Example #1
0
void drawLabels(){

  // "Hadron Gas"
  TLatex *xHad1 = new TLatex(0.11, 0.13, "Hadron");
  TLatex *xHad2 = new TLatex(0.15, 0.085, "Gas");
  xHad1->SetTextSize(0.04);
  xHad2->SetTextSize(0.04);
  if(iColor)xHad1->SetTextColor(4);
  if(iColor)xHad2->SetTextColor(4);
  xHad1->Draw();
  xHad2->Draw();

  //"Quark Gloun Plasma"
  TLatex *xQGP1 = new TLatex(0.55, 0.8, "Quark Gluon");
  TLatex *xQGP2 = new TLatex(0.62, 0.755, "Plasma");
  xQGP1->SetTextSize(0.04);
  xQGP2->SetTextSize(0.04);
  if(iColor)xQGP1->SetTextColor(4);
  if(iColor)xQGP2->SetTextColor(4);
  xQGP1->Draw();
  xQGP2->Draw();

  //"Early Universe"
  TArrow *aUniv = new TArrow(.025, 0.95,.025, 0.45,0.03,"|>");
  aUniv->SetLineWidth(2);
  if(iColor)aUniv->SetLineColor(2);
  if(iColor)aUniv->SetFillColor(2);
  aUniv->Draw();
  TLatex *xUniv = new TLatex(0.075, 0.58, "Early Universe");
  xUniv->SetTextSize(0.04);
  xUniv->SetTextAngle(90);
  if(iColor)xUniv->SetTextColor(2);
  xUniv->Draw();
  
  //"Neutron Stars"
  TArrow *aNeut = new TArrow(.65, .05 ,.99, 0.075,0.03,"|>");
  aNeut->SetLineWidth(2);
  if(iColor)aNeut->SetLineColor(8);
  if(iColor)aNeut->SetFillColor(8);
  aNeut->Draw();
  TLatex *xNeut = new TLatex(0.735, 0.08, "Neutron Stars");
  xNeut->SetTextSize(0.04);
  xNeut->SetTextAngle(5);
  if(iColor)xNeut->SetTextColor(8);
  xNeut->Draw();

  //"Critical Point"
  TLatex *xCrit1 = new TLatex(0.2, 0.585, "Critical");
  TLatex *xCrit2 = new TLatex(0.225, 0.54, "Point");
  xCrit1->SetTextSize(0.04);
  xCrit2->SetTextSize(0.04);
  xCrit1->Draw();
  xCrit2->Draw();
}
Example #2
0
void drawEventRPhi(double vxlb, double vylb, double vxl0, double vyl0, double pmu1, double phimu1, double pmu2, double phimu2, double ppr, double phipr, double ppi, double phipi, int colors = 0)
{
    Color_t colMu1(1), colMu2(1), colPr(1), colPi(1), colL0(1), colLb(1);
    switch(colors)
    {
	case 0:
	    colLb=1; colL0=2; colMu1=2; colMu2=2; colPr=3; colPi=4; break;
	case 1:
	    colLb=11; colL0=50; colMu1=50; colMu2=50; colPr=8; colPi=9; break;
    }
    // draw the vertices
    TMarker *m;
    const double xlb = vxlb;
    const double ylb = vylb;
    m = new TMarker(xlb,ylb,7);
    m->SetMarkerColor(colLb);
    m->Draw();
    const double xl0 = vxl0;
    const double yl0 = vyl0;
    m = new TMarker(xl0,yl0,7);
    m->SetMarkerColor(colL0);
    m->Draw();
    // draw the l0 flight line
    TLine *l;
    l = new TLine(vxlb,vylb,vxl0,vyl0);
    l->SetLineColor(colL0);
    l->SetLineStyle(2);
    l->Draw();
    // draw the muons
    TArrow *a;
    const double xmu1 = xlb + scalemu * pmu1 * TMath::Cos(phimu1);
    const double ymu1 = ylb + scalemu * pmu1 * TMath::Sin(phimu1);
    a = new TArrow(xlb,ylb,xmu1,ymu1,.01,">");
    a->SetLineColor(colMu1);
    a->Draw();
    const double xmu2 = xlb + scalemu * pmu2 * TMath::Cos(phimu2);
    const double ymu2 = ylb + scalemu * pmu2 * TMath::Sin(phimu2);
    a = new TArrow(xlb,ylb,xmu2,ymu2,.01,">");
    a->SetLineColor(colMu2);
    a->Draw();
    // draw the p and pi
    const double xpr = xl0 + scalepr * ppr * TMath::Cos(phipr);
    const double ypr = yl0 + scalepr * ppr * TMath::Sin(phipr);
    a = new TArrow(xl0,yl0,xpr,ypr,.01,">");
    a->SetLineColor(colPr);
    a->Draw();
    const double xpi = xl0 + scalepi * ppi * TMath::Cos(phipi);
    const double ypi = yl0 + scalepi * ppi * TMath::Sin(phipi);
    a = new TArrow(xl0,yl0,xpi,ypi,.01,">");
    a->SetLineColor(colPi);
    a->Draw();
}
Example #3
0
void drawArrow(Double_t u, Double_t v, Double_t du, Double_t due, Double_t dv, Double_t dve){

  if ( du+dv ){ 

    Double_t arrowLengthSqr = du*du+dv*dv;
    Double_t relErrorOnArrowLength = sqrt(du*du*due*due+dv*dv*dve*dve)/arrowLengthSqr;
    
    Int_t color = 0; //-10, -9, -7, -4, 0
    Int_t lwid = 2;
    if ( relErrorOnArrowLength>0.5 ) color=kBlue-9;
    if ( relErrorOnArrowLength<0.4 ) color=kBlue-7;
    if ( relErrorOnArrowLength<0.3 ) color=kBlue-4;
    if ( relErrorOnArrowLength<0.2 ) color=kBlue;
    //    if ( relErrorOnArrowLength<0.1 ) color=kBlue;
    if ( relErrorOnArrowLength<0.1 ) {
      color=kBlue;
      lwid = 3;
    }
   if ( relErrorOnArrowLength<0.05 ) {
      color=kBlue;
      lwid = 4;
    }
   
   Double_t arrowSize = 0.006;

    TArrow * ar = new TArrow(u-0.5*du,v-0.5*dv,u+0.5*du,v+0.5*dv,arrowSize,"|>");
    ar->SetLineWidth(lwid);
    ar->SetFillColor(color);
    ar->SetLineColor(color);
    ar->Draw();
  }

}
Example #4
0
void Interface::dessinVent(double vent)
{
    if(vent != 0){
        TArrow *vecteurVent = new TArrow(245,290,245 + 5*vent,290);
        vecteurVent->SetLineColor(kBlack);
        vecteurVent->Draw();
    }

}
Example #5
0
void
HHV4Vector::Draw(Int_t color, Int_t style) const
{  // draw particle for event display in x-y view
  TArrow *Ar = new TArrow(0, 0, Px(), Py(), 0.001, "|>");
  Ar->SetLineColor(color);
  Ar->SetFillColor(color);
  Ar->SetLineWidth(3);
  Ar->SetLineStyle(style);
  Ar->Draw();
}
Example #6
0
// draw a horizontal arrow of a certain length in pad coordinates at xy in NDC
// returns the new x in NDC
double drawArrowLength(TPad* pad, double x, double y, double length, Color_t color = 1)
{
    const double x1 = NDCtoUserX(pad,x);
    const double y1 = NDCtoUserY(pad,y);
    const double x2 = x1 + length;
    const double y2 = y1;
    TArrow *a = new TArrow(x1,y1,x2,y2,.01,">");
    a->SetLineColor(color);
    a->Draw();
    //pad->Update();
    cout << "Arrow: " << length << " " << pad->GetX2()-pad->GetX1() << endl;
    return x + (length/(pad->GetX2()-pad->GetX1()));
}
void draw_synapse(Double_t cx1, Double_t cy1, Double_t cx2, Double_t cy2,
                  Double_t  rad1, Double_t rad2, Double_t weightNormed)
{
   const Double_t TIP_SIZE   = 0.01;
   const Double_t MAX_WEIGHT = 8;
   const Double_t MAX_COLOR  = 100;  // red
   const Double_t MIN_COLOR  = 60;   // blue

   if (weightNormed == 0) return;

   //   gStyle->SetPalette(100, NULL);

   TArrow *arrow = new TArrow(cx1+rad1, cy1, cx2-rad2, cy2, TIP_SIZE, ">");
   arrow->SetFillColor(1);
   arrow->SetFillStyle(1001);
   arrow->SetLineWidth((Int_t)(TMath::Abs(weightNormed)*MAX_WEIGHT+0.5));
   arrow->SetLineColor((Int_t)((weightNormed+1.0)/2.0*(MAX_COLOR-MIN_COLOR)+MIN_COLOR+0.5));
   arrow->Draw();
}
Example #8
0
void EvtSel_Q2Pmiss(){

  Styles style2; style2.setPadsStyle(2); style2.applyStyle();

  TString NameTrees[3] = {"AWG82/ntuples/small/RAll_RunAll.root", 
			  "AWG82/ntuples/small/uds_RunAll.root", "AWG82/ntuples/small/ccbar_RunAll.root"};
  TChain gen("ntp1"), cont("ntp1");
  gen.Add(NameTrees[0]);
  for(int t=1; t<3; t++) cont.Add(NameTrees[t]);
  double totMCB = 0, totuds = 0, totccbar = 0, totdata = 0, totOffdata = 0;
  getNumberB(NameTrees[0], "All", totMCB, totdata, totuds, totccbar, totOffdata);
  double wuds = totMCB/totuds*2.09/1.05;     

  TH1F *hCount = new TH1F("hCount","",100,-4,12);
  gen.Draw("candM2>>hCount","weight");
  double nTotal = hCount->Integral();
  cont.Draw("candM2>>hCount","weight");
  nTotal += hCount->Integral()*wuds;

  TLine line; line.SetLineStyle(2); line.SetLineColor(28); line.SetLineWidth(2);
  TArrow arrow; arrow.SetLineColor(28); arrow.SetFillColor(28); arrow.SetLineWidth(2);
  TCanvas can("can","Pmiss and q2 cuts");
  can.Divide(2,1); TPad *cPad = (TPad *)can.cd(1);
  int bins[] = {42,40}, colors[2][4] = {{8,4,1,3},{8,2,4,1}};
  double xrange[2][2] = {{0,4.2},{-3,13}}, yield[2][4], maxi[] = {-99,-99};
  TString Variable[] = {"candPMiss","candQ2"};
  TString labels[2][4] = {{"Signal (", "Normaliz. (","Had. bkg. (",""},
 			  {"Signal (", "D l #nu (", "D* l #nu (", "Bkg. ("}};
//   TString labels[2][4] = {{"Signal", "Normaliz.","Had. Bkg.",""},
// 			  {"Signal", "D l #nu", "D* l #nu", "Bkg."}};
  TString cuts[2][4] = {{"(candType<3&&MCType>4&&MCType<7||candType>2&&MCType>10&&MCType<13)*weight",
			 "(candType<3&&MCType>0&&MCType<5||candType>2&&MCType>6&&MCType<11)*weight",
			 "(MCType==0&&MCCombmode==12)*weight", ""},
			{"(candType<3&&MCType>4&&MCType<7||candType>2&&MCType>10&&MCType<13)*weight",
			 "(candType<3&&(MCType==1||MCType==3)||candType>2&&(MCType==7||MCType==9))*weight",
			 "(candType<3&&(MCType==2||MCType==4)||candType>2&&(MCType==8||MCType==10))*weight",
			 "(!(candType<3&&MCType>0&&MCType<7||candType>2&&MCType>6&&MCType<13))*weight"}};
  double legW = 0.4, legH = 0.225;
  double legX = 1-style2.PadRightMargin-0.02, legY = 1-style2.PadTopMargin-0.02;
  TLegend *leg[2];
  leg[0] = new TLegend(legX-legW, legY-legH, legX, legY);
  legW = 0.24; legH = 0.285; legX = 0.47;
  leg[1] = new TLegend(legX-legW, legY-legH, legX, legY);
  TH1F* h[2][4];
  for(int pad=0; pad<2; pad++){
    leg[pad]->SetTextSize(style2.LabelSize); leg[pad]->SetFillColor(0); 
    leg[pad]->SetTextFont(style2.nFont);  leg[pad]->SetBorderSize(0);
    for(int i=0; i<4; i++) {
      if(pad==0 && i==3) continue;
      TString hname = "h"; hname += pad; hname += i;
      h[pad][i] = new TH1F(hname,"",bins[pad],xrange[pad][0],xrange[pad][1]);
      h[pad][i]->SetLineWidth(2);  h[pad][i]->SetLineColor(colors[pad][i]);
      TString vari = Variable[pad]; vari += ">>"; vari += hname;
      gen.Draw(vari,cuts[pad][i]);
      if(i==3){
	hname = "hCont"; hname += pad; hname += i;
	TH1F *hCont = new TH1F(hname,"",bins[pad],xrange[pad][0],xrange[pad][1]);
	TString vari = Variable[pad]; vari += ">>"; vari += hname;
	cont.Draw(vari,cuts[pad][i]);
	hCont->Scale(wuds);
	h[pad][i]->Add(hCont);
	hCont->Delete();
      }
      yield[pad][i] = h[pad][i]->Integral();
      h[pad][i]->Scale(1000/h[pad][i]->Integral());
      if(h[pad][i]->GetMaximum()>maxi[pad]) maxi[pad] = h[pad][i]->GetMaximum();
      labels[pad][i] += RoundNumber(yield[pad][i]*100,0,nTotal); labels[pad][i] += "%)";
      leg[pad]->AddEntry(h[pad][i],labels[pad][i]);
    }
    h[pad][0]->SetMaximum(maxi[pad]*1.22);
  }
  h[0][0]->Draw();
  style2.fixYAxis(h[0][0],cPad);
  style2.setTitles(h[0][0],"|p_{miss}| (GeV)","Entries/(100 MeV)","a)");
  h[0][1]->Draw("same");h[0][2]->Draw("same");
  leg[0]->Draw();
  line.DrawLine(0.2,h[0][0]->GetMinimum(), 0.2,maxi[0]/1.45);
  arrow.DrawArrow(0.2,maxi[0]/1.65,0.5,maxi[0]/1.65,0.01,"|>");


  cPad = (TPad *)can.cd(2);
  h[1][0]->Draw();
  style2.fixYAxis(h[1][0],cPad);
  style2.setTitles(h[1][0],"q^{2} (GeV^{2})","Entries/(0.4 GeV^{2})","b)");
  h[1][1]->Draw("same"); h[1][2]->Draw("same"); h[1][3]->Draw("same");
  leg[1]->Draw();
  line.DrawLine(4,h[1][0]->GetMinimum(), 4,maxi[1]/1.45);
  arrow.DrawArrow(4,maxi[1]/1.65,5.4,maxi[1]/1.65,0.01,"|>");

