Plotting/Modules/LimitCalculation.C

#include <iostream>
#include <vector>
#include <sys/stat.h>

#include <TCut.h>
#include <TROOT.h>
#include <TCanvas.h>
#include <TMath.h>
#include <TColor.h>
#include <TPaveText.h>
#include <TRandom.h>
#include <TH1.h>
#include <TH2.h>
#include <TF1.h>
#include <TSQLResult.h>
#include <TProfile.h>

//#include "TTbar_stuff.C"
using namespace std;

using namespace PlottingSetup;


void rediscover_the_top(string mcjzb, string datajzb) {
  cout << "Hi! today we are going to (try to) rediscover the top!" << endl;
  TCanvas *c3 = new TCanvas("c3","c3");
  c3->SetLogy(1);
  vector<float> binning;
  //binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
  /*
  binning.push_back(50);
  binning.push_back(100);
  binning.push_back(150);
  binning.push_back(200);
  binning.push_back(500);
  
  
  TH1F *dataprediction = allsamples.Draw("dataprediction",    "-"+datajzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,  luminosity);
  TH1F *puresignal     = allsamples.Draw("puresignal",    datajzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,  luminosity);
//  TH1F *puresignal     = allsamples.Draw("puresignal",        mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc,  luminosity,allsamples.FindSample("TTJets"));
  TH1F *observed       = allsamples.Draw("observed",          datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
  /*
  ofstream myfile;
  TH1F *ratio = (TH1F*)observed->Clone();
  ratio->Divide(dataprediction);
  ratio->GetYaxis()->SetTitle("Ratio obs/pred");
  ratio->Draw();
  c3->SaveAs("testratio.png");
  myfile.open ("ShapeFit_log.txt");
  establish_upper_limits(observed,dataprediction,puresignal,"LM4",myfile);
  myfile.close();
  */
  
  
  int nbins=100;
  float low=0;
  float hi=500;
  TCanvas *c4 = new TCanvas("c4","c4",900,900);
  c4->Divide(2,2);
  c4->cd(1);
  c4->cd(1)->SetLogy(1);
  TH1F *datapredictiont = allsamples.Draw("datapredictiont",    "-"+datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,  luminosity);
  TH1F *datapredictiono = allsamples.Draw("datapredictiono",    "-"+datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,  luminosity);
  datapredictiont->Add(datapredictiono,-1);
  cout << "Second way of doing this !!!! Analytical shape to the left :-D" << endl;
  vector<TF1*> functions = do_cb_fit_to_plot(datapredictiont,10);
  datapredictiont->SetMarkerColor(kRed);
  datapredictiont->SetLineColor(kRed);
  datapredictiont->Draw();
  functions[1]->Draw("same");
  TText *title1 = write_title("Top Background Prediction (JZB<0, with osof subtr)");
  title1->Draw();
  
  c4->cd(2);
  c4->cd(2)->SetLogy(1);
  TH1F *observedt = allsamples.Draw("observedt", datajzb,  nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,  luminosity);
  observedt->Draw();
  datapredictiont->Draw("histo,same");
  functions[1]->Draw("same");
  TText *title2 = write_title("Observed and predicted background");
  title2->Draw();
  
  c4->cd(3);
  c4->cd(3)->SetLogy(1);
//  TH1F *ratio = (TH1F*)observedt->Clone();

  TH1F *analytical_background_prediction= new TH1F("analytical_background_prediction","",nbins,low,hi);
  for(int i=0;i<=nbins;i++) {
    analytical_background_prediction->SetBinContent(i+1,functions[1]->Eval(((hi-low)/((float)nbins))*(i+0.5)));
    analytical_background_prediction->SetBinError(i+1,TMath::Sqrt(functions[1]->Eval(((hi-low)/((float)nbins))*(i+0.5))));
  }
  analytical_background_prediction->GetYaxis()->SetTitle("JZB [GeV]");
  analytical_background_prediction->GetYaxis()->CenterTitle();
  TH1F *analyticaldrawonly = (TH1F*)analytical_background_prediction->Clone();
  analytical_background_prediction->SetFillColor(TColor::GetColor("#3399FF"));
  analytical_background_prediction->SetMarkerSize(0);
  analytical_background_prediction->Draw("e5");
  analyticaldrawonly->Draw("histo,same");
  functions[1]->Draw("same");
  TText *title3 = write_title("Analytical bg pred histo");
  title3->Draw();
  
  c4->cd(4);
//  c4->cd(4)->SetLogy(1);
  vector<float> ratio_binning;
  ratio_binning.push_back(0);
  ratio_binning.push_back(5);
  ratio_binning.push_back(10);
  ratio_binning.push_back(20);
  ratio_binning.push_back(50);
//  ratio_binning.push_back(60);
/*
  ratio_binning.push_back(51);
  ratio_binning.push_back(52);
  ratio_binning.push_back(53);
  ratio_binning.push_back(54);
  ratio_binning.push_back(55);
  ratio_binning.push_back(56);
  ratio_binning.push_back(57);
  ratio_binning.push_back(58);
  ratio_binning.push_back(59);
  ratio_binning.push_back(60);
//  ratio_binning.push_back(70);*/
//  ratio_binning.push_back(80);
//  ratio_binning.push_back(90);
ratio_binning.push_back(80);
//  ratio_binning.push_back(110);
  ratio_binning.push_back(500);
  
