTitleSize(htmp8->GetXaxis()->GetTitleSize()*1.2);
  cth->cd(1);
  htmp8->Draw();
  ll->Draw("Lsame");
  gr[1][1]->SetMarkerStyle(20);
  gr[1][1]->Draw("Psame");
  gr_c2th_05->Draw("LPsame");
  cth->cd(2);
  htmp8->Draw();
  ll->Draw("Lsame");
  gr[2][1]->SetMarkerStyle(20);
  gr[2][1]->Draw("Psame");
  gr_c2th_510->Draw("LPsame");
  cth->cd(3);
  htmp8->Draw();
  ll->Draw("Lsame");
  gr[4][1]->SetMarkerStyle(20);
  gr[4][1]->Draw("Psame");
  gr_c2th_2025->Draw("LPsame");

  TLegend* legend_cth = new TLegend(0.25,0.24,0.75,0.4);
  legend_cth->SetFillStyle(0);
  legend_cth->AddEntry(gr[1][1],"Data","P");
  legend_cth->AddEntry(gr_c2th_05,"3D hydro. model","PL");
  cth->cd(1);
  legend_cth->Draw("same");

  TLatex* latex8 = new TLatex();
  latex8->SetNDC();
  latex8->SetTextSize(latex3->GetTextSize());
  cth->cd(1);
  latex8->DrawLatex(0.8,0.25,histtitle[1]);
  latex8->DrawLatex(0.285,0.88,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  cth->cd(2);
  latex8->DrawLatex(0.68,0.25,histtitle[2]);
  latex8->DrawLatex(0.07,0.45,"4.4 < #eta^{b} < 5");
  latex8->DrawLatex(0.07,0.35,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex8->DrawLatex(0.07,0.25,"p_{T}^{b} > 0 GeV/c");
  cth->cd(3);
  latex8->DrawLatex(0.68,0.25,histtitle[4]);

  TCanvas* cth3 = new TCanvas("cth3","",900,330);
  makeMultiPanelCanvas(cth3,3,1,0.01,0.0,0.2,0.17,0.02);
  TH2D* htmp9 = new TH2D("htmp9",";#eta^{a};r_{3}(#eta^{a},#eta^{b})",100,-0.12,2.49,100,0.7,1.06);
  fixedFontHist(htmp9,0.9,1.3);
  htmp9->GetXaxis()->CenterTitle();
  htmp9->GetYaxis()->CenterTitle();
  htmp9->GetYaxis()->SetTitleSize(htmp9->GetYaxis()->GetTitleSize()*1.4);
  htmp9->GetXaxis()->SetTitleSize(htmp9->GetXaxis()->GetTitleSize()*1.2);
  cth3->cd(1);
  htmp9->Draw();
  ll->Draw("Lsame");
  gr[1][2]->SetMarkerStyle(20);
  gr[1][2]->Draw("Psame");
  gr_c3th_05->Draw("LPsame");
  cth3->cd(2);
  htmp9->Draw();
  ll->Draw("Lsame");
  gr[2][2]->SetMarkerStyle(20);
  gr[2][2]->Draw("Psame");
  gr_c3th_510->Draw("LPsame");
  cth3->cd(3);
  htmp9->Draw();
  ll->Draw("Lsame");
  gr[4][2]->SetMarkerStyle(20);
  gr[4][2]->Draw("Psame");
  gr_c3th_2025->Draw("LPsame");
  cth3->cd(1);
  legend_cth->Draw("same");

  cth3->cd(1);
  latex8->DrawLatex(0.8,0.25,histtitle[1]);
  latex8->DrawLatex(0.285,0.88,"CMS PbPb #sqrt{s_{NN}} = 2.76 TeV");
  cth3->cd(2);
  latex8->DrawLatex(0.68,0.25,histtitle[2]);
  latex8->DrawLatex(0.07,0.45,"4.4 < #eta^{b} < 5");
  latex8->DrawLatex(0.07,0.35,"0.3 < p_{T}^{a} < 3 GeV/c");
  latex8->DrawLatex(0.07,0.25,"p_{T}^{b} > 0 GeV/c");
  cth3->cd(3);
  latex8->DrawLatex(0.68,0.25,histtitle[4]);
/*
  SaveCanvas(cth,"HI/FactBreak","epetadeco_HI_theory_r2");
  SaveCanvas(cth3,"HI/FactBreak","epetadeco_HI_theory_r3");
*/
  SaveCanvas(c,"HI/FactBreak","epetadeco_HI_r2");
  SaveCanvas(cc,"HI/FactBreak","epetadeco_HI_r3");
//  SaveCanvas(ccaa,"HI/FactBreak","epetadeco_HI_r2ratio");
//  SaveCanvas(c1,"HI/FactBreak","epetadeco_HI_C");
//  SaveCanvas(cc2,"HI/FactBreak","epetadeco_HI_cos");
}