  TString pName = "public_html/EvtSel_Q2Pmiss.eps"; 
  can.SaveAs(pName);
  for(int pad=0; pad<2; pad++){
    leg[pad]->Delete();
    for(int i=0; i<4; i++){
      if(pad==0 && i==3) continue;
      h[pad][i]->Delete();
    }
  }
  hCount->Delete();
}
Example #9
0
void drawEventZR(double vrlb, double vzlb, double vrl0, double vzl0, double pmu1, double etamu1, double pmu2, double etamu2, double ppr, double etapr, double ppi, double etapi, int colors = 0)
{
    Color_t colMu1(1), colMu2(1), colPr(1), colPi(1), colL0(1), colLb(1);
    switch(colors)
    {
	case 0:
	    colLb=1; colL0=2; colMu1=2; colMu2=2; colPr=3; colPi=4; break;
	case 1:
	    colLb=11; colL0=50; colMu1=50; colMu2=50; colPr=8; colPi=9; break;
    }
    cout << etamu1 << " " << etamu2 << " " << etapr << " " << etapi << endl;
    const double thetamu1 = 2*TMath::ATan(TMath::Exp(-etamu1));
    const double thetamu2 = 2*TMath::ATan(TMath::Exp(-etamu2));
    const double thetapr = 2*TMath::ATan(TMath::Exp(-etapr));
    const double thetapi = 2*TMath::ATan(TMath::Exp(-etapi));
    //const double thetamu1 = 2*TMath::ATan(TMath::Exp(-TMath::Abs(etamu1)))*sign(etamu1);
    //const double thetamu2 = 2*TMath::ATan(TMath::Exp(-TMath::Abs(etamu2)))*sign(etamu2);
    //const double thetapr = 2*TMath::ATan(TMath::Exp(-TMath::Abs(etapr)))*sign(etapr);
    //const double thetapi = 2*TMath::ATan(TMath::Exp(-TMath::Abs(etapi)))*sign(etapi);
    // draw the vertices
    TMarker *m;
    const double xlb = vzlb;
    const double ylb = vrlb;
    m = new TMarker(xlb,ylb,7);
    m->SetMarkerColor(colLb);
    m->Draw();
    const double xl0 = vzl0;
    const double yl0 = vrl0;
    m = new TMarker(xl0,yl0,7);
    m->SetMarkerColor(colL0);
    m->Draw();
    // draw the l0 flight line
    TLine *l;
    l = new TLine(vzlb,vrlb,vzl0,vrl0);
    l->SetLineColor(colL0);
    l->SetLineStyle(2);
    l->Draw();
    // draw the muons
    TArrow *a;
    const double xmu1 = xlb + scalemu * pmu1 * TMath::Cos(thetamu1);
    const double ymu1 = ylb + scalemu * pmu1 * TMath::Sin(thetamu1);
    a = new TArrow(xlb,ylb,xmu1,ymu1,.01,">");
    a->SetLineColor(colMu1);
    a->Draw();
    const double xmu2 = xlb + scalemu * pmu2 * TMath::Cos(thetamu2);
    const double ymu2 = ylb + scalemu * pmu2 * TMath::Sin(thetamu2);
    a = new TArrow(xlb,ylb,xmu2,ymu2,.01,">");
    a->SetLineColor(colMu2);
    a->Draw();
    // draw the p and pi
    const double xpr = xl0 + scalepr * ppr * TMath::Cos(thetapr);
    const double ypr = yl0 + scalepr * ppr * TMath::Sin(thetapr);
    a = new TArrow(xl0,yl0,xpr,ypr,.01,">");
    a->SetLineColor(colPr);
    a->Draw();
    const double xpi = xl0 + scalepi * ppi * TMath::Cos(thetapi);
    const double ypi = yl0 + scalepi * ppi * TMath::Sin(thetapi);
    a = new TArrow(xl0,yl0,xpi,ypi,.01,">");
    a->SetLineColor(colPi);
    a->Draw();
}
Example #10
0
void ClassTree()
{

   TCanvas *ClassTree = new TCanvas("ClassTree", "",186,135,594,449);
   ClassTree->SetHighLightColor(2);
   ClassTree->Range(0,5,20,20);
   ClassTree->SetFillColor(33);
   ClassTree->SetBorderSize(2);
   TLine *line = new TLine(0.5,18.15,4.4,18.15);
   line->Draw();
   line = new TLine(4.4,17.725,4.4,18.575);
   line->Draw();
   
   TPaveLabel *pl = new TPaveLabel(1,17.895,4.205,18.405,"TArray","br");
   pl->SetFillColor(30);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(0.5,16.875,1,16.875);
   line->Draw();
   
   pl = new TPaveLabel(1,16.62,4.205,17.13,"TAttFill","br");
   pl->SetFillColor(30);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(0.5,16.025,1,16.025);
   line->Draw();
   
   pl = new TPaveLabel(1,15.77,4.205,16.28,"TAttLine","br");
   pl->SetFillColor(30);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(0.5,15.175,1,15.175);
   line->Draw();
   
   pl = new TPaveLabel(1,14.92,4.205,15.43,"TAttMarker","br");
   pl->SetFillColor(30);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(0.5,9.775,4.4,9.775);
   line->Draw();
   line = new TLine(4.4,7.65,4.4,12.325);
   line->Draw();
   
   pl = new TPaveLabel(1,9.52,4.205,10.03,"TObject","br");
   pl->SetFillColor(5);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(4.4,12.325,4.9,12.325);
   line->Draw();
   
   pl = new TPaveLabel(4.9,12.07,8.105,12.58,"AliArrayI","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(4.4,11.475,4.9,11.475);
   line->Draw();
   
   pl = new TPaveLabel(4.9,11.22,8.105,11.73,"AliArrayS","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(4.4,18.575,4.9,18.575);
   line->Draw();
   
   pl = new TPaveLabel(4.9,18.32,8.105,18.83,"TArrayI","br");
   pl->SetFillColor(30);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(4.4,17.725,4.9,17.725);
   line->Draw();
   
   pl = new TPaveLabel(4.9,17.47,8.105,17.98,"TArrayS","br");
   pl->SetFillColor(30);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(4.4,10.2,8.3,10.2);
   line->Draw();
   
   pl = new TPaveLabel(4.9,9.945,8.105,10.455,"TCollection","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(4.4,7.65,8.3,7.65);
   line->Draw();
   line = new TLine(8.3,6.8,8.3,8.075);
   line->Draw();
   
   pl = new TPaveLabel(4.9,7.395,8.105,7.905,"TNamed","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(8.3,8.075,12.2,8.075);
   line->Draw();
   
   pl = new TPaveLabel(8.8,7.82,12.005,8.33,"AliSegmentArray","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(8.3,10.2,12.2,10.2);
   line->Draw();
   
   pl = new TPaveLabel(8.8,9.945,12.005,10.455,"TSeqCollection","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(8.3,6.8,8.8,6.8);
   line->Draw();
   
   pl = new TPaveLabel(8.8,6.545,12.005,7.055,"TTree","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(12.2,8.075,12.7,8.075);
   line->Draw();
   
   pl = new TPaveLabel(12.7,7.82,15.905,8.33,"AliTPCClustersArray","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(12.2,10.2,16.1,10.2);
   line->Draw();
   
   pl = new TPaveLabel(12.7,9.945,15.905,10.455,"TObjArray","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   line = new TLine(16.1,10.2,16.6,10.2);
   line->Draw();
   
   pl = new TPaveLabel(16.6,9.945,19.805,10.455,"TClonesArray","br");
   pl->SetFillColor(18);
   pl->SetTextSize(0.9);
   pl->Draw();
   
   pl = new TPaveLabel(0.1,19.1,18.2,19.9,"*AliSegmet:*AliSegmentArray:*AliArrayI:*AliArrayS:TTree:*TObjArray","br");
   pl->SetFillColor(42);
   pl->SetTextSize(0.7);
   pl->Draw();
   line = new TLine(11.4041,6.8,14.3025,10.2);
   line->SetLineColor(6);
   line->SetLineStyle(3);
   line->Draw();
   line = new TLine(11.4842,6.8,14.3025,10.2);
   line->SetLineColor(6);
   line->SetLineStyle(3);
   line->Draw();
   line = new TLine(6.5025,12.325,6.5025,18.575);
   line->SetLineColor(4);
   line->SetLineStyle(2);
   line->Draw();
   line = new TLine(6.5025,11.475,6.5025,17.725);
   line->SetLineColor(4);
   line->SetLineStyle(2);
   line->Draw();
   line = new TLine(10.4025,6.8,2.6025,16.025);
   line->SetLineColor(4);
   line->SetLineStyle(2);
   line->Draw();
   line = new TLine(10.4025,6.8,2.6025,16.875);
   line->SetLineColor(4);
   line->SetLineStyle(2);
   line->Draw();
   line = new TLine(10.4025,6.8,2.6025,15.175);
   line->SetLineColor(4);
   line->SetLineStyle(2);
   line->Draw();
   TArrow *arrow = new TArrow(5.43417,10.2,6.5025,10.2,0.008,"|>");
   arrow->SetFillColor(2);
   arrow->SetFillStyle(1001);
   arrow->SetLineColor(2);
   arrow->Draw();
   arrow = new TArrow(6.85861,10.2,2.6025,9.775,0.008,"|>");
   arrow->SetFillColor(2);
   arrow->SetFillStyle(1001);
   arrow->SetLineColor(2);
   arrow->Draw();
   arrow = new TArrow(9.60125,8.075,14.3025,10.2,0.008,"|>");
   arrow->SetFillColor(2);
   arrow->SetFillStyle(1001);
   arrow->SetLineColor(2);
   arrow->Draw();
   arrow = new TArrow(10.1354,8.075,6.5025,12.325,0.008,"|>");
   arrow->SetFillColor(2);
   arrow->SetFillStyle(1001);
   arrow->SetLineColor(2);
   arrow->Draw();
   arrow = new TArrow(11.2037,8.075,10.4025,6.8,0.008,"|>");
   arrow->SetFillColor(2);
   arrow->SetFillStyle(1001);
   arrow->SetLineColor(2);
   arrow->Draw();
   arrow = new TArrow(13.9019,10.2,2.6025,9.775,0.008,"|>");
   arrow->SetFillColor(2);
   arrow->SetFillStyle(1001);
   arrow->SetLineColor(2);
   arrow->Draw();
   arrow = new TArrow(19.2708,10.2,14.3025,10.2,0.008,"|>");
   arrow->SetFillColor(2);
   arrow->SetFillStyle(1001);
   arrow->SetLineColor(2);
   arrow->Draw();
   ClassTree->Modified();
   ClassTree->cd();
}
Example #11
0
void toyMC(int nsteps = 1e6) {
    
    Float_t LA = 9.2;
    Float_t LB = 10.3;
    
    Float_t SF = 492./LB;
    Float_t eSF = TMath::Sqrt(23.*23.+19.7*19.7)/LB;
//     Float_t OF = 358./LA;
//     Float_t eOF = 27./LA;
    Float_t OF = 358./LB;
    Float_t eOF = 31./LB;
    
    Float_t SigB = 188.+238-414;
    
    
    TH1F* hSig = new TH1F("hSig ; SF-R_{SF/OF}#timesOF ; ","Signal component",600,-100.,500.);
    
    hSig->SetLineColor(kRed+2);
    
    TRandom3* ran = new TRandom3();
    
    for ( int i=0; i<nsteps; ++i ) {
        
        Float_t nBSF = ran->Gaus(SF*LB,eSF*LB);
        Float_t nBOF = ran->Gaus(OF*LB,eOF*LB);
        Float_t rsfof = ran->Gaus(1.0,0.05);
        
        hSig->Fill(nBSF-nBOF*rsfof);
        
    }
    
    
    TCanvas* mycan = new TCanvas("mycan","",100,10,900,600);
    mycan->SetLogy();
    TH1F* hSigNorm = hSig->DrawNormalized("");
    hSigNorm->SetMinimum(1e-5);
    hSigNorm->Draw();
    
    // Find 95% CL range
    float integral = 0;
    int binStart = -1;
    while ( integral <= 0.025 ) {
        ++binStart;
        integral += hSigNorm->GetBinContent(binStart);
    }
    std::cout << integral << " up to " << hSigNorm->GetBinCenter(binStart) << std::endl;
    integral = 0;
    int binEnd = hSigNorm->GetNbinsX()+2;
    while ( integral <= 0.025 ) {
        --binEnd;
        integral += hSigNorm->GetBinContent(binEnd);
    }
    std::cout << integral << " up to " << hSigNorm->GetBinCenter(binEnd) << std::endl;
    