  TH1F *observedtb = allsamples.Draw("observedtb", datajzb,  ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,  luminosity);
  TH1F *datapredictiontb = allsamples.Draw("datapredictiontb",    "-"+datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,  luminosity);
  TH1F *datapredictiontbo = allsamples.Draw("datapredictiontbo",    "-"+datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,  luminosity);
  datapredictiontb->Add(datapredictiontbo,-1);
  TH1F *analytical_background_predictionb = allsamples.Draw("analytical_background_predictionb",datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets&&"mll<2",data,  luminosity);
  for(int i=0;i<=ratio_binning.size();i++) {
    analytical_background_predictionb->SetBinContent(i+1,functions[1]->Eval(analytical_background_predictionb->GetBinCenter(i)));
    analytical_background_predictionb->SetBinError(i+1,TMath::Sqrt(functions[1]->Eval(analytical_background_predictionb->GetBinCenter(i))));
  }
  
  TH1F *ratio = (TH1F*) observedtb->Clone();
  ratio->Divide(datapredictiontb);
  
  for (int i=0;i<=ratio_binning.size();i++) {
    cout << observedtb->GetBinLowEdge(i+1) << ";"<<observedtb->GetBinContent(i+1) << ";" << datapredictiontb->GetBinContent(i+1) << " --> " << ratio->GetBinContent(i+1) << "+/-" << ratio->GetBinError(i+1) << endl;
  }
  
//  ratio->Divide(datapredictiontb);
//  ratio->Divide(analytical_background_predictionb);
//  TGraphAsymmErrors *JZBratio= histRatio(observedtb,analytical_background_predictionb,data,ratio_binning);
//  ratio->Divide(analytical_background_prediction);
//  ratio->Divide(datapredictiont);
//  ratio->GetYaxis()->SetTitle("obs/pred");
//  JZBratio->Draw("AP");
  ratio->GetYaxis()->SetRangeUser(0,10);
  ratio->Draw();
//analytical_background_predictionb->Draw();
//  JZBratio->SetTitle("");
  TText *title4 = write_title("Ratio of observed to predicted");
  title4->Draw();
  
//  CompleteSave(c4,"test/ttbar_discovery_dataprediction___analytical_function");
  CompleteSave(c4,"test/ttbar_discovery_dataprediction__analytical__new_binning_one_huge_bin_from_80");

  
}

void calculate_upper_limits(string mcjzb, string datajzb) {
  write_warning("calculate_upper_limits","Upper limit calculation temporarily deactivated");
//  write_warning("calculate_upper_limits","Calculation of SUSY upper limits has been temporarily suspended in favor of top discovery");
//  rediscover_the_top(mcjzb,datajzb);
/*  
  TCanvas *c3 = new TCanvas("c3","c3");
  c3->SetLogy(1);
  vector<float> binning;
  //binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
  binning.push_back(50);
  binning.push_back(100);
  binning.push_back(150);
  binning.push_back(200);
  binning.push_back(500);
  TH1F *datapredictiona = allsamples.Draw("datapredictiona",    "-"+datajzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc,  luminosity);
  TH1F *datapredictionb = allsamples.Draw("datapredictionb",    "-"+datajzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity);
  TH1F *datapredictionc = allsamples.Draw("datapredictionc",    datajzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity);
  TH1F *dataprediction = (TH1F*)datapredictiona->Clone();
  dataprediction->Add(datapredictionb,-1);
  dataprediction->Add(datapredictionc);
  TH1F *puresignal     = allsamples.Draw("puresignal",        mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
  TH1F *signalpred     = allsamples.Draw("signalpred",    "-"+mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
  TH1F *signalpredlo   = allsamples.Draw("signalpredlo",  "-"+mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
  TH1F *signalpredro   = allsamples.Draw("signalpredro",      mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
  TH1F *puredata       = allsamples.Draw("puredata",          datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
  signalpred->Add(signalpredlo,-1);
  signalpred->Add(signalpredro);
  puresignal->Add(signalpred,-1);//subtracting signal contamination
  ofstream myfile;
  myfile.open ("ShapeFit_log.txt");
  establish_upper_limits(puredata,dataprediction,puresignal,"LM4",myfile);
  myfile.close();
*/ 
}

vector<float> compute_one_upper_limit(float mceff,float mcefferr, int ibin, string mcjzb, bool doobserved=false) {
  float sigma95=0.0,sigma95A=0.0;
  cout << "Now calling : CL95(" << luminosity << "," <<  lumiuncert*luminosity << "," << mceff << "," << mcefferr << "," << Npred[ibin] << "," << Nprederr[ibin] << "," << Nobs[ibin] << "," << false << "," << 1<< ") " << endl;
  sigma95 = CL95(luminosity, lumiuncert*luminosity, mceff, mcefferr, Npred[ibin], Nprederr[ibin], Nobs[ibin], false, 1);
  if(doobserved) {
    cout << "Now calling : CL95A(" << luminosity << "," <<  lumiuncert*luminosity << "," << mceff << "," << mcefferr << "," << Npred[ibin] << "," << Nprederr[ibin] << "," << 1<< ") " << endl;
    sigma95A = CLA(luminosity, lumiuncert*luminosity, mceff, mcefferr, Npred[ibin], Nprederr[ibin], 1);
  }
  vector<float> sigmas;
  sigmas.push_back(sigma95);
  sigmas.push_back(sigma95A);
  return sigmas;
}

void compute_upper_limits_from_counting_experiment(vector<vector<float> > uncertainties,vector<float> jzbcuts, string mcjzb, bool doobserved) {
  cout << "Doing counting experiment ... " << endl;
  vector<vector<string> > limits;
  vector<vector<float> > vlimits;
  
