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#include <iostream>
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#include <vector>
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#include <sys/stat.h>
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#include <fstream>
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#include <TCut.h>
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#include <TROOT.h>
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#include <TCanvas.h>
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#include <TMath.h>
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#include <TColor.h>
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#include <TPaveText.h>
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#include <TRandom.h>
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#include <TH1.h>
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#include <TH2.h>
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#include <TF1.h>
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#include <TSQLResult.h>
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#include <TProfile.h>
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//#include "TTbar_stuff.C"
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using namespace std;
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using namespace PlottingSetup;
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void rediscover_the_top(string mcjzb, string datajzb) {
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dout << "Hi! today we are going to (try to) rediscover the top!" << endl;
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TCanvas *c3 = new TCanvas("c3","c3");
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c3->SetLogy(1);
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vector<float> binning;
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//binning=allsamples.get_optimal_binsize(mcjzb,cutmass&&cutOSSF&&cutnJets,20,50,800);
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/*
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binning.push_back(50);
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binning.push_back(100);
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binning.push_back(150);
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binning.push_back(200);
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binning.push_back(500);
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TH1F *dataprediction = allsamples.Draw("dataprediction", "-"+datajzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
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TH1F *puresignal = allsamples.Draw("puresignal", datajzb, binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data, luminosity);
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// TH1F *puresignal = allsamples.Draw("puresignal", mcjzb, binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,mc, luminosity,allsamples.FindSample("TTJets"));
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TH1F *observed = allsamples.Draw("observed", datajzb,binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data,luminosity);
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/*
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ofstream myfile;
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TH1F *ratio = (TH1F*)observed->Clone();
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ratio->Divide(dataprediction);
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ratio->GetYaxis()->SetTitle("Ratio obs/pred");
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ratio->Draw();
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c3->SaveAs("testratio.png");
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myfile.open ("ShapeFit_log.txt");
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establish_upper_limits(observed,dataprediction,puresignal,"LM4",myfile);
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myfile.close();
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*/
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int nbins=100;
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float low=0;
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float hi=500;
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TCanvas *c4 = new TCanvas("c4","c4",900,900);
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c4->Divide(2,2);
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c4->cd(1);
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c4->cd(1)->SetLogy(1);
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TH1F *datapredictiont = allsamples.Draw("datapredictiont", "-"+datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
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TH1F *datapredictiono = allsamples.Draw("datapredictiono", "-"+datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data, luminosity);
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datapredictiont->Add(datapredictiono,-1);
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dout << "Second way of doing this !!!! Analytical shape to the left :-D" << endl;
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vector<TF1*> functions = do_cb_fit_to_plot(datapredictiont,10);
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datapredictiont->SetMarkerColor(kRed);
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datapredictiont->SetLineColor(kRed);
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datapredictiont->Draw();
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functions[1]->Draw("same");
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TText *title1 = write_title("Top Background Prediction (JZB<0, with osof subtr)");
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title1->Draw();
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c4->cd(2);
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c4->cd(2)->SetLogy(1);
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TH1F *observedt = allsamples.Draw("observedt", datajzb, nbins,low,hi, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
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observedt->Draw();
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datapredictiont->Draw("histo,same");
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functions[1]->Draw("same");
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TText *title2 = write_title("Observed and predicted background");
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title2->Draw();
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c4->cd(3);
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c4->cd(3)->SetLogy(1);
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// TH1F *ratio = (TH1F*)observedt->Clone();
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TH1F *analytical_background_prediction= new TH1F("analytical_background_prediction","",nbins,low,hi);
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for(int i=0;i<=nbins;i++) {
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analytical_background_prediction->SetBinContent(i+1,functions[1]->Eval(((hi-low)/((float)nbins))*(i+0.5)));
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analytical_background_prediction->SetBinError(i+1,TMath::Sqrt(functions[1]->Eval(((hi-low)/((float)nbins))*(i+0.5))));
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}