    // Draw 95% CL
    TBox* range95 = new TBox(hSigNorm->GetBinCenter(binStart),hSigNorm->GetMinimum(),hSigNorm->GetBinCenter(binEnd),1.2*hSigNorm->GetMaximum());
    range95->SetFillColor(kBlue-9);
    range95->SetFillStyle(1000);
    range95->SetLineColor(range95->GetFillColor());
    range95->Draw();
    
    hSigNorm->SetTitle("hSigNorm; \"S\" #equiv SF - R_{SF/OF}#timesOF ; pdf");
    hSigNorm->Draw("same");
    
    std::cout << "Integrating from 0 to " << SigB << ": " << std::endl;
    std::cout << hSigNorm->Integral(0,hSigNorm->FindBin(SigB)) <<std::endl;
    
    TLegend* legend = new TLegend(0.6,0.7,0.95,0.9,"","brNDC");
    legend->SetBorderSize(0);
    legend->AddEntry(hSigNorm,"Expected \"S\" for block B","l");
    legend->AddEntry(range95,"95% region","f");
    legend->Draw();

    mycan->RedrawAxis();
    mycan->SaveAs("toyMCexp.pdf");

    TArrow* a = new TArrow(SigB,hSigNorm->GetMaximum(),SigB,hSigNorm->GetMinimum()*1.1,0.02);
    a->SetLineColor(kBlue+2);
    a->Draw();


    TLegend* legend2 = new TLegend(0.6,0.6,0.95,0.7,"","brNDC");
    legend2->SetBorderSize(0);
    legend2->AddEntry(a,"Observed (p-value 0.6%)","l");
    legend2->Draw();
    

    mycan->SaveAs("toyMC.pdf");
    
}
void RoutePlot(){
gStyle->SetTitleX(0.21);
gStyle->SetTitleY(0.98);

  const int minIteration=0;
  const int Iteration=10;
  int nParticles=20;
  
  TGraph* emptygraph = new TGraph(1);
  emptygraph->SetPoint(0,1000,0.005);
  
  std::vector< std::vector<TGraph*> > graphs;
  std::vector<TPolyLine*> lines;
  std::vector<TGraph*> FirstPoints;
  std::vector<TGraph*> LastPoints;
  std::vector< std::vector<TArrow*> > arrows;
  

  //get max an min ROC
  Int_t bestPartIteration[Iteration];
  Double_t bestROCIteration[Iteration];
  for(int o=0;o<Iteration;o++){bestROCIteration[o]=0.0;}
  Double_t maxROC=0.0;
  Double_t minROC=1.0;
  Double_t bestROCGlobal=0.0;
  for(int i=0;i<nParticles;i++){
//      if(!(i==1 or i==13 or i==5 or i==6 or i==8 or i==4 or i==14 or i==18))continue;

//     std::cout<<i<<std::endl;
    std::string buffer="";
    std::stringstream buffer2;
    buffer2<<i;
//     std::cout<<buffer2.str()<<" "<<buffer2.str()<<std::endl;
//     buffer2>>buffer;
    std::string filename="../Particles_long/Particle";
    filename+=buffer2.str();
    filename+="/ParticleRoute.txt";
//     std::cout<<filename.c_str()<<std::endl;
    std::ifstream inputfile(filename.c_str());
//     std::ifstream inputfile("Particles_long/Particle1/ParticleRoute.txt");

    int k=0;
    double nTrees=0.0;
    double shrinkage=0.0;
    double bagging=0.0;
    double cuts=0.0;
    double ROC=0.0;
    double KS=0.0;
    double depth=0.0;
    bool readline=true;
    while(readline){
      inputfile>>ROC;
      inputfile>>KS;
      inputfile>>nTrees;
      inputfile>>shrinkage;
      inputfile>>bagging;
      inputfile>>cuts;
//       inputfile>>depth;
      std::string dump="";
      int j=0;
      do{
        inputfile>>dump;
//         std::cout<<dump<<std::endl;
        j++;
//         if(dump=="--Next--")std::cout<<"here"<<std::endl;
//         if(dump=="--Next--\n")std::cout<<"too"<<std::endl;
//         if(dump=="")std::cout<<"never"<<std::endl;

      }while(dump!="--Next--" and dump!="--Next--\n" and dump!="");
//       std::cout<<"Data "<<nTrees<<" "<<shrinkage<<" "<<ROC<<std::endl;
      if(dump!="" and k>=minIteration){
        if(ROC>maxROC)maxROC=ROC;
        if(ROC<minROC and ROC!=0)minROC=ROC;
      
      }
      k++;
//      inputfile>>dump;
      if(inputfile.eof() or dump=="" or k==Iteration)readline=false;
    }

    inputfile.close();
    std::cout<<"NPoints: "<<k<<std::endl;
  }
  std::cout<<"ROC range "<<minROC<<"  "<<maxROC<<std::endl;
  
  //get marker scaling;
  Double_t maxSize=2.4;
  Double_t minSize=0.3;
  minROC=0.74;
  Double_t m = (maxSize-minSize)/(maxROC-minROC);
  Double_t abschnitt = maxSize-m*maxROC;
  std::cout<<m<<" "<<abschnitt<<std::endl;
  std::cout<<minSize<<" "<<maxSize<<std::endl;

      
  //read points
  for(int i=0;i<nParticles;i++){
      if(!(i==1 or i==2 or i==4 or i==10 or i==13 or i==14 or i==17))continue;

    std::cout<<i<<std::endl;
    std::string buffer="";
    std::stringstream buffer2;
    buffer2<<i;
//     std::cout<<buffer2.str()<<" "<<buffer2.str()<<std::endl;
//     buffer2>>buffer;
    std::string filename="../Particles_long/Particle";
    filename+=buffer2.str();
    filename+="/ParticleRoute.txt";
    std::cout<<filename.c_str()<<std::endl;
    std::ifstream inputfile(filename.c_str());
//     std::ifstream inputfile("Particles_long/Particle1/ParticleRoute.txt");

    std::vector< TGraph*> buffgraph;
    graphs.push_back( buffgraph);
    lines.push_back(new TPolyLine);
    FirstPoints.push_back(new TGraph);
    LastPoints.push_back(new TGraph);
    std::vector< TArrow*> buffarrow;
    arrows.push_back(buffarrow);


    int k=0;
    int kk=0;
    double nTrees=0.0;
    double shrinkage=0.0;
    double bagging=0.0;
    double cuts=0.0;
    double ROC=0.0;
    double KS=0.0;
    double depth=0.0;
    
    bool readline=true;
    while(readline){
      inputfile>>ROC;
      inputfile>>KS;
      inputfile>>nTrees;
      inputfile>>shrinkage;
      inputfile>>bagging;
      inputfile>>cuts;
//       inputfile>>depth;
      std::string dump="";
      int j=0;
      do{
        inputfile>>dump;
//         std::cout<<dump<<std::endl;
        j++;
//         if(dump=="--Next--")std::cout<<"here"<<std::endl;
//         if(dump=="--Next--\n")std::cout<<"too"<<std::endl;
//         if(dump=="")std::cout<<"never"<<std::endl;

      }while(dump!="--Next--" and dump!="--Next--\n" and dump!="");
//       std::cout<<"Data "<<nTrees<<" "<<shrinkage<<" "<<ROC<<std::endl;
      if(dump!="" and k>=minIteration){
        kk++;
        graphs.back().push_back(new TGraph);
        graphs.back().back()->SetPoint(0,nTrees,shrinkage);
        if(ROC==0)graphs.back().back()->SetMarkerStyle(3);
        else{
          graphs.back().back()->SetMarkerStyle(8);
//           std::cout<<TMath::Exp(ROC)<<std::endl;
          Double_t size=m*ROC+abschnitt;
          graphs.back().back()->SetMarkerSize(size); 
          std::cout<<j<<" "<<ROC<<" "<<size<<std::endl;

        }
        if(k==minIteration)graphs.back().back()->SetMarkerStyle(34);
        if(k>=minIteration)lines.back()->SetPoint(kk-1,nTrees,shrinkage);
        
        
           
          
          //if(k==0)FirstPoints.back()->SetPoint(0,nTrees,shrinkage);
      
      }
      if(ROC>=bestROCIteration[k]){
      bestROCIteration[k]=ROC;
      bestPartIteration[k]=i;
//       if(ROC>=bestROCGlobal)bestROCGlobal=ROC;
//       if(bestROCGlobal>=bestROCIteration[k])bestROCIteration[k]=bestROCGlobal;
      }
      
      k++;
//      inputfile>>dump;
      if(inputfile.eof() or dump=="" or k==Iteration)readline=false;
    }
    
//     LastPoints.back()->SetPoint(0,nTrees,bagging);

    inputfile.close();
    std::cout<<"NPoints: "<<k<<std::endl;
    
    //get velocities
    for(size_t l=1;l<graphs.back().size()-1;l++){
//       std::cout<<graphs.size()<<std::endl;
      Double_t PrevTrees=0.001;
      Double_t PrevShrinkage=0.001;
      graphs.back().at(l-1)->GetPoint(0,PrevTrees,PrevShrinkage);
//       std::cout<<PrevTrees<<" "<<PrevShrinkage<<std::endl;
      Double_t CurrTrees;
      Double_t CurrShrinkage;
      graphs.back().at(l)->GetPoint(0,CurrTrees,CurrShrinkage);
      Double_t NextTrees;
      Double_t NextShrinkage;
      graphs.back().at(l+1)->GetPoint(0,NextTrees,NextShrinkage);
      Double_t velTree=CurrTrees-PrevTrees;
      Double_t velShrinkage=CurrShrinkage-PrevShrinkage;
      Double_t nvelTree=NextTrees-CurrTrees;
      Double_t nvelShrinkage=NextShrinkage-CurrShrinkage;
      Double_t forceTrees=nvelTree-0.73*velTree;
      Double_t forceShrinkage=nvelShrinkage-0.73*velShrinkage;
      arrows.back().push_back(new TArrow(CurrTrees,CurrShrinkage,CurrTrees+forceTrees,CurrShrinkage+forceShrinkage,0.02,">"));
      
    }
    
  }//end input loop
    
    //Get velocities
    
    
    TCanvas* c = new TCanvas("c","c",1024,768);
    TLegend* leg= new TLegend(0.5,0.75,0.7,0.95);
    leg->SetFillColor(0);
    leg->SetTextFont(42);
    std::vector<TGraph*> leggraphs;

    for(size_t i=0;i<graphs.size();i++){
      leggraphs.push_back(new TGraph);
      leggraphs.back()->SetMarkerColor(1+i);
      leggraphs.back()->SetMarkerStyle(8);
      leggraphs.back()->SetMarkerSize(1);
      if(i==2)leggraphs.back()->SetMarkerColor(9);
      leg->AddEntry(leggraphs.back(), Form("particle %i",i+1),"p");
    }
    TLegend* legMarker= new TLegend(0.7,0.65,0.9,0.95);
    legMarker->SetFillColor(0);
    legMarker->SetFillStyle(0);
    legMarker->SetTextFont(42);
    TLegend* legCMS= new TLegend(0.07,0.85,0.39,0.95);
    legCMS->SetFillColor(0);
    legCMS->SetFillStyle(0);
    legCMS->SetBorderSize(0);
    legCMS->SetTextFont(42);
    legCMS->AddEntry((TObject*)0,"CMS private work","");
    TPaveText* legExplain= new TPaveText(0.23,0.84,0.73,0.94,"NDC");
    legExplain->SetFillColor(3);
    legExplain->SetFillStyle(0);
    legExplain->SetBorderSize(0);
    legExplain->AddText("BDTs trained and tested with t#bar{t}H, H#rightarrowb#bar{b} and t#bar{t} MC-Samples");
    legExplain->SetTextFont(42);
    
    TGraph* initMarker = new TGraph();
    initMarker->SetMarkerStyle(34);
    initMarker->SetMarkerSize(1.5);
    TGraph* zeroKSMarker = new TGraph();
    zeroKSMarker->SetMarkerStyle(3);
    zeroKSMarker->SetMarkerSize(1.5);
    legMarker->AddEntry(initMarker,"init. pos.","p");
    
    TArrow* legArrow = new TArrow(100,0.01,200,0.02,0.02,">");
    TArrow* legArrow2 = new TArrow(1270,0.0453,1320,0.0453,0.02,">");
    
    legArrow->SetLineColor(0);
    legArrow->SetFillColor(0);
    legArrow2->SetLineWidth(2);
    legArrow2->SetAngle(40);
    legMarker->AddEntry(legArrow,"#Delta#vec{v}","");
//         legMarker->AddEntry((TObject*)0,"","");
    legMarker->AddEntry(zeroKSMarker,"KS < min KS","p");

    TGraph* sizegraph1 = new TGraph();
    sizegraph1->SetMarkerStyle(8);
    Double_t size2=m*0.74+abschnitt;
    sizegraph1->SetMarkerSize(size2);
    legMarker->AddEntry(sizegraph1, "A_{ROC} = 0.74","p");
    TGraph* sizegraph2 = new TGraph();
    sizegraph2->SetMarkerStyle(8);
    size2=m*0.76+abschnitt;
    sizegraph2->SetMarkerSize(size2);
    legMarker->AddEntry(sizegraph2, "A_{ROC} = 0.76","p");
    TGraph* sizegraph3 = new TGraph();
    sizegraph3->SetMarkerStyle(8);
    size2=m*0.78+abschnitt;
    sizegraph3->SetMarkerSize(size2);
    legMarker->AddEntry(sizegraph3, "A_{ROC} = 0.78","p");
    