  
  for(int isample=0;isample<signalsamples.collection.size();isample++) {
    vector<string> rows;
    vector<float> vrows;
    cout << "Considering sample " << signalsamples.collection[isample].samplename << endl;
    rows.push_back(signalsamples.collection[isample].samplename);
    for(int ibin=0;ibin<jzbcuts.size();ibin++) {
      cout << "_________________________________________________________________________________" << endl;
      float JZBcutat=uncertainties[isample*jzbcuts.size()+ibin][0];
      float mceff=uncertainties[isample*jzbcuts.size()+ibin][1];
      float staterr=uncertainties[isample*jzbcuts.size()+ibin][2];
      float systerr=uncertainties[isample*jzbcuts.size()+ibin][3];
      float toterr =uncertainties[isample*jzbcuts.size()+ibin][4];
      float observed,null,result;
      fill_result_histos(observed, null,null,null,null,null,null,null,mcjzb,JZBcutat,(int)5,result,(signalsamples.FindSample(signalsamples.collection[isample].filename)),signalsamples);
      observed-=result;//this is the actual excess we see!
      float expected=observed/luminosity;
      
      cout << "Sample: " << signalsamples.collection[isample].samplename << ", JZB>"<<JZBcutat<< " : " << mceff << " +/- " << staterr << " (stat) +/- " << systerr << " (syst) --> toterr = " << toterr << endl;
      vector<float> sigmas = compute_one_upper_limit(mceff,toterr,ibin,mcjzb,doobserved);
      
      if(doobserved) {
        rows.push_back(any2string(sigmas[0])+";"+any2string(sigmas[1])+";"+"("+any2string(expected)+")");
        vrows.push_back(sigmas[0]);
        vrows.push_back(sigmas[1]);
        vrows.push_back(expected);
      }
      else {
        rows.push_back(any2string(sigmas[0])+"("+any2string(expected)+")");
        vrows.push_back(sigmas[0]);
        vrows.push_back(expected);
      }
    }//end of bin loop
    limits.push_back(rows);
    vlimits.push_back(vrows);
  }//end of sample loop
  cout << endl << endl << "PAS table 3: " << endl << endl;
  cout << "\t";
  for (int irow=0;irow<jzbcuts.size();irow++) {
    cout << jzbcuts[irow] << "\t";
  }
  cout << endl;
  for(int irow=0;irow<limits.size();irow++) {
    for(int ientry=0;ientry<limits[irow].size();ientry++) {
      cout << limits[irow][ientry] << "\t";
    }
    cout << endl;
  }
  
  if(!doobserved) {
    cout << endl << endl << "LIMITS: " << endl;
    cout << "\t";
    for (int irow=0;irow<jzbcuts.size();irow++) {
      cout << jzbcuts[irow] << "\t";
    }
    cout << endl;
    for(int irow=0;irow<limits.size();irow++) {
      cout << limits[irow][0] << "\t";
      for(int ientry=0;ientry<jzbcuts.size();ientry++) {
        cout << Round(vlimits[irow][2*ientry] / vlimits[irow][2*ientry+1],3)<< "\t";
      }
      cout << endl;
    }
  }//do observed
}

void susy_scan_axis_labeling(TH2F *histo) {
  histo->GetXaxis()->SetTitle("#Chi_{2}^{0}-LSP");
  histo->GetXaxis()->CenterTitle();
  histo->GetYaxis()->SetTitle("m_{#tilde{q}}");
  histo->GetYaxis()->CenterTitle();
}

void scan_susy_space(string mcjzb, string datajzb) {
  TCanvas *c3 = new TCanvas("c3","c3");
  vector<float> binning;
  binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
  float arrbinning[binning.size()];
  for(int i=0;i<binning.size();i++) arrbinning[i]=binning[i];
  TH1F *puredata   = allsamples.Draw("puredata",  datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
  puredata->SetMarkerSize(DataMarkerSize);
  TH1F *allbgs   = allsamples.Draw("allbgs",  "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
  TH1F *allbgsb   = allsamples.Draw("allbgsb",  "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
  TH1F *allbgsc   = allsamples.Draw("allbgsc",  datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
  allbgs->Add(allbgsb,-1);
  allbgs->Add(allbgsc);
  int ndata=puredata->Integral();
  ofstream myfile;
  myfile.open ("susyscan_log.txt");
  TFile *susyscanfile = new TFile("/scratch/fronga/SMS/T5z_SqSqToQZQZ_38xFall10.root");
  TTree *suevents = (TTree*)susyscanfile->Get("events");
  TH2F *exclusionmap = new TH2F("exclusionmap","",20,0,500,20,0,1000);
  TH2F *exclusionmap1s = new TH2F("exclusionmap1s","",20,0,500,20,0,1000);
  TH2F *exclusionmap2s = new TH2F("exclusionmap2s","",20,0,500,20,0,1000);
  TH2F *exclusionmap3s = new TH2F("exclusionmap3s","",20,0,500,20,0,1000);
  
  susy_scan_axis_labeling(exclusionmap);
  susy_scan_axis_labeling(exclusionmap1s);
  susy_scan_axis_labeling(exclusionmap2s);
  susy_scan_axis_labeling(exclusionmap3s);
  