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analytical_background_prediction->GetYaxis()->SetTitle("JZB [GeV]");
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analytical_background_prediction->GetYaxis()->CenterTitle();
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TH1F *analyticaldrawonly = (TH1F*)analytical_background_prediction->Clone();
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analytical_background_prediction->SetFillColor(TColor::GetColor("#3399FF"));
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analytical_background_prediction->SetMarkerSize(0);
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analytical_background_prediction->Draw("e5");
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analyticaldrawonly->Draw("histo,same");
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functions[1]->Draw("same");
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TText *title3 = write_title("Analytical bg pred histo");
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title3->Draw();
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c4->cd(4);
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// c4->cd(4)->SetLogy(1);
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vector<float> ratio_binning;
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ratio_binning.push_back(0);
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ratio_binning.push_back(5);
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ratio_binning.push_back(10);
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ratio_binning.push_back(20);
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ratio_binning.push_back(50);
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// ratio_binning.push_back(60);
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/*
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ratio_binning.push_back(51);
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ratio_binning.push_back(52);
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ratio_binning.push_back(53);
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ratio_binning.push_back(54);
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ratio_binning.push_back(55);
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ratio_binning.push_back(56);
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ratio_binning.push_back(57);
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ratio_binning.push_back(58);
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ratio_binning.push_back(59);
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ratio_binning.push_back(60);
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// ratio_binning.push_back(70);*/
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// ratio_binning.push_back(80);
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// ratio_binning.push_back(90);
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ratio_binning.push_back(80);
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// ratio_binning.push_back(110);
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ratio_binning.push_back(500);
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TH1F *observedtb = allsamples.Draw("observedtb", datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
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TH1F *datapredictiontb = allsamples.Draw("datapredictiontb", "-"+datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets,data, luminosity);
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TH1F *datapredictiontbo = allsamples.Draw("datapredictiontbo", "-"+datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSOF&&cutnJets,data, luminosity);
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datapredictiontb->Add(datapredictiontbo,-1);
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TH1F *analytical_background_predictionb = allsamples.Draw("analytical_background_predictionb",datajzb, ratio_binning, "JZB [GeV]", "events", cutmass&&cutOSSF&&cutnJets&&"mll<2",data, luminosity);
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for(int i=0;i<=ratio_binning.size();i++) {
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analytical_background_predictionb->SetBinContent(i+1,functions[1]->Eval(analytical_background_predictionb->GetBinCenter(i)));
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analytical_background_predictionb->SetBinError(i+1,TMath::Sqrt(functions[1]->Eval(analytical_background_predictionb->GetBinCenter(i))));
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}
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TH1F *ratio = (TH1F*) observedtb->Clone();
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ratio->Divide(datapredictiontb);
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for (int i=0;i<=ratio_binning.size();i++) {
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dout << observedtb->GetBinLowEdge(i+1) << ";"<<observedtb->GetBinContent(i+1) << ";" << datapredictiontb->GetBinContent(i+1) << " --> " << ratio->GetBinContent(i+1) << "+/-" << ratio->GetBinError(i+1) << endl;
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}
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// ratio->Divide(datapredictiontb);
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// ratio->Divide(analytical_background_predictionb);
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// TGraphAsymmErrors *JZBratio= histRatio(observedtb,analytical_background_predictionb,data,ratio_binning);
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// ratio->Divide(analytical_background_prediction);
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// ratio->Divide(datapredictiont);
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// ratio->GetYaxis()->SetTitle("obs/pred");
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// JZBratio->Draw("AP");
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ratio->GetYaxis()->SetRangeUser(0,10);
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ratio->Draw();
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//analytical_background_predictionb->Draw();
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// JZBratio->SetTitle("");
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TText *title4 = write_title("Ratio of observed to predicted");
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title4->Draw();
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// CompleteSave(c4,"test/ttbar_discovery_dataprediction___analytical_function");
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CompleteSave(c4,"test/ttbar_discovery_dataprediction__analytical__new_binning_one_huge_bin_from_80");
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}
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vector<float> compute_one_upper_limit(float mceff,float mcefferr, int ibin, string mcjzb, bool doobserved=false) {
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float sigma95=-9.9,sigma95A=-9.9;
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int nuisancemodel=1;
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if(mceff<=0) {
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write_warning(__FUNCTION__,"Cannot compute upper limit in this configuration as the efficiency is negative:");
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dout << "mc efficiency=" << mceff << " +/- " << mcefferr;
