ReverseXAxis (TGraphAsymmErrors *g, double size) { // Remove the current axis g->GetXaxis()->SetLabelOffset(999); g->GetXaxis()->SetTickLength(0); // Redraw the new axis gPad->Update(); g->GetYaxis()->SetTitle("Event Selection Efficiency"); TGaxis *newaxis = new TGaxis(gPad->GetUxmax(), gPad->GetUymin(), gPad->GetUxmin(), gPad->GetUymin(), g->GetXaxis()->GetXmin(), g->GetXaxis()->GetXmax(), 510,"-"); newaxis->SetLabelOffset(-0.04); newaxis->SetTitle("Centrality"); newaxis->SetTitleFont(42); newaxis->SetTitleSize(size); newaxis->SetLabelSize(size); newaxis->CenterTitle(); newaxis->SetLabelFont(42); newaxis->Draw(); }
void plot_figure(TString fn,TPad *thePad,bool saxis=false,float ymin=-2.0,float ymax=1.0,bool with_d=false) { //cout<<"wit"<<with_d<<endl; gStyle->SetOptFit(); gStyle->SetPadTickY(1); gStyle->SetLineStyleString(11,"40 20"); float xmin=0,xmax=2; thePad->cd(); //thePad->SetGrid(); /***************************************************** Colors *****************************************************/ int HRMcol=kRed+2; int RNAcol=kMagenta; int QGScol=kGreen+1; float kb2b=1000; Double_t x,y; /***************************************************** Format the pad *****************************************************/ thePad->SetTopMargin(0.15); TH1F *hr = thePad->DrawFrame(xmin,ymin,xmax,ymax); hr->SetXTitle("Q (GeV)"); hr->SetYTitle("t_{20}"); /*hr->GetYaxis()->SetTitleOffset(1.5); hr->GetYaxis()->SetTitleSize(.06); hr->GetYaxis()->SetTitleFont(42); hr->GetYaxis()->CenterTitle(); hr->GetXaxis()->SetTitleSize(.06); hr->GetXaxis()->SetTitleFont(42); *//***************************************************** Draw legend *****************************************************/ TLegend *dummylegend=new TLegend(); TLegend *legend=new TLegend(0.59,0.17,0.94,0.55); legend->SetMargin(0.2); legend->SetTextFont(72); legend->SetTextSize(0.035); legend->SetFillStyle(0); legend->SetBorderSize(0); legend->Draw(); TLegend *thlegend=new TLegend(0.23,0.64,0.57,0.84); thlegend->SetMargin(0.2); thlegend->SetTextFont(72); thlegend->SetTextSize(0.035); thlegend->SetFillStyle(0); thlegend->SetBorderSize(0); thlegend->Draw(); thePad->SetLeftMargin(0.19); /***************************************************** Draw top axis *****************************************************/ float titlex1=0.47, titley1=0.85,titlex2=0.56,titley2=0.95; if (saxis) { titley1=0.72;titley2=0.82; TGaxis *axispp = new TGaxis(thePad->GetUxmin(),thePad->GetUymax()*1, thePad->GetUxmax(), thePad->GetUymax()*1, xmin*0.1973, xmax*0.1973,510,"-R"); axispp->SetTitle("Q (GeV)"); axispp->SetLabelFont(42); axispp->SetLabelSize(0.04); axispp->SetTitleFont(42); axispp->SetTitleSize(.055); axispp->Draw(); } /***************************************************** Make Title *****************************************************/ //TPaveLabel *label = new TPaveLabel(titlex1,titley1,titlex2,titley2,"^{3}He(#gamma,pp)n","NDC"); //label->SetTextSize(0.7); //label->SetFillStyle(0); //label->SetTextFont(42); //label->SetBorderSize(0); //label->Draw(); //TPaveLabel *label = new TPaveLabel(titlex1,titley1-0.06,titlex2,titley2-0.06,"90#circc.m.","NDC"); //label->SetTextSize(0.5); //label->SetFillStyle(0); //label->SetTextFont(42); //label->SetBorderSize(0); //label->Draw(); /*-------------------------------------------------------------------------------------- Constants? ---------------------------------------------------------------------------------------*/ Double_t xmd = 1.875613; Double_t xmdsq = xmd*xmd; Double_t q0sq = 1.15; Double_t degr = 0.01745329252; Double_t xhbarc = 0.1973; /*-------------------------------------------------------------------------------------- Plot IMII modelfor t20 ---------------------------------------------------------------------------------------*/ const Int_t npt = 94; //Double_t x, y; Double_t qfm[npt]; Double_t qsqpt[npt] = {0.0003893797, 0.003893797, 0.03893797, 0.05840695, 0.07787593, 0.09734491, 0.1168139, 0.1362829, 0.1557519, 0.1752208, 0.1946898, 0.2530968, 0.3115037, 0.3893797, 0.4672556, 0.5451315, 0.6230075, 0.7008834, 0.7787593, 0.8566352, 0.9345112, 1.012387, 1.090263, 1.168139, 1.246015, 1.323891, 1.401767, 1.479643, 1.557519, 1.596457, 1.635395, 1.674333, 1.71327, 1.752208, 1.810615, 1.830084, 1.869022, 1.90796, 1.946898, 1.985836, 2.024774, 2.063712, 2.10265, 2.141588, 2.180526, 2.219464, 2.258402, 2.29734, 2.336278, 2.375216, 2.414154, 2.453092, 2.49203, 2.530968, 2.569906, 2.608844, 2.647782, 2.68672, 2.725658, 2.803534, 2.881409, 2.959285, 3.037161, 3.115037, 3.309727, 3.504417, 3.699107, 3.893797, 4.088486, 4.283176, 4.477866, 4.672556, 4.867246, 5.061936, 5.256625, 5.451315, 5.646005, 5.840695, 6.035385, 6.230075, 6.424764, 6.619454, 6.716799, 6.814144, 6.911489, 7.008834, 7.106179, 7.203524, 7.300869, 7.398214, 7.495558, 7.592903, 7.690248, 7.787593}; Double_t t20theory[npt] = {-0.001309568, -0.0131055, -0.1318868, -0.1984704, -0.2654408, -0.3327329, -0.4002368, -0.4677915, -0.5351828, -0.6021447, -0.668362, -0.8587877, -1.027779, -1.198694, -1.286326, -1.282388, -1.197382, -1.054978, -0.8820486, -0.7009335, -0.5265257, -0.3668914, -0.2252485, -0.1019077, 0.004321276, 0.09524616, 0.1728195, 0.238883, 0.2950801, 0.3199333, 0.3428342, 0.3639258, 0.3833423, 0.4012027, 0.4253075, 0.432676, 0.4464807, 0.4591073, 0.4706305, 0.4811208, 0.4906344, 0.4992296, 0.506956, 0.5138575, 0.5199757, 0.5253475, 0.5300049, 0.5339787, 0.5372949, 0.539977, 0.5420477, 0.5435232, 0.5444235, 0.5447623, 0.5445543, 0.5438103, 0.5425456, 0.540766, 0.5384844, 0.5324458, 0.5245013, 0.514713, 0.5031468, 0.4898722, 0.4497016, 0.4006593, 0.3444063, 0.2827923, 0.2178549, 0.1514989, 0.08547981, 0.02124835, -0.04018853, -0.09806195, -0.1520174, -0.2019219, -0.2477681, -0.2898, -0.3282607, -0.3633281, -0.3951718, -0.4241511, -0.4375907, -0.4502916, -0.4622216, -0.473322, -0.4835232, -0.4927239, -0.500801, -0.5076282, -0.513053, -0.516797, -0.5184837, -0.5176145}; //FILE *fp = fopen("im2.dat","r"); for (Int_t i=0;i<npt;i++) { // Int_t ncols = fscanf(fp,"%f, %f",&x, &y); // qsqpt[i] = x; // t20theory[i] = y; qfm[i] = qsqpt[i]**(0.5)/xhbarc; // printf(" line %d read: %f %f \n",i,qsqpt[i],t20theory[i]); } //fclose(fp); //TGraph* gQGS=new TGraph("log170_89.dat","%lg %lg"); gQGS = new TGraph(npt,qsqpt,t20theory); gQGS->SetLineColor(kMagenta); gQGS->SetMarkerStyle(20); gQGS->SetMarkerSize(1.3); gQGS->SetLineStyle(11); gQGS->SetLineWidth(2); gQGS->Draw("l"); thlegend->AddEntry(gQGS,"IMII","L"); /*-------------------------------------------------------------------------------------- Plot IMII+ME modelfor t20 ---------------------------------------------------------------------------------------*/ Double_t t20theoryme[npt] = {-0.001325945, -0.01328168, -0.1349228, -0.2041014, -0.2743705, -0.3456319, -0.4177289, -0.4904376, -0.5634585, -0.6364107, -0.7088243, -0.9168859, -1.095754, -1.251422, -1.277469, -1.170903, -0.9677308, -0.7200701, -0.4713423, -0.2466468, -0.05555869, 0.101535, 0.2283672, 0.3298602, 0.4107891, 0.4752683, 0.5266488, 0.567598, 0.6002075, 0.6139116, 0.6261154, 0.6369641, 0.6465931, 0.6551208, 0.6660647, 0.6692667, 0.6750632, 0.6801088, 0.6844693, 0.6882072, 0.6913724, 0.694014, 0.6961743, 0.6978924, 0.6992062, 0.7001432, 0.7007343, 0.701005, 0.7009771, 0.7006715, 0.7001097, 0.6993112, 0.6982906, 0.6970643, 0.6956426, 0.6940377, 0.6922587, 0.6903158, 0.6882191, 0.6836015, 0.6784688, 0.6728624, 0.6668122, 0.6603509, 0.6425963, 0.622676, 0.6008623, 0.5773537, 0.5521636, 0.5259722, 0.4991099, 0.4706432, 0.4410795, 0.4127616, 0.3872456, 0.3640124, 0.3422358, 0.3246932, 0.3143134, 0.3116054, 0.3142227, 0.3184956, 0.3200235, 0.3212056, 0.3227668, 0.3250734, 0.3281051, 0.3321319, 0.3372873, 0.3437867, 0.351448, 0.3600231, 0.3689893, 0.3779735}; TGraph* gRNA=new TGraph(npt,qsqpt,t20theoryme); gRNA->SetLineColor(kRed); gRNA->SetMarkerStyle(1); gRNA->SetMarkerSize(1.3); gRNA->SetLineStyle(11); gRNA->SetLineWidth(3); gRNA->Draw("l"); thlegend->AddEntry(gRNA,"IM+E II","L"); /*-------------------------------------------------------------------------------------- Dan Phillips no rpg(f/g=0) ---------------------------------------------------------------------------------------*/ const Int_t nph = 66; Double_t qph[nph] = { 0.01, 0.25, 0.5, 0.75, 1.0, 1.5, 2.0, 2.5, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0, 13.0, 14.0, 15.0, 16.0, 17.0, 18.0, 19.0, 20.0, 21.0, 22.0, 23.0, 24.0, 25.0, 26.0, 27.0, 28.0, 29.0, 30.0, 31.0, 32.0, 33.0, 34.0, 35.0, 36.0, 37.0, 38.0, 39.0, 40.0, 41.0, 42.0, 43.0, 44.0, 45.0, 47.5, 50.0, 52.5, 55.0, 57.5, 60.0, 62.5, 65.0, 70.0, 75.0, 80.0, 85.0, 90.0, 95.0, 100.0}; for (Int_t i=0;i<nph;i++) {qph[i] = qph[i]*xhbarc**2;} Double_t tphrpg0[nph] = {-0.00139028, -0.0347797, -0.0705278, -0.106823, -0.143214, -0.215941, -0.28903, -0.36176, -0.437352, -0.594782, -0.753442, -0.905365, -1.04209, -1.14824, -1.2301, -1.27076, -1.26585, -1.21681, -1.13043, -1.01648, -0.885684, -0.7701, -0.630809, -0.495011, -0.366781, -0.248492, -0.141153, -0.0449377, 0.0407569, 0.116675, 0.183835, 0.230211, 0.284553, 0.332797, 0.375647, 0.41358, 0.447136, 0.476061, 0.502346, 0.525668, 0.546396, 0.561598, 0.57851, 0.593626, 0.607141, 0.619222, 0.630017, 0.638943, 0.647659, 0.655433, 0.662379, 0.675447, 0.686163, 0.693653, 0.698255, 0.70103, 0.701985, 0.701414, 0.699577, 0.696913, 0.68897, 0.68092, 0.673572, 0.668027, 0.665207, 0.664439}; TGraph* gph=new TGraph(nph,qph,tphrpg0); gph->SetLineColor(9); gph->SetMarkerStyle(1); gph->SetMarkerSize(1.3); gph->SetLineStyle(1); gph->SetLineWidth(3); gph->Draw("l"); thlegend->AddEntry(gph,"#rho#pi#gamma f/g=0","L"); Double_t tphrpg3[nph] = {-0.00139212, -0.0348353, -0.0706589, -0.10705, -0.143559, -0.216597, -0.290087, -0.363321, -0.439532, -0.598654, -0.759312, -0.913351, -1.0519, -1.15918, -1.24066, -1.27901, -1.2698, -1.21493, -1.12197, -1.00156, -0.865071, -0.744981, -0.60214, -0.464095, -0.334789, -0.216384, -0.109662, -0.0145868, 0.069612, 0.143819, 0.20915, 0.254731, 0.307099, 0.353368, 0.394259, 0.43028, 0.461982, 0.489554, 0.51413, 0.535803, 0.554941, 0.568991, 0.584356, 0.59797, 0.610026, 0.620686, 0.630093, 0.63772, 0.645084, 0.651525, 0.657156, 0.666024, 0.673624, 0.678127, 0.679481, 0.67949, 0.677837, 0.674823, 0.670722, 0.662356, 0.650039, 0.638996, 0.628928, 0.620671, 0.614933, 0.610454}; //TGraph* gph3=new TGraph(nph,qph,tphrpg3); //gph3->SetLineColor(39); //gph3->SetMarkerStyle(1); //gph3->SetMarkerSize(1.3); //gph3->SetLineStyle(2); //gph3->SetLineWidth(2); //TPaveLabel * Label = new TPaveLabel(0.20,0.66,0.48,0.71,"Propagator f/g=3","NDC"); //Label->SetTextSize(0.6); //Label->SetLineColor(kWhite); //Label->SetFillColor(kWhite); //Label->SetTextColor(39); //Label->SetBorderSize(0); //Label->Draw(); //gph3->Draw("l"); Double_t tphrpg6[nph] = {-0.00139403, -0.0348929, -0.0707944, -0.107286, -0.143917, -0.217276, -0.29118, -0.364936, -0.441787, -0.602659, -0.765378, -0.921581, -1.06195, -1.17027, -1.25116, -1.28686, -1.27292, -1.21183, -1.11202, -0.985056, -0.84299, -0.718589, -0.572616, -0.432822, -0.302967, -0.184961, -0.0793357, 0.0141671, 0.0964853, 0.168642, 0.231842, 0.276257, 0.326398, 0.370465, 0.409197, 0.443123, 0.472809, 0.498773, 0.52149, 0.541377, 0.558796, 0.571442, 0.58515, 0.597161, 0.607665, 0.616818, 0.624764, 0.630973, 0.636932, 0.642002, 0.646291, 0.650319, 0.654857, 0.656509, 0.654827, 0.652371, 0.648479, 0.643459, 0.637587, 0.622962, 0.607813, 0.595048, 0.583592, 0.574033, 0.566854, 0.560502}; TGraph* gph6=new TGraph(nph,qph,tphrpg6); gph6->SetLineColor(49); gph6->SetMarkerStyle(1); gph6->SetMarkerSize(1.3); gph6->SetLineStyle(1); gph6->SetLineWidth(2); gph6->Draw("l"); thlegend->AddEntry(gph6,"#rho#pi#gamma f/g=6.1","L"); /*-------------------------------------------------------------------------------------- put line at -root(2) ---------------------------------------------------------------------------------------*/ Int_t n = 2; float xfm[2] = {0., 9.}; float yt20[2] = {0., 0.}; TGraph* g0=new TGraph(n,xfm,yt20); g0->SetLineColor(1); g0->SetMarkerStyle(1); g0->SetMarkerSize(1.3); g0->SetLineStyle(1); g0->SetLineWidth(1); g0->Draw("l"); yt20[0] = -1.*2**(0.5); yt20[1] = yt20[0]; xfm[1] = 1.; TGraph* g1=new TGraph(n,xfm,yt20); g1->SetLineColor(1); g1->SetMarkerStyle(1); g1->SetMarkerSize(1.3); g1->SetLineStyle(3); g1->SetLineWidth(1); g1->Draw("l"); /* sanity checks plots11dsdtSet(100,0.040,0.020,0.05,0.000,0.140,kBlack,legend,"E03-101 140 MeV Bins Pn< 100 Mev/c 80 mr X 40 mr"); */ /* PRL */ //plotSet(kBlue,legend,"T_{20}"); //plotSet(kBlue,legend,""); plotSet(kBlue,legend,""); //plots11dsdtSet(kBlue,legend,""); /***************************************************** Add the rest of the legend enteries *****************************************************/ //if(!with_d){ //legend->AddEntry(gQGS,"QGS","l"); //legend->AddEntry(gRNA,"RNA","l"); //legend->AddEntry(gHRM,"HRM","F"); //}; gStyle->SetPaperSize(20,26); //default //TPaveLabel *label = new TPaveLabel(0.5,0.4,0.85,0.5,"Preliminary","NDC"); //label->SetTextColor(kBlue); //label->Draw(); //cout<<with_d<<endl; c->SaveAs(fn+".pdf"); c->SaveAs(fn+".eps"); c->SaveAs(fn+".png"); }