  Int_t MyPalette[100];
  Double_t r[]    = {0., 0.0, 1.0, 1.0, 1.0};
  Double_t g[]    = {0., 0.0, 0.0, 1.0, 1.0};
  Double_t b[]    = {0., 1.0, 0.0, 0.0, 1.0};
  Double_t stop[] = {0., .25, .50, .75, 1.0};
  Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 100);
  for (int i=0;i<100;i++) MyPalette[i] = FI+i;
   
  gStyle->SetPalette(100, MyPalette);
  
  for(int m23=50;m23<500;m23+=25) {
    for (int m0=(2*(m23-50)+150);m0<=1000;m0+=50)
    {
      c3->cd();
      stringstream drawcondition;
      drawcondition << "pfJetGoodNum>=3&&(TMath::Abs(masses[0]-"<<m0<<")<10&&TMath::Abs(masses[2]-masses[3]-"<<m23<<")<10)&&mll>5&&id1==id2";
      TH1F *puresignal = new TH1F("puresignal","puresignal",binning.size()-1,arrbinning);
      TH1F *puresignall= new TH1F("puresignall","puresignal",binning.size()-1,arrbinning);
      stringstream drawvar,drawvar2;
      drawvar<<mcjzb<<">>puresignal";
      drawvar2<<"-"<<mcjzb<<">>puresignall";
      suevents->Draw(drawvar.str().c_str(),drawcondition.str().c_str());
      suevents->Draw(drawvar2.str().c_str(),drawcondition.str().c_str());
      if(puresignal->Integral()<60) {
        delete puresignal;
        continue;
      }
      puresignal->Add(puresignall,-1);//we need to correct for the signal contamination - we effectively only see (JZB>0)-(JZB<0) !!
      puresignal->Scale(ndata/(20*puresignal->Integral()));//normalizing it to 5% of the data
      stringstream saveas;
      saveas<<"Model_Scan/m0_"<<m0<<"__m23_"<<m23;
      cout << "PLEASE KEEP IN MIND THAT SIGNAL CONTAMINATION IS NOT REALLY TAKEN CARE OF YET DUE TO LOW STATISTICS! SHOULD BE SOMETHING LIKE THIS : "<< endl;
//        TH1F *signalpredlo   = allsamples.Draw("signalpredlo",  "-"+mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
//        TH1F *signalpredro   = allsamples.Draw("signalpredro",      mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
//        TH1F *puredata       = allsamples.Draw("puredata",          datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
//        signalpred->Add(signalpredlo,-1);
//        signalpred->Add(signalpredro);
//        puresignal->Add(signalpred,-1);//subtracting signal contamination
//---------------------
//      cout << "(m0,m23)=("<<m0<<","<<m23<<") contains " << puresignal->Integral() << endl;
//    TH1F *puresignal = allsamples.Draw("puresignal",mcjzb,  binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc,  luminosity,allsamples.FindSample("LM4"));
      vector<float> results=establish_upper_limits(puredata,allbgs,puresignal,saveas.str(),myfile);  
      if(results.size()==0) {
        delete puresignal;
        continue;
      }
      exclusionmap->Fill(m23,m0,results[0]);
      exclusionmap1s->Fill(m23,m0,results[1]);
      exclusionmap2s->Fill(m23,m0,results[2]);
      exclusionmap3s->Fill(m23,m0,results[3]);
      delete puresignal;
      cout << "(m0,m23)=("<<m0<<","<<m23<<") : 3 sigma at " << results[3] << endl;
    }
  }//end of model scan for loop
  
  cout << "Exclusion Map contains" << exclusionmap->Integral() << " (integral) and entries: " << exclusionmap->GetEntries() << endl;
  c3->cd();
  exclusionmap->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_Mean_values");
  exclusionmap->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_Mean_values");
  
  exclusionmap1s->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_1sigma_values");
  exclusionmap1s->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_1sigma_values");
  
  exclusionmap2s->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_2sigma_values");
  exclusionmap2s->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_2sigma_values");
  
  exclusionmap3s->Draw("CONTZ");
  CompleteSave(c3,"Model_Scan/CONT/Model_Scan_3sigma_values");
  exclusionmap3s->Draw("COLZ");
  CompleteSave(c3,"Model_Scan/COL/Model_Scan_3sigma_values");
  
  TFile *exclusion_limits = new TFile("exclusion_limits.root","RECREATE");
  exclusionmap->Write();
  exclusionmap1s->Write();
  exclusionmap2s->Write();
  exclusionmap3s->Write();
  exclusion_limits->Close();
  susyscanfile->Close();
  