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vector<float> sigmas;
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sigmas.push_back(-1);
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sigmas.push_back(-1);
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return sigmas;
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} else {
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dout << "Now calling : CL95(" << luminosity << "," << lumiuncert*luminosity << "," << mceff << "," << mcefferr << "," << Npred[ibin] << "," << Nprederr[ibin] << "," << Nobs[ibin] << "," << false << "," << nuisancemodel<< ") " << endl;
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sigma95 = CL95(luminosity, lumiuncert*luminosity, mceff, mcefferr, Npred[ibin], Nprederr[ibin], Nobs[ibin], false, nuisancemodel);
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if(doobserved) {
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dout << "Now calling : CLA(" << luminosity << "," << lumiuncert*luminosity << "," << mceff << "," << mcefferr << "," << Npred[ibin] << "," << Nprederr[ibin] << "," << nuisancemodel<< ") " << endl;
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sigma95A = CLA(luminosity, lumiuncert*luminosity, mceff, mcefferr, Npred[ibin], Nprederr[ibin], nuisancemodel);
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}
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vector<float> sigmas;
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sigmas.push_back(sigma95);
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sigmas.push_back(sigma95A);
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return sigmas;
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}
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}
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void compute_upper_limits_from_counting_experiment(vector<vector<float> > uncertainties,vector<float> jzbcuts, string mcjzb, bool doobserved) {
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dout << "Doing counting experiment ... " << endl;
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vector<vector<string> > limits;
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vector<vector<float> > vlimits;
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for(int isample=0;isample<signalsamples.collection.size();isample++) {
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vector<string> rows;
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vector<float> vrows;
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dout << "Considering sample " << signalsamples.collection[isample].samplename << endl;
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rows.push_back(signalsamples.collection[isample].samplename);
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for(int ibin=0;ibin<jzbcuts.size();ibin++) {
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dout << "_________________________________________________________________________________" << endl;
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float JZBcutat=uncertainties[isample*jzbcuts.size()+ibin][0];
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float mceff=uncertainties[isample*jzbcuts.size()+ibin][1];
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float staterr=uncertainties[isample*jzbcuts.size()+ibin][2];
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float systerr=uncertainties[isample*jzbcuts.size()+ibin][3];
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float toterr =uncertainties[isample*jzbcuts.size()+ibin][4];
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float observed,observederr,null,result;
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// fill_result_histos(observed,observederr, null,null,null,null,null,null,null,mcjzb,JZBcutat,14000,(int)5,result,(signalsamples.FindSample(signalsamples.collection[isample].filename)),signalsamples);
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// observed-=result;//this is the actual excess we see!
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// float expected=observed/luminosity;
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dout << "Sample: " << signalsamples.collection[isample].samplename << ", JZB>"<<JZBcutat<< " : " << mceff << " +/- " << staterr << " (stat) +/- " << systerr << " (syst) --> toterr = " << toterr << endl;
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vector<float> sigmas = compute_one_upper_limit(mceff,toterr,ibin,mcjzb,doobserved);
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if(doobserved) {
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// rows.push_back(any2string(sigmas[0])+";"+any2string(sigmas[1])+";"+"("+any2string(expected)+")");
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rows.push_back(any2string(sigmas[0])+";"+any2string(sigmas[1])+";"+"("+any2string(signalsamples.collection[isample].xs)+")");
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vrows.push_back(sigmas[0]);
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vrows.push_back(sigmas[1]);
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// vrows.push_back(expected);
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vrows.push_back(signalsamples.collection[isample].xs);
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}
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else {
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// rows.push_back(any2string(sigmas[0])+"("+any2string(expected)+")");
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rows.push_back(any2string(sigmas[0]));
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vrows.push_back(sigmas[0]);
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vrows.push_back(signalsamples.collection[isample].xs);
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// vrows.push_back(expected);
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}
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}//end of bin loop
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limits.push_back(rows);
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vlimits.push_back(vrows);
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}//end of sample loop
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dout << endl << endl << endl << "_________________________________________________________________________________________________" << endl << endl;
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dout << endl << endl << "PAS table 3: (notation: limit [95%CL])" << endl << endl;
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dout << "\t";
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for (int irow=0;irow<jzbcuts.size();irow++) {
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dout << jzbcuts[irow] << "\t";
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}
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dout << endl;
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for(int irow=0;irow<limits.size();irow++) {
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for(int ientry=0;ientry<limits[irow].size();ientry++) {
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if (limits[irow][ientry]>0) dout << limits[irow][ientry] << "\t";
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else dout << " (N/A) \t";
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}
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dout << endl;