//************************************************************* void arrangeCanvas(TCanvas *canv,TH1F* meanplots[100],TH1F* widthplots[100],Int_t nFiles, TString LegLabels[10], bool onlyBias){ //************************************************************* TPaveText *ali = new TPaveText(0.18,0.87,0.50,0.93,"NDC"); ali->SetFillColor(10); ali->SetTextColor(1); ali->SetTextFont(42); ali->SetMargin(0.); ali->SetLineColor(10); ali->SetShadowColor(10); // pt->SetTextAlign(11); TText *alitext = ali->AddText("Alignment: PCL"); //"Preliminary 2015 - 0T collision data"); alitext->SetTextSize(0.04); TLegend *lego = new TLegend(0.18,0.80,0.78,0.92); lego-> SetNColumns(2); //TLegend *lego = new TLegend(0.18,0.77,0.50,0.86); lego->SetFillColor(10); lego->SetTextSize(0.04); lego->SetTextFont(42); lego->SetFillColor(10); lego->SetLineColor(10); lego->SetShadowColor(10); TPaveText *pt = NULL; TPaveText *pt2 = NULL; TPaveText *pt3 = NULL; if(!onlyBias){ pt =new TPaveText(0.179,0.955,0.260,0.985,"NDC"); } else { pt =new TPaveText(0.179,0.955,0.260,0.985,"NDC"); } pt->SetFillColor(10); pt->SetTextColor(1); pt->SetTextFont(61); // pt->SetTextAlign(11); TText *text1 = pt->AddText("CMS"); //"Preliminary 2015 - 0T collision data"); text1->SetTextSize(0.05); float extraOverCmsTextSize = 0.76; if(!onlyBias){ pt2 =new TPaveText(0.3,0.95,0.503,0.98,"NDC"); } else { pt2 =new TPaveText(0.3,0.95,0.503,0.98,"NDC"); } pt2->SetFillColor(10); pt2->SetTextColor(1); pt2->SetTextFont(52); pt2->SetTextAlign(22); TText *text2 = pt2->AddText("work in progress"); text2->SetTextSize(0.05*extraOverCmsTextSize); if(!onlyBias){ pt3 =new TPaveText(0.6,0.95,0.98,0.98,"NDC"); } else { pt3 =new TPaveText(0.6,0.95,0.98,0.98,"NDC"); } pt3->SetFillColor(10); pt3->SetTextColor(1); pt3->SetTextFont(42); // pt2->SetTextAlign(11); TText *text3 = pt3->AddText("3.8T collision data 2015"); text3->SetTextSize(0.05*extraOverCmsTextSize); canv->SetFillColor(10); if(!onlyBias) { canv->Divide(2,1); canv->cd(1)->SetBottomMargin(0.12); canv->cd(1)->SetLeftMargin(0.17); canv->cd(1)->SetRightMargin(0.02); canv->cd(1)->SetTopMargin(0.06); canv->cd(2)->SetBottomMargin(0.12); canv->cd(2)->SetLeftMargin(0.17); canv->cd(2)->SetRightMargin(0.02); canv->cd(2)->SetTopMargin(0.06); canv->cd(1); } else { canv->cd()->SetBottomMargin(0.14); canv->cd()->SetLeftMargin(0.17); canv->cd()->SetRightMargin(0.02); canv->cd()->SetTopMargin(0.06); canv->cd(); } Double_t absmin(999.); Double_t absmax(-999.); for(Int_t i=0; i<nFiles; i++){ if(meanplots[i]->GetMaximum()>absmax) absmax = meanplots[i]->GetMaximum(); if(meanplots[i]->GetMinimum()<absmin) absmin = meanplots[i]->GetMinimum(); } Double_t safeDelta=(absmax-absmin)/2.; Double_t theExtreme=std::max(absmax,TMath::Abs(absmin)); for(Int_t i=0; i<nFiles; i++){ TString myTitle = meanplots[i]->GetName(); float axmin = -999; float axmax = 999.; int ndiv = 510; if(myTitle.Contains("eta")){ axmin = -2.5; axmax = 2.5; ndiv = 505; } else if (myTitle.Contains("phi")){ axmin = -TMath::Pi(); axmax = TMath::Pi(); ndiv = 510; } else { std::cout<<"unrecongnized variable"; } meanplots[i]->GetXaxis()->SetLabelOffset(999); meanplots[i]->GetXaxis()->SetTickLength(0); // Redraw the new axis gPad->Update(); TGaxis *newaxis = new TGaxis(gPad->GetUxmin(),gPad->GetUymin(), gPad->GetUxmax(),gPad->GetUymin(), axmin, axmax, //meanplots[i]->GetXaxis()->GetXmin(), //meanplots[i]->GetXaxis()->GetXmax(), ndiv,"SDH"); TGaxis *newaxisup = new TGaxis(gPad->GetUxmin(),gPad->GetUymax(), gPad->GetUxmax(),gPad->GetUymax(), axmin, axmax, //meanplots[i]->GetXaxis()->GetXmin(), //meanplots[i]->GetXaxis()->GetXmax(), ndiv,"-SDH"); newaxis->SetLabelOffset(0.02); newaxis->SetLabelFont(42); newaxis->SetLabelSize(.05); newaxis->Draw(); newaxisup->SetLabelOffset(-0.02); newaxisup->SetLabelFont(42); newaxisup->SetLabelSize(0); newaxisup->Draw(); if(i==0){ //meanplots[i]->GetYaxis()->SetRangeUser(absmin-safeDelta/2.,absmax+safeDelta); std::cout<<"name is: "<< meanplots[i]->GetName() << " absmin:" <<absmin<<" absmax: "<<absmax<<" safeDelta: "<<safeDelta<<std::endl; TString theTitle = meanplots[i]->GetName(); if( theTitle.Contains("Norm")){ meanplots[i]->GetYaxis()->SetRangeUser(std::min(-0.48,absmin-safeDelta),std::max(0.48,absmax+safeDelta)); } else { if(!onlyBias){ meanplots[i]->GetYaxis()->SetRangeUser(absmin-safeDelta,absmax+safeDelta); } else { meanplots[i]->GetYaxis()->SetRangeUser(-theExtreme-(TMath::Abs(absmin)/10.),theExtreme+(TMath::Abs(absmax/10.))); } //meanplots[i]->GetYaxis()->SetRangeUser(-theExtreme,theExtreme); } meanplots[i]->Draw("e1"); if(onlyBias){ Int_t nbins = meanplots[i]->GetNbinsX(); Double_t lowedge = meanplots[i]->GetBinLowEdge(1); Double_t highedge = meanplots[i]->GetBinLowEdge(nbins+1); TH1F* hzero = DrawZero(meanplots[i],nbins,lowedge,highedge); hzero->Draw("PLsame"); } } else meanplots[i]->Draw("e1sames"); lego->AddEntry(meanplots[i],LegLabels[i]); } //ali->Draw(); lego->Draw(); pt->Draw("same"); pt2->Draw("same"); pt3->Draw("same"); if(!onlyBias){ canv->cd(2); Double_t absmax2(-999.); for(Int_t i=0; i<nFiles; i++){ if(widthplots[i]->GetMaximum()>absmax2) absmax2 = widthplots[i]->GetMaximum(); } Double_t safeDelta2=absmax2/3.; for(Int_t i=0; i<nFiles; i++){ TString myTitle = widthplots[i]->GetName(); float axmin = -999; float axmax = 999.; int ndiv = 510; if(myTitle.Contains("eta")){ axmin = -2.5; axmax = 2.5; ndiv = 505; } else if (myTitle.Contains("phi")){ axmin = -TMath::Pi(); axmax = TMath::Pi(); ndiv = 510; } else { std::cout<<"unrecongnized variable"; } widthplots[i]->GetXaxis()->SetLabelOffset(999); widthplots[i]->GetXaxis()->SetTickLength(0); // Redraw the new axis gPad->Update(); TGaxis *newaxis2 = new TGaxis(gPad->GetUxmin(),gPad->GetUymin(), gPad->GetUxmax(),gPad->GetUymin(), axmin, axmax, //widthplots[i]->GetXaxis()->GetXmin(), //widthplots[i]->GetXaxis()->GetXmax(), ndiv,"SDH"); newaxis2->SetLabelOffset(0.02); newaxis2->SetLabelFont(42); newaxis2->SetLabelSize(.05); newaxis2->Draw(); TGaxis *newaxis2up = new TGaxis(gPad->GetUxmin(),gPad->GetUymax(), gPad->GetUxmax(),gPad->GetUymax(), axmin, axmax, //widthplots[i]->GetXaxis()->GetXmin(), //widthplots[i]->GetXaxis()->GetXmax(), ndiv,"-SDH"); newaxis2up->SetLabelOffset(-0.02); newaxis2up->SetLabelFont(42); newaxis2up->SetLabelSize(0.); newaxis2up->Draw(); if(i==0) widthplots[i]->Draw("e1"); else widthplots[i]->Draw("e1sames"); widthplots[i]->SetMinimum(0.5); widthplots[i]->SetMaximum(absmax2+safeDelta2); } lego->Draw(); pt->Draw("same"); pt2->Draw("same"); pt3->Draw("same"); } }
void drawmat_DBD(char* FILEN) { //char* title = "Material budget for ILD_O1_v05" ; double M_PI = 3.14159265358979312e+00 ; // 180./pi = 57.295779 ; //ntuple variables double itheta, nrvxd, nrsit, nrtpc, nrtpc_i, nrset, nrecal ; // stuff for histograms const int nhist = 7; TString htitle[nhist]; int idx = 0 ; htitle[idx++] = "ECAL layer 1"; htitle[idx++] = "SET"; htitle[idx++] = "outside TPC"; htitle[idx++] = "TPC"; htitle[idx++] = "SIT + FTD"; htitle[idx++] = "VXT"; htitle[idx++] = "dummy"; TString hname[nhist]; idx = 0 ; hname[idx++] = "ecal"; hname[idx++] = "set"; hname[idx++] = "tpc_o"; hname[idx++] = "tpc_i"; hname[idx++] = "sit"; hname[idx++] = "vtx"; hname[idx++] = "dummy"; int nbin = 90 ; // 720 float xmin = -90; float xmax = -0; int color[nhist] = { 14, 8, 38, 2, 1, 9}; TString option[nhist]; TLegend *leg = new TLegend (0.2, 0.7, 0.45, 0.9); leg->SetFillStyle(0); // stuff for histograms TH1F* hmat[nhist]; for (int ihist = 0; ihist < nhist; ihist++) { hmat[ihist] = new TH1F(hname[ihist],"",nbin,xmin,xmax); //// ensure proper errors // hmat[ihist]->Sumw2(); hmat[ihist]->SetLineColor(color[ihist]); hmat[ihist]->SetLineWidth(3); hmat[ihist]->SetTitle(";#theta / degrees;X_{0}"); } // read tree TFile* file = new TFile ( FILEN ) ; TTree* tree = (TTree *) file->Get("ntuple"); if (!tree) { cout << "ERROR: Couldn't open tree ntuple on file: "<< FILEN << endl; return 1; } tree->SetBranchAddress("itheta", &itheta); tree->SetBranchAddress("nrecal", &nrecal); tree->SetBranchAddress("nrset", &nrset); tree->SetBranchAddress("nrtpc", &nrtpc); tree->SetBranchAddress("nrtpc_i", &nrtpc_i); tree->SetBranchAddress("nrsit", &nrsit); tree->SetBranchAddress("nrvxd", &nrvxd); int entries = tree->GetEntries(); cout << "tree has " << entries << " entries" << endl; // event loop for (int ievt = 0; ievt < entries; ++ievt) { tree->GetEntry(ievt); if (itheta < 4.45) continue; hmat[0]->Fill(-itheta,nrecal); hmat[1]->Fill(-itheta,nrset); hmat[2]->Fill(-itheta,nrtpc); if( itheta > 8. ) hmat[3]->Fill(-itheta,nrtpc_i); hmat[4]->Fill(-itheta,nrsit); hmat[5]->Fill(-itheta,nrvxd); hmat[6]->Fill(-itheta,1); } // for (int ibin = 0; ibin < nbin+1; ++ibin) { // cout << "Bin " << ibin << " has " << hmat[4]->GetBinContent(ibin) << " entries" << endl; // } c1 = new TCanvas("c1","c1",600,600); bool first = true ; #define _include_Ecal 0 #if _include_Ecal for (int ihist = 0; ihist < nhist-1; ihist++) { #else for (int ihist = 1; ihist < nhist-1; ihist++) { #endif // average double counts hmat[ihist]->Divide( hmat[nhist-1] ); if( first ) { hmat[ihist]->Draw( "" ); // --------- change axis labels from minus to plus -------- c1->Update() ; TF1 *f1 = new TF1("f1","-x",0,90); hmat[ihist]->GetXaxis()->SetLabelOffset(99); Double_t x_min = c1->GetUxmin(); Double_t x_max = c1->GetUxmax(); Double_t y_min = c1->GetUymin(); //std::cout << "x_min " << x_min << " x_max " << x_max << " y_min " << y_min << std::endl ; TGaxis *axis = new TGaxis( x_min, y_min, x_max, y_min, "f1", 5); axis->SetLabelSize( 0.06 ); axis->SetLabelFont( 42 ); axis->Draw(); // -----end: change axis labels from minus to plus -------- first = false ; } else { hmat[ihist]->Draw( "same" ); } leg->AddEntry(hmat[ihist],htitle[ihist],"L"); } leg->Draw(); std::string pdfFile( std::string( FILEN ) + std::string( ".pdf" ) ) ; c1->Print( pdfFile.c_str() ) ; }