    
    
    for(size_t i=0;i<graphs.size();i++){

      if(i==0){
        c->cd();
        
        
        emptygraph->Draw("AP");
        c->Update();
        emptygraph->GetXaxis()->SetLimits(200,1600);
        emptygraph->GetXaxis()->SetRangeUser(200,1600);

        emptygraph->GetYaxis()->SetLimits(0.0,0.05);
        emptygraph->GetYaxis()->SetRangeUser(0.0,0.05);
        //emptygraph->SetTitle("particle paths in the n_{Trees} - shrinkage plane");
        emptygraph->SetTitle("");
        emptygraph->GetXaxis()->SetTitle("n_{Trees}");
        emptygraph->GetYaxis()->SetTitle("shrinkage");
        emptygraph->GetYaxis()->SetTitleOffset(1.5);
        emptygraph->GetXaxis()->SetTitleOffset(1.2);
       std::cout<<emptygraph->GetXaxis()->GetTitleFont()<<std::endl;

	c->SetTopMargin(0.05);
        c->Update();
        for(size_t j=0;j<graphs.at(i).size();j++){
//           graphs.at(i).at(j)->SetMarkerStyle(3);
          graphs.at(i).at(j)->SetMarkerColor(1+i);
          graphs.at(i).at(j)->SetLineColor(1+i);
//         graphs.at(i)->GetXaxis()->SetLimits(200.0,2500.0);
//         graphs.at(i)->GetYaxis()->SetLimits(0.1,0.9);
//         graphs.at(i)->GetZaxis()->SetRangeUser(0.0,1.0);
          graphs.at(i).at(j)->Draw("P SAME");
        c->Update();
        }
        for(size_t j=0;j<arrows.at(i).size();j++){
          arrows.at(i).at(j)->SetLineColor(1+i);
          arrows.at(i).at(j)->SetFillColor(1+i);
          arrows.at(i).at(j)->SetAngle(40);
          arrows.at(i).at(j)->SetLineWidth(1.9);
          arrows.at(i).at(j)->Draw("");
          c->Update();
        }
        lines.at(i)->SetLineColor(1+i);
        lines.at(i)->SetLineStyle(7);
        lines.at(i)->Draw();
        c->Update();
        
//         FirstPoints.at(i)->SetMarkerStyle(20);
//         FirstPoints.at(i)->SetMarkerColor(1+i);
//         FirstPoints.at(i)->Draw("P SAME");
//         LastPoints.at(i)->SetMarkerStyle(21);
//         LastPoints.at(i)->SetMarkerColor(1+i);
//         LastPoints.at(i)->Draw("P SAME");
//         c->Update();
//         LastPoints.at(i)->GetXaxis()->SetRangeUser(200.0,2500.0);
//         LastPoints.at(i)->GetYaxis()->SetRangeUser(0.0001,0.05);
//         LastPoints.at(i)->GetZaxis()->SetRangeUser(0.0,1.0);
//         LastPoints.at(i)->Draw("P SAME");

//         graphs.at(i)->Draw("P SAME");
        c->Update();
//         TObject* view = c->GetView3D();
//         TAxis3D *axis = TAxis3D::GetPadAxis();
//         std::cout<<view<<std::endl;
//         TAxis3D::ToggleRulers();     // To pop axice down
//         axis->SetLabelColor(kBlue); // Paint the axice labels with blue color
//         axis->SetAxisColor(kRed);   // Paint the axice itself with blue color
//         TAxis3D::ToggleRulers(); 
//         axis->Paint();// To pop axice up
//         c->Update();
        
      }
      else{
        c->cd();
        for(size_t j=0;j<graphs.at(i).size();j++){
//           graphs.at(i).at(j)->SetMarkerStyle(3);
          graphs.at(i).at(j)->SetMarkerColor(1+i);
          graphs.at(i).at(j)->SetLineColor(1+i);
          if(i==2){
          graphs.at(i).at(j)->SetMarkerColor(9);
          graphs.at(i).at(j)->SetLineColor(9);
          }
//         graphs.at(i)->GetXaxis()->SetRangeUser(200.0,2500.0);
//         graphs.at(i)->GetYaxis()->SetRangeUser(0.0001,0.05);
//         graphs.at(i)->GetZaxis()->SetRangeUser(0.0,1.0);
          graphs.at(i).at(j)->Draw("SAME P");
        c->Update();
        }
        for(size_t j=0;j<arrows.at(i).size();j++){
        arrows.at(i).at(j)->SetLineColor(1+i);
        arrows.at(i).at(j)->SetFillColor(1+i);
        if(i==2){
        arrows.at(i).at(j)->SetLineColor(9);
        arrows.at(i).at(j)->SetFillColor(9);
        }
        arrows.at(i).at(j)->SetAngle(40);
        arrows.at(i).at(j)->SetLineWidth(1.9);


        arrows.at(i).at(j)->Draw("");
        c->Update();
        }
        lines.at(i)->SetLineColor(1+i);
        lines.at(i)->SetLineStyle(7);
        if(i==2)lines.at(i)->SetLineColor(9);

        lines.at(i)->Draw();
        c->Update();
        
// d        FirstPoints.at(i)->SetMarkerStyle(20);
//     d    FirstPoints.at(i)->SetMarkerColor(1+i);
//         FirstPoints.at(i)->Draw("P Same");
//         LastPoints.at(i)->SetMarkerStyle(21);
//         LastPoints.at(i)->SetMarkerColor(1+i);
//         LastPoints.at(i)->Draw("P Same");
        c->Update();
      }
      
    }
    legArrow2->Draw("");
    leg->Draw();
    legMarker->Draw();
    legCMS->Draw();
    //legExplain->Draw();
    c->Update();
    TString outfile="ParticleRoute_";
    outfile+=Iteration;
    outfile+="eng.eps";
    c->SaveAs(outfile);
    
    
    for(int p=0;p<Iteration;p++){
    if(p>0 and bestROCIteration[p-1]>bestROCIteration[p])bestROCIteration[p]=bestROCIteration[p-1];

    std::cout<<p<<" "<<bestROCIteration[p]<<" "<<bestPartIteration[p]<<std::endl;
    
    }
}
void determineWorkingPoint(TString algo="csv",TString baseURL="~/scratch0/top-nosyst/plotter.root")
{
  float workPoint(0.244);
  float sfb(1.020),    sfberr(0.04);      //from BTV-11-003
  float sflight(1.08), sflighterr(0.13);  //from BTV-11-002
  //  float sfb(0.99),        sfberr(0.099);      //from BTV-11-001
  //  float sflight(1.07882), sflighterr(0.244);  //from BTV-11-001
  if(algo=="tche")
    {
      workPoint=1.7;
      sfb=0.95; sfberr=0.095;
      sflight=1.08018; sflighterr=0.1125;
    }

  TObjArray bjets=getDistributionFromPlotter(algo+"b",baseURL);
  TObjArray lightjets=getDistributionFromPlotter(algo+"light",baseURL);
  
  TH1F *bDisc=(TH1F *) bjets.At(1);
  TH1F *lightDisc=(TH1F *) lightjets.At(1);
  
  setStyle();
  gStyle->SetOptFit(0);

  TCanvas *cnv = getNewCanvas("c","c",false);
  cnv->Clear();
  cnv->SetCanvasSize(1200,1200);
  cnv->SetWindowSize(1200,1200);
  cnv->Divide(2,2);

  //draw the discriminator
  TPad *p = (TPad *)cnv->cd(1); 
  bDisc->SetTitle("b");
  bDisc->SetLineColor(1);
  bDisc->SetMarkerColor(1);
  bDisc->SetMarkerStyle(20);
  bDisc->SetFillStyle(0);
  bDisc->DrawNormalized("histe1");
  lightDisc->SetLineColor(1);
  lightDisc->SetMarkerColor(1);
  lightDisc->SetMarkerStyle(24);
  lightDisc->SetFillStyle(0);
  lightDisc->SetTitle("udcsg");
  lightDisc->DrawNormalized("histe1same");
  TLegend *leg=p->BuildLegend();
  formatForCmsPublic(p,leg,"CMS simulation",2);

  //draw the b/light efficiencies
  p=(TPad *)cnv->cd(2);
  p->SetLogy();
  TGraphAsymmErrors *bEff     = getEfficiencyFrom(bDisc);
  TGraphAsymmErrors *lightEff = getEfficiencyFrom(lightDisc);
  bEff->SetMarkerStyle(20);
  bEff->SetFillStyle(0);
  bEff->Draw("ap");
  bEff->GetXaxis()->SetTitle(bDisc->GetXaxis()->GetTitle());
  bEff->GetYaxis()->SetTitle("Efficiency");
  lightEff->SetMarkerStyle(24);
  lightEff->SetFillStyle(0);
  lightEff->Draw("p");

  //draw relatively to a given working point
  p=(TPad *)cnv->cd(3);
  Double_t baseBEff=bEff->Eval(workPoint);
  TGraphAsymmErrors *relBEff=new TGraphAsymmErrors;
  relBEff->SetMarkerStyle(20);
  relBEff->SetFillStyle(0);
  Double_t baseLightEff=lightEff->Eval(workPoint);
  TGraphAsymmErrors *relLightEff=new TGraphAsymmErrors;
  relLightEff->SetMarkerStyle(24);
  relLightEff->SetFillStyle(0);
  for(int ip=0; ip<bEff->GetN(); ip++)
    {
      Double_t cut, y,ey; 
      bEff->GetPoint(ip,cut,y);     ey = bEff->GetErrorY(ip);
      Double_t relEff(y/baseBEff);
      if(relEff<sfb+2*sfberr && relEff>sfb-2*sfberr)
	{
	  int ipt=relBEff->GetN();
	  relBEff->SetPoint(ipt,cut,relEff);
	  relBEff->SetPointError(ipt,0,0,ey/baseBEff,ey/baseBEff);
	}

      lightEff->GetPoint(ip,cut,y);     ey = lightEff->GetErrorY(ip);
      relEff=y/baseLightEff;
      //      if(relEff<sflight+7*sflighterr && relEff>sflight-7*sflighterr)
      if(relEff<sflight+3*sflighterr && relEff>sflight-3*sflighterr)
	{
	  int ipt=relLightEff->GetN();
	  relLightEff->SetPoint(ipt,cut,relEff);
	  relLightEff->SetPointError(ipt,0,0,ey/baseLightEff,ey/baseLightEff);
	}
    }

  relLightEff->Draw("ap");
  relLightEff->GetXaxis()->SetTitle( bDisc->GetXaxis()->GetTitle() );
  relLightEff->GetYaxis()->SetTitle( "#varepsilon/#varepsilon_{0}" );
  relLightEff->Fit("expo","Q+");
  TF1 *ffunc=relLightEff->GetFunction("expo");
  float newLightCut=(TMath::Log(sflight)-ffunc->GetParameter(0))/ffunc->GetParameter(1);
  float newLightCutErrPlus=(TMath::Log(sflight+sflighterr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newLightCut;
  float newLightCutErrMinus=(TMath::Log(sflight-sflighterr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newLightCut;
  TArrow *lightArrow = new TArrow(newLightCut, sflight-3*sflighterr, newLightCut, sflight-3*sflighterr*0.8, 0.02, "<|");
  lightArrow->SetLineColor(kGray+2);
  lightArrow->SetFillColor(kGray+2);
  lightArrow->Draw("SAME <|");

  relBEff->Draw("p");
  relBEff->Fit("expo","Q+");
  ffunc=relBEff->GetFunction("expo");
  float newBCut=(TMath::Log(sfb)-ffunc->GetParameter(0))/ffunc->GetParameter(1);
  float newBCutErrPlus=(TMath::Log(sfb+sfberr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newBCut;
  float newBCutErrMinus=(TMath::Log(sfb-sfberr)-ffunc->GetParameter(0))/ffunc->GetParameter(1)-newBCut;
  cout <<  sfb << " " << sfb+sfberr << " " << sfb-sfberr << endl;
  TArrow *bArrow    = new TArrow(newBCut, sflight-3*sflighterr, newBCut, sflight-3*sflighterr*0.8, 0.02, "<|");
  bArrow->Draw("SAME <|");

  //draw epsilon_b vs epsilon_q
  p=(TPad *)cnv->cd(4);
  p->SetLogy();

  TGraphAsymmErrors *perf=new TGraphAsymmErrors;
  perf->SetName("algoperformance");
  perf->SetMarkerStyle(20);
  perf->SetFillStyle(0);
  for(int ip=0; ip<bEff->GetN(); ip++)
    {
      Double_t cut;
      Double_t x,ex; bEff->GetPoint(ip,cut,x);     ex = bEff->GetErrorY(ip);
      Double_t y,ey; lightEff->GetPoint(ip,cut,y); ey = lightEff->GetErrorY(ip);
      perf->SetPoint(ip,x,y);
      perf->SetPointError(ip,ex,ex,ey,ey);
    }
  perf->Draw("ap");
  perf->GetXaxis()->SetTitle( bEff->GetTitle() );
  perf->GetYaxis()->SetTitle( lightEff->GetTitle() );

  //new performance expected after applying the new cuts
  TGraphAsymmErrors *newperf=new TGraphAsymmErrors;
  newperf->SetName("newalgoperformance");
  newperf->SetMarkerStyle(24);
  newperf->SetFillStyle(0);
  newperf->SetLineWidth(2);
  newperf->SetLineColor(kRed);
  newperf->SetLineColor(kRed);
  newperf->SetPoint(0,baseBEff*sfb,baseLightEff*sflight);
  newperf->SetPointError(0,baseBEff*sfberr,baseBEff*sfberr,baseLightEff*sflighterr,baseLightEff*sflighterr);
  newperf->Draw("p");

  cnv->Modified();
  cnv->Update();
  cnv->SaveAs("discFlavor.C");  
  cnv->SaveAs("discFlavor.png");  


  cout << "[determineWorkingPoint]" << endl
       << "To emulate the measured scale-factors you can use the following new cuts per jet flavor" << endl
       << "SF-b : "     << newBCut << " +" << newBCutErrPlus << " " << newBCutErrMinus << endl
       << "SF-light : " << newLightCut << " +" << newLightCutErrPlus << " " << newLightCutErrMinus << endl;
}
Example #14
0
int
main (int argc, char *argv[])
{
  if (argc != 2)
    {
      cout << "Usage: " << argv[0] << " INPUT_FILE" << endl;
      cout << "  or:  " << argv[0] << " INPUT_LIST" << endl;
      cout << "" << endl;
      cout << endl;

      return 0;
    }
  string inputFile = argv[1], upperInputFile;
  upperInputFile.resize (inputFile.length ());
  transform (inputFile.begin (), inputFile.end (), upperInputFile.begin (), ::toupper);