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}
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if(!doobserved) {
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dout << endl << endl << "LIMITS: (Tex)" << endl;
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tout << "\\begin{tabular}{ | l | ";
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for (int irow=0;irow<jzbcuts.size();irow++) tout << " l |";
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tout << "} " << endl << " \\hline " << endl << "& \t ";
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for (int irow=0;irow<jzbcuts.size();irow++) {
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tout << "JZB $>$ " << jzbcuts[irow] << " GeV & \t ";
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}
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tout << " \\\\ \\hline " << endl;
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for(int irow=0;irow<limits.size();irow++) {
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tout << limits[irow][0] << " \t";
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for(int ientry=0;ientry<jzbcuts.size();ientry++) {
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if(vlimits[irow][2*ientry]>0) tout << " & " << Round(vlimits[irow][2*ientry],2) << " \t (" << Round(vlimits[irow][2*ientry] / vlimits[irow][2*ientry+1],3)<< "x \\sigma ) \t";
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else tout << " & ( N / A ) \t";
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// dout << Round(vlimits[irow][2*ientry],3) << " / " << Round(vlimits[irow][2*ientry+1],3)<< "\t";
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}
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tout << " \\\\ \\hline " << endl;
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}
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tout << "\\end{tabular}" << endl;
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}//do observed
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dout << endl << endl << "Final selection efficiencies with total statistical and systematic errors, and corresponding observed and expected upper limits (UL) on ($\\sigma\\times$ BR $\\times$ acceptance) for the LM4 and LM8 scenarios, in the different regions. The last column contains the predicted ($\\sigma \\times $BR$\\times$ acceptance) at NLO obtained from Monte Carlo simulation." << endl;
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dout << "Scenario \t Efficiency [%] \t Upper limits [pb] \t \\sigma [pb]" << endl;
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for(int icut=0;icut<jzbcuts.size();icut++) {
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dout << "Region with JZB>" << jzbcuts[icut] << endl;
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for(int isample=0;isample<signalsamples.collection.size();isample++) {
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dout << limits[isample][0] << "\t" << Round(100*uncertainties[isample*jzbcuts.size()+icut][1],3) << "+/-" << Round(100*uncertainties[isample*jzbcuts.size()+icut][2],3) << " (stat) +/- " << Round(100*uncertainties[isample*jzbcuts.size()+icut][3],3) << " (syst) \t" << Round((vlimits[isample][2*icut]),3) << "\t" << Round(vlimits[isample][2*icut+1],3) << endl;
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}
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dout << endl;
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}
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| 286 |
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| 287 |
write_warning(__FUNCTION__,"Still need to update the script");
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}
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| 289 |
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| 290 |
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| 291 |
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| 292 |
/********************************************************************** new : Limits using SHAPES ***********************************
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| 294 |
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| 295 |
SSSSSSSSSSSSSSS hhhhhhh
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| 296 |
SS:::::::::::::::Sh:::::h
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| 297 |
S:::::SSSSSS::::::Sh:::::h
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| 298 |
S:::::S SSSSSSSh:::::h
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| 299 |
S:::::S h::::h hhhhh aaaaaaaaaaaaa ppppp ppppppppp eeeeeeeeeeee ssssssssss
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| 300 |
S:::::S h::::hh:::::hhh a::::::::::::a p::::ppp:::::::::p ee::::::::::::ee ss::::::::::s
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| 301 |
S::::SSSS h::::::::::::::hh aaaaaaaaa:::::ap:::::::::::::::::p e::::::eeeee:::::eess:::::::::::::s
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| 302 |
SS::::::SSSSS h:::::::hhh::::::h a::::app::::::ppppp::::::pe::::::e e:::::es::::::ssss:::::s
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| 303 |
SSS::::::::SS h::::::h h::::::h aaaaaaa:::::a p:::::p p:::::pe:::::::eeeee::::::e s:::::s ssssss
|
| 304 |
SSSSSS::::S h:::::h h:::::h aa::::::::::::a p:::::p p:::::pe:::::::::::::::::e s::::::s
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| 305 |
S:::::S h:::::h h:::::h a::::aaaa::::::a p:::::p p:::::pe::::::eeeeeeeeeee s::::::s
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| 306 |
S:::::S h:::::h h:::::ha::::a a:::::a p:::::p p::::::pe:::::::e ssssss s:::::s
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| 307 |
SSSSSSS S:::::S h:::::h h:::::ha::::a a:::::a p:::::ppppp:::::::pe::::::::e s:::::ssss::::::s
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| 308 |
S::::::SSSSSS:::::S h:::::h h:::::ha:::::aaaa::::::a p::::::::::::::::p e::::::::eeeeeeee s::::::::::::::s
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| 309 |
S:::::::::::::::SS h:::::h h:::::h a::::::::::aa:::ap::::::::::::::pp ee:::::::::::::e s:::::::::::ss
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| 310 |
SSSSSSSSSSSSSSS hhhhhhh hhhhhhh aaaaaaaaaa aaaap::::::pppppppp eeeeeeeeeeeeee sssssssssss
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| 311 |
p:::::p
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| 312 |
p:::::p
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| 313 |
p:::::::p
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| 314 |
p:::::::p
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p:::::::p
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ppppppppp
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| 317 |
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| 318 |
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| 319 |
*********************************************************************** new : Limits using SHAPES ***********************************/
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|
| 322 |
void limit_shapes_for_systematic_effect(TFile *limfile, string identifier, string mcjzb, string datajzb, int JES,vector<float> binning, TCanvas *limcan) {
|
| 323 |
dout << "Creatig shape templates ... ";
|
| 324 |
if(identifier!="") dout << "for systematic called "<<identifier;
|
| 325 |
dout << endl;
|
| 326 |
int dataormc=mcwithsignal;//this is only for tests - for real life you want dataormc=data !!!