  myfile.close();
}


Revision:	1.2
Committed:	Tue Jul 19 15:04:16 2011 UTC (13 years, 9 months ago) by buchmann
Content type:	text/plain
Branch:	MAIN
Changes since 1.1:	+76 -17 lines
Log Message:	Introduced new limit calculation interfacing with the standard CMS CL script
#	User	Rev	Content
1	buchmann	1.1	#include <iostream>
2			#include <vector>
3			#include <sys/stat.h>
4
5			#include <TCut.h>
6			#include <TROOT.h>
7			#include <TCanvas.h>
8			#include <TMath.h>
9			#include <TColor.h>
10			#include <TPaveText.h>
11			#include <TRandom.h>
12			#include <TH1.h>
13			#include <TH2.h>
14			#include <TF1.h>
15			#include <TSQLResult.h>
16			#include <TProfile.h>
17
18			//#include "TTbar_stuff.C"
19			using namespace std;
20
21			using namespace PlottingSetup;
22
23
24			void rediscover_the_top(string mcjzb, string datajzb) {
25			cout << "Hi! today we are going to (try to) rediscover the top!" << endl;
26			TCanvas *c3 = new TCanvas("c3","c3");
27			c3->SetLogy(1);
28			vector<float> binning;
29			//binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
30			/*
31			binning.push_back(50);
32			binning.push_back(100);
33			binning.push_back(150);
34			binning.push_back(200);
35			binning.push_back(500);
36
37
38			TH1F *dataprediction = allsamples.Draw("dataprediction", "-"+datajzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
39			TH1F *puresignal = allsamples.Draw("puresignal", datajzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data, luminosity);
40			// TH1F *puresignal = allsamples.Draw("puresignal", mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc, luminosity,allsamples.FindSample("TTJets"));
41			TH1F *observed = allsamples.Draw("observed", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
42			/*
43			ofstream myfile;
44			TH1F ratio = (TH1F)observed->Clone();
45			ratio->Divide(dataprediction);
46			ratio->GetYaxis()->SetTitle("Ratio obs/pred");
47			ratio->Draw();
48			c3->SaveAs("testratio.png");
49			myfile.open ("ShapeFit_log.txt");
50			establish_upper_limits(observed,dataprediction,puresignal,"LM4",myfile);
51			myfile.close();
52			*/
53
54
55			int nbins=100;
56			float low=0;
57			float hi=500;
58			TCanvas *c4 = new TCanvas("c4","c4",900,900);
59			c4->Divide(2,2);
60			c4->cd(1);
61			c4->cd(1)->SetLogy(1);
62			TH1F *datapredictiont = allsamples.Draw("datapredictiont", "-"+datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
63			TH1F *datapredictiono = allsamples.Draw("datapredictiono", "-"+datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data, luminosity);
64			datapredictiont->Add(datapredictiono,-1);
65			cout << "Second way of doing this !!!! Analytical shape to the left :-D" << endl;
66			vector<TF1*> functions = do_cb_fit_to_plot(datapredictiont,10);
67			datapredictiont->SetMarkerColor(kRed);
68			datapredictiont->SetLineColor(kRed);
69			datapredictiont->Draw();
70			functions[1]->Draw("same");
71			TText *title1 = write_title("Top Background Prediction (JZB<0, with osof subtr)");
72			title1->Draw();
73
74			c4->cd(2);
75			c4->cd(2)->SetLogy(1);
76			TH1F *observedt = allsamples.Draw("observedt", datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
77			observedt->Draw();
78			datapredictiont->Draw("histo,same");
79			functions[1]->Draw("same");
80			TText *title2 = write_title("Observed and predicted background");
81			title2->Draw();
82
83			c4->cd(3);
84			c4->cd(3)->SetLogy(1);
85			// TH1F ratio = (TH1F)observedt->Clone();
86
87			TH1F *analytical_background_prediction= new TH1F("analytical_background_prediction","",nbins,low,hi);
88			for(int i=0;i<=nbins;i++) {
89			analytical_background_prediction->SetBinContent(i+1,functions[1]->Eval(((hi-low)/((float)nbins))*(i+0.5)));
90			analytical_background_prediction->SetBinError(i+1,TMath::Sqrt(functions[1]->Eval(((hi-low)/((float)nbins))*(i+0.5))));
91			}
92			analytical_background_prediction->GetYaxis()->SetTitle("JZB [GeV]");
93			analytical_background_prediction->GetYaxis()->CenterTitle();
94			TH1F analyticaldrawonly = (TH1F)analytical_background_prediction->Clone();
95			analytical_background_prediction->SetFillColor(TColor::GetColor("#3399FF"));
96			analytical_background_prediction->SetMarkerSize(0);
97			analytical_background_prediction->Draw("e5");
98			analyticaldrawonly->Draw("histo,same");
99			functions[1]->Draw("same");
100			TText *title3 = write_title("Analytical bg pred histo");
101			title3->Draw();
102
103			c4->cd(4);
104			// c4->cd(4)->SetLogy(1);
105			vector<float> ratio_binning;
106			ratio_binning.push_back(0);
107			ratio_binning.push_back(5);
108			ratio_binning.push_back(10);
109			ratio_binning.push_back(20);
110			ratio_binning.push_back(50);
111			// ratio_binning.push_back(60);
112			/*
113			ratio_binning.push_back(51);
114			ratio_binning.push_back(52);
115			ratio_binning.push_back(53);
116			ratio_binning.push_back(54);
117			ratio_binning.push_back(55);
118			ratio_binning.push_back(56);
119			ratio_binning.push_back(57);
120			ratio_binning.push_back(58);