void plot_figure(TString fn,TPad *thePad,bool saxis=false,float ymin=1.0e-10,float ymax=1.0e-02,bool with_d=false) { //cout<<"wit"<<with_d<<endl; gStyle->SetOptFit(); gStyle->SetPadTickY(1); //gStyle->SetLogY(); gStyle->SetLineStyleString(11,"40 20"); float xmin=0,xmax=4; thePad->cd(); thePad->SetLogy(); //thePad->SetGrid(); /***************************************************** Colors *****************************************************/ int HRMcol=kRed+2; int RNAcol=kMagenta; int QGScol=kGreen+1; Double_t x,y; /***************************************************** Format the pad *****************************************************/ thePad->SetTopMargin(0.15); TH1F *hr = thePad->DrawFrame(xmin,ymin,xmax,ymax); hr->SetXTitle("Q^{2} (GeV^{2})"); hr->SetYTitle("B"); hr->GetYaxis()->SetTitleOffset(1.5); hr->GetYaxis()->SetTitleSize(.06); hr->GetYaxis()->SetTitleFont(42); hr->GetYaxis()->CenterTitle(); hr->GetXaxis()->SetTitleSize(.06); hr->GetXaxis()->SetTitleFont(42); /***************************************************** Draw legend *****************************************************/ TLegend *dummylegend=new TLegend(); TLegend *legend=new TLegend(0.66,0.64,0.93,0.84); legend->SetMargin(0.2); legend->SetTextFont(72); legend->SetTextSize(0.035); legend->SetFillStyle(0); legend->SetBorderSize(0); legend->Draw(); TLegend *thlegend=new TLegend(0.33,0.64,0.66,0.84); thlegend->SetMargin(0.2); thlegend->SetTextFont(72); thlegend->SetTextSize(0.035); thlegend->SetFillStyle(0); thlegend->SetBorderSize(0); thlegend->Draw(); thePad->SetLeftMargin(0.19); /***************************************************** Draw top axis *****************************************************/ float titlex1=0.47, titley1=0.85,titlex2=0.56,titley2=0.95; if (saxis) { titley1=0.72;titley2=0.82; TGaxis *axispp = new TGaxis(thePad->GetUxmin(),thePad->GetUymax(), thePad->GetUxmax(), thePad->GetUymax(), xmin/0.1973**2, xmax/0.1973**2,510,"-R"); axispp->SetTitle("Q^{2} (fm^{-2})"); axispp->SetLabelFont(42); axispp->SetLabelSize(0.04); axispp->SetTitleFont(42); axispp->SetTitleSize(.055); axispp->Draw(); } /***************************************************** Make Title *****************************************************/ //TPaveLabel *label = new TPaveLabel(titlex1,titley1,titlex2,titley2,"^{3}He(#gamma,pp)n","NDC"); //label->SetTextSize(0.7); //label->SetFillStyle(0); //label->SetTextFont(42); //label->SetBorderSize(0); //label->Draw(); //TPaveLabel *label = new TPaveLabel(titlex1,titley1-0.06,titlex2,titley2-0.06,"90#circc.m.","NDC"); //label->SetTextSize(0.5); //label->SetFillStyle(0); //label->SetTextFont(42); //label->SetBorderSize(0); //label->Draw(); /*-------------------------------------------------------------------------------------- Constants? ---------------------------------------------------------------------------------------*/ Double_t xmd = 1.875613; Double_t xmdsq = xmd*xmd; Double_t q0sq = 1.15; Double_t degr = 0.01745329252; Double_t xhbarc = 0.1973; /*-------------------------------------------------------------------------------------- Plot IMII modelfor B ---------------------------------------------------------------------------------------*/ const Int_t npt = 95; //Double_t x, y; Double_t qfm[npt]; Double_t qsqpt[npt] = { 0.0000, 0.0004, 0.0039, 0.0389, 0.0584, 0.0779, 0.0973, 0.1168, 0.1363, 0.1558, 0.1752, 0.1947, 0.2531, 0.3115, 0.3894, 0.4673, 0.5451, 0.6230, 0.7009, 0.7788, 0.8566, 0.9345, 1.0124, 1.0903, 1.1681, 1.2460, 1.3239, 1.4018, 1.4796, 1.5575, 1.5965, 1.6354, 1.6743, 1.7133, 1.7522, 1.8106, 1.8301, 1.8690, 1.9080, 1.9469, 1.9858, 2.0248, 2.0637, 2.1026, 2.1416, 2.1805, 2.2195, 2.2584, 2.2973, 2.3363, 2.3752, 2.4142, 2.4531, 2.4920, 2.5310, 2.5699, 2.6088, 2.6478, 2.6867, 2.7257, 2.8035, 2.8814, 2.9593, 3.0372, 3.1150, 3.3097, 3.5044, 3.6991, 3.8938, 4.0885, 4.2832, 4.4779, 4.6726, 4.8672, 5.0619, 5.2566, 5.4513, 5.6460, 5.8407, 6.0354, 6.2301, 6.4248, 6.6195, 6.7168, 6.8141, 6.9115, 7.0088, 7.1062, 7.2035, 7.3009, 7.3982, 7.4956, 7.5929, 7.6902, 7.7876}; Double_t atheory[npt] = { 1.0710E-05, 1.0574E-04, 9.3420E-04, 3.5050E-03, 3.4115E-03, 3.0845E-03, 2.6987E-03, 2.3221E-03, 1.9803E-03, 1.6807E-03, 1.4229E-03, 1.2034E-03, 7.2925E-04, 4.4651E-04, 2.3739E-04, 1.2959E-04, 7.2494E-05, 4.1431E-05, 2.4107E-05, 1.4229E-05, 8.4877E-06, 5.0970E-06, 3.0687E-06, 1.8439E-06, 1.0999E-06, 6.4724E-07, 3.7264E-07, 2.0753E-07, 1.0994E-07, 5.3905E-08, 3.6143E-08, 2.3248E-08, 1.4106E-08, 7.8561E-09, 3.8096E-09, 7.1157E-10, 2.6517E-10, 7.6047E-12, 3.8643E-10, 1.1987E-09, 2.2880E-09, 3.5354E-09, 4.8498E-09, 6.1665E-09, 7.4371E-09, 8.6270E-09, 9.7149E-09, 1.0688E-08, 1.1537E-08, 1.2263E-08, 1.2867E-08, 1.3352E-08, 1.3726E-08, 1.3996E-08, 1.4171E-08, 1.4259E-08, 1.4270E-08, 1.4209E-08, 1.4089E-08, 1.3914E-08, 1.3434E-08, 1.2822E-08, 1.2120E-08, 1.1364E-08, 1.0584E-08, 8.6526E-09, 6.8980E-09, 5.4000E-09, 4.1725E-09, 3.1908E-09, 2.4208E-09, 1.8250E-09, 1.3673E-09, 1.0200E-09, 7.5739E-10, 5.5948E-10, 4.1182E-10, 3.0194E-10, 2.2009E-10, 1.5958E-10, 1.1516E-10, 8.2658E-11, 5.8806E-11, 4.9418E-11, 4.1436E-11, 3.4661E-11, 2.8921E-11, 2.4066E-11, 1.9968E-11, 1.6516E-11, 1.3608E-11, 1.1156E-11, 9.0935E-12, 7.3668E-12, 5.9294E-12}; //TGraph* gQGS=new TGraph("log170_89.dat","%lg %lg"); gQGS = new TGraph(npt,qsqpt,atheory); gQGS->SetLineColor(kMagenta); gQGS->SetMarkerStyle(20); gQGS->SetMarkerSize(1.3); gQGS->SetLineStyle(11); gQGS->SetLineWidth(2); //TPaveLabel * Label = new TPaveLabel(0.74,0.24,0.84,0.30,"IMII","NDC"); //Label->SetTextSize(0.6); //Label->SetLineColor(kWhite); //Label->SetFillColor(kWhite); //Label->SetTextColor(kMagenta); //Label->SetBorderSize(0); //Label->Draw(); gQGS->Draw("l"); thlegend->AddEntry(gQGS,"IMII","L"); /*-------------------------------------------------------------------------------------- Plot IMII+ME modelfor B ---------------------------------------------------------------------------------------*/ Double_t atheoryme[npt] = { 1.0806E-05, 1.0669E-04, 9.4299E-04, 3.5533E-03, 3.4668E-03, 3.1422E-03, 2.7561E-03, 2.3777E-03, 2.0331E-03, 1.7302E-03, 1.4689E-03, 1.2459E-03, 7.6183E-04, 4.7094E-04, 2.5382E-04, 1.4061E-04, 7.9917E-05, 4.6454E-05, 2.7523E-05, 1.6562E-05, 1.0086E-05, 6.1936E-06, 3.8206E-06, 2.3582E-06, 1.4498E-06, 8.8327E-07, 5.2973E-07, 3.1019E-07, 1.7528E-07, 9.3887E-08, 6.6801E-08, 4.6325E-08, 3.1059E-08, 1.9921E-08, 1.1991E-08, 4.6073E-09, 3.0706E-09, 1.0502E-09, 1.3882E-10, 4.4654E-11, 5.3635E-10, 1.4329E-09, 2.5922E-09, 3.9043E-09, 5.2841E-09, 6.6632E-09, 8.0019E-09, 9.2634E-09, 1.0425E-08, 1.1476E-08, 1.2409E-08, 1.3215E-08, 1.3893E-08, 1.4448E-08, 1.4882E-08, 1.5208E-08, 1.5432E-08, 1.5567E-08, 1.5619E-08, 1.5596E-08, 1.5350E-08, 1.4883E-08, 1.4254E-08, 1.3528E-08, 1.2744E-08, 1.0662E-08, 8.6328E-09, 6.8749E-09, 5.3894E-09, 4.1719E-09, 3.2238E-09, 2.4857E-09, 1.9002E-09, 1.4523E-09, 1.1197E-09, 8.7045E-10, 6.7932E-10, 5.3066E-10, 4.1792E-10, 3.3449E-10, 2.7250E-10, 2.2493E-10, 1.8672E-10, 1.7020E-10, 1.5532E-10, 1.4219E-10, 1.3070E-10, 1.2068E-10, 1.1198E-10, 1.0447E-10, 9.8023E-11, 9.2442E-11, 8.7575E-11, 8.3244E-11, 7.9331E-11}; TGraph* gRNA=new TGraph(npt,qsqpt,atheoryme); gRNA->SetLineColor(kRed); gRNA->SetMarkerStyle(1); gRNA->SetMarkerSize(1.3); gRNA->SetLineStyle(11); gRNA->SetLineWidth(3); //TPaveLabel * Label = new TPaveLabel(0.72,0.34,0.89,0.40,"IM+E II","NDC"); //Label->SetTextSize(0.6); //Label->SetLineColor(kWhite); //Label->SetFillColor(kWhite); //Label->SetTextColor(kRed); //Label->SetBorderSize(0); //Label->Draw(); gRNA->Draw("l"); thlegend->AddEntry(gRNA,"IM+E II","L"); /*-------------------------------------------------------------------------------------- Dan Phillips no rpg(f/g=0) ---------------------------------------------------------------------------------------*/ const Int_t nph = 66; Double_t qph[nph] = { 0.0, 0.2, 0.5, 0.8, 1.0, 1.5, 2.0, 2.5, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0, 13.0, 14.0, 15.0, 16.0, 17.0, 18.0, 19.0, 20.0, 21.0, 22.0, 23.0, 24.0, 25.0, 26.0, 27.0, 28.0, 29.0, 30.0, 31.0, 32.0, 33.0, 34.0, 35.0, 36.0, 37.0, 38.0, 39.0, 40.0, 41.0, 42.0, 43.0, 44.0, 45.0, 47.5, 50.0, 52.5, 55.0, 57.5, 60.0, 62.5, 65.0, 70.0, 75.0, 80.0, 85.0, 90.0, 95.0, 100.0}; for (Int_t i=0;i<nph;i++) {qph[i] = qph[i]*xhbarc**2;} Double_t tphrpg0[nph] = { 1.0947E-04, 1.9851E-03, 2.9335E-03, 3.3468E-03, 3.4916E-03, 3.4072E-03, 3.1031E-03, 2.7207E-03, 2.3330E-03, 1.6663E-03, 1.1822E-03, 8.4372E-04, 6.0546E-04, 4.3536E-04, 3.1518E-04, 2.3030E-04, 1.6981E-04, 1.2638E-04, 9.4826E-05, 7.1682E-05, 5.4533E-05, 4.1635E-05, 3.1895E-05, 2.4516E-05, 1.8919E-05, 1.4661E-05, 1.1401E-05, 8.8907E-06, 6.9517E-06, 5.4487E-06, 4.2756E-06, 3.3572E-06, 2.6366E-06, 2.0698E-06, 1.6242E-06, 1.2738E-06, 9.9798E-07, 7.9339E-07, 6.2007E-07, 4.8291E-07, 3.7446E-07, 2.8884E-07, 2.2138E-07, 1.6846E-07, 1.2710E-07, 9.4863E-08, 6.9878E-08, 5.0644E-08, 3.5914E-08, 2.4760E-08, 1.6446E-08, 7.0652E-09, 1.2173E-09, 7.6159E-12, 9.6591E-10, 2.6954E-09, 4.5038E-09, 6.0939E-09, 7.3450E-09, 6.3859E-09, 6.7640E-09, 6.3279E-09, 5.5286E-09, 4.5850E-09, 3.6182E-09, 2.7204E-09}; TGraph* gph=new TGraph(nph,qph,tphrpg0); gph->SetLineColor(9); gph->SetMarkerStyle(1); gph->SetMarkerSize(1.3); gph->SetLineStyle(1); gph->SetLineWidth(3); //TPaveLabel * Label = new TPaveLabel(0.545,0.16,0.755,0.22,"#rho#pi#gamma f/g=0","NDC"); //Label->SetTextSize(0.6); //Label->SetLineColor(kWhite); //Label->SetFillColor(kWhite); //Label->SetTextColor(9); //Label->SetBorderSize(0); //Label->Draw(); gph->Draw("l"); thlegend->AddEntry(gph,"#rho#pi#gamma f/g=0","L"); Double_t tphrpg3[nph] = {1.0907E-04, 1.9766E-03, 2.9192E-03, 3.3286E-03, 3.4707E-03, 3.3824E-03, 3.0769E-03, 2.6944E-03, 2.3073E-03, 1.6423E-03, 1.1612E-03, 8.2554E-04, 5.8989E-04, 4.2211E-04, 3.0392E-04, 2.2073E-04, 1.6165E-04, 1.1941E-04, 8.8865E-05, 6.6570E-05, 5.0141E-05, 3.7859E-05, 2.8647E-05, 2.1720E-05, 1.6508E-05, 1.2580E-05, 9.6042E-06, 7.3376E-06, 5.6085E-06, 4.2865E-06, 3.2703E-06, 2.4882E-06, 1.8860E-06, 1.4224E-06, 1.0665E-06, 7.9418E-07, 5.8638E-07, 4.3319E-07, 3.1260E-07, 2.2158E-07, 1.5352E-07, 1.0325E-07, 6.6740E-08, 4.0856E-08, 2.3101E-08, 1.1490E-08, 4.5140E-09, 9.8979E-10, 3.1737E-13, 8.5748E-10, 3.0274E-09, 9.8315E-09, 1.9608E-08, 2.8845E-08, 3.6378E-08, 4.1832E-08, 4.5388E-08, 4.7378E-08, 4.8091E-08, 4.4323E-08, 4.0773E-08, 3.5870E-08, 3.0742E-08, 2.5819E-08, 2.1278E-08, 1.7241E-08}; //TGraph* gph3=new TGraph(nph,qph,tphrpg3); //gph3->SetLineColor(39); //gph3->SetMarkerStyle(1); //gph3->SetMarkerSize(1.3); //gph3->SetLineStyle(2); //gph3->SetLineWidth(2); //TPaveLabel * Label = new TPaveLabel(0.60,0.49,0.82,0.55,"Propagator f/g=3","NDC"); //Label->SetTextSize(0.6); //Label->SetLineColor(kWhite); //Label->SetFillColor(kWhite); //Label->SetTextColor(39); //Label->SetBorderSize(0); //Label->Draw(); //gph3->Draw("l"); Double_t tphrpg6[nph] = {1.0866E-04, 1.9679E-03, 2.9046E-03, 3.3099E-03, 3.4491E-03, 3.3569E-03, 3.0500E-03, 2.6674E-03, 2.2810E-03, 1.6177E-03, 1.1396E-03, 8.0697E-04, 5.7402E-04, 4.0863E-04, 2.9249E-04, 2.1104E-04, 1.5343E-04, 1.1242E-04, 8.2908E-05, 6.1486E-05, 4.5796E-05, 3.4145E-05, 2.5473E-05, 1.9008E-05, 1.4190E-05, 1.0598E-05, 7.9092E-06, 5.8892E-06, 4.3719E-06, 3.2319E-06, 2.3729E-06, 1.7267E-06, 1.2421E-06, 8.8052E-07, 6.1299E-07, 4.1706E-07, 2.7536E-07, 1.7461E-07, 1.0443E-07, 5.7152E-08, 2.7017E-08, 9.6080E-09, 1.5284E-09, 1.7233E-10, 3.5226E-09, 1.0061E-08, 1.8644E-08, 2.8417E-08, 3.8799E-08, 4.9346E-08, 5.9730E-08, 8.3215E-08, 1.0290E-07, 1.1730E-07, 1.2653E-07, 1.3121E-07, 1.3238E-07, 1.3099E-07, 1.2769E-07, 1.1937E-07, 1.0601E-07, 9.1747E-08, 7.8220E-08, 6.5922E-08, 5.4966E-08, 4.5409E-08}; TGraph* gph6=new TGraph(nph,qph,tphrpg6); gph6->SetLineColor(49); gph6->SetMarkerStyle(1); gph6->SetMarkerSize(1.3); gph6->SetLineStyle(1); gph6->SetLineWidth(2); //TPaveLabel * Label = new TPaveLabel(0.23,0.16,0.45,0.22,"#rho#pi#gamma f/g=6.1","NDC"); //Label->SetTextSize(0.6); //Label->SetLineColor(kWhite); //Label->SetFillColor(kWhite); //Label->SetTextColor(49); //Label->SetBorderSize(0); //Label->Draw(); gph6->Draw("l"); thlegend->AddEntry(gph6,"#rho#pi#gamma f/g=6.1","L"); /* sanity checks plots11dsdtSet(100,0.040,0.020,0.05,0.000,0.140,kBlack,legend,"E03-101 140 MeV Bins Pn< 100 Mev/c 80 mr X 40 mr"); */ /* PRL */ //plotSet(kBlue,legend,"T_{20}"); //plotSet(kBlue,legend,""); plotSet(kBlue,legend,""); //plots11dsdtSet(kBlue,legend,""); /***************************************************** Add the rest of the legend enteries *****************************************************/ //if(!with_d){ //legend->AddEntry(gQGS,"QGS","l"); //legend->AddEntry(gRNA,"RNA","l"); //legend->AddEntry(gHRM,"HRM","F"); //}; gStyle->SetPaperSize(20,26); //default //TPaveLabel *label = new TPaveLabel(0.5,0.4,0.85,0.5,"Preliminary","NDC"); //label->SetTextColor(kBlue); //label->Draw(); //cout<<with_d<<endl; c->SaveAs(fn+".pdf"); c->SaveAs(fn+".eps"); c->SaveAs(fn+".png"); }