|
| 327 |
if(dataormc!=data) write_warning(__FUNCTION__,"WATCH OUT! Not using data for limits!!!! this is ok for tests, but not ok for anything official!");
|
| 328 |
|
| 329 |
TCut limitnJetcut;
|
| 330 |
if(JES==noJES) limitnJetcut=cutnJets;
|
| 331 |
else {
|
| 332 |
if(JES==JESdown) limitnJetcut=cutnJetsJESdown;
|
| 333 |
if(JES==JESup) limitnJetcut=cutnJetsJESup;
|
| 334 |
}
|
| 335 |
TH1F *ZOSSFP = allsamples.Draw("ZOSSFP",datajzb,binning, "JZB4limits", "events",cutmass&&cutOSSF&&limitnJetcut&&basiccut,dataormc,luminosity);
|
| 336 |
TH1F *ZOSOFP = allsamples.Draw("ZOSOFP",datajzb,binning, "JZB4limits", "events",cutmass&&cutOSOF&&limitnJetcut&&basiccut,dataormc,luminosity);
|
| 337 |
TH1F *ZOSSFN = allsamples.Draw("ZOSSFN","-"+datajzb,binning, "JZB4limits", "events",cutmass&&cutOSSF&&limitnJetcut&&basiccut,dataormc,luminosity);
|
| 338 |
TH1F *ZOSOFN = allsamples.Draw("ZOSOFN","-"+datajzb,binning, "JZB4limits", "events",cutmass&&cutOSOF&&limitnJetcut&&basiccut,dataormc,luminosity);
|
| 339 |
|
| 340 |
TH1F *SBOSSFP = allsamples.Draw("SBOSSFP",datajzb,binning, "JZB4limits", "events",cutOSSF&&limitnJetcut&&basiccut&&sidebandcut,dataormc,luminosity);
|
| 341 |
TH1F *SBOSOFP = allsamples.Draw("SBOSOFP",datajzb,binning, "JZB4limits", "events",cutOSOF&&limitnJetcut&&basiccut&&sidebandcut,dataormc,luminosity);
|
| 342 |
TH1F *SBOSSFN = allsamples.Draw("SBOSSFN","-"+datajzb,binning, "JZB4limits", "events",cutOSSF&&limitnJetcut&&basiccut&&sidebandcut,dataormc,luminosity);
|
| 343 |
TH1F *SBOSOFN = allsamples.Draw("SBOSOFN","-"+datajzb,binning, "JZB4limits", "events",cutOSOF&&limitnJetcut&&basiccut&&sidebandcut,dataormc,luminosity);
|
| 344 |
|
| 345 |
TH1F *LZOSSFP = allsamples.Draw("LZOSSFP",mcjzb,binning, "JZB4limits", "events",cutmass&&cutOSSF&&limitnJetcut&&basiccut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 346 |
TH1F *LZOSOFP = allsamples.Draw("LZOSOFP",mcjzb,binning, "JZB4limits", "events",cutmass&&cutOSOF&&limitnJetcut&&basiccut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 347 |
TH1F *LZOSSFN = allsamples.Draw("LZOSSFN","-"+mcjzb,binning, "JZB4limits", "events",cutmass&&cutOSSF&&limitnJetcut&&basiccut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 348 |
TH1F *LZOSOFN = allsamples.Draw("LZOSOFN","-"+mcjzb,binning, "JZB4limits", "events",cutmass&&cutOSOF&&limitnJetcut&&basiccut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 349 |
|
| 350 |
TH1F *LSBOSSFP = allsamples.Draw("LSBOSSFP",mcjzb,binning, "JZB4limits", "events",cutOSSF&&limitnJetcut&&basiccut&&sidebandcut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 351 |