121			ratio_binning.push_back(59);
122			ratio_binning.push_back(60);
123			// ratio_binning.push_back(70);*/
124			// ratio_binning.push_back(80);
125			// ratio_binning.push_back(90);
126			ratio_binning.push_back(80);
127			// ratio_binning.push_back(110);
128			ratio_binning.push_back(500);
129
130			TH1F *observedtb = allsamples.Draw("observedtb", datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
131			TH1F *datapredictiontb = allsamples.Draw("datapredictiontb", "-"+datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
132			TH1F *datapredictiontbo = allsamples.Draw("datapredictiontbo", "-"+datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data, luminosity);
133			datapredictiontb->Add(datapredictiontbo,-1);
134			TH1F *analytical_background_predictionb = allsamples.Draw("analytical_background_predictionb",datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets&&"mll<2",data, luminosity);
135			for(int i=0;i<=ratio_binning.size();i++) {
136			analytical_background_predictionb->SetBinContent(i+1,functions[1]->Eval(analytical_background_predictionb->GetBinCenter(i)));
137			analytical_background_predictionb->SetBinError(i+1,TMath::Sqrt(functions[1]->Eval(analytical_background_predictionb->GetBinCenter(i))));
138			}
139
140			TH1F ratio = (TH1F) observedtb->Clone();
141			ratio->Divide(datapredictiontb);
142
143			for (int i=0;i<=ratio_binning.size();i++) {
144			cout << observedtb->GetBinLowEdge(i+1) << ";"<<observedtb->GetBinContent(i+1) << ";" << datapredictiontb->GetBinContent(i+1) << " --> " << ratio->GetBinContent(i+1) << "+/-" << ratio->GetBinError(i+1) << endl;
145			}
146
147			// ratio->Divide(datapredictiontb);
148			// ratio->Divide(analytical_background_predictionb);
149			// TGraphAsymmErrors *JZBratio= histRatio(observedtb,analytical_background_predictionb,data,ratio_binning);
150			// ratio->Divide(analytical_background_prediction);
151			// ratio->Divide(datapredictiont);
152			// ratio->GetYaxis()->SetTitle("obs/pred");
153			// JZBratio->Draw("AP");
154			ratio->GetYaxis()->SetRangeUser(0,10);
155			ratio->Draw();
156			//analytical_background_predictionb->Draw();
157			// JZBratio->SetTitle("");
158			TText *title4 = write_title("Ratio of observed to predicted");
159			title4->Draw();
160
161			// CompleteSave(c4,"test/ttbar_discovery_dataprediction___analytical_function");
162			CompleteSave(c4,"test/ttbar_discovery_dataprediction__analytical__new_binning_one_huge_bin_from_80");
163
164
165
166
167
168			}
169
170			void calculate_upper_limits(string mcjzb, string datajzb) {
171			write_warning("calculate_upper_limits","Upper limit calculation temporarily deactivated");
172			// write_warning("calculate_upper_limits","Calculation of SUSY upper limits has been temporarily suspended in favor of top discovery");
173			// rediscover_the_top(mcjzb,datajzb);
174			/*
175			TCanvas *c3 = new TCanvas("c3","c3");
176			c3->SetLogy(1);
177			vector<float> binning;
178			//binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
179			binning.push_back(50);
180			binning.push_back(100);
181			binning.push_back(150);
182			binning.push_back(200);
183			binning.push_back(500);
184			TH1F *datapredictiona = allsamples.Draw("datapredictiona", "-"+datajzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc, luminosity);
185			TH1F *datapredictionb = allsamples.Draw("datapredictionb", "-"+datajzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity);
186			TH1F *datapredictionc = allsamples.Draw("datapredictionc", datajzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity);
187			TH1F dataprediction = (TH1F)datapredictiona->Clone();
188			dataprediction->Add(datapredictionb,-1);
189			dataprediction->Add(datapredictionc);
190			TH1F *puresignal = allsamples.Draw("puresignal", mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
191			TH1F *signalpred = allsamples.Draw("signalpred", "-"+mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
192			TH1F *signalpredlo = allsamples.Draw("signalpredlo", "-"+mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
193			TH1F *signalpredro = allsamples.Draw("signalpredro", mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
194			TH1F *puredata = allsamples.Draw("puredata", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
195			signalpred->Add(signalpredlo,-1);
196			signalpred->Add(signalpredro);
197			puresignal->Add(signalpred,-1);//subtracting signal contamination
198			ofstream myfile;
199			myfile.open ("ShapeFit_log.txt");
200			establish_upper_limits(puredata,dataprediction,puresignal,"LM4",myfile);
201			myfile.close();
202			*/
203			}
204
205	buchmann	1.2	vector<float> compute_one_upper_limit(float mceff,float mcefferr, int ibin, string mcjzb, bool doobserved=false) {
206			float sigma95=0.0,sigma95A=0.0;
207			cout << "Now calling : CL95(" << luminosity << "," << lumiuncert*luminosity << "," << mceff << "," << mcefferr << "," << Npred[ibin] << "," << Nprederr[ibin] << "," << Nobs[ibin] << "," << false << "," << 1<< ") " << endl;