/// /// Make a plot out of a 1D histogram holding a 1-CL curve. /// The strategy is to always convert the 1-CL histogram (hCL) into /// a TGraph. This way we can add known points (solutions, points /// at end of scan range) and also have a filled area without line /// smoothing. This is not possible with histograms due to a Root bug. /// /// The function draws the TGraphs, and returns a pointer to the /// TGraph object that can be used in the TLegend. /// /// Markers are plotted if the method name of the scanner is "Plugin" or "BergerBoos" or "DatasetsPlugin". /// One can plot a line instead of points even for the Plugin method by /// using setPluginMarkers(). /// /// For the angle variables, a new axis is painted that is in Deg. /// /// \param s The scanner to plot. /// \param first /// \param last /// \param filled /// TGraph* OneMinusClPlot::scan1dPlot(MethodAbsScan* s, bool first, bool last, bool filled, int CLsType) { if ( arg->debug ){ cout << "OneMinusClPlot::scan1dPlot() : plotting "; cout << s->getName() << " (" << s->getMethodName() << ")" << endl; } if ( m_mainCanvas==0 ){ m_mainCanvas = newNoWarnTCanvas(name+getUniqueRootName(), title, 800, 600); } m_mainCanvas->cd(); bool plotPoints = ( s->getMethodName()=="Plugin" || s->getMethodName()=="BergerBoos" || s->getMethodName()=="DatasetsPlugin" ) && plotPluginMarkers; TH1F *hCL = (TH1F*)s->getHCL()->Clone(getUniqueRootName()); if (CLsType==1) hCL = (TH1F*)s->getHCLs()->Clone(getUniqueRootName()); else if (CLsType==2) hCL = (TH1F*)s->getHCLsFreq()->Clone(getUniqueRootName()); // fix inf and nan entries for ( int i=1; i<=s->getHCL()->GetNbinsX(); i++ ){ if ( s->getHCL()->GetBinContent(i)!=s->getHCL()->GetBinContent(i) || std::isinf(s->getHCL()->GetBinContent(i)) ) s->getHCL()->SetBinContent(i, 0.0); } // remove errors the hard way, else root ALWAYS plots them if ( !plotPoints ) hCL = histHardCopy(hCL, true, true); // disable any statistics box hCL->SetStats(0); // Convert the histogram into a TGraph so we can add the solution. // Also, the lf2 drawing option is broken in latest root versions. TGraph *g; if ( plotPoints ) g = new TGraphErrors(hCL->GetNbinsX()); else g = new TGraph(hCL->GetNbinsX()); g->SetName(getUniqueRootName()); for ( int i=0; i<hCL->GetNbinsX(); i++ ){ g->SetPoint(i, hCL->GetBinCenter(i+1), hCL->GetBinContent(i+1)); if ( plotPoints ) ((TGraphErrors*)g)->SetPointError(i, 0.0, hCL->GetBinError(i+1)); } // add solution if ( ! s->getSolutions().empty() ){ TGraphTools t; TGraph *gNew = t.addPointToGraphAtFirstMatchingX(g, s->getScanVar1Solution(0), 1.0); delete g; g = gNew; } // // set last point to the same p-value as first point by hand // // some angle plots sometimes don't manage to do it by themselves... // if ( arg->isQuickhack(XX) ) // { // Double_t pointx0, pointy0, err0; // Double_t pointx1, pointy1, err1; // g->GetPoint(0, pointx0, pointy0); // g->GetPoint(g->GetN()-1, pointx1, pointy1); // g->SetPoint(g->GetN()-1, pointx1, pointy0); // if ( plotPoints ) err0 = ((TGraphErrors*)g)->GetErrorY(0); // if ( plotPoints ) ((TGraphErrors*)g)->SetPointError(g->GetN()-1, 0.0, err0); // } // add end points of scan range if ( !plotPoints ) { Double_t pointx0, pointy0; TGraph *gNew = new TGraph(g->GetN()+4); gNew->SetName(getUniqueRootName()); for ( int i=0; i<g->GetN(); i++) { g->GetPoint(i, pointx0, pointy0); gNew->SetPoint(i+2, pointx0, pointy0); } // add origin gNew->SetPoint(0, hCL->GetXaxis()->GetXmin(), 0); // add a point at first y height but at x=origin. g->GetPoint(0, pointx0, pointy0); gNew->SetPoint(1, hCL->GetXaxis()->GetXmin(), pointy0); // add a point at last y height but at x=xmax. g->GetPoint(g->GetN()-1, pointx0, pointy0); gNew->SetPoint(gNew->GetN()-2, hCL->GetXaxis()->GetXmax(), pointy0); // add a point at xmax, 0 gNew->SetPoint(gNew->GetN()-1, hCL->GetXaxis()->GetXmax(), 0); g = gNew; } int color = s->getLineColor(); if(CLsType>0 && s->getMethodName().Contains("Plugin") && !arg->plotpluginonly) { if (CLsType==1) color = kBlue-7; else if (CLsType==2) color = kBlue+2; } else if(CLsType>0) { if (CLsType==1) color = s->getLineColor() - 5; if (CLsType==2) color = s->getLineColor() - 4; } g->SetLineColor(color); if ( filled ){ g->SetLineWidth(2); double alpha = arg->isQuickhack(12) ? 0.4 : 1.; if ( arg->isQuickhack(24) ) alpha = 0.; g->SetFillColorAlpha(color,alpha); g->SetLineStyle(1); g->SetFillStyle( s->getFillStyle() ); } else{ g->SetLineWidth(2); g->SetLineStyle(s->getLineStyle()); if ( last && arg->isQuickhack(25) ) g->SetLineWidth(3); } if ( plotPoints ){ g->SetLineWidth(1); g->SetMarkerColor(color); g->SetMarkerStyle(8); g->SetMarkerSize(0.6); if(CLsType==1) { g->SetMarkerStyle(33); g->SetMarkerSize(1); } if(CLsType==2) { g->SetMarkerStyle(21); } } // build a histogram which holds the axes float min = arg->scanrangeMin == arg->scanrangeMax ? hCL->GetXaxis()->GetXmin() : arg->scanrangeMin; float max = arg->scanrangeMin == arg->scanrangeMax ? hCL->GetXaxis()->GetXmax() : arg->scanrangeMax; TH1F *haxes = new TH1F("haxes"+getUniqueRootName(), "", 100, min, max); haxes->SetStats(0); haxes->GetXaxis()->SetTitle(s->getScanVar1()->GetTitle()); haxes->GetYaxis()->SetTitle("1-CL"); haxes->GetXaxis()->SetLabelFont(font); haxes->GetYaxis()->SetLabelFont(font); haxes->GetXaxis()->SetTitleFont(font); haxes->GetYaxis()->SetTitleFont(font); haxes->GetXaxis()->SetTitleOffset(0.9); haxes->GetYaxis()->SetTitleOffset(0.85); haxes->GetXaxis()->SetLabelSize(labelsize); haxes->GetYaxis()->SetLabelSize(labelsize); haxes->GetXaxis()->SetTitleSize(titlesize); haxes->GetYaxis()->SetTitleSize(titlesize); int xndiv = arg->ndiv==-1 ? 407 : abs(arg->ndiv); bool optimizeNdiv = arg->ndiv<0 ? true : false; haxes->GetXaxis()->SetNdivisions(xndiv, optimizeNdiv); haxes->GetYaxis()->SetNdivisions(407, true); // plot y range float plotYMax; float plotYMin; if ( plotLegend && !arg->isQuickhack(22) ) { if ( arg->plotlog ) { plotYMin = 1.e-3; plotYMax = 10.; } else { plotYMin = 0.0 ; plotYMax = 1.3; } } else { if ( arg->plotlog ) { plotYMin = 1.e-3; plotYMax = 1.0; } else { plotYMin = 0.0 ; plotYMax = 1.0; } } // change if passed as option plotYMin = arg->plotymin > 0. ? arg->plotymin : plotYMin; plotYMax = arg->plotymax > 0. ? arg->plotymax : plotYMax; haxes->GetYaxis()->SetRangeUser( plotYMin, plotYMax ); haxes->Draw("axissame"); g->SetHistogram(haxes); TString drawOption = ""; if ( plotPoints ) drawOption += " pe"; else if ( filled ) drawOption += " F"; else drawOption += " L"; if ( first ) drawOption += " A"; g->Draw(drawOption); //if ( drawOption.Contains("F") ) ((TGraph*)g->Clone())->Draw("L"); gPad->Update(); float ymin = gPad->GetUymin(); float ymax = gPad->GetUymax(); float xmin = gPad->GetUxmin(); float xmax = gPad->GetUxmax(); // for the angles, draw a new axis in units of degrees if ( isAngle(s->getScanVar1()) ){ haxes->GetXaxis()->SetTitle(s->getScanVar1()->GetTitle() + TString(" [#circ]")); haxes->GetXaxis()->SetNdivisions(0); // disable old axis if ( last ){ // new top axis TString chopt = "-U"; // - = downward ticks, U = unlabeled, http://root.cern.ch/root/html534/TGaxis.html if ( !optimizeNdiv ) chopt += "N"; // n = no bin optimization TGaxis *axist = new TGaxis(xmin, 1, xmax, 1, RadToDeg(xmin), RadToDeg(xmax), xndiv, chopt); axist->SetName("axist"); axist->Draw(); // new bottom axis float axisbMin = RadToDeg(xmin); float axisbMax = RadToDeg(xmax); if ( arg->isQuickhack(3) ){ ///< see documentation of --qh option in OptParser.cpp axisbMin += 180.; axisbMax += 180.; } chopt = ""; // - = downward ticks, U = unlabeled, http://root.cern.ch/root/html534/TGaxis.html if ( !optimizeNdiv ) chopt += "N"; // n = no bin optimization TGaxis *axisb = new TGaxis(xmin, ymin, xmax, ymin, axisbMin, axisbMax, xndiv, chopt); axisb->SetName("axisb"); axisb->SetLabelFont(font); axisb->SetLabelSize(labelsize); axisb->Draw(); } } else { if ( last ){ // add top axis TString chopt = "-U"; // - = downward ticks, U = unlabeled, http://root.cern.ch/root/html534/TGaxis.html if ( !optimizeNdiv ) chopt += "N"; // n = no bin optimization TGaxis *axist = new TGaxis(xmin, 1.0, xmax, 1.0, xmin, xmax, xndiv, chopt); axist->SetName("axist"); axist->SetLineWidth(1); axist->Draw(); } } if ( last ) { // add right axis TGaxis *axisr = 0; if ( arg->plotlog ){ float f3min = 1e-3; float f3max = (plotLegend && !arg->isQuickhack(22)) ? 10. : 1.; TF1 *f3 = new TF1("f3","log10(x)",f3min,f3max); axisr = new TGaxis(xmax, f3min, xmax, f3max, "f3", 510, "G+"); } else{ axisr = new TGaxis(xmax, ymin, xmax, ymax, 0, (plotLegend && !arg->isQuickhack(22)) ? 1.3 : 1.0, 407, "+"); } axisr->SetLabelSize(0); axisr->SetLineWidth(1); axisr->SetName("axisr"); axisr->SetLabelColor(kWhite); axisr->SetTitleColor(kWhite); axisr->Draw(); // redraw right axis as well because the 1-CL graph can cover the old one haxes->Draw("axissame"); } return g; }
void PlotPotential2D( const TString &sim, Int_t time, Int_t zoom=2, Int_t Nbins=2, const TString &options="") { #ifdef __CINT__ gSystem->Load("libplasma.so"); #endif PlasmaGlob::Initialize(); // Palettes! gROOT->Macro("PlasmaPalettes.C"); // Init Units table PUnits::UnitsTable::Get(); // Load PData PData *pData = PData::Get(sim.Data()); pData->LoadFileNames(time); if(!pData->IsInit()) return; TString opt = options; // More makeup gStyle->SetPadGridY(0); if(opt.Contains("gridx")) { gStyle->SetPadGridX(1); } if(opt.Contains("gridy")) { gStyle->SetPadGridY(1); } // Some plasma constants Double_t n0 = pData->GetPlasmaDensity(); Double_t omegap = pData->GetPlasmaFrequency(); Double_t timedepth = 1.; if(omegap!=0.0) timedepth = 1/omegap; Double_t kp = pData->GetPlasmaK(); Double_t skindepth = 1.; if(kp!