TH1F *LSBOSOFP = allsamples.Draw("LSBOSOFP",mcjzb,binning, "JZB4limits", "events",cutOSOF&&limitnJetcut&&basiccut&&sidebandcut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 352 |
TH1F *LSBOSSFN = allsamples.Draw("LSBOSSFN","-"+mcjzb,binning, "JZB4limits", "events",cutOSSF&&limitnJetcut&&basiccut&&sidebandcut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 353 |
TH1F *LSBOSOFN = allsamples.Draw("LSBOSOFN","-"+mcjzb,binning, "JZB4limits", "events",cutOSOF&&limitnJetcut&&basiccut&&sidebandcut,mc,luminosity,allsamples.FindSample("LM4"));
|
| 354 |
|
| 355 |
string obsname="data_obs";
|
| 356 |
string predname="background";
|
| 357 |
string signalname="signal";
|
| 358 |
if(identifier!="") {
|
| 359 |
obsname=("data_"+identifier);
|
| 360 |
predname=("background_"+identifier);
|
| 361 |
signalname="signal_"+identifier;
|
| 362 |
}
|
| 363 |
|
| 364 |
TH1F *obs = (TH1F*)ZOSSFP->Clone();
|
| 365 |
obs->SetName(obsname.c_str());
|
| 366 |
obs->Write();
|
| 367 |
TH1F *pred = (TH1F*)ZOSSFN->Clone();
|
| 368 |
pred->Add(ZOSOFP,1.0/3);
|
| 369 |
pred->Add(ZOSOFN,-1.0/3);
|
| 370 |
pred->Add(SBOSSFP,1.0/3);
|
| 371 |
pred->Add(SBOSSFN,-1.0/3);
|
| 372 |
pred->Add(SBOSOFP,1.0/3);
|
| 373 |
pred->Add(SBOSOFN,-1.0/3);
|
| 374 |
pred->SetName(predname.c_str());
|
| 375 |
pred->Write();
|
| 376 |
|
| 377 |
// TH1F *Lobs = (TH1F*)LZOSSFP->Clone();
|
| 378 |
// TH1F *Lpred = (TH1F*)LZOSSFN->Clone();
|
| 379 |
|
| 380 |
TH1F *Lobs = new TH1F("Lobs","Lobs",binning.size()-1,&binning[0]);
|
| 381 |
TH1F *Lpred = new TH1F("Lpred","Lpred",binning.size()-1,&binning[0]);
|
| 382 |
Lobs->Add(LZOSSFP);
|
| 383 |
Lpred->Add(LZOSSFN);
|
| 384 |
Lpred->Add(LZOSOFP,1.0/3);
|
| 385 |
Lpred->Add(LZOSOFN,-1.0/3);
|
| 386 |
Lpred->Add(LSBOSSFP,1.0/3);
|
| 387 |
Lpred->Add(LSBOSSFN,-1.0/3);
|
| 388 |
Lpred->Add(LSBOSOFP,1.0/3);
|
| 389 |
Lpred->Add(LSBOSOFN,-1.0/3);
|
| 390 |
TH1F *signal = (TH1F*)Lobs->Clone();
|
| 391 |
signal->Add(Lpred,-1);
|
| 392 |
signal->SetName(signalname.c_str());
|
| 393 |
signal->Write();
|
| 394 |
|
| 395 |
delete Lobs;
|
| 396 |
delete Lpred;
|
| 397 |
|
| 398 |
delete ZOSSFP;
|
| 399 |
delete ZOSOFP;
|
| 400 |
delete ZOSSFN;
|
| 401 |
delete ZOSOFN;
|
| 402 |
|
| 403 |
delete SBOSSFP;
|
| 404 |
delete SBOSOFP;
|
| 405 |
delete SBOSSFN;
|
| 406 |
delete SBOSOFN;
|
| 407 |
|
| 408 |
delete LZOSSFP;
|
| 409 |
delete LZOSOFP;
|
| 410 |
delete LZOSSFN;
|
| 411 |
delete LZOSOFN;
|
| 412 |
|
| 413 |
delete LSBOSSFP;
|
| 414 |
delete LSBOSOFP;
|
| 415 |
delete LSBOSSFN;
|
| 416 |
delete LSBOSOFN;
|
| 417 |
|
| 418 |
}
|
| 419 |
|
| 420 |
void prepare_datacard(TFile *f) {
|
| 421 |
TH1F *dataob = (TH1F*)f->Get("data_obs");
|
| 422 |
TH1F *signal = (TH1F*)f->Get("signal");
|
| 423 |
TH1F *background = (TH1F*)f->Get("background");