208			sigma95 = CL95(luminosity, lumiuncert*luminosity, mceff, mcefferr, Npred[ibin], Nprederr[ibin], Nobs[ibin], false, 1);
209			if(doobserved) {
210			cout << "Now calling : CL95A(" << luminosity << "," << lumiuncert*luminosity << "," << mceff << "," << mcefferr << "," << Npred[ibin] << "," << Nprederr[ibin] << "," << 1<< ") " << endl;
211			sigma95A = CLA(luminosity, lumiuncert*luminosity, mceff, mcefferr, Npred[ibin], Nprederr[ibin], 1);
212			}
213			vector<float> sigmas;
214			sigmas.push_back(sigma95);
215			sigmas.push_back(sigma95A);
216			return sigmas;
217			}
218
219			void compute_upper_limits_from_counting_experiment(vector<vector<float> > uncertainties,vector<float> jzbcuts, string mcjzb, bool doobserved) {
220	buchmann	1.1	cout << "Doing counting experiment ... " << endl;
221	buchmann	1.2	vector<vector<string> > limits;
222			vector<vector<float> > vlimits;
223
224	buchmann	1.1
225			for(int isample=0;isample<signalsamples.collection.size();isample++) {
226	buchmann	1.2	vector<string> rows;
227			vector<float> vrows;
228	buchmann	1.1	cout << "Considering sample " << signalsamples.collection[isample].samplename << endl;
229	buchmann	1.2	rows.push_back(signalsamples.collection[isample].samplename);
230	buchmann	1.1	for(int ibin=0;ibin<jzbcuts.size();ibin++) {
231	buchmann	1.2	cout << "_________________________________________________________________________________" << endl;
232			float JZBcutat=uncertainties[isample*jzbcuts.size()+ibin][0];
233			float mceff=uncertainties[isample*jzbcuts.size()+ibin][1];
234			float staterr=uncertainties[isample*jzbcuts.size()+ibin][2];
235			float systerr=uncertainties[isample*jzbcuts.size()+ibin][3];
236			float toterr =uncertainties[isample*jzbcuts.size()+ibin][4];
237			float observed,null,result;
238			fill_result_histos(observed, null,null,null,null,null,null,null,mcjzb,JZBcutat,(int)5,result,(signalsamples.FindSample(signalsamples.collection[isample].filename)),signalsamples);
239			observed-=result;//this is the actual excess we see!
240			float expected=observed/luminosity;
241
242			cout << "Sample: " << signalsamples.collection[isample].samplename << ", JZB>"<<JZBcutat<< " : " << mceff << " +/- " << staterr << " (stat) +/- " << systerr << " (syst) --> toterr = " << toterr << endl;
243			vector<float> sigmas = compute_one_upper_limit(mceff,toterr,ibin,mcjzb,doobserved);
244
245			if(doobserved) {
246			rows.push_back(any2string(sigmas[0])+";"+any2string(sigmas[1])+";"+"("+any2string(expected)+")");
247			vrows.push_back(sigmas[0]);
248			vrows.push_back(sigmas[1]);
249			vrows.push_back(expected);
250			}
251			else {
252			rows.push_back(any2string(sigmas[0])+"("+any2string(expected)+")");
253			vrows.push_back(sigmas[0]);
254			vrows.push_back(expected);
255			}
256	buchmann	1.1	}//end of bin loop
257	buchmann	1.2	limits.push_back(rows);
258			vlimits.push_back(vrows);
259	buchmann	1.1	}//end of sample loop
260	buchmann	1.2	cout << endl << endl << "PAS table 3: " << endl << endl;
261			cout << "\t";
262			for (int irow=0;irow<jzbcuts.size();irow++) {
263			cout << jzbcuts[irow] << "\t";
264			}
265			cout << endl;
266			for(int irow=0;irow<limits.size();irow++) {
267			for(int ientry=0;ientry<limits[irow].size();ientry++) {
268			cout << limits[irow][ientry] << "\t";
269			}
270			cout << endl;
271			}
272
273			if(!doobserved) {
274			cout << endl << endl << "LIMITS: " << endl;
275			cout << "\t";
276			for (int irow=0;irow<jzbcuts.size();irow++) {
277			cout << jzbcuts[irow] << "\t";
278			}
279			cout << endl;
280			for(int irow=0;irow<limits.size();irow++) {
281			cout << limits[irow][0] << "\t";
282			for(int ientry=0;ientry<jzbcuts.size();ientry++) {
283			cout << Round(vlimits[irow][2ientry] / vlimits[irow][2ientry+1],3)<< "\t";
284			}
285			cout << endl;
286			}
287			}//do observed
288	buchmann	1.1	}
289
290			void susy_scan_axis_labeling(TH2F *histo) {
291			histo->GetXaxis()->SetTitle("#Chi_{2}^{0}-LSP");
292			histo->GetXaxis()->CenterTitle();
293			histo->GetYaxis()->SetTitle("m_{#tilde{q}}");
294			histo->GetYaxis()->CenterTitle();
295			}
296
297			void scan_susy_space(string mcjzb, string datajzb) {
298			TCanvas *c3 = new TCanvas("c3","c3");
299			vector<float> binning;
300			binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
301			float arrbinning[binning.size()];
302			for(int i=0;i<binning.size();i++) arrbinning[i]=binning[i];
303			TH1F *puredata = allsamples.Draw("puredata", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
304			puredata->SetMarkerSize(DataMarkerSize);
305			TH1F *allbgs = allsamples.Draw("allbgs", "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
306			TH1F *allbgsb = allsamples.Draw("allbgsb", "-"+datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
307			TH1F *allbgsc = allsamples.Draw("allbgsc", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data,luminosity);
308			allbgs->Add(allbgsb,-1);
309			allbgs->Add(allbgsc);
310			int ndata=puredata->Integral();