  // so canvases don't appear on the screen when being created
  // very useful when running on the OSU T3 from CERN
  gROOT->SetBatch();
  gStyle->SetPadTopMargin(0.1);
  gStyle->SetPadBottomMargin(0.1);
  gStyle->SetPadLeftMargin(0.03);
  gStyle->SetPadRightMargin(0.08);

  //Create chain of root trees
  TChain chain("Delphes");

  if (upperInputFile.length () < 5 || upperInputFile.substr (upperInputFile.length () - 5, 5) != ".ROOT")
  {
    ifstream fin (inputFile);
    string line;
    while(getline(fin, line))
      {
        chain.Add(line.c_str());
      }
    fin.close();
  }
  else
    chain.Add(inputFile.c_str());

  // Create object of class ExRootTreeReader
  ExRootTreeReader *treeReader = new ExRootTreeReader(&chain);

  // Get pointers to branches used in this analysis
  TClonesArray *branchTrack = treeReader->UseBranch("Track");
  TClonesArray *branchCluster = treeReader->UseBranch("Cluster"); 
  TClonesArray *branchNPU = treeReader->UseBranch("NPU");

  //gStyle->SetOptStat(10011);
  //actually, let's turn this off for now
  gStyle->SetOptStat(0);


  TH2D *hist[LEN];
  signal (SIGINT, signalHandler);
  //Loop over a LEN Events
  for (int event = 0; event < LEN && !interrupted; event++) {

    //Load Branches
    treeReader->ReadEntry(event);

    // N.B. this is a hack put in by Andrew using the ScalarHT class                                                                                                                                    
    // it's the number of pileup interactions, it's not actually the HT                                                                                                                                 
    unsigned nInteractions = (unsigned) ((ScalarHT *) branchNPU->At(0))->HT + 1;
    int nClusters = branchCluster->GetEntries();


    // create and format the histogram for this event
    TString name = "TrackPtVsTrackZ_" + TString(Form("%d",event+1));
    TCanvas *can = new TCanvas(name,name,1600,500);

    TString title = "Event " + TString(Form("%d",event+1)) + ": ";
    title += TString(Form("%d",nInteractions)) + " Interactions, ";
    title += TString(Form("%d",nClusters)) + " Clusters";

    hist[event] = new TH2D(name, title, X_BIN, X_MIN, X_MAX, Y_BIN, Y_MIN, Y_MAX);
    hist[event]->GetXaxis()->SetTitle("track z [mm]");
    hist[event]->GetXaxis()->SetLabelOffset(0.02);
    hist[event]->GetXaxis()->SetTitleOffset(1.2);
    hist[event]->GetYaxis()->SetTitle("track p_{T} [GeV]");
    hist[event]->GetYaxis()->SetTitleOffset(0.35);


    
    TArrow *genPVArrow = new TArrow(0,0,0,0.01,0.01,"|>");
    genPVArrow->SetLineColor(3);
    genPVArrow->SetFillColor(3);
    genPVArrow->SetLineWidth(0.1);
    genPVArrow->SetAngle(40);

    vector<float> interactionPositions;
    vector<TLine *> clusterLineVector;
    Cluster *recoPV = (Cluster *) branchCluster->At(0);
    TLine *highELine = new TLine(recoPV->Z,0,recoPV->Z,Y_MAX);
    highELine->SetLineColor(1);
    highELine->SetLineWidth(0.8);
    highELine->SetLineStyle(3);

    // Draw cluster lines
    // Skip first cluster since we've already drawn it (start from 1)
    for(int iCluster = 1; iCluster < branchCluster->GetEntries(); iCluster++) {
	Cluster *cluster = (Cluster *) branchCluster->At(iCluster);
	TLine *clusterLine = new TLine(cluster->Z,0,cluster->Z,Y_MAX);
	clusterLine->SetLineWidth(0.5);
	clusterLineVector.push_back(clusterLine);
    }
   
    for(int iTrack = 0; iTrack < branchTrack->GetEntries(); iTrack++) {
        Track *track = (Track *) branchTrack->At(iTrack);
	if (track->PT < Y_MAX) hist[event]->Fill(track->Z, track->PT);
	else hist[event]->Fill(track->Z, Y_MAX-0.01); // if entry would be off the y-scale, draw it in the last bin

        if(track->IsPU==0) { // track comes from primary interaction
//           genPVArrow->SetX1(track->TrueZ);  FIXME
//           genPVArrow->SetX2(track->TrueZ); FIXME
	}
//	else if (find(interactionPositions.begin(), interactionPositions.end(), track->TrueZ) == interactionPositions.end()){ FIXME
//	  interactionPositions.push_back(track->TrueZ); FIXME
//	} FIXME
    }

    //create arrows for all the generated pileup interactions
    vector<TArrow *> interactionArrowVector;
    for(uint iInteraction = 0; iInteraction < interactionPositions.size() ; iInteraction++) {
      TArrow *interactionArrow = new TArrow(interactionPositions.at(iInteraction),0,interactionPositions.at(iInteraction),0.01,0.01,"|>");
      interactionArrow->SetLineWidth(0.1);
      interactionArrow->SetAngle(20);
      interactionArrow->SetLineColor(2);
      interactionArrow->SetFillColor(2);
      interactionArrowVector.push_back(interactionArrow);
    }
  
    //Draw and save images
    hist[event]->Draw("contz");
    for(uint iCluster = 0; iCluster < clusterLineVector.size(); iCluster++) {
      clusterLineVector.at(iCluster)->Draw();
    } 
    for(uint iInteraction = 0; iInteraction < interactionArrowVector.size(); iInteraction++) {
      interactionArrowVector.at(iInteraction)->Draw();
    } 
    highELine->Draw();
    genPVArrow->Draw();

    TLegend *leg = new TLegend(0.07,0.6,0.25,0.89);
    leg->SetBorderSize(0);
    leg->SetFillColor(0);
    leg->SetFillStyle(0);
    leg->AddEntry(genPVArrow, "Primary Gen. Interaction", "");
    if (interactionArrowVector.size() > 0) leg->AddEntry(interactionArrowVector.at(0), "Pileup Interactions", "");
    leg->AddEntry(highELine, "Highest #Sigmap_{T}^{2} Cluster", "l");
    if (clusterLineVector.size() > 0) leg->AddEntry(clusterLineVector.at(0), "Other Clusters", "l");
    leg->Draw();


    //hack to get the triangles to draw in the legend
    double x_left = X_MIN + (X_MAX-X_MIN)/13;
    double x_right = X_MIN + (X_MAX-X_MIN)/13;

    if (interactionArrowVector.size() > 0){
      TArrow *interactionArrowLabel = new TArrow(x_left,Y_MAX*0.86,x_right,Y_MAX*0.86,0.02,"|>");
      interactionArrowLabel->SetLineWidth(1);
      interactionArrowLabel->SetAngle(20);
      interactionArrowLabel->SetLineColor(2);
      interactionArrowLabel->SetFillColor(2);
      interactionArrowLabel->Draw();
    }
    TArrow *genPVArrowLabel = new TArrow(x_left,Y_MAX*0.94,x_right,Y_MAX*0.94,0.02,"|>");
    genPVArrowLabel->SetLineWidth(1);
    genPVArrowLabel->SetAngle(40);
    genPVArrowLabel->SetLineColor(3);
    genPVArrowLabel->SetFillColor(3);
    genPVArrowLabel->Draw();
    
    can->SaveAs("output/" + name + ".pdf");
    //can->Write();

  }
}
//void gluinostopMassLifetime(double lumi=4560., double maxInstLumi=5000.) {
void gluinostopMassLifetime(double lumi=4560.) {

  ExtraLimitPlots plots(lumi);
  //mchamp index 0 is used, corresponds to 0th mass point = 100 GeV
  plots.calculateCrossSections(7,4,3,0,39,9);

  // xsecs as extracted from nllfast http://web.physik.rwth-aachen.de/service/wiki/bin/view/Main/SquarksandGluinos
  // gluino (m_squark=m_gluino):  "nllfast gg mstw <mass> <mass>"
  // gluino (m_squark>>m_gluino): "nllfast gdcpl mstw <mass>"
  // stop: "nllfast st mstw <mass>"
  double g_mass [21] = {  
    200 ,     250 ,     300 ,     350 ,     400 ,   
    450 ,     500 ,     550 ,     600 ,     650 ,   
    700 ,     750 ,     800 ,     850 ,     900 ,   
    950 ,    1000 ,    1050 ,    1100 ,    1150 ,   
    1200 };
  double g_xsec [21] = {  
    1010,      302,     106,     42.6,     18.9,
    8.93,     4.52,    2.39,     1.31,    0.744,
    0.434,   0.259,   0.157,   0.0967,   0.0603,
    0.0381, 0.0244,  0.0157,   0.0102,  0.00667,
    0.00440
  };
  double g_xsecdcpl [21] = {  
    1010,      302,     106,     42.6,     18.9,
    8.93,     4.52,    2.39,     1.31,    0.744,
    0.434,   0.259,   0.157,   0.0967,   0.0603,
    0.0381, 0.0244,  0.0157,   0.0102,  0.00667,
    0.00440
  };
  double s_mass [21] = {  
    100 ,     150 ,     200 ,     250 ,     300 ,   
    350 ,     400 ,     450 ,     500 ,     550 ,   
    600 ,     650 ,     700 ,     750 ,     800 ,   
    850 ,     900 ,     950 ,    1000 ,    1050 ,   
    1100 
  };
  double s_xsec [21] = {  
    560,       80.3,     18.5,     5.58,     2.00,
    0.807,    0.357,    0.170,   0.0856,   0.0452,
    0.0248,  0.0140,  0.00811,  0.00480,  0.00290,
    0.00177,0.00110, 0.000687, 0.000435, 0.000278,
    0.000180 
  };
  double m_mass [10] = {  
    100 ,        200 ,     300 ,     400 ,     500 ,   
    600 ,        700 ,     800 ,     900 ,    1000 
  };
  double m_xsec [10] = {  
    1.88,      0.1402,      0.02622,   0.006968, 0.002257,
    0.0008183, 0.0003228, 0.0001333, 0.00005764, 0.0000254
  };

  //gluino xsec
  vector<double> masses;
  for (int i = 0; i < 21; ++i)  {
    masses.push_back(g_mass[i]);
    g_xsec [i] = log10 (g_xsec [i]*1e3) * 20.;
    g_xsecdcpl [i] = log10 (g_xsecdcpl [i]*1e3) * 20.;
  }
  //  Xsection gluino_xs (masses, g_xsec);
  Xsection gluino_xs (masses, g_xsecdcpl);
  
  //stop xsec
  masses.clear();
  for (int i = 0; i < 19; ++i)  {
    masses.push_back(s_mass[i]);
    s_xsec [i] = log10 (s_xsec [i]*1e3) * 20.;
  }
  Xsection stop_xs (masses, s_xsec);

  //mchamp xsec
  masses.clear();
  for (int i = 0; i < 10; ++i)  {
    masses.push_back(m_mass[i]);
    m_xsec [i] = log10 (m_xsec [i]*1e3) * 20.;
  }
  Xsection mchamp_xs (masses, m_xsec);
  
  // graphs
  TGraph* g_obs     = new TGraph (*plots.getLimitGluino());
  gluino_xs.xsec2mass (g_obs);

  TGraph* g_exp      = new TGraph (*plots.getExpLimitGluino());
  gluino_xs.xsec2mass (g_exp);
  TGraphAsymmErrors* g_exp_1sig = new TGraphAsymmErrors (*plots.getExpLimitGluino1Sig());
  gluino_xs.xsec2mass (g_exp_1sig);
  TGraphAsymmErrors* g_exp_2sig = new TGraphAsymmErrors (*plots.getExpLimitGluino2Sig());
  gluino_xs.xsec2mass (g_exp_2sig);

  TGraph* stop_obs     = new TGraph (*plots.getLimitStop());
  stop_xs.xsec2mass (stop_obs);

  TGraph* stop_exp      = new TGraph (*plots.getExpLimitStop());
  stop_xs.xsec2mass (stop_exp);
  TGraphAsymmErrors* stop_exp_1sig = new TGraphAsymmErrors (*plots.getExpLimitStop1Sig());
  stop_xs.xsec2mass (stop_exp_1sig);
  TGraphAsymmErrors* stop_exp_2sig = new TGraphAsymmErrors (*plots.getExpLimitStop2Sig());
  stop_xs.xsec2mass (stop_exp_2sig);


  TGraph* mchamp_obs     = new TGraph (*plots.getLimitMchamp());
  mchamp_xs.xsec2mass (mchamp_obs);

  TGraph* mchamp_exp      = new TGraph (*plots.getExpLimitMchamp());
  mchamp_xs.xsec2mass (mchamp_exp);
  TGraphAsymmErrors* mchamp_exp_1sig = new TGraphAsymmErrors (*plots.getExpLimitMchamp1Sig());
  mchamp_xs.xsec2mass (mchamp_exp_1sig);
  TGraphAsymmErrors* mchamp_exp_2sig = new TGraphAsymmErrors (*plots.getExpLimitMchamp2Sig());
  mchamp_xs.xsec2mass (mchamp_exp_2sig);