=0.0) skindepth = 1/kp; Double_t E0 = pData->GetPlasmaE0(); // Some beam properties: Double_t Ebeam = pData->GetBeamEnergy(); Double_t gamma = pData->GetBeamGamma(); Double_t vbeam = pData->GetBeamVelocity(); cout << Form(" - Bunch gamma = %8.4f", gamma ) << endl; cout << Form(" - Bunch velocity = %8.4f c", vbeam ) << endl; // Other parameters Float_t trapPotential = 1.0 - (1.0/gamma); cout << Form(" - Trap. potential = %8.4f mc2/e",trapPotential) << endl; cout << endl; // Time in OU Float_t Time = pData->GetRealTime(); // z start of the plasma in normalized units. Float_t zStartPlasma = pData->GetPlasmaStart()*kp; // z start of the beam in normalized units. Float_t zStartBeam = pData->GetBeamStart()*kp; // z start of the neutral in normalized units. Float_t zStartNeutral = pData->GetNeutralStart()*kp; // z end of the neutral in normalized units. Float_t zEndNeutral = pData->GetNeutralEnd()*kp; if(opt.Contains("center")) { Time -= zStartPlasma; if(opt.Contains("comov")) // Centers on the head of the beam. Time += zStartBeam; } Float_t shiftz = pData->Shift(opt); // cout << "Shift = " << shiftz << endl; // Calculate the "axis range" in number of bins. If Nbins==0 a RMS width is taken. Double_t rms0 = pData->GetBeamRmsY() * kp; if(pData->IsCyl()) rms0 = pData->GetBeamRmsR() * kp; Int_t FirstyBin = 0; Int_t LastyBin = 0; if(Nbins==0) { if(rms0>0.0) Nbins = TMath::Nint(rms0 / pData->GetDX(1)); else Nbins = 1; } // Slice width limits. if(!pData->IsCyl()) { FirstyBin = pData->GetNX(1)/2 + 1 - Nbins; LastyBin = pData->GetNX(1)/2 + Nbins; } else { FirstyBin = 1; LastyBin = Nbins; } // ---------------------------------------------------------------------------------- // Get charge density histos Int_t Nspecies = pData->NSpecies(); TH2F **hDen2D = new TH2F*[Nspecies]; // Get charge density on-axis TH1F **hDen1D = new TH1F*[Nspecies]; // And electric current (integrated) TH1F **hCur1D = new TH1F*[Nspecies]; for(Int_t i=0; i<Nspecies; i++) { hDen2D[i] = NULL; if(!pData->GetChargeFileName(i)) continue; cout << Form(" Getting charge density of specie: ") << i << endl; char hName[24]; sprintf(hName,"hDen2D_%i",i); hDen2D[i] = (TH2F*) gROOT->FindObject(hName); if(hDen2D[i]) delete hDen2D[i]; if(!pData->Is3D()) hDen2D[i] = pData->GetCharge(i,opt); else hDen2D[i] = pData->GetCharge2DSliceZY(i,-1,Nbins,opt+"avg"); hDen2D[i]->SetName(hName); hDen2D[i]->GetXaxis()->CenterTitle(); hDen2D[i]->GetYaxis()->CenterTitle(); hDen2D[i]->GetZaxis()->CenterTitle(); if(opt.Contains("comov")) hDen2D[i]->GetXaxis()->SetTitle("k_{p} #zeta"); else hDen2D[i]->GetXaxis()->SetTitle("k_{p} z"); if(pData->IsCyl()) hDen2D[i]->GetYaxis()->SetTitle("k_{p} r"); else hDen2D[i]->GetYaxis()->SetTitle("k_{p} y"); hDen2D[i]->GetZaxis()->SetTitle("n [n_{0}]"); hDen1D[i] = NULL; hCur1D[i] = NULL; if(!pData->GetEfieldFileName(i)) continue; sprintf(hName,"hDen1D_%i",i); hDen1D[i] = (TH1F*) gROOT->FindObject(hName); if(hDen1D[i]) delete hDen1D[i]; // 1D histograms if(pData->Is3D()) { hDen1D[i] = pData->GetH1SliceZ3D(pData->GetChargeFileName(i)->c_str(),"charge",-1,Nbins,-1,Nbins,opt+"avg"); } else if(pData->IsCyl()) { // Cylindrical: The first bin with r>0 is actually the number 1 (not the 0). hDen1D[i] = pData->GetH1SliceZ(pData->GetChargeFileName(i)->c_str(),"charge",1,Nbins,opt+"avg"); } else { // 2D cartesian hDen1D[i] = pData->GetH1SliceZ(pData->GetChargeFileName(i)->c_str(),"charge",-1,Nbins,opt+"avg"); } hDen1D[i]->SetName(hName); // if(hDen1D[i]) delete hDen1D[i]; // hDen1D[i] = (TH1F*) hE2D[i]->ProjectionX(hName,FirstyBin,LastyBin); // hDen1D[i]->Scale(1.0/(LastyBin-FirstyBin+1)); if(opt.Contains("comov")) hDen1D[i]->GetXaxis()->SetTitle("#zeta [c/#omega_{p}]"); else hDen1D[i]->GetXaxis()->SetTitle("z [c/#omega_{p}]"); if(i==0) hDen1D[i]->GetYaxis()->SetTitle("n/n_{0}"); else if(i==1) hDen1D[i]->GetYaxis()->SetTitle("n_{b}/n_{0}"); else hDen1D[i]->GetYaxis()->SetTitle("n_{i}/n_{0}"); // Get the current: if(i==0) continue; sprintf(hName,"hCur1D_%i",i); hCur1D[i] = (TH1F*) gROOT->FindObject(hName); if(hCur1D[i]) delete hCur1D[i]; if(opt.Contains("curr")) { // To get the current is needed to read in a wider transverse range which includes all the charge. Int_t NbinsT = 100; if(pData->Is3D()) { hCur1D[i] = pData->GetH1SliceZ3D(pData->GetChargeFileName(i)->c_str(),"charge",-1,NbinsT,-1,NbinsT,opt+"int"); } else if(pData->IsCyl()) { // Cylindrical: The first bin with r>0 is actually the number 1 (not the 0). hCur1D[i] = pData->GetH1SliceZ(pData->GetChargeFileName(i)->c_str(),"charge",1,NbinsT,opt+"int"); } else { // 2D cartesian hCur1D[i] = pData->GetH1SliceZ(pData->GetChargeFileName(i)->c_str(),"charge",-1,NbinsT,opt+"int"); } hCur1D[i]->SetName(hName); if(opt.Contains("comov")) { hCur1D[i]->GetXaxis()->SetTitle("#zeta [c/#omega_{p}]"); hCur1D[i]->GetYaxis()->SetTitle("dn/d#zeta [(n_{0}/k_{p}^{3}) (#omega_{p}/c)]"); } else { hCur1D[i]->GetXaxis()->SetTitle("z [c/#omega_{p}]"); hCur1D[i]->GetYaxis()->SetTitle("dn/dz [(n_{0}/k_{p}^{3}) (#omega_{p}/c)]"); } Int_t NB = hCur1D[i]->GetNbinsX(); Float_t dx = (hCur1D[i]->GetBinLowEdge(1)-hCur1D[i]->GetBinLowEdge(NB+1))/NB; // hCur1D[i]->Scale(dx); Float_t Charge = hCur1D[i]->Integral() * dx; cout << Form(" Integrated charge of specie %3i = %8.4f n0 * kp^-3",i,Charge) << endl; } } // Get electric fields 2D const Int_t Nfields = 3; TH2F **hE2D = new TH2F*[Nfields]; TH1F **hE1D = new TH1F*[Nfields]; TH2F *hV2D = NULL; TH1F *hV1D = NULL; for(Int_t i=0; i<Nfields; i++) { hE2D[i] = NULL; hE1D[i] = NULL; if(!pData->GetEfieldFileName(i)) continue; cout << Form(" Getting electric field number ") << i+1 << endl; char hName[24]; sprintf(hName,"hE2D_%i",i); hE2D[i] = (TH2F*) gROOT->FindObject(hName); if(hE2D[i]) delete hE2D[i]; if(!pData->Is3D()) hE2D[i] = pData->GetEField(i,opt); else hE2D[i] = pData->GetEField2DSliceZY(i,-1,Nbins,opt+"avg"); hE2D[i]->SetName(hName); hE2D[i]->GetXaxis()->CenterTitle(); hE2D[i]->GetYaxis()->CenterTitle(); hE2D[i]->GetZaxis()->CenterTitle(); if(opt.Contains("comov")) hE2D[i]->GetXaxis()->SetTitle("k_{p} #zeta"); else hE2D[i]->GetXaxis()->SetTitle("k_{p} z"); if(pData->IsCyl()) hE2D[i]->GetYaxis()->SetTitle("k_{p} r"); else hE2D[i]->GetYaxis()->SetTitle("k_{p} y"); if(i==0) hE2D[i]->GetZaxis()->SetTitle("E_{z}/E_{0}"); else if(i==1) hE2D[i]->GetZaxis()->SetTitle("E_{y}/E_{0}"); else if(i==2) hE2D[i]->GetZaxis()->SetTitle("E_{x}/E_{0}"); sprintf(hName,"hE1D_%i",i); hE1D[i] = (TH1F*) gROOT->FindObject(hName); if(hE1D[i]) delete hE1D[i]; // 1D histograms char nam[3]; sprintf(nam,"e%i",i+1); if(pData->Is3D()) { if(i==0) hE1D[i] = pData->GetH1SliceZ3D(pData->GetEfieldFileName(i)->c_str(),nam,-1,Nbins,-1,Nbins,opt+"avg"); else hE1D[i] = pData->GetH1SliceZ3D(pData->GetEfieldFileName(i)->c_str(),nam,-Nbins,Nbins,-Nbins,Nbins,opt+"avg"); } else if(pData->IsCyl()) { // Cylindrical: The first bin with r>0 is actually the number 1 (not the 0). hE1D[i] = pData->GetH1SliceZ(pData->GetEfieldFileName(i)->c_str(),nam,1,Nbins,opt+"avg"); } else { // 2D cartesian if(i==0) hE1D[i] = pData->GetH1SliceZ(pData->GetEfieldFileName(i)->c_str(),nam,-1,Nbins,opt+"avg"); else hE1D[i] = pData->GetH1SliceZ(pData->GetEfieldFileName(i)->c_str(),nam,-Nbins,Nbins,opt+"avg"); } hE1D[i]->SetName(hName); if(opt.Contains("comov")) hE1D[i]->GetXaxis()->SetTitle("#zeta [c/#omega_{p}]"); else hE1D[i]->GetXaxis()->SetTitle("z [c/#omega_{p}]"); if(i==0) hE1D[i]->GetYaxis()->SetTitle("E_{z} [E_{0}]"); else if(i==1) hE1D[i]->GetYaxis()->SetTitle("E_{y} [E_{0}]"); else if(i==2) hE1D[i]->GetYaxis()->SetTitle("E_{x} [E_{0}]"); // Alternative // if(hE1D[i]) delete hE1D[i]; // hE1D[i] = (TH1F*) hE2D[i]->ProjectionX(hName,FirstyBin,LastyBin); // hE1D[i]->Scale(1.0/(LastyBin-FirstyBin+1)); if(i==0) { Int_t NbinsX = hE2D[i]->GetNbinsX(); Int_t NbinsY = hE2D[i]->GetNbinsY(); Float_t dx = pData->GetDX(0); sprintf(hName,"hV2D"); hV2D = (TH2F*) hE2D[i]->Clone(hName); hV2D->Reset(); sprintf(hName,"hV1D"); hV1D = (TH1F*) hE1D[i]->Clone(hName); hV1D->Reset(); for(Int_t j=NbinsY; j>0; j--) { Double_t integral = 0.0; for(Int_t k=NbinsX; k>0; k--) { integral += hE2D[i]->GetBinContent(k,j) * dx; hV2D->SetBinContent(k,j,integral); } } Double_t integral = 0.0; for(Int_t k=NbinsX; k>0; k--) { integral += hE1D[i]->GetBinContent(k) * dx; hV1D->SetBinContent(k,integral); } } } // Now, combine the electric field components into the total |E| // and calculate ionization probability for He: // Outter Helium electron Double_t Eion0 = 24.59 * PUnits::eV; Double_t Z = 1; TH2F *hETotal2D = (TH2F*) hE2D[0]->Clone("hETotal2D"); hETotal2D->Reset(); TH2F *hIonProb2D = (TH2F*) hE2D[0]->Clone("hIonProb2D"); hIonProb2D->Reset(); TH1F *hETotal1D = (TH1F*) hE1D[0]->Clone("hETotal1D"); hETotal1D->Reset(); TH1F *hIonProb1D = (TH1F*) hE1D[0]->Clone("hIonProb1D"); hIonProb1D->Reset(); { Int_t NbinsX = hE2D[0]->GetNbinsX(); Int_t NbinsY = hE2D[0]->GetNbinsY(); for(Int_t j=0; j<NbinsX; j++) { for(Int_t k=0; k<NbinsY; k++) { Double_t E1 = hE2D[0]->GetBinContent(j,k); Double_t E2 = hE2D[1]->GetBinContent(j,k); Double_t E3 = hE2D[2]->GetBinContent(j,k); Double_t E = TMath::Sqrt(E1*E1+E2*E2+E3*E3); hETotal2D->SetBinContent(j,k,E); E *= E0; // Double_t IonProb = (PFunc::ADK(E,Eion0,Z,l,m)/PUnits::atomictime)*PUnits::femtosecond; Double_t IonProb = PFunc::ADK_ENG(E,Eion0,Z) * PUnits::femtosecond; // if(IonProb>1) IonProb = 1.0; // cout << "Ion prob = " << IonProb << endl; hIonProb2D->SetBinContent(j,k,IonProb); } Double_t E1 = hE1D[0]->GetBinContent(j); Double_t E2 = hE1D[1]->GetBinContent(j); Double_t E3 = hE1D[2]->GetBinContent(j); Double_t E = TMath::Sqrt(E1*E1+E2*E2+E3*E3); hETotal1D->SetBinContent(j,E); E *= E0; // Double_t IonProb = (PFunc::ADK(E,Eion0,Z,l,m)/PUnits::atomictime)*PUnits::femtosecond; Double_t IonProb = PFunc::ADK_ENG(E,Eion0,Z) * PUnits::femtosecond; // cout << "Ion prob = " << IonProb << endl; hIonProb1D->SetBinContent(j,IonProb); } } hETotal2D->GetZaxis()->SetTitle("E [E_{0}]"); hIonProb2D->GetZaxis()->SetTitle("W_{ADK} [fs^{-1}]"); hETotal1D->GetYaxis()->SetTitle("E [E_{0}]"); hIonProb1D->GetYaxis()->SetTitle("W_{ADK} [fs^{-1}]"); // Tunning the Histograms // --------------------- // Chaning to user units: // -------------------------- if(opt.Contains("units") && n0) { for(Int_t i=0; i<Nspecies; i++) { if(!hDen2D[i]) continue; Int_t NbinsX = hDen2D[i]->GetNbinsX(); Float_t xMin = skindepth * hDen2D[i]->GetXaxis()->GetXmin() / PUnits::um; Float_t xMax = skindepth * hDen2D[i]->GetXaxis()->GetXmax() / PUnits::um; Int_t NbinsY = hDen2D[i]->GetNbinsY(); Float_t ymin = skindepth * hDen2D[i]->GetYaxis()->GetXmin() / PUnits::um; Float_t ymax = skindepth * hDen2D[i]->GetYaxis()->GetXmax() / PUnits::um; hDen2D[i]->SetBins(NbinsX,xMin,xMax,NbinsY,ymin,ymax); // for(Int_t j=0;j<hDen2D[i]->GetNbinsX();j++) { // for(Int_t k=0;k<hDen2D[i]->GetNbinsY();k++) { // hDen2D[i]->SetBinContent(j,k, hDen2D[i]->GetBinContent(j,k) * n0 / (1e17/PUnits::cm3) ); // } // } if(pData->IsCyl()) hDen2D[i]->GetYaxis()->SetTitle("r [#mum]"); else hDen2D[i]->GetYaxis()->SetTitle("y [#mum]"); if(opt.Contains("comov")) hDen2D[i]->GetXaxis()->SetTitle("#zeta [#mum]"); else hDen2D[i]->GetXaxis()->SetTitle("z [#mum]"); // if(i==0) // hDen2D[i]->GetZaxis()->SetTitle("n_{e} [10^{17}/cm^{3}]"); // else if(i==1) // hDen2D[i]->GetZaxis()->SetTitle("n_{b} [10^{17}/cm^{3}]"); // else // hDen2D[i]->GetZaxis()->SetTitle("n_{i} [10^{17}/cm^{3}]"); hDen1D[i]->SetBins(NbinsX,xMin,xMax); // for(Int_t j=0;j<hDen1D[i]->GetNbinsX();j++) { // hDen1D[i]->SetBinContent(j, hDen1D[i]->GetBinContent(j) * n0 / (1e17/PUnits::cm3) ); // } if(opt.Contains("comov")) hDen1D[i]->GetXaxis()->SetTitle("#zeta [#mum]"); else hDen1D[i]->GetXaxis()->SetTitle("z [#mum]"); if(hCur1D[i]) { hCur1D[i]->SetBins(NbinsX,xMin,xMax); Double_t binSize = (xMax - xMin)/NbinsX; // bin size in um. Double_t dV = skindepth * skindepth * skindepth; Double_t lightspeed = PConst::c_light / (PUnits::um/PUnits::femtosecond); hCur1D[i]->Scale(TMath::Abs(n0 * dV * (PConst::ElectronCharge/PUnits::picocoulomb) * (kp * PConst::c_light * PUnits::femtosecond))); hCur1D[i]->GetYaxis()->SetTitle("I[kA]"); hCur1D[i]->GetYaxis()->SetTitle(""); if(opt.Contains("comov")) hCur1D[i]->GetXaxis()->SetTitle("#zeta [#mum]"); else hCur1D[i]->GetXaxis()->SetTitle("z [#mum]"); Float_t Charge = hCur1D[i]->Integral() * (binSize / lightspeed); cout << Form(" Integrated charge of specie %3i = %8f pC",i,Charge) << endl; } } for(Int_t i=0; i<Nfields; i++) { Int_t NbinsX = hE2D[i]->GetNbinsX(); Float_t xMin = skindepth * hE2D[i]->GetXaxis()->GetXmin() / PUnits::um; Float_t xMax = skindepth * hE2D[i]->GetXaxis()->GetXmax() / PUnits::um; Int_t NbinsY = hE2D[i]->GetNbinsY(); Float_t ymin = skindepth * hE2D[i]->GetYaxis()->GetXmin() / PUnits::um; Float_t ymax = skindepth * hE2D[i]->GetYaxis()->GetXmax() / PUnits::um; hE2D[i]->SetBins(NbinsX,xMin,xMax,NbinsY,ymin,ymax); hE1D[i]->SetBins(NbinsX,xMin,xMax); for(Int_t j=0; j<hE2D[i]->GetNbinsX(); j++) { for(Int_t k=0; k<hE2D[i]->GetNbinsY(); k++) { hE2D[i]->SetBinContent(j,k, hE2D[i]->GetBinContent(j,k) * ( E0 / (PUnits::GV/PUnits::m) ) ); } hE1D[i]->SetBinContent(j, hE1D[i]->GetBinContent(j) * ( E0 / (PUnits::GV/PUnits::m) ) ); } if(pData->IsCyl()) hE2D[i]->GetYaxis()->SetTitle("r [#mum]"); else hE2D[i]->GetYaxis()->SetTitle("y [#mum]"); if(opt.Contains("comov")) hE2D[i]->GetXaxis()->SetTitle("#zeta [#mum]"); else hE2D[i]->GetXaxis()->SetTitle("z [#mum]"); if(i==0) hE2D[i]->GetZaxis()->SetTitle("E_{z} [GV/m]"); else if(i==1) hE2D[i]->GetZaxis()->SetTitle("E_{y} [GV/m]"); else