311			ofstream myfile;
312			myfile.open ("susyscan_log.txt");
313			TFile *susyscanfile = new TFile("/scratch/fronga/SMS/T5z_SqSqToQZQZ_38xFall10.root");
314			TTree suevents = (TTree)susyscanfile->Get("events");
315			TH2F *exclusionmap = new TH2F("exclusionmap","",20,0,500,20,0,1000);
316			TH2F *exclusionmap1s = new TH2F("exclusionmap1s","",20,0,500,20,0,1000);
317			TH2F *exclusionmap2s = new TH2F("exclusionmap2s","",20,0,500,20,0,1000);
318			TH2F *exclusionmap3s = new TH2F("exclusionmap3s","",20,0,500,20,0,1000);
319
320			susy_scan_axis_labeling(exclusionmap);
321			susy_scan_axis_labeling(exclusionmap1s);
322			susy_scan_axis_labeling(exclusionmap2s);
323			susy_scan_axis_labeling(exclusionmap3s);
324
325			Int_t MyPalette[100];
326			Double_t r[] = {0., 0.0, 1.0, 1.0, 1.0};
327			Double_t g[] = {0., 0.0, 0.0, 1.0, 1.0};
328			Double_t b[] = {0., 1.0, 0.0, 0.0, 1.0};
329			Double_t stop[] = {0., .25, .50, .75, 1.0};
330			Int_t FI = TColor::CreateGradientColorTable(5, stop, r, g, b, 100);
331			for (int i=0;i<100;i++) MyPalette[i] = FI+i;
332
333			gStyle->SetPalette(100, MyPalette);
334
335			for(int m23=50;m23<500;m23+=25) {
336			for (int m0=(2*(m23-50)+150);m0<=1000;m0+=50)
337			{
338			c3->cd();
339			stringstream drawcondition;
340			drawcondition << "pfJetGoodNum>=3&&(TMath::Abs(masses[0]-"<<m0<<")<10&&TMath::Abs(masses[2]-masses[3]-"<<m23<<")<10)&&mll>5&&id1==id2";
341			TH1F *puresignal = new TH1F("puresignal","puresignal",binning.size()-1,arrbinning);
342			TH1F *puresignall= new TH1F("puresignall","puresignal",binning.size()-1,arrbinning);
343			stringstream drawvar,drawvar2;
344			drawvar<<mcjzb<<">>puresignal";
345			drawvar2<<"-"<<mcjzb<<">>puresignall";
346			suevents->Draw(drawvar.str().c_str(),drawcondition.str().c_str());
347			suevents->Draw(drawvar2.str().c_str(),drawcondition.str().c_str());
348			if(puresignal->Integral()<60) {
349			delete puresignal;
350			continue;
351			}
352			puresignal->Add(puresignall,-1);//we need to correct for the signal contamination - we effectively only see (JZB>0)-(JZB<0) !!
353			puresignal->Scale(ndata/(20*puresignal->Integral()));//normalizing it to 5% of the data
354			stringstream saveas;
355			saveas<<"Model_Scan/m0_"<<m0<<"__m23_"<<m23;
356			cout << "PLEASE KEEP IN MIND THAT SIGNAL CONTAMINATION IS NOT REALLY TAKEN CARE OF YET DUE TO LOW STATISTICS! SHOULD BE SOMETHING LIKE THIS : "<< endl;
357			// TH1F *signalpredlo = allsamples.Draw("signalpredlo", "-"+mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
358			// TH1F *signalpredro = allsamples.Draw("signalpredro", mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
359			// TH1F *puredata = allsamples.Draw("puredata", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
360			// signalpred->Add(signalpredlo,-1);
361			// signalpred->Add(signalpredro);
362			// puresignal->Add(signalpred,-1);//subtracting signal contamination
363			//---------------------
364			// cout << "(m0,m23)=("<<m0<<","<<m23<<") contains " << puresignal->Integral() << endl;
365			// TH1F *puresignal = allsamples.Draw("puresignal",mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc, luminosity,allsamples.FindSample("LM4"));
366			vector<float> results=establish_upper_limits(puredata,allbgs,puresignal,saveas.str(),myfile);
367			if(results.size()==0) {
368			delete puresignal;
369			continue;
370			}
371			exclusionmap->Fill(m23,m0,results[0]);
372			exclusionmap1s->Fill(m23,m0,results[1]);
373			exclusionmap2s->Fill(m23,m0,results[2]);
374			exclusionmap3s->Fill(m23,m0,results[3]);
375			delete puresignal;
376			cout << "(m0,m23)=("<<m0<<","<<m23<<") : 3 sigma at " << results[3] << endl;
377			}
378			}//end of model scan for loop
379
380			cout << "Exclusion Map contains" << exclusionmap->Integral() << " (integral) and entries: " << exclusionmap->GetEntries() << endl;
381			c3->cd();
382			exclusionmap->Draw("CONTZ");
383			CompleteSave(c3,"Model_Scan/CONT/Model_Scan_Mean_values");
384			exclusionmap->Draw("COLZ");
385			CompleteSave(c3,"Model_Scan/COL/Model_Scan_Mean_values");
386
387			exclusionmap1s->Draw("CONTZ");
388			CompleteSave(c3,"Model_Scan/CONT/Model_Scan_1sigma_values");
389			exclusionmap1s->Draw("COLZ");
390			CompleteSave(c3,"Model_Scan/COL/Model_Scan_1sigma_values");
391
392			exclusionmap2s->Draw("CONTZ");
393			CompleteSave(c3,"Model_Scan/CONT/Model_Scan_2sigma_values");
394			exclusionmap2s->Draw("COLZ");
395			CompleteSave(c3,"Model_Scan/COL/Model_Scan_2sigma_values");
396
397			exclusionmap3s->Draw("CONTZ");
398			CompleteSave(c3,"Model_Scan/CONT/Model_Scan_3sigma_values");
399			exclusionmap3s->Draw("COLZ");
400			CompleteSave(c3,"Model_Scan/COL/Model_Scan_3sigma_values");
401
402			TFile *exclusion_limits = new TFile("exclusion_limits.root","RECREATE");
403			exclusionmap->Write();
404			exclusionmap1s->Write();
405			exclusionmap2s->Write();
406			exclusionmap3s->Write();
407			exclusion_limits->Close();
408			susyscanfile->Close();
409
410			myfile.close();
411			}
412
413
414
415