  
  TCanvas *canvas = new TCanvas("allMassLifetime", "allMassLifetime", 800, 600);
  
  canvas->SetLogx();
  canvas->SetGridy();

  
  TH1F* h = new TH1F ("h", "", 1,  7.5e-8, 1e6);
  h->SetStats (0);
  //h->SetMinimum (300);
  h->SetMinimum (0);
  //h->SetMaximum (1500);
  h->SetMaximum (600);
  h->SetTitle("Beamgap Expt");
  //  h->GetXaxis()->SetTitle("#tau_{#tilde{g},#tilde{t},#tilde{#tau}} [s]");
  h->GetXaxis()->SetTitle("#tau [s]");
  h->GetYaxis()->SetTitle("m [GeV]  ");
  h->Draw ("");

  
  
  // limit arrows
  double* x = g_obs->GetX();
  for (int i = 0; i < g_obs->GetN(); ++i) {
    if (x[i] > 0.5) {
      double y =  g_obs->GetY()[i];
      TArrow* arrow = new TArrow (x[i], y, h->GetXaxis()->GetXmin(), y, 0.02);
      arrow->SetLineColor (kRed);
      arrow->SetLineWidth (2);
      //arrow->Draw();
      cout << "GLUINO mass limit @ " << x[i] << "sec is found: " << y << endl;
      break;
    }
  }
  x = g_obs->GetX();
  for (int i = 0; i < stop_obs->GetN(); ++i) {
    if (x[i] > 0.5) {
      double y =  stop_obs->GetY()[i];
      TArrow* arrow = new TArrow (x[i], y, h->GetXaxis()->GetXmin(), y, 0.02);
      arrow->SetLineColor (kBlue);
      arrow->SetLineWidth (2);
      //arrow->Draw();
      cout << "STOP mass limit @ " << x[i] << "sec is found: " << y << endl;
      break;
    }
  }
  x = mchamp_obs->GetX();
  for (int i = 0; i < mchamp_obs->GetN(); ++i) {
    if (x[i] > 0.5) {
      double y =  mchamp_obs->GetY()[i];
      TArrow* arrow = new TArrow (x[i], y, h->GetXaxis()->GetXmin(), y, 0.02);
      arrow->SetLineColor (kBlack);
      arrow->SetLineWidth (2);
      arrow->Draw();
      cout << "MCHAMP mass limit @ " << x[i] << "sec is found: " << y << endl;
      break;
    }
  }
 
  // gluino  
  // 2 sigma band
  if (g_exp_2sig) {
    g_exp_2sig->SetLineColor(0);
    g_exp_2sig->SetLineStyle(0);
    g_exp_2sig->SetLineWidth(0);
    g_exp_2sig->SetFillColor(kYellow);
    g_exp_2sig->SetFillStyle(1001);
    //g_exp_2sig->Draw("3");
  }
  
  // 1 sigma band
  if (g_exp_1sig) {
    // g_exp_1sig->SetLineColor(8);
    g_exp_1sig->SetLineColor(0);
    g_exp_1sig->SetLineStyle(0);
    g_exp_1sig->SetLineWidth(0);
    // g_exp_1sig->SetFillColor(8);
    g_exp_1sig->SetFillColor(kGreen);
    g_exp_1sig->SetFillStyle(1001);
    // g_exp_1sig->SetFillStyle(3005);
    //g_exp_1sig->Draw("3");
    // g_exp_1sig->Draw("lX");
  }
  
  
  // epxected limit
  if (g_exp) {
    g_exp->SetLineColor(kRed);
    g_exp->SetLineStyle(4);
    g_exp->SetLineWidth(2);
    //g_exp->Draw("l3");
  }
  

  // observed limit
  if (g_obs) {
    g_obs->SetLineColor(kRed);
    g_obs->SetLineStyle(1);
    g_obs->SetLineWidth(2);
    //g_obs->Draw("l");
  }
  
  // stop  
  // 2 sigma band
  if (stop_exp_2sig) {
    stop_exp_2sig->SetLineColor(0);
    stop_exp_2sig->SetLineStyle(0);
    stop_exp_2sig->SetLineWidth(0);
    stop_exp_2sig->SetFillColor(kYellow);
    stop_exp_2sig->SetFillStyle(1001);
    //stop_exp_2sig->Draw("3");
  }
  
  // 1 sigma band
  if (stop_exp_1sig) {
    // stop_exp_1sig->SetLineColor(8);
    stop_exp_1sig->SetLineColor(0);
    stop_exp_1sig->SetLineStyle(0);
    stop_exp_1sig->SetLineWidth(0);
    // stop_exp_1sig->SetFillColor(8);
    stop_exp_1sig->SetFillColor(kGreen);
    stop_exp_1sig->SetFillStyle(1001);
    // stop_exp_1sig->SetFillStyle(3005);
    //stop_exp_1sig->Draw("3");
    // stop_exp_1sig->Draw("lX");
  }
  
  
  // epxected limit
  if (stop_exp) {
    stop_exp->SetLineColor(kBlue);
    stop_exp->SetLineStyle(3);
    stop_exp->SetLineWidth(2);
    //stop_exp->Draw("l3");
  }
  

  // observed limit
  if (stop_obs) {
    stop_obs->SetLineColor(kBlue);
    stop_obs->SetLineStyle(2);
    stop_obs->SetLineWidth(2);
    //stop_obs->Draw("l");
  }


  //mchamp
  // 2 sigma band
  if (mchamp_exp_2sig) {
    mchamp_exp_2sig->SetLineColor(0);
    mchamp_exp_2sig->SetLineStyle(0);
    mchamp_exp_2sig->SetLineWidth(0);
    mchamp_exp_2sig->SetFillColor(kYellow);
    mchamp_exp_2sig->SetFillStyle(1001);
    mchamp_exp_2sig->Draw("3");
  }
  
  // 1 sigma band
  if (mchamp_exp_1sig) {
    // mchamp_exp_1sig->SetLineColor(8);
    mchamp_exp_1sig->SetLineColor(0);
    mchamp_exp_1sig->SetLineStyle(0);
    mchamp_exp_1sig->SetLineWidth(0);
    // mchamp_exp_1sig->SetFillColor(8);
    mchamp_exp_1sig->SetFillColor(kGreen);
    mchamp_exp_1sig->SetFillStyle(1001);
    // mchamp_exp_1sig->SetFillStyle(3005);
    mchamp_exp_1sig->Draw("3");
    // mchamp_exp_1sig->Draw("lX");
  }
  
  
  // epxected limit
  if (mchamp_exp) {
    mchamp_exp->SetLineColor(kBlack);
    mchamp_exp->SetLineStyle(3);
    mchamp_exp->SetLineWidth(2);
    mchamp_exp->Draw("l3");
  }
  

  // observed limit
  if (mchamp_obs) {
    mchamp_obs->SetLineColor(kBlack);
    mchamp_obs->SetLineStyle(2);
    mchamp_obs->SetLineWidth(2);
    mchamp_obs->Draw("l");
  }

  
  

  TPaveText* blurb = new TPaveText(0.20, 0.63, 0.60, 0.90, "NDC");
  blurb->AddText("CMS Preliminary 2012");
  //blurb->AddText("CMS 2012");
  blurb->AddText("#int L dt = 19.7 fb^{-1}"); //,  #int L_{eff} dt = 935 pb^{-1}");
  //blurb->AddText("L^{max}_{inst} = 3.5 #times 10^{33} cm^{-2}s^{-1}");

  // std::stringstream label;
  // label<<"#int L dt = "<<lumi<<" pb^{-1}";
  // blurb->AddText(label.str().c_str());
  // double peakInstLumi=maxInstLumi;
  // int exponent=30;
  // while (peakInstLumi>10) {
  //   peakInstLumi/=10;
  //   ++exponent;
  // }
  // std::stringstream label2;
  // label2<<"L^{max}_{inst} = "<<peakInstLumi<<" x 10^{"<<exponent<<"} cm^{-2}s^{-1}";
//  blurb->AddText(label2.str().c_str());
  blurb->AddText("#sqrt{s} = 8 TeV");
  //blurb->AddText("E_{gluon} > 120 GeV, E_{top} > 150 GeV");
  blurb->SetTextFont(42);
  blurb->SetBorderSize(0);
  blurb->SetFillColor(0);
  blurb->SetShadowColor(0);
  blurb->SetTextAlign(12);
  blurb->SetTextSize(0.033);
  blurb->Draw();

  TLegend* leg = new TLegend(0.6, 0.62, 0.87, 0.90,"95% CL Limits:","NDC");
  leg->SetTextSize(0.033);
  leg->SetBorderSize(0);
  leg->SetTextFont(42);
  leg->SetFillColor(0);

  //leg->AddEntry(g_obs, " #tilde{g} observed", "l");
  //leg->AddEntry(stop_obs, " #tilde{t} observed", "l");
  leg->AddEntry(mchamp_obs, "mchamp observed", "l");

  TGraph* expectedStyle1 = new TGraph (*g_exp);
  expectedStyle1->SetFillColor (g_exp_1sig->GetFillColor());
  TGraph* expectedStyle2 = new TGraph (*g_exp);
  expectedStyle2->SetFillColor (g_exp_2sig->GetFillColor());
  //leg->AddEntry(expectedStyle1, " #tilde{g} expected #pm1#sigma", "lf");
  //leg->AddEntry(expectedStyle2, " #tilde{g} expected #pm2#sigma", "lf");

  expectedStyle1 = new TGraph (*stop_exp);
  expectedStyle1->SetFillColor (stop_exp_1sig->GetFillColor());
  expectedStyle2 = new TGraph (*stop_exp);
  expectedStyle2->SetFillColor (stop_exp_2sig->GetFillColor());
  //leg->AddEntry(expectedStyle1, " #tilde{t} expected #pm1#sigma", "lf");
  //leg->AddEntry(expectedStyle2, " #tilde{t} expected #pm2#sigma", "lf");

  expectedStyle1 = new TGraph (*mchamp_exp);
  expectedStyle1->SetFillColor (mchamp_exp_1sig->GetFillColor());
  expectedStyle2 = new TGraph (*mchamp_exp);
  expectedStyle2->SetFillColor (mchamp_exp_2sig->GetFillColor());
  leg->AddEntry(expectedStyle1, "mchamp expected #pm1#sigma", "lf");
  leg->AddEntry(expectedStyle2, "mchamp expected #pm2#sigma", "lf");

  leg->Draw();

  h->Draw("sameaxis");

  canvas->Print("gluinostopmchampMassLifetime.png");
  canvas->Print("gluinostopmchampMassLifetime.pdf");
}
void CCProtonPi0_SideBandTool::Plot_NoRatio(int ind, std::string sb_name, std::string var_name, MnvH1D* data, MnvH1D* mc_total, MnvH1D* signal, MnvH1D* WithPi0, MnvH1D* QELike, MnvH1D* SinglePiPlus, MnvH1D* Other)
{
    (void) mc_total;
    std::string type;
    if (ind == 0) type = "Nominal";
    else type = "Fitted";

    std::string norm = "POT";
    std::string plot_title = "Side Band: " + sb_name + " " + type + " " + norm + " Normalized";

    // Get Histograms -- Use new Histograms not to change originals
    MnvH1D* h_data = new MnvH1D(*data);
    h_data->GetYaxis()->CenterTitle();
    h_data->GetXaxis()->SetNdivisions(5,5,0);
    h_data->GetYaxis()->SetNdivisions(5,5,0);

    MnvH1D* h_signal = new MnvH1D(*signal);
    h_signal->GetYaxis()->CenterTitle();
    h_signal->SetFillColor(kGreen+1);
    h_signal->SetLineColor(kGreen+1);
    h_signal->SetFillStyle(3002);
    h_signal->SetLineWidth(2);
    h_signal->GetXaxis()->SetNdivisions(5,5,0);
    h_signal->GetYaxis()->SetNdivisions(5,5,0);

    MnvH1D* h_WithPi0 = new MnvH1D(*WithPi0);
    h_WithPi0->GetYaxis()->CenterTitle();
    h_WithPi0->SetFillColor(kRed);
    h_WithPi0->SetLineColor(kRed);
    h_WithPi0->SetFillStyle(3002);
    h_WithPi0->SetLineWidth(2);
    h_WithPi0->GetXaxis()->SetNdivisions(5,5,0);
    h_WithPi0->GetYaxis()->SetNdivisions(5,5,0);
  
    MnvH1D* h_QELike = new MnvH1D(*QELike);
    h_QELike->GetYaxis()->CenterTitle();
    h_QELike->SetFillColor(kOrange-1);
    h_QELike->SetLineColor(kOrange-1);
    h_QELike->SetFillStyle(3002);
    h_QELike->SetLineWidth(2);
    h_QELike->GetXaxis()->SetNdivisions(5,5,0);
    h_QELike->GetYaxis()->SetNdivisions(5,5,0);
 
    MnvH1D* h_SinglePiPlus = new MnvH1D(*SinglePiPlus);
    h_SinglePiPlus->GetYaxis()->CenterTitle();
    h_SinglePiPlus->SetFillColor(kBlue);
    h_SinglePiPlus->SetLineColor(kBlue);
    h_SinglePiPlus->SetFillStyle(3002);
    h_SinglePiPlus->SetLineWidth(2);
    h_SinglePiPlus->GetXaxis()->SetNdivisions(5,5,0);
    h_SinglePiPlus->GetYaxis()->SetNdivisions(5,5,0);