|
| 424 |
|
| 425 |
ofstream datacard;
|
| 426 |
ensure_directory_exists(get_directory()+"/limits");
|
| 427 |
datacard.open ((get_directory()+"/limits/susydatacard.txt").c_str());
|
| 428 |
datacard << "Writing this to a file.\n";
|
| 429 |
datacard << "imax 1\n";
|
| 430 |
datacard << "jmax 1\n";
|
| 431 |
datacard << "kmax *\n";
|
| 432 |
datacard << "---------------\n";
|
| 433 |
datacard << "shapes * * limitfile.root $PROCESS $PROCESS_$SYSTEMATIC\n";
|
| 434 |
datacard << "---------------\n";
|
| 435 |
datacard << "bin 1\n";
|
| 436 |
datacard << "observation "<<dataob->Integral()<<"\n";
|
| 437 |
datacard << "------------------------------\n";
|
| 438 |
datacard << "bin 1 1\n";
|
| 439 |
datacard << "process signal background\n";
|
| 440 |
datacard << "process 0 1\n";
|
| 441 |
datacard << "rate "<<signal->Integral()<<" "<<background->Integral()<<"\n";
|
| 442 |
datacard << "--------------------------------\n";
|
| 443 |
datacard << "lumi lnN 1.10 1.0\n";
|
| 444 |
datacard << "bgnorm lnN 1.00 1.4 uncertainty on our prediction (40%)\n";
|
| 445 |
datacard << "JES shape 1 1 uncertainty on background shape and normalization\n";
|
| 446 |
datacard << "peak shape 1 1 uncertainty on signal resolution. Assume the histogram is a 2 sigma shift, \n";
|
| 447 |
datacard << "# so divide the unit gaussian by 2 before doing the interpolation\n";
|
| 448 |
datacard.close();
|
| 449 |
}
|
| 450 |
|
| 451 |
|
| 452 |
void prepare_limits(string mcjzb, string datajzb, float jzbpeakerrordata, float jzbpeakerrormc, vector<float> jzbbins) {
|
| 453 |
ensure_directory_exists(get_directory()+"/limits");
|
| 454 |
TFile *limfile = new TFile((get_directory()+"/limits/limitfile.root").c_str(),"RECREATE");
|
| 455 |
TCanvas *limcan = new TCanvas("limcan","Canvas for calculating limits");
|
| 456 |
limit_shapes_for_systematic_effect(limfile,"",mcjzb,datajzb,noJES,jzbbins,limcan);
|
| 457 |
limit_shapes_for_systematic_effect(limfile,"peakUp",newjzbexpression(mcjzb,jzbpeakerrormc),newjzbexpression(datajzb,jzbpeakerrordata),noJES,jzbbins,limcan);
|
| 458 |
limit_shapes_for_systematic_effect(limfile,"peakDown",newjzbexpression(mcjzb,-jzbpeakerrormc),newjzbexpression(datajzb,-jzbpeakerrordata),noJES,jzbbins,limcan);
|
| 459 |
limit_shapes_for_systematic_effect(limfile,"JESUp",mcjzb,datajzb,JESup,jzbbins,limcan);
|
| 460 |
limit_shapes_for_systematic_effect(limfile,"JESDown",mcjzb,datajzb,JESdown,jzbbins,limcan);
|
| 461 |
|
| 462 |
prepare_datacard(limfile);
|
| 463 |
limfile->Close();
|
| 464 |
write_info("prepare_limits","limitfile.root and datacard.txt have been generated. You can now use them to calculate limits!");
|
| 465 |
|
| 466 |
}
|