    MnvH1D* h_Other = new MnvH1D(*Other);
    h_Other->GetYaxis()->CenterTitle();
    h_Other->SetFillColor(kGray+2);
    h_Other->SetLineColor(kGray+2);
    h_Other->SetFillStyle(3002);
    h_Other->SetLineWidth(2);
    h_Other->GetXaxis()->SetNdivisions(5,5,0);
    h_Other->GetYaxis()->SetNdivisions(5,5,0);
  
    // Clear Error Bars
    h_signal->ClearAllErrorBands();
    h_WithPi0->ClearAllErrorBands();
    h_QELike->ClearAllErrorBands();
    h_SinglePiPlus->ClearAllErrorBands();
    h_Other->ClearAllErrorBands();

    TObjArray* mc_hists = new TObjArray;
    mc_hists->Add(h_Other);
    mc_hists->Add(h_SinglePiPlus);
    mc_hists->Add(h_QELike);
    mc_hists->Add(h_WithPi0);
    mc_hists->Add(h_signal);
 
    // ------------------------------------------------------------------------
    // Plot 
    // ------------------------------------------------------------------------
    MnvPlotter* plotter = new MnvPlotter();
    plotter->SetRootEnv();
 
    gStyle->SetCanvasDefW(640);
    gStyle->SetCanvasDefH(480); // 4x3 aspect ratio
    gStyle->SetPadRightMargin(0.05);
    gStyle->SetEndErrorSize(2);
    gStyle->SetStripDecimals(false);

    plotter->axis_minimum = 0.01;
    plotter->legend_text_size  = 0.04;
    plotter->legend_text_font = 42; // default 62 (bold)
    plotter->data_marker_size = 0.8;
    plotter->axis_title_font_x   = 42;
    plotter->axis_title_size_x   = 0.06;
    plotter->axis_title_offset_x = 1.1;
    plotter->axis_title_font_y   = 42;
    plotter->axis_title_size_y   = 0.06;
    plotter->axis_title_offset_y = 1.0;
    plotter->axis_label_size = 0.05;
    plotter->axis_label_font = 42;
    plotter->headroom = 1.75;

    plotter->mc_line_width = 2;
    
    TCanvas* c = new TCanvas("c");

    /*
       void MnvPlotter::DrawDataStackedMC(
            const MnvH1D *  dataHist,
            const TObjArray *    mcHists,
            const Double_t   mcScale = 1.0,
            const std::string &  legPos = "L",
            const std::string &  dataName = "Data",
            const Int_t  mcBaseColor = 2,
            const Int_t  mcColorOffset = 1,
            const Int_t  mcFillStyle = 3001,
            const char *     xaxislabel = "",
            const char *     yaxislabel = "",
            bool     cov_area_normalize = false   
       )    
    */
    plotter->DrawDataStackedMC(h_data, mc_hists, POT_ratio, "N", "Data (3.33e20 POT)", 0, 0, 3002);

    // Add Legend
    double leg_x_min = 0.55;
    double leg_x_max = 0.90;
    double leg_y_min = 0.55;
    double leg_y_max = 0.85;

    h_data->SetMarkerStyle(plotter->data_marker);
    h_data->SetMarkerSize(plotter->data_marker_size);
    h_data->SetMarkerColor(plotter->data_color);
    h_data->SetLineColor(plotter->data_color);
    h_data->SetLineWidth(plotter->data_line_width);

    TLegend *legend = new TLegend(leg_x_min, leg_y_min, leg_x_max, leg_y_max);
    legend->SetBorderSize(0);
    legend->SetFillColor(-1);
    legend->SetFillStyle(0);
    legend->SetTextFont(42);
    legend->SetTextSize(0.04);
    legend->AddEntry(h_data, "Data", "lep");
    legend->AddEntry(h_signal, "Signal", "f");
    legend->AddEntry(h_WithPi0, "Bkgrd: #pi^{0} + meson(s)", "f");
    legend->AddEntry(h_QELike, "Bkgrd: zero meson", "f");
    legend->AddEntry(h_SinglePiPlus, "Bkgrd: charged meson(s)", "f");
    legend->AddEntry(h_Other, "Bkgrd: other", "f");
    legend->SetTextSize(0.04);
    legend->SetTextFont(42);
    legend->Draw();

    // Add Alines if Original Side Band
    //if (false) {
    if (sb_name.compare("Original") == 0) {
        double max_bin = h_data->GetMaximumBin();
        double hist_max = h_data->GetBinContent(max_bin)*1.2;

        TLine line;
        TArrow arrow;
        // Cut Line at 60 MeV
        line.SetLineWidth(2);
        line.SetLineStyle(2);
        line.SetLineColor(kBlack);
        arrow.SetLineWidth(2);
        arrow.SetLineColor(kBlack);
        line.DrawLine(60.0, 0.0, 60.0, hist_max);
        arrow.DrawArrow(60.0, hist_max, 50.0, hist_max, 0.01);

        line.DrawLine(200.0, 0.0, 200.0, hist_max);
        arrow.DrawArrow(200.0, hist_max, 210.0, hist_max, 0.01);

        arrow.SetLineColor(kBlue);
        arrow.DrawArrow(134.98,hist_max/8,134.98,0, 0.01); 
    } 

    // Add Normalization Label
    TLatex norm_text;
    norm_text.SetNDC();
    norm_text.SetTextColor(kBlue);
    norm_text.SetTextSize(0.03);
    norm_text.SetTextAlign(22);
    norm_text.DrawLatex(0.35,0.85,"POT Normalized");

    double info_text_x = 0.85;
    double info_text_y = 0.85;
    TLatex info_text;
    info_text.SetNDC();
    info_text.SetTextColor(kBlack);
    info_text.SetTextFont(62);
    info_text.SetTextAlign(12);
    info_text.SetTextSize(0.04);
    if ( ind == 0) info_text.DrawLatex(info_text_x, info_text_y, "(a)");
    else info_text.DrawLatex(info_text_x, info_text_y, "(b)");

    // Plot Output
    c->Update();
    std::string plotDir = Folder_List::plotDir_Paper;
    std::string out_name;
    out_name = plotDir + var_name + "_" + sb_name + "_" + type + "_" + norm + ".pdf"; 

    c->Print(out_name.c_str(),"pdf");

    delete h_data;
    delete h_signal;
    delete h_WithPi0;
    delete h_QELike;
    delete h_SinglePiPlus;
    delete h_Other;
    delete legend;
    delete c;
    delete plotter;
}
Example #17
0
void rf106_plotdecoration()
{

  // S e t u p   m o d e l 
  // ---------------------

  // Create observables
  RooRealVar x("x","x",-10,10) ;

  // Create Gaussian
  RooRealVar sigma("sigma","sigma",1,0.1,10) ;
  RooRealVar mean("mean","mean",-3,-10,10) ;
  RooGaussian gauss("gauss","gauss",x,mean,sigma) ;

  // Generate a sample of 1000 events with sigma=3
  RooDataSet* data = gauss.generate(x,1000) ;

  // Fit pdf to data
  gauss.fitTo(*data) ;


  // P l o t   p . d . f   a n d   d a t a 
  // -------------------------------------

  // Overlay projection of gauss on data
  RooPlot* frame = x.frame(Name("xframe"),Title("RooPlot with decorations"),Bins(40)) ;
  data->plotOn(frame) ;
  gauss.plotOn(frame) ;


  // A d d   b o x   w i t h   p d f   p a r a m e t e r s 
  // -----------------------------------------------------

  // Left edge of box starts at 55% of Xaxis)
  gauss.paramOn(frame,Layout(0.55)) ;


  // A d d   b o x   w i t h   d a t a   s t a t i s t i c s
  // -------------------------------------------------------  

  // X size of box is from 55% to 99% of Xaxis range, top of box is at 80% of Yaxis range)
  data->statOn(frame,Layout(0.55,0.99,0.8)) ;


  // A d d   t e x t   a n d   a r r o w 
  // -----------------------------------

  // Add text to frame
  TText* txt = new TText(2,100,"Signal") ;
  txt->SetTextSize(0.04) ;
  txt->SetTextColor(kRed) ;
  frame->addObject(txt) ;

  // Add arrow to frame
  TArrow* arrow = new TArrow(2,100,-1,50,0.01,"|>") ;
  arrow->SetLineColor(kRed) ;
  arrow->SetFillColor(kRed) ;
  arrow->SetLineWidth(3) ;
  frame->addObject(arrow) ;


  // P e r s i s t   f r a m e   w i t h   a l l   d e c o r a t i o n s   i n   R O O T   f i l e
  // ---------------------------------------------------------------------------------------------

  TFile f("rf106_plotdecoration.root","RECREATE") ;
  frame->Write() ;
  f.Close() ;

  // To read back and plot frame with all decorations in clean root session do
  // root> TFile f("rf106_plotdecoration.root") ;
  // root>  xframe->Draw() ;

  new TCanvas("rf106_plotdecoration","rf106_plotdecoration",600,600) ;
  gPad->SetLeftMargin(0.15) ; frame->GetYaxis()->SetTitleOffset(1.6) ; frame->Draw() ;
  
}
void gluinostopMassLifetime(double lumi=4560., double maxInstLumi=5000.) {

  ExtraLimitPlots plots(lumi);
  plots.calculateCrossSections(4,6,3,39,9);

  // xsecs as extracted from nllfast http://web.physik.rwth-aachen.de/service/wiki/bin/view/Main/SquarksandGluinos
  // gluino (m_squark=m_gluino):  "nllfast gg mstw <mass> <mass>"
  // gluino (m_squark>>m_gluino): "nllfast gdcpl mstw <mass>"
  // stop: "nllfast st mstw <mass>"
  // the xsec of gluino and stop are updated for 13TeV analysis, the xsecs are extracted from:
  // https://twiki.cern.ch/twiki/bin/view/LHCPhysics/SUSYCrossSections#Cross_sections_for_various_S_AN2
  double g_mass [21] = {  
    200 ,     250 ,     300 ,     350 ,     400 ,   
    450 ,     500 ,     550 ,     600 ,     650 ,   
    700 ,     750 ,     800 ,     850 ,     900 ,   
    950 ,    1000 ,    1050 ,    1100 ,    1150 ,   
    1200 };
  double g_xsec [21] = {  
    3574,      1190,     462,     202,     98.0,
    50.4,      27.4,    15.6,     9.20,    5.60,
    3.53,      2.27,     1.49,   0.996,   0.677,
    0.466,     0.325,  0.229,   0.163,  0.118,
    0.0856
  };
  double g_xsecdcpl [21] = {  
    3574,      1190,     462,     202,     98.0,
    50.4,      27.4,    15.6,     9.20,    5.60,
    3.53,      2.27,     1.49,   0.996,   0.677,
    0.466,     0.325,  0.229,   0.163,  0.118,
    0.0856
  };
  double s_mass [21] = {  
    100 ,     150 ,     200 ,     250 ,     300 ,   
    350 ,     400 ,     450 ,     500 ,     550 ,   
    600 ,     650 ,     700 ,     750 ,     800 ,   
    850 ,     900 ,     950 ,    1000 ,    1050 ,   
    1100 };
  double s_xsec [21] = {  
    1521,       249.4,     64.5,     21.6,     8.51,
    3.79,        1.84,    0.948,   0.518,   0.296,
    0.175,      0.107,  0.067,  0.0431,  0.0283,
    0.0190,    0.0129, 0.00883, 0.00615, 0.00432,
    0.00307
  };

  //gluino xsec
  vector<double> masses;
  for (int i = 0; i < 21; ++i)  {
    masses.push_back(g_mass[i]);
    g_xsec [i] = log10 (g_xsec [i]*1e3) * 20.;
    g_xsecdcpl [i] = log10 (g_xsecdcpl [i]*1e3) * 20.;
  }
  //  Xsection gluino_xs (masses, g_xsec);
  Xsection gluino_xs (masses, g_xsecdcpl);
  
  //stop xsec
  masses.clear();
  for (int i = 0; i < 19; ++i)  {
    masses.push_back(s_mass[i]);
    s_xsec [i] = log10 (s_xsec [i]*1e3) * 20.;
  }
  Xsection stop_xs (masses, s_xsec);
  
  // graphs
  TGraph* g_obs     = new TGraph (*plots.getLimitGluino());
  gluino_xs.xsec2mass (g_obs);

  TGraph* g_exp      = new TGraph (*plots.getExpLimitGluino());
  gluino_xs.xsec2mass (g_exp);
  TGraphAsymmErrors* g_exp_1sig = new TGraphAsymmErrors (*plots.getExpLimitGluino1Sig());
  gluino_xs.xsec2mass (g_exp_1sig);
  TGraphAsymmErrors* g_exp_2sig = new TGraphAsymmErrors (*plots.getExpLimitGluino2Sig());
  gluino_xs.xsec2mass (g_exp_2sig);

  TGraph* stop_obs     = new TGraph (*plots.getLimitStop());
  stop_xs.xsec2mass (stop_obs);

  TGraph* stop_exp      = new TGraph (*plots.getExpLimitStop());
  stop_xs.xsec2mass (stop_exp);
  TGraphAsymmErrors* stop_exp_1sig = new TGraphAsymmErrors (*plots.getExpLimitStop1Sig());
  stop_xs.xsec2mass (stop_exp_1sig);
  TGraphAsymmErrors* stop_exp_2sig = new TGraphAsymmErrors (*plots.getExpLimitStop2Sig());
  stop_xs.xsec2mass (stop_exp_2sig);

  
  TCanvas *canvas = new TCanvas("allMassLifetime", "allMassLifetime", 800, 600);
  
  canvas->SetLogx();
//  canvas->SetGridy();

  
  TH1F* h = new TH1F ("h", "", 1,  7.5e-8, 1e6);
  h->SetStats (0);
  h->SetMinimum (300);
  h->SetMaximum (2000);
  h->SetTitle("Beamgap Expt");
  //  h->GetXaxis()->SetTitle("#tau_{#tilde{g},#tilde{t},#tilde{#tau}} [s]");
  h->GetXaxis()->SetTitle("#tau [s]");
  h->GetYaxis()->SetTitle("m [GeV]  ");
  h->Draw ("");

  
  
  // limit arrows
  double* x = g_obs->GetX();
  for (int i = 0; i < g_obs->GetN(); ++i) {
    if (x[i] > 0.5) {
      double y =  g_obs->GetY()[i];
      TArrow* arrow = new TArrow (x[i], y, h->GetXaxis()->GetXmin(), y, 0.02);
      arrow->SetLineColor (kRed);
      arrow->SetLineWidth (2);
      //arrow->Draw();
      cout << "GLUINO mass limit @ " << x[i] << "sec is found: " << y << endl;
      break;
    }
  }
  x = g_obs->GetX();
  for (int i = 0; i < stop_obs->GetN(); ++i) {
    if (x[i] > 0.5) {
      double y =  stop_obs->GetY()[i];
      TArrow* arrow = new TArrow (x[i], y, h->GetXaxis()->GetXmin(), y, 0.02);
      arrow->SetLineColor (kBlue);
      arrow->SetLineWidth (2);
      //arrow->Draw();
      cout << "STOP mass limit @ " << x[i] << "sec is found: " << y << endl;
      break;
    }
  }
 
  // gluino  
  // 2 sigma band
  if (g_exp_2sig) {
    g_exp_2sig->SetLineColor(0);
    g_exp_2sig->SetLineStyle(0);
    g_exp_2sig->SetLineWidth(0);
    g_exp_2sig->SetFillColor(kYellow);
    g_exp_2sig->SetFillStyle(1001);
    g_exp_2sig->Draw("3");
  }
  
  // 1 sigma band
  if (g_exp_1sig) {
    // g_exp_1sig->SetLineColor(8);
    g_exp_1sig->SetLineColor(0);
    g_exp_1sig->SetLineStyle(0);
    g_exp_1sig->SetLineWidth(0);
    // g_exp_1sig->SetFillColor(8);
    g_exp_1sig->SetFillColor(kGreen);
    g_exp_1sig->SetFillStyle(1001);
    // g_exp_1sig->SetFillStyle(3005);
    g_exp_1sig->Draw("3");
    // g_exp_1sig->Draw("lX");
  }
  
  
  // epxected limit
  if (g_exp) {
    g_exp->SetLineColor(kRed);
    g_exp->SetLineStyle(4);
    g_exp->SetLineWidth(2);
    g_exp->Draw("l3");
  }
  

  // observed limit
  if (g_obs) {
    g_obs->SetLineColor(kRed);
    g_obs->SetLineStyle(1);
    g_obs->SetLineWidth(2);
    g_obs->Draw("l");
  }
  
  // stop  
  // 2 sigma band
  if (stop_exp_2sig) {
    stop_exp_2sig->SetLineColor(0);
    stop_exp_2sig->SetLineStyle(0);
    stop_exp_2sig->SetLineWidth(0);
    stop_exp_2sig->SetFillColor(kYellow);
    stop_exp_2sig->SetFillStyle(1001);
    stop_exp_2sig->Draw("3");
  }
  
  // 1 sigma band
  if (stop_exp_1sig) {
    // stop_exp_1sig->SetLineColor(8);
    stop_exp_1sig->SetLineColor(0);
    stop_exp_1sig->SetLineStyle(0);
    stop_exp_1sig->SetLineWidth(0);
    // stop_exp_1sig->SetFillColor(8);
    stop_exp_1sig->SetFillColor(kGreen);
    stop_exp_1sig->SetFillStyle(1001);
    // stop_exp_1sig->SetFillStyle(3005);
    stop_exp_1sig->Draw("3");
    // stop_exp_1sig->Draw("lX");
  }
  
  
  // epxected limit
  if (stop_exp) {
    stop_exp->SetLineColor(kBlue);
    stop_exp->SetLineStyle(3);
    stop_exp->SetLineWidth(2);
    stop_exp->Draw("l3");
  }
  

  // observed limit
  if (stop_obs) {
    stop_obs->SetLineColor(kBlue);
    stop_obs->SetLineStyle(2);
    stop_obs->SetLineWidth(2);
    stop_obs->Draw("l");
  }
  
  

  TPaveText* blurb = new TPaveText(0.20, 0.63, 0.60, 0.90, "NDC");
  blurb->AddText("CMS Preliminary 2015");
  //blurb->AddText("CMS 2012");
  blurb->AddText("#int L dt = 2.46 fb^{-1}"); //,  #int L_{eff} dt = 935 pb^{-1}");
  //blurb->AddText("L^{max}_{inst} = 3.5 #times 10^{33} cm^{-2}s^{-1}");

  // std::stringstream label;
  // label<<"#int L dt = "<<lumi<<" pb^{-1}";
  // blurb->AddText(label.str().c_str());
  // double peakInstLumi=maxInstLumi;
  // int exponent=30;
  // while (peakInstLumi>10) {
  //   peakInstLumi/=10;
  //   ++exponent;
  // }
  // std::stringstream label2;
  // label2<<"L^{max}_{inst} = "<<peakInstLumi<<" x 10^{"<<exponent<<"} cm^{-2}s^{-1}";
//  blurb->AddText(label2.str().c_str());
  blurb->AddText("#sqrt{s} = 13 TeV");
  blurb->AddText("E_{g} > 120 GeV, E_{t} > 150 GeV");
  blurb->AddText("E_{jet} > 70 GeV");
  blurb->SetTextFont(42);
  blurb->SetBorderSize(0);
  blurb->SetFillColor(0);
  blurb->SetShadowColor(0);
  blurb->SetTextAlign(12);
  blurb->SetTextSize(0.033);
  blurb->Draw();

  TLegend* leg = new TLegend(0.6, 0.62, 0.87, 0.90,"95% CL Limits:","NDC");
  leg->SetTextSize(0.033);
  leg->SetBorderSize(0);
  leg->SetTextFont(42);
  leg->SetFillColor(0);

  leg->AddEntry(g_obs, " #tilde{g} observed", "l");
  leg->AddEntry(stop_obs, " #tilde{t} observed", "l");

  TGraph* expectedStyle1 = new TGraph (*g_exp);
  expectedStyle1->SetFillColor (g_exp_1sig->GetFillColor());
  TGraph* expectedStyle2 = new TGraph (*g_exp);
  expectedStyle2->SetFillColor (g_exp_2sig->GetFillColor());
  leg->AddEntry(expectedStyle1, " #tilde{g} expected #pm1#sigma", "lf");
  leg->AddEntry(expectedStyle2, " #tilde{g} expected #pm2#sigma", "lf");

  expectedStyle1 = new TGraph (*stop_exp);
  expectedStyle1->SetFillColor (stop_exp_1sig->GetFillColor());
  expectedStyle2 = new TGraph (*stop_exp);
  expectedStyle2->SetFillColor (stop_exp_2sig->GetFillColor());
  leg->AddEntry(expectedStyle1, " #tilde{t} expected #pm1#sigma", "lf");
  leg->AddEntry(expectedStyle2, " #tilde{t} expected #pm2#sigma", "lf");
  leg->Draw();

  h->Draw("sameaxis");

  canvas->Print("gluinostopMassLifetime.png");
  canvas->Print("gluinostopMassLifetime.pdf");
}
Example #19
0
// draw the same thing but after reco
void genPlots02(std::string fullPath, int nOverlay = 500, bool custBinning = false)
{
    const int fVerbose(1);
    setTDRStyle();
    gStyle->SetOptStat(112211);
    gStyle->SetPalette(1);
    // Canvas
    c = new TCanvas("c2","c2",1000,600);
    const unsigned int nPadX = 1;
    const unsigned int nPadY = 1;
    c->Divide(nPadX,nPadY);
    const unsigned int nPads=nPadX*nPadY;
    for(unsigned int i=1; i<=nPads; i++)
    {
	TPad* pad= (TPad*)c->cd(i);
	pad->SetTopMargin(0.10);
	pad->SetRightMargin(0.20);
	pad->SetLeftMargin(0.15);
    }
    // Open file
    TFile *f = TFile::Open(fullPath.c_str());
    if (f==0)
    {
	cout << "File " << fullPath << " not found -- exiting" << endl;
	return;
    }
    if(fVerbose>0)
	cout << "Succesfully opened file " << fullPath << endl;
    // Get TTree
    TTree* t = (TTree*) f->Get("events");
    if(fVerbose>0) cout << "Got TTree with " << t->GetEntries() << " entries" << endl;
    // Do a cut, if needed
    //t->Draw(">>lst","chi2lb>.1&&mlb>5.61&&mlb<5.63");
    //t->Draw(">>lst","chi2lb>.1&&isSig==1");
    t->Draw(">>lst","(rid1m&4)==4&&(rid2m&4)==4&&mjp>2.895&&mjp<3.295&&prob1m>0.1&&prob2m>0.1&&ptjp>2&&probjp>0.005&&ml0>1.101&&ml0<1.129&&probpr>0.02&&probpi>0.02&&rptpr>rptpi&&ptl0>3&&rptpr>1&&rptpi>0.5&&probl0>0.02&&alphal0<0.3&&d3l0>1&&d3l0/d3El0>10&&problb>0.001&&alphalb<0.3");
    TEventList *lst;
    lst = (TEventList*)gDirectory->Get("lst");
    t->SetEventList(lst);
    if(fVerbose>0) cout << "Got TTree with " << t->GetEntries() << " entries" << endl;

    // Do plots
    c->cd(1);
    //doPlot2d(t,"hrzL0vtx", "vrl0:TMath::Abs(vzl0)",30,0,300,30,0,120,"Tit","|z|","r","cm","cm");
    if (custBinning)
    {
	double newbinsX[]={0,2,4,6,8,10,12,14,16,18,20,22,24,26,28,30,32,34,36,38,40,42,44,46,48,50};
	const int newbinsX_size = sizeof(newbinsX)/sizeof(double);
	std::vector<double> binvecX(newbinsX,newbinsX+newbinsX_size);
	//double newbinsY[]={0,1,2,3,4,5,6,7,8,9,10};
	double newbinsY[]={0,0.5,1,2,4,8,16,32};
	const int newbinsY_size = sizeof(newbinsY)/sizeof(double);
	std::vector<double> binvecY(newbinsY,newbinsY+newbinsY_size);
	doPlot2d(t,"hrzL0vtxreco", "vrl0:TMath::Abs(vzl0)",binvecX, binvecY,"#Lambda vertices","|z|","r","cm","cm");
    }
    else
    {
	doPlot2d(t,"hrzL0vtxreco", "vrl0:TMath::Abs(vzl0)",30,0,50,30,0,30,"#Lambda vertices","|z|","r","cm","cm");
    }

    // add tracker
    TPad* pad;
    pad = (TPad*)c->cd(1);
    pad->Modified();
    pad->Update();
    repositionPalette("hrzL0vtxreco");
    pad->Update();
    pad->SetLogz();
    drawTracker(pad);

    if (nOverlay<=0) return;
    int maxN = nOverlay;
    if (maxN > t->GetEntries()) maxN = t->GetEntries();
    double vrl0,vzl0,ppr,ppi,etapr,etapi;
    t->SetBranchAddress("vrl0",&vrl0);
    t->SetBranchAddress("vzl0",&vzl0);
    t->SetBranchAddress("ppr",&ppr);
    t->SetBranchAddress("etapr",&etapr);
    t->SetBranchAddress("ppi",&ppi);
    t->SetBranchAddress("etapi",&etapi);
    double scalepr = 4;
    double scalepi = 8;

    { // reference indicator
	const double x1pr = 0; const double y1pr = -3;
	const double x2pr = scalepr; const double y2pr = y1pr;
	const double versatz = 14;
	const double x1pi = x1pr+versatz; const double y1pi = -3;
	const double x2pi = x2pr+versatz+scalepi; const double y2pi = y1pi;
	TArrow *a;
	a = new TArrow(x1pr,y1pr,x2pr,y2pr,.01,">");
	a->SetLineColor(24);
	a->Draw();
	TLatex tl;
	tl.SetTextSize(20);
	tl.SetTextFont(4);
	tl.DrawLatex(x1pr,y2pr-1.2,"p(p) / 1 GeV");
	a = new TArrow(x1pi,y1pi,x2pi,y2pi,.01,">");
	a->SetLineColor(20);
	a->Draw();
	tl.SetTextSize(20);
	tl.SetTextFont(4);
	tl.DrawLatex(x1pi,y2pi-1.2,"p(#pi) / 1 GeV");
    }
    for (int i = 0; i!=maxN; i++)
    {
	t->GetEntry(i);
	const double thetapr = 2*TMath::ATan(TMath::Exp(-TMath::Abs(etapr)));
	const double thetapi = 2*TMath::ATan(TMath::Exp(-TMath::Abs(etapi)));
	const double x1=TMath::Abs(vzl0);
	const double y1=vrl0;
	const double x2pr=x1+scalepr*ppr*TMath::Cos(thetapr);
	const double y2pr=y1+scalepr*ppr*TMath::Sin(thetapr);
	const double x2pi=x1+scalepi*ppi*TMath::Cos(thetapi);
	const double y2pi=y1+scalepi*ppi*TMath::Sin(thetapi);
	TArrow *a;
        a = new TArrow(x1,y1,x2pr,y2pr,.01,">");
	a->SetLineColor(24);
	a->Draw();
        a = new TArrow(x1,y1,x2pi,y2pi,.01,">");
	a->SetLineColor(20);
	a->Draw();
	TMarker *m = new TMarker(x1,y1,7);
	m->SetMarkerColor(28);
	m->Draw();
    }
}