if(i==2) hE2D[i]->GetZaxis()->SetTitle("E_{x} [GV/m]"); if(opt.Contains("comov")) hE1D[i]->GetXaxis()->SetTitle("#zeta [mm]"); else hE1D[i]->GetXaxis()->SetTitle("z [mm]"); if(i==0) hE1D[i]->GetYaxis()->SetTitle("E_{z} [GV/m]"); else if(i==1) hE1D[i]->GetYaxis()->SetTitle("E_{y} [GV/m]"); else if(i==2) hE1D[i]->GetYaxis()->SetTitle("E_{x} [GV/m]"); if(i==0) { hV2D->SetBins(NbinsX,xMin,xMax,NbinsY,ymin,ymax); hETotal2D->SetBins(NbinsX,xMin,xMax,NbinsY,ymin,ymax); hIonProb2D->SetBins(NbinsX,xMin,xMax,NbinsY,ymin,ymax); hV1D->SetBins(NbinsX,xMin,xMax); hETotal1D->SetBins(NbinsX,xMin,xMax); hIonProb1D->SetBins(NbinsX,xMin,xMax); for(Int_t j=0; j<NbinsX; j++) { for(Int_t k=0; k<NbinsY; k++) { hV2D->SetBinContent(j,k, hV2D->GetBinContent(j,k) * E0 * skindepth / (PUnits::MV)); hETotal2D->SetBinContent(j,k, hETotal2D->GetBinContent(j,k) * ( E0 / (PUnits::GV/PUnits::m) ) ); } hV1D->SetBinContent(j, hV1D->GetBinContent(j) * ( E0 * skindepth / (PUnits::MV) ) ); hETotal1D->SetBinContent(j, hETotal1D->GetBinContent(j) * ( E0 / (PUnits::GV/PUnits::m) ) ); } if(pData->IsCyl()) { hV2D->GetYaxis()->SetTitle("r [#mum]"); hETotal2D->GetYaxis()->SetTitle("r [#mum]"); } else { hV2D->GetYaxis()->SetTitle("y [#mum]"); hETotal2D->GetYaxis()->SetTitle("y [#mum]"); } if(opt.Contains("comov")) { hV2D->GetXaxis()->SetTitle("#zeta [#mum]"); hV1D->GetXaxis()->SetTitle("#zeta [#mum]"); hETotal2D->GetXaxis()->SetTitle("#zeta [#mum]"); hETotal1D->GetXaxis()->SetTitle("#zeta [#mum]"); } else { hV2D->GetXaxis()->SetTitle("z [#mum]"); hV2D->GetXaxis()->SetTitle("z [#mum]"); hETotal2D->GetXaxis()->SetTitle("z [#mum]"); hETotal1D->GetXaxis()->SetTitle("z [#mum]"); } hV2D->GetZaxis()->SetTitle("#Psi-#Psi_{t} [MV]"); hV1D->GetYaxis()->SetTitle("#Psi-#Psi_{t} [MV]"); hETotal2D->GetZaxis()->SetTitle("E [GV/m]"); hETotal1D->GetYaxis()->SetTitle("E [GV/m]"); } } } // --------------------------------------------------- Vertical Zoom ------------ Float_t yRange = (hDen2D[0]->GetYaxis()->GetXmax() - hDen2D[0]->GetYaxis()->GetXmin())/zoom; Float_t midPoint = (hDen2D[0]->GetYaxis()->GetXmax() + hDen2D[0]->GetYaxis()->GetXmin())/2.; Float_t yMin = midPoint-yRange/2; Float_t yMax = midPoint+yRange/2; if(pData->IsCyl()) { yMin = pData->GetXMin(1); yMax = yRange; } for(Int_t i=0; i<Nspecies; i++) { if(!hDen2D[i]) continue; hDen2D[i]->GetYaxis()->SetRangeUser(yMin,yMax); } for(Int_t i=0; i<Nfields; i++) { if(!hE2D[i]) continue; hE2D[i]->GetYaxis()->SetRangeUser(yMin,yMax); } hETotal2D->GetYaxis()->SetRangeUser(yMin,yMax); Float_t xMin = hDen2D[0]->GetXaxis()->GetXmin(); Float_t xMax = hDen2D[0]->GetXaxis()->GetXmax(); Float_t xRange = xMax - xMin; // ------------- z Zoom --------------------------------- Plasma palette ----------- // Set the range of the plasma charge density histogram for maximum constrast // using a dynamic palette wich adjust the nominal value to a certain color. Float_t density = 1; Float_t Base = density; Float_t *Max = new Float_t[Nspecies]; Float_t *Min = new Float_t[Nspecies]; for(Int_t i=0; i<Nspecies; i++) { if(!hDen2D[i]) continue; Max[i] = hDen2D[i]->GetMaximum(); Min[i] = 1.01E-1 * Base; if(i==1) Min[i] = 1.01E-1 * Base; if(i==2) Min[i] = 1.01E-4 * Base; hDen2D[i]->GetZaxis()->SetRangeUser(Min[i],Max[i]); } // Dynamic plasma palette const Int_t plasmaDNRGBs = 3; const Int_t plasmaDNCont = 64; Float_t basePos = 0.5; if(Max[0]!=Min[0]) { if(opt.Contains("logz")) { Float_t a = 1.0/(TMath::Log10(Max[0])-TMath::Log10(Min[0])); Float_t b = TMath::Log10(Min[0]); basePos = a*(TMath::Log10(Base) - b); } else { basePos = (1.0/(Max[0]-Min[0]))*(Base - Min[0]); } } Double_t plasmaDStops[plasmaDNRGBs] = { 0.00, basePos, 1.00 }; Double_t plasmaDRed[plasmaDNRGBs] = { 0.99, 0.90, 0.00 }; Double_t plasmaDGreen[plasmaDNRGBs] = { 0.99, 0.90, 0.00 }; Double_t plasmaDBlue[plasmaDNRGBs] = { 0.99, 0.90, 0.00 }; PPalette * plasmaPalette = (PPalette*) gROOT->FindObject("plasma"); plasmaPalette->CreateGradientColorTable(plasmaDNRGBs, plasmaDStops, plasmaDRed, plasmaDGreen, plasmaDBlue, plasmaDNCont); // Change the range of z axis for the fields to be symmetric. Float_t *Emax = new Float_t[Nfields]; Float_t *Emin = new Float_t[Nfields]; for(Int_t i=0; i<Nfields; i++) { Emax[i] = hE2D[i]->GetMaximum(); Emin[i] = hE2D[i]->GetMinimum(); if(Emax[i] > TMath::Abs(Emin[i])) Emin[i] = -Emax[i]; else Emax[i] = -Emin[i]; hE2D[i]->GetZaxis()->SetRangeUser(Emin[i],Emax[i]); } // Potential if(opt.Contains("units")) { trapPotential *= ( E0 * skindepth / (PUnits::MV) ); } Float_t Vmin = hV1D->GetMinimum(); { // Shift potential Int_t NbinsX = hV2D->GetNbinsX(); Int_t NbinsY = hV2D->GetNbinsY(); for(Int_t j=0; j<NbinsX; j++) { for(Int_t k=0; k<NbinsY; k++) { hV2D->SetBinContent(j,k, hV2D->GetBinContent(j,k) - Vmin -trapPotential); } hV1D->SetBinContent(j, hV1D->GetBinContent(j) - Vmin -trapPotential); } } Vmin = hV1D->GetMinimum(); Float_t Vmax = hV1D->GetMaximum(); // Dynamic potential palette const Int_t potPNRGBs = 5; const Int_t potPNCont = 64; Float_t zeroPos = -Vmin/(Vmax-Vmin); Double_t potPStops[potPNRGBs] = { 0.00, zeroPos-3.0/potPNCont,zeroPos, zeroPos+3.0/potPNCont, 1.00 }; Double_t potPRed[potPNRGBs] = { 0.518, 0.965, 0.90, 0.498, 0.106 }; Double_t potPGreen[potPNRGBs] = { 0.078, 0.925, 0.90, 0.718, 0.078 }; Double_t potPBlue[potPNRGBs] = { 0.106, 0.353, 0.90, 0.780, 0.518 }; PPalette * potentialPalette = (PPalette*) gROOT->FindObject("rbow2inv"); potentialPalette->CreateGradientColorTable(potPNRGBs, potPStops, potPRed, potPGreen, potPBlue, potPNCont); // Extract contours TCanvas* c = new TCanvas("c","Contour List",0,0,600,600); c->cd(); // Potential TH2F *hV2Dc = (TH2F*) hV2D->Clone("hV2Dc"); const Int_t Ncontours = 25; Double_t contours[Ncontours]; for(Int_t i=0; i<Ncontours; i++) { contours[i] = i*(trapPotential/5.0) - trapPotential; } hV2Dc->SetContour(Ncontours, contours); hV2Dc->Draw("cont list"); c->Update(); TObjArray *contsV2D = (TObjArray*) gROOT->GetListOfSpecials()->FindObject("contours"); TClonesArray graphsV2D("TGraph",Ncontours); { Int_t ncontours = contsV2D->GetSize(); TList* clist = NULL; Int_t nGraphs = 0; TGraph *gr = NULL; for(Int_t i = 0; i < ncontours; i++) { if(i==0) continue; clist = (TList*) contsV2D->At(i); for(Int_t j = 0 ; j < clist->GetSize(); j++) { gr = (TGraph*) clist->At(j); if(!gr) continue; gr->SetLineWidth(1); gr->SetLineColor(kGray+1); if( !((i)%5) ) { gr->SetLineWidth(2); gr->SetLineColor(kGray+2); } new(graphsV2D[nGraphs]) TGraph(*gr) ; nGraphs++; } } } // Ion probability hIonProb2D->GetZaxis()->SetRangeUser(0.00501,80); TH2F *hIonProb2Dc = (TH2F*) hIonProb2D->Clone("hIonProb2Dc"); const Int_t NcontI = 4; Double_t contI[NcontI] = {0.01,0.1,1.0,10.0}; hIonProb2Dc->SetContour(NcontI, contI); hIonProb2Dc->Draw("cont list"); c->Update(); TObjArray *contsI2D = (TObjArray*) gROOT->GetListOfSpecials()->FindObject("contours"); TClonesArray graphsI2D("TGraph",NcontI); { Int_t ncontours = contsI2D->GetSize(); TList* clist = NULL; Int_t nGraphs = 0; TGraph *gr = NULL; for(Int_t i = 0; i < ncontours; i++) { clist = (TList*) contsI2D->At(i); for(Int_t j = 0 ; j < clist->GetSize(); j++) { gr = (TGraph*) clist->At(j); if(!gr) continue; if( !(i%2) ) { gr->SetLineWidth(1); gr->SetLineStyle(2); gr->SetLineColor(kOrange-3); } else { gr->SetLineWidth(1); gr->SetLineStyle(1); gr->SetLineColor(kOrange-3); } new(graphsI2D[nGraphs]) TGraph(*gr) ; nGraphs++; } } } // "Axis range" in Osiris units: Double_t ylow = hDen2D[0]->GetYaxis()->GetBinLowEdge(FirstyBin); Double_t yup = hDen2D[0]->GetYaxis()->GetBinUpEdge(LastyBin); Double_t xmin = hDen2D[0]->GetXaxis()->GetXmin(); Double_t xmax = hDen2D[0]->GetXaxis()->GetXmax(); TLine *lineYzero = new TLine(xmin,0.0,xmax,0.0); lineYzero->SetLineColor(kGray+2); lineYzero->SetLineStyle(2); TLine *lineYup = new TLine(xmin,yup,xmax,yup); lineYup->SetLineColor(kGray+1); lineYup->SetLineStyle(2); TLine *lineYdown = new TLine(xmin,ylow,xmax,ylow); lineYdown->SetLineColor(kGray+1); lineYdown->SetLineStyle(2); zStartPlasma -= shiftz; zStartNeutral -= shiftz; zEndNeutral -= shiftz; if(opt.Contains("units")) { zStartPlasma *= skindepth / PUnits::um; zStartNeutral *= skindepth / PUnits::um; zEndNeutral *= skindepth / PUnits::um; } // cout << "Start plasma = " << zStartPlasma << endl; TLine *lineStartPlasma = new TLine(zStartPlasma,yMin,zStartPlasma,yMax); lineStartPlasma->SetLineColor(kGray+2); lineStartPlasma->SetLineStyle(2); lineStartPlasma->SetLineWidth(3); // cout << "Start plasma = " << zStartNeutral << endl; TLine *lineStartNeutral = new TLine(zStartNeutral,yMin,zStartNeutral,yMax); lineStartNeutral->SetLineColor(kGray+1); lineStartNeutral->SetLineStyle(2); lineStartNeutral->SetLineWidth(3); // cout << "End plasma = " << zEndNeutral << endl; TLine *lineEndNeutral = new TLine(zEndNeutral,yMin,zEndNeutral,yMax); lineEndNeutral->SetLineColor(kGray+1); lineEndNeutral->SetLineStyle(2); lineEndNeutral->SetLineWidth(3); // Plotting // ----------------------------------------------- // Canvas setup TCanvas *C = new TCanvas("C","2D Charge density and Electric field",750,666); // Palettes setup TExec *exPlasma = new TExec("exPlasma","plasmaPalette->cd();"); TExec *exElec = new TExec("exElec","redelectronPalette->cd();"); TExec *exHot = new TExec("exHot","hotPalette->cd();"); TExec *exField = new TExec("exField","rbow2Palette->cd();"); TExec *exFieldT = new TExec("exFieldT","redPalette->cd();"); TExec *exIonP = new TExec("exIonP","redPalette->cd();"); TExec *exPot = new TExec("exPot","rbow2invPalette->cd();"); // Actual Plotting! // ------------------------------------------------------------ // Output file TString fOutName = Form("./%s/Plots/Potential2D/Potential2D",pData->GetPath().c_str()); fOutName += Form("-%s_%i",pData->GetName(),time); // Setup Pad layout: Float_t lMargin = 0.15; Float_t rMargin = 0.18; Float_t bMargin = 0.15; Float_t tMargin = 0.04; Float_t factor = 1.0; PlasmaGlob::CanvasAsymPartition(C,2,lMargin,rMargin,bMargin,tMargin,factor); TPad *pad[2]; TString sLabels[] = {"(a)","(b)"}; // Text objects TPaveText **textLabel = new TPaveText*[2]; C->cd(0); char pname[16]; sprintf(pname,"pad_%i",1); pad[0] = (TPad*) gROOT->FindObject(pname); pad[0]->Draw(); pad[0]->cd(); // <---------------------------------------------- Top Plot --------- if(opt.Contains("logz")) { pad[0]->SetLogz(1); } else { pad[0]->SetLogz(0); } pad[0]->SetFrameLineWidth(3); pad[0]->SetTickx(1); // Re-range: for(Int_t i=0; i<Nspecies; i++) { if(!hDen2D[i]) continue; hDen2D[i]->GetYaxis()->SetRangeUser(yMin -(factor-1)*yRange, yMax); } TH2F *hFrame = (TH2F*) gROOT->FindObject("hFrame1"); if(hFrame) delete hFrame; hFrame = (TH2F*) hDen2D[0]->Clone("hFrame1"); hFrame->Reset(); hFrame->SetLabelFont(42,"xyz"); hFrame->SetTitleFont(42,"xyz"); hFrame->GetYaxis()->SetNdivisions(505); hFrame->GetYaxis()->SetLabelSize(0.085); hFrame->GetYaxis()->SetTitleSize(0.09); hFrame->GetYaxis()->SetTitleOffset(0.7); hFrame->GetYaxis()->SetTickLength(0.02); hFrame->GetXaxis()->SetLabelOffset(999.); hFrame->GetXaxis()->SetTitleOffset(999.); hFrame->GetXaxis()->SetTickLength(0.04); // Frame asymmetry: hFrame->Draw("col"); // hDen2D[0]->GetZaxis()->SetNdivisions(505); // Injected electrons if any if(Nspecies>=3) { if(hDen2D[2]) { exHot->Draw(); hDen2D[2]->Draw("colz same"); } } // Plasma hDen2D[0]->GetZaxis()->SetTitleFont(42); exPlasma->Draw(); hDen2D[0]->Draw("colz same"); // Beam driver. if(hDen2D[1]) { // hDen2D[1]->GetZaxis()->SetNdivisions(505); exElec->Draw(); hDen2D[1]->Draw("colz same"); } { TGraph *gr = (TGraph*) graphsV2D.At(4); gr->Draw("C"); } { TGraph *gr = (TGraph*) graphsI2D.At(1); gr->Draw("C"); } if(opt.Contains("1dline")) { lineYzero->Draw(); lineYdown->Draw(); lineYup->Draw(); } if(opt.Contains("sline")) { if(zStartPlasma>xmin && zStartPlasma<xmax) lineStartPlasma->Draw(); if(zStartNeutral>xmin && zStartNeutral<xmax) lineStartNeutral->Draw(); if(zEndNeutral>xmin && zEndNeutral<xmax) lineEndNeutral->Draw(); } // lineYdown->Draw(); // lineYup->Draw(); // Palettes re-arrangement pad[0]->Update(); Float_t y1 = pad[0]->GetBottomMargin(); Float_t y2 = 1 - pad[0]->GetTopMargin(); Float_t x1 = pad[0]->GetLeftMargin(); Float_t x2 = 1 - pad[0]->GetRightMargin(); TPaletteAxis *palette = NULL; if(Nspecies>=3) { if(hDen2D[2]) { palette = (TPaletteAxis*)hDen2D[2]->GetListOfFunctions()->FindObject("palette"); } } if(palette) { palette->SetY2NDC(y2 - 0.00); palette->SetY1NDC(0.66*(y1+y2) + 0.00); palette->SetX1NDC(x2 + 0.005); palette->SetX2NDC(x2 + 0.03); // palette->SetTitleFont(42); // palette->SetTitleOffset(0.85); palette->SetTitleOffset(999.9); palette->SetTitleSize(0.075); palette->SetLabelFont(42); palette->SetLabelSize(0.075); palette->SetLabelOffset(0.001); palette->SetBorderSize(2); palette->SetLineColor(1); } palette = (TPaletteAxis*)hDen2D[0]->GetListOfFunctions()->FindObject("palette"); if(palette) { palette->SetY2NDC(0.66*(y1+y2) - 0.00); palette->SetY1NDC(0.33*(y1+y2) + 0.00); palette->SetX1NDC(x2 + 0.005); palette->SetX2NDC(x2 + 0.03); // palette->SetTitleFont(42); palette->SetTitleOffset(0.80); palette->SetTitleSize(0.075); palette->SetLabelFont(42); palette->SetLabelSize(0.075); palette->SetLabelOffset(0.001); palette->SetBorderSize(2); palette->SetLineColor(1); } palette = (TPaletteAxis*)hDen2D[1]->GetListOfFunctions()->FindObject("palette"); if(palette) { palette->SetY2NDC(0.33*(y1+y2) - 0.00); palette->SetY1NDC(y1 + 0.00); palette->SetX1NDC(x2 + 0.005); palette->SetX2NDC(x2 + 0.03); //palette->SetTitleFont(42); //palette->SetTitleOffset(0.85); palette->SetTitleOffset(999.9); palette->SetTitleSize(0.075); palette->SetLabelFont(42); palette->SetLabelSize(0.075); palette->SetLabelOffset(0.001); palette->SetBorderSize(2); palette->SetLineColor(1); } // 1D charge density plots: Float_t yaxismin = pad[0]->GetUymin(); Float_t yaxismax = pad[0]->GetUymin() + 0.33*(pad[0]->GetUymax() - pad[0]->GetUymin()) - 0.00; Float_t denmin = Min[1]; Float_t denmax = Max[1]; if(opt.Contains("logz")) { denmin = TMath::Log10(denmin); denmax = TMath::Log10(denmax); } Float_t curmin = 0.0; Float_t curmax = 0.0; if(opt.Contains("curr")) { curmin = 0.0; curmax = hCur1D[1]->GetMaximum(); cout << Form(" Maximum driver current = %6.2f kA ", curmax) << endl ; if(Nspecies>=3) if(hCur1D[2]) cout << Form(" Maximum witness current = %6.2f kA ", hCur1D[2]->GetMaximum()) << endl ; // Round for better plotting curmax = 0.1*TMath::Nint(curmax*10); } for(Int_t i=0; i<Nspecies; i++) { if(!hDen1D[i]) continue; Float_t slope = (yaxismax - yaxismin)/(denmax - denmin); for(Int_t j=0; j<hDen1D[i]->GetNbinsX(); j++) { Float_t content = hDen1D[i]->GetBinContent(j+1); if(opt.Contains("logz")) content = TMath::Log10(content); if(content<denmin) hDen1D[i]->SetBinContent(j+1,yaxismin); else hDen1D[i]->SetBinContent(j+1,(content - denmin) * slope + yaxismin); } if(hCur1D[i]) { slope = (yaxismax - yaxismin)/(curmax - curmin); for(Int_t j=0; j<hCur1D[i]->GetNbinsX(); j++) { Float_t content = hCur1D[i]->GetBinContent(j+1); if(content<curmin) hCur1D[i]->SetBinContent(j+1,yaxismin); else hCur1D[i]->SetBinContent(j+1,(content - curmin) * slope + yaxismin); } } } // Plasma on-axis density: // hDen1D[0]->SetLineWidth(2); // hDen1D[0]->SetLineColor(kGray+1); // // // PlasmaGlob::SetH1Style(hDen1D[0],1); // hDen1D[0]->Draw("same C"); if(opt.Contains("curr")) { hCur1D[1]->SetLineWidth(2); hCur1D[1]->SetLineColor(PlasmaGlob::elecLine); hCur1D[1]->Draw("same C"); } else { hDen1D[1]->SetLineWidth(2); hDen1D[1]->SetLineColor(PlasmaGlob::elecLine); // hDen1D[1]->Draw("same C"); } if(Nspecies>=3) { if(hDen1D[2]) { if(opt.Contains("curr")) { hCur1D[2]->SetLineWidth(2); hCur1D[2]->SetLineColor(kOrange+8); hCur1D[2]->Draw("same C"); } else { hDen1D[2]->SetLineWidth(2); hDen1D[2]->SetLineColor(kOrange+8); // hDen1D[2]->Draw("same C"); } } } // Current axis TGaxis *axis = NULL; if(opt.Contains("curr")) { axis = new TGaxis(xMax-xRange/6.0,yMin - (factor-1)*yRange, xMax-xRange/6.0,yaxismax, 0.001,curmax,503,"+LS"); axis->SetLineWidth(1); axis->SetLineColor(kGray+3);//PlasmaGlob::elecLine); axis->SetLabelColor(kGray+3);//PlasmaGlob::elecLine); axis->SetLabelSize(0.06); axis->SetLabelOffset(0.01); axis->SetLabelFont(42); axis->SetTitleColor(kGray+3);//PlasmaGlob::elecLine); axis->SetTitleSize(0.06); axis->SetTitleOffset(0.6); axis->SetTitleFont(42); axis->SetTickSize(0.03); axis->SetTitle("I [kA]"); axis->CenterTitle(); axis->SetNdivisions(505); axis->Draw(); } TPaveText *textTime = new TPaveText(xMax - 0.3*xRange, yMax-0.15*yRange, xMax-0.1, yMax-0.05*yRange); //x2-0.17,y2-0.12,x2-0.02,y2-0.02,"NDC"); PlasmaGlob::SetPaveTextStyle(textTime,32); char ctext[128]; if(opt.Contains("units") && n0) sprintf(ctext,"z = %5.1f #mum", Time * skindepth / PUnits::um); else sprintf(ctext,"t = %5.1f #omega_{p}^{-1}",Time); textTime->SetTextFont(42); textTime->AddText(ctext); textTime->Draw(); // textDen->Draw(); // if(opt.Contains("units")) // textWav->Draw(); textLabel[0] = new TPaveText(xMin + 0.02*xRange, yMax-0.2*yRange, xMin+0.30*xRange, yMax-0.05*yRange); PlasmaGlob::SetPaveTextStyle(textLabel[0],12); textLabel[0]->SetTextFont(42); textLabel[0]->AddText(sLabels[0]); textLabel[0]->Draw(); pad[0]->RedrawAxis(); C->cd(0); sprintf(pname,"pad_%i",0); pad[1] = (TPad*) gROOT->FindObject(pname); pad[1]->Draw(); pad[1]->cd(); // <--------------------------------------------------------- Bottom Plot pad[1]->SetFrameLineWidth(3); pad[1]->SetTickx(1); hFrame = (TH2F*) gROOT->FindObject("hFrame2"); if(hFrame) delete hFrame; hFrame = (TH2F*) hDen2D[0]->Clone("hFrame2"); hFrame->Reset(); Float_t yFactor = pad[0]->GetAbsHNDC()/pad[1]->GetAbsHNDC(); hFrame->GetYaxis()->SetLabelSize(yFactor*0.085); hFrame->GetYaxis()->SetTitleSize(yFactor*0.09); hFrame->GetYaxis()->SetTitleOffset(0.7/yFactor); hFrame->GetYaxis()->SetTickLength(0.02/yFactor); hFrame->GetXaxis()->SetTitleSize(0.10); hFrame->GetXaxis()->SetLabelSize(0.08); hFrame->GetXaxis()->SetLabelOffset(0.02); hFrame->GetXaxis()->SetTitleOffset(1.0); hFrame->GetXaxis()->SetTickLength(0.04*yFactor); hFrame->SetLabelFont(42,"xyz"); hFrame->SetTitleFont(42,"xyz"); hFrame->Draw("col"); // hE2D[0]->GetZaxis()->SetNdivisions(505); hV2D->GetZaxis()->SetTitleFont(42); hV2D->GetZaxis()->SetTickLength(0.02/yFactor); exPot->Draw(); hV2D->Draw("col z same"); for(Int_t i=0; i<graphsV2D.GetEntriesFast(); i++) { TGraph *gr = (TGraph*) graphsV2D.At(i); if(!gr) continue; gr->Draw("C"); } for(Int_t i=0; i<graphsI2D.GetEntriesFast(); i++) { //if(i!=2) continue; TGraph *gr = (TGraph*) graphsI2D.At(i); if(!gr) continue; gr->Draw("C"); } if(opt.Contains("1dline")) { lineYzero->Draw(); lineYdown->Draw(); lineYup->Draw(); } if(opt.Contains("sline")) { if(zStartPlasma>xmin && zStartPlasma<xmax) lineStartPlasma->Draw(); if(zStartNeutral>xmin && zStartNeutral<xmax) lineStartNeutral->Draw(); if(zEndNeutral>xmin && zEndNeutral<xmax) lineEndNeutral->Draw(); } pad[1]->Update(); y1 = pad[1]->GetBottomMargin(); y2 = 1 - pad[1]->GetTopMargin(); x1 = pad[1]->GetLeftMargin(); x2 = 1 - pad[1]->GetRightMargin(); palette = (TPaletteAxis*)hV2D->GetListOfFunctions()->FindObject("palette"); if(palette) { palette->SetY2NDC(y2 - 0.00); palette->SetY1NDC(y1 + 0.00); palette->SetX1NDC(x2 + 0.005); palette->SetX2NDC(x2 + 0.03); // palette->SetTitleFont(42); palette->SetTitleSize(yFactor*0.075); palette->SetTitleOffset(0.80/yFactor); palette->SetLabelSize(yFactor*0.075); palette->SetLabelFont(42); palette->SetLabelOffset(0.01/yFactor); palette->SetBorderSize(2); palette->SetLineColor(1); } pad[1]->RedrawAxis(); textLabel[1] = new TPaveText(xMin + 0.02*xRange, yMax-0.2*yRange, xMin+0.30*xRange, yMax-0.05*yRange); PlasmaGlob::SetPaveTextStyle(textLabel[1],12); textLabel[1]->SetTextFont(42); textLabel[1]->AddText(sLabels[1]); textLabel[1]->Draw(); C->cd(); // Print to a file PlasmaGlob::imgconv(C,fOutName,opt); // --------------------------------------------------------- PlasmaGlob::DestroyCanvases(); }
void ZinvEstimate(){//main programme //Set Canvas Style TStyle *gStyle = new TStyle("gStyle","Style for P-TDR"); SetStyle st; st.SetPars(gStyle); //finished setting canvas style DataMC plot; //Important //In kevins v3 production due to a bug puWeight is divided to all standard MC weights ...this should be removed //from the code if you are using it for version otherthan V3 TString InputFilePathV4="/eos/uscms/store/user/pedrok/SUSY2015/Analysis/Skims/Run2ProductionV4/"; TString InputFilePathV3="/eos/uscms/store/user/pedrok/SUSY2015/Analysis/Skims/Run2ProductionV3/"; TString InputFilePathV2="/eos/uscms/store/user/pedrok/SUSY2015/Analysis/Skims/Run2ProductionV2/"; TChain* tZinv = new TChain("tree"); tZinv->Add(InputFilePathV4+"tree_signal/tree_ZJetsToNuNu_HT*.root"); ReadTree Zinv(tZinv); //reading the GJets MC TChain* tGJets = new TChain("tree"); tGJets->Add(InputFilePathV4+"tree_GJet_CleanVars/tree_GJets_HT-*.root"); ReadTree GJets(tGJets); //reading QCD MC TChain* tQCD = new TChain("tree"); tQCD->Add(InputFilePathV4+"tree_GJet_CleanVars/tree_QCD_HT*.root"); ReadTree QCD(tQCD); //reading Single photon Data TChain* tData = new TChain("tree"); tData->Add(InputFilePathV4+"tree_GJet_CleanVars/tree_SinglePhoton_*.root"); ReadTree Data(tData); double Lumi=1280.23; int nBinsHT=13; int nBinsMHT=7; int nBinsPt=8; int nBinsNJ=6; int nBinsS=25; double HTbins[14]={500.,600.,700,800,900,1000.,1100,1200.,1300,1400,1500,1700,2000,3000}; double MHTbins[8]={200.,300,400,500.,600,750.,1000,1500.}; double Ptbins[9]={100,200.,300,400,500.,600,750.,1000,1500.}; double NJetsbins[7]={4,5,6,7,8,9,12}; /////////Three MHT Bins double MHTbin1Min=200; double MHTbin1Max=350; double MHTbin2Min=350; double MHTbin2Max=500; double MHTbin3Min=500; double MHTbin3Max=1500; ///////////Three MHT Bins int nBinAN=18; double nBinANmax=18.5; /////////////////////////////////////////////////////////////////////////////All user input changes above TH1F *hHT_Zinv=new TH1F("hHT_Zinv","hHT_Zinv",nBinsHT,HTbins); TH1F *hMHT_Zinv=new TH1F("hMHT_Zinv","hMHT_Zinv",nBinsMHT,MHTbins); TH1F *hNJets_Zinv=new TH1F("hNJets_Zinv","hNJets_Zinv",nBinsNJ,NJetsbins); TH1F *hHT_GJets=new TH1F("hHT_GJets","hHT_GJets",nBinsHT,HTbins); TH1F *hMHT_GJets=new TH1F("hMHT_GJets","hMHT_GJets",nBinsMHT,MHTbins); TH1F *hNJets_GJets=new TH1F("hNJets_GJets","hNJets_GJets",nBinsNJ,NJetsbins); TH1F *hSieta_GJetsEB=new TH1F("hSieta_GJetsEB","hSieta_GJetsEB",nBinsS,0.006,0.0107); TH1F *hSieta_GJetsEC=new TH1F("hSieta_GJetsEC","hSieta_GJetsEC",nBinsS,0.01,0.0272); TH1F *hSieta_GJetsEBLow=new TH1F("hSieta_GJetsEBLow","hSieta_GJetsEBLow",nBinsS,0.006,0.0107); TH1F *hSieta_GJetsECLow=new TH1F("hSieta_GJetsECLow","hSieta_GJetsECLow",nBinsS,0.01,0.0272); TH1F *hSieta_GJetsEBMed=new TH1F("hSieta_GJetsEBMed","hSieta_GJetsEBMed",nBinsS,0.006,0.0107); TH1F *hSieta_GJetsECMed=new TH1F("hSieta_GJetsECMed","hSieta_GJetsECMed",nBinsS,0.01,0.0272); TH1F *hSieta_GJetsEBHigh=new TH1F("hSieta_GJetsEBHigh","hSieta_GJetsEBHigh",nBinsS,0.006,0.0107); TH1F *hSieta_GJetsECHigh=new TH1F("hSieta_GJetsECHigh","hSieta_GJetsECHigh",nBinsS,0.01,0.0272); TH1F *hPhPt_GJetsEB=new TH1F("hPhPt_GJetsEB","hPhPt_GJetsEB",nBinsPt,Ptbins); TH1F *hPhPt_GJetsEC=new TH1F("hPhPt_GJetsEC","hPhPt_GJetsEC",nBinsPt,Ptbins); TH1F *hHT_QCD=new TH1F("hHT_QCD","hHT_QCD",nBinsHT,HTbins); TH1F *hMHT_QCD=new TH1F("hMHT_QCD","hMHT_QCD",nBinsMHT,MHTbins); TH1F *hNJets_QCD=new TH1F("hNJets_QCD","hNJets_QCD",nBinsNJ,NJetsbins); TH1F *hSieta_QCDEB=new TH1F("hSieta_QCDEB","hSieta_QCDEB",nBinsS,0.006,0.0107); TH1F *hSieta_QCDEC=new TH1F("hSieta_QCDEC","hSieta_QCDEC",nBinsS,0.01,0.0272); TH1F *hSieta_QCDEBLow=new TH1F("hSieta_QCDEBLow","hSieta_QCDEBLow",nBinsS,0.006,0.0107); TH1F *hSieta_QCDECLow=new TH1F("hSieta_QCDECLow","hSieta_QCDECLow",nBinsS,0.01,0.0272); TH1F *hSieta_QCDEBMed=new TH1F("hSieta_QCDEBMed","hSieta_QCDEBMed",nBinsS,0.006,0.0107); TH1F *hSieta_QCDECMed=new TH1F("hSieta_QCDECMed","hSieta_QCDECMed",nBinsS,0.01,0.0272); TH1F *hSieta_QCDEBHigh=new TH1F("hSieta_QCDEBHigh","hSieta_QCDEBHigh",nBinsS,0.006,0.0107); TH1F *hSieta_QCDECHigh=new TH1F("hSieta_QCDECHigh","hSieta_QCDECHigh",nBinsS,0.01,0.0272); TH1F *hPhPt_QCDEB=new TH1F("hPhPt_QCDEB","hPhPt_QCDEB",nBinsPt,Ptbins); TH1F *hPhPt_QCDEC=new TH1F("hPhPt_QCDEC","hPhPt_QCDEC",nBinsPt,Ptbins); TH1F *hHT_Data=new TH1F("hHT_Data","hHT_Data",nBinsHT,HTbins); TH1F *hMHT_Data=new TH1F("hMHT_Data","hMHT_Data",nBinsMHT,MHTbins); TH1F *hNJets_Data=new TH1F("hNJets_Data","hNJets_Data",nBinsNJ,NJetsbins); TH1F *hSieta_DataEB=new TH1F("hSieta_DataEB","hSieta_DataEB",nBinsS,0.006,0.0107); TH1F *hSieta_DataEC=new TH1F("hSieta_DataEC","hSieta_DataEC",nBinsS,0.01,0.0272);; TH1F *hSieta_DataEBLow=new TH1F("hSieta_DataEBLow","hSieta_DataEBLow",nBinsS,0.006,0.0107); TH1F *hSieta_DataECLow=new TH1F("hSieta_DataECLow","hSieta_DataECLow",nBinsS,0.01,0.0272); TH1F *hSieta_DataEBMed=new TH1F("hSieta_DataEBMed","hSieta_DataEBMed",nBinsS,0.006,0.0107); TH1F *hSieta_DataECMed=new TH1F("hSieta_DataECMed","hSieta_DataECMed",nBinsS,0.01,0.0272); TH1F *hSieta_DataEBHigh=new TH1F("hSieta_DataEBHigh","hSieta_DataEBHigh",nBinsS,0.006,0.0107); TH1F *hSieta_DataECHigh=new TH1F("hSieta_DataECHigh","hSieta_DataECHigh",nBinsS,0.01,0.0272); TH1F *hPhPt_DataEB=new TH1F("hPhPt_DataEB","hPhPt_DataEB",nBinsPt,Ptbins); TH1F *hPhPt_DataEC=new TH1F("hPhPt_DataEC","hPhPt_DataEC",nBinsPt,Ptbins); TH1F *h_NZinv18bin=new TH1F("h_NZinv18bin","h_NZinv18bin",nBinAN,0.5,nBinANmax); // TH1F *h_NZinv18binC=new TH1F("h_NZinv18binC","h_NZinv18binC",nBinAN,0.5,nBinANmax); //TH1F *EBestimate=new TH1F("EBestimate","EBestimate",18,0.5,18.5); //TH1F *ECestimate=new TH1F("ECestimate","ECestimate",18,0.5,18.5); TH1F *ZinvEstimate=new TH1F("ZinvEstimate","ZinvEstimate",nBinAN,0.5,nBinANmax); TH1F *h_NGJets18bin=new TH1F("h_NGJets18binC","h_NGJets18binC",nBinAN,0.5,nBinANmax); TH1F *h_NGJets18binEB=new TH1F("h_NGJets18binEB","h_NGJets18binEB",nBinAN,0.5,nBinANmax); TH1F *h_NGJets18binEC=new TH1F("h_NGJets18binEC","h_NGJets18binEC",nBinAN,0.5,nBinANmax); TH1F *h_NQCD18binEB=new TH1F("h_NQCD18binEB","h_NQCD18binEB",nBinAN,0.5,nBinANmax); TH1F *h_NQCD18binEC=new TH1F("h_NQCD18binEC","h_NQCD18binEC",nBinAN,0.5,nBinANmax); TH1F *h_Ndata18binEB=new TH1F("h_Ndata18binEB","h_Ndata18binEB",nBinAN,0.5,nBinANmax); TH1F *h_Ndata18binEC=new TH1F("h_Ndata18binEC","h_Ndata18binEC",nBinAN,0.5,nBinANmax); TH1F *h_ZgammaR18bin=new TH1F("h_ZgammaR18bin","h_ZgammmaR18bin",nBinAN,0.5,nBinANmax); TH1F *h_ZgammaRWSF=new TH1F("h_ZgammaRWSF","h_ZgammmaRWSF",nBinAN,0.5,nBinANmax); int maxEvents_Zinv=tZinv->GetEntries(); cout<<"maxEventsZinv: "<<maxEvents_Zinv<<endl; for(int iEv=0;iEv<maxEvents_Zinv;iEv++){//Looping over Zinv MC/////////////////////////////////////// tZinv->GetEntry(iEv); if(iEv % 1000000==0){cout<<"Event no Zinv : "<<iEv<<endl;} int binNumber_Zinv = computeBin( Zinv.MHTclean, Zinv.HTclean, Zinv.NJetsclean, k13TeV); double weight=0; if(binNumber_Zinv >-1 && Zinv.BTagsclean==0){//Filling Yield(N_Obsereved) in Zinv h_NZinv18bin->Fill(binNumber_Zinv,(Lumi*Zinv.Weight)); h_NZinv18binC->Fill(binNumber_Zinv,(Lumi*Zinv.Weight)); } }//Lopping over Zinv MC////////////////////////////////////////////////////////// cout<<"Zinv Observed MC: "<<h_NZinv18bin->Integral()<<endl; cout<<"First bin: "<<h_NZinv18bin->GetBinContent(0)<<endl; for(int i=1;i<19;i++){ cout<<"Zinv Bin Content: "<<h_NZinv18bin->GetBinContent(i)<<endl; } int maxEvents_GJets=tGJets->GetEntries(); cout<<"maxEventsGJets: "<<maxEvents_GJets<<endl; for(int iEv=0;iEv<maxEvents_GJets;iEv++){//Looping over GJets MC/////////////////////////////////////// tGJets->GetEntry(iEv); if(iEv % 1000000==0){cout<<"Event no GJets : "<<iEv<<endl;} int binNumber_GJets = computeBin( GJets.MHTclean, GJets.HTclean, GJets.NJetsclean, k13TeV); int index=GJets.photonIndex(); if(binNumber_GJets >-1 && GJets.BTagsclean==0 && index !=-1 && GJets.photon_nonPrompt->at(index) !=1){//Filling Yield(N_Obsereved) in GJets MC hHT_GJets->Fill(GJets.HTclean,Lumi*GJets.Weight); hMHT_GJets->Fill(GJets.MHTclean,Lumi*GJets.Weight); hNJets_GJets->Fill(GJets.NJetsclean,Lumi*GJets.Weight); h_NGJets18bin->Fill(binNumber_GJets,Lumi*GJets.Weight); if(fabs(GJets.bestPhoton->at(0).Eta())< 1.4442){//barrel hSieta_GJetsEB->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); h_NGJets18binEB->Fill(binNumber_GJets,Lumi*GJets.Weight); hPhPt_GJetsEB->Fill(GJets.photonCands->at(index).Pt(),Lumi*GJets.Weight); ////////////////////////////////////Sieta in MHT bins if(GJets.MHTclean >MHTbin1Min && GJets.MHTclean< MHTbin1Max){ hSieta_GJetsEBLow->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); } if(GJets.MHTclean >MHTbin2Min && GJets.MHTclean< MHTbin2Max){ hSieta_GJetsEBMed->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); } if(GJets.MHTclean >MHTbin3Min && GJets.MHTclean< MHTbin3Max){ hSieta_GJetsEBHigh->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); } /////////////////////////Sieta in MHT bins }//barrel if(fabs(GJets.bestPhoton->at(0).Eta())> 1.566 && fabs(GJets.bestPhoton->at(0).Eta())< 2.5){//endcap hSieta_GJetsEC->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); h_NGJets18binEC->Fill(binNumber_GJets,Lumi*GJets.Weight); hPhPt_GJetsEC->Fill(GJets.photonCands->at(index).Pt(),Lumi*GJets.Weight); ////////////////////////////////////Sieta in MHT bins if(GJets.MHTclean >MHTbin1Min && GJets.MHTclean< MHTbin1Max){ hSieta_GJetsECLow->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); } if(GJets.MHTclean >MHTbin2Min && GJets.MHTclean< MHTbin2Max){ hSieta_GJetsECMed->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); } if(GJets.MHTclean >MHTbin3Min && GJets.MHTclean< MHTbin3Max){ hSieta_GJetsECHigh->Fill(GJets.photon_sigmaIetaIeta->at(index),Lumi*GJets.Weight); } /////////////////////////Sieta in MHT bins }//endcap }//Filling Yield(N_Obsereved) in GJets MC }//Looping over GJets MC////////////////////////////////////////////////////////////////////////// cout<<"Total GJets Events: "<<hHT_GJets->Integral(); int maxEvents_QCD=tQCD->GetEntries(); cout<<"maxEventsQCD: "<<maxEvents_QCD<<endl; for(int iEv=0;iEv<maxEvents_QCD;iEv++){//Looping over QCD MC tQCD->GetEntry(iEv); if(iEv % 1000000==0){cout<<"Event no QCD : "<<iEv<<endl;} int binNumber_QCD = computeBin( QCD.MHTclean, QCD.HTclean, QCD.NJetsclean, k13TeV); int index=QCD.photonIndex(); if(binNumber_QCD >-1 && QCD.BTagsclean==0 && index !=-1 && QCD.photon_nonPrompt->at(index) ==1 ){//Filling Yield(N_Obsereved) in QCD MC hHT_QCD->Fill(QCD.HTclean,Lumi*QCD.Weight); hMHT_QCD->Fill(QCD.MHTclean,Lumi*QCD.Weight); hNJets_QCD->Fill(QCD.NJetsclean,Lumi*QCD.Weight); if(fabs(QCD.bestPhoton->at(0).Eta())< 1.4442){//barrel hSieta_QCDEB->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); h_NQCD18binEB->Fill(binNumber_QCD,Lumi*QCD.Weight); hPhPt_QCDEB->Fill(QCD.photonCands->at(index).Pt(),Lumi*QCD.Weight); ////////////////////////////////////Sieta in MHT bins if(QCD.MHTclean >MHTbin1Min && QCD.MHTclean< MHTbin1Max){ hSieta_QCDEBLow->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); } if(QCD.MHTclean >MHTbin2Min && QCD.MHTclean< MHTbin2Max){ hSieta_QCDEBMed->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); } if(QCD.MHTclean >MHTbin3Min && QCD.MHTclean< MHTbin3Max){ hSieta_QCDEBHigh->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); } /////////////////////////Sieta in MHT bins }//barrel if(fabs(QCD.bestPhoton->at(0).Eta())> 1.566 && abs(QCD.bestPhoton->at(0).Eta()) <2.5 ){//endcap hSieta_QCDEC->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); h_NQCD18binEC->Fill(binNumber_QCD,Lumi*QCD.Weight); hPhPt_QCDEC->Fill(QCD.photonCands->at(index).Pt(),Lumi*QCD.Weight); }//endcap ////////////////////////////////////Sieta in MHT bins if(QCD.MHTclean >MHTbin1Min && QCD.MHTclean< MHTbin1Max){ hSieta_QCDECLow->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); } if(QCD.MHTclean >MHTbin2Min && QCD.MHTclean< MHTbin2Max){ hSieta_QCDECMed->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); } if(QCD.MHTclean >MHTbin3Min && QCD.MHTclean< MHTbin3Max){ hSieta_QCDECHigh->Fill(QCD.photon_sigmaIetaIeta->at(index),Lumi*QCD.Weight); } /////////////////////////Sieta in MHT bins }//Filling Yield(N_Obsereved) in QCD MC }//Looping over QCD MC int maxEvents_Data=tData->GetEntries(); //cout<<"maxEvents in Single Photon Data: "<<maxEvents_Data<<endl; for(int iEv=0;iEv<maxEvents_Data;iEv++){//Data tData->GetEntry(iEv); if(iEv % 1000000==0){cout<<"Event no Data : "<<iEv<<endl;} //cout<<"Event no: "<<iEv<<endl; int binNumber_Data = computeBin( Data.MHTclean, Data.HTclean, Data.NJetsclean, k13TeV); int index=Data.photonIndex(); if(binNumber_Data >-1 && Data.BTagsclean==0 && index !=-1){//Filling Yield(N_Obsereved) in Data bool PassTrigger=false; for(int itr=0;itr<Data.TriggerNames->size();itr++){ //cout<<"trigger size: "<<Data.TriggerNames->at(itr)<<endl; if(Data.TriggerNames->at(itr)=="HLT_Photon90_CaloIdL_PFHT500_v3" && Data.TriggerPass->at(itr)==1){ PassTrigger=true; } } if(PassTrigger==true){//trigger pass hHT_Data->Fill(Data.HTclean); hMHT_Data->Fill(Data.MHTclean); hNJets_Data->Fill(Data.NJetsclean); if(fabs(Data.bestPhoton->at(0).Eta())< 1.4442){//barrel h_Ndata18binEB->Fill(binNumber_Data); hSieta_DataEB->Fill(Data.photon_sigmaIetaIeta->at(index)); hPhPt_DataEB->Fill(Data.photonCands->at(index).Pt()); ////////////////////////////////////Sieta in MHT bins if(Data.MHTclean >MHTbin1Min && Data.MHTclean< MHTbin1Max){ hSieta_DataEBLow->Fill(Data.photon_sigmaIetaIeta->at(index)); } if(Data.MHTclean >MHTbin2Min && Data.MHTclean< MHTbin2Max){ hSieta_DataEBMed->Fill(Data.photon_sigmaIetaIeta->at(index)); } if(Data.MHTclean >MHTbin3Min && Data.MHTclean< MHTbin3Max){ hSieta_DataEBHigh->Fill(Data.photon_sigmaIetaIeta->at(index)); } /////////////////////////Sieta in MHT bins }//barrel if(fabs(Data.bestPhoton->at(0).Eta())> 1.566 && fabs(Data.bestPhoton->at(0).Eta())< 2.5 ){//endcap h_Ndata18binEC->Fill(binNumber_Data); hSieta_DataEC->Fill(Data.photon_sigmaIetaIeta->at(index)); hPhPt_DataEC->Fill(Data.photonCands->at(index).Pt()); ////////////////////////////////////Sieta in MHT bins if(Data.MHTclean >MHTbin1Min && Data.MHTclean< MHTbin1Max){ hSieta_DataECLow->Fill(Data.photon_sigmaIetaIeta->at(index)); } if(Data.MHTclean >MHTbin2Min && Data.MHTclean< MHTbin2Max){ hSieta_DataECMed->Fill(Data.photon_sigmaIetaIeta->at(index)); } if(Data.MHTclean >MHTbin3Min && Data.MHTclean< MHTbin3Max){ hSieta_DataECHigh->Fill(Data.photon_sigmaIetaIeta->at(index)); } /////////////////////////Sieta in MHT bins }//endcap }//trigger pass }//Filling Yield(N_Obsereved) in Data }//Data //trigger efficiency ///////////////////////////defining legend char Legname1[100]; TLegend *leg[24]; for(int k0=0;k0<24;k0++){ sprintf(Legname1,"leg_1D%i",k0); leg[k0]=new TLegend(0.5,0.7,0.80,0.89); leg[k0]->SetTextFont(62); leg[k0]->SetLineColor(1); leg[k0]->SetLineStyle(1); leg[k0]->SetLineWidth(3); leg[k0]->SetFillColor(0); leg[k0]->SetFillStyle(1001); leg[k0]->SetShadowColor(0); leg[k0]->SetDrawOption(0); leg[k0]->SetBorderSize(0); leg[k0]->SetTextSize(0.03); } ///////////////////////////////ZinvMC Yield //TCanvas *ZinvMCYield=new TCanvas("ZinvMC","ZinvMC"); //ZinvMCYield->SetLogy(); h_NZinv18bin->Sumw2(); h_NZinv18bin->SetFillColor(1); h_NZinv18bin->SetFillStyle(1000); h_NZinv18bin->GetXaxis()->SetTitle("bin Number"); h_NZinv18bin->GetYaxis()->SetTitle("Z/Gamma Ratio"); //h_NZinv18bin->Draw("hist"); //////////////////////////////////////////////Calculating Zgamma Ratio start TPaveText *tpav1 = new TPaveText(0.1956522,0.6247818,0.729097,0.8970332,"brNDC"); tpav1->SetBorderSize(0); tpav1->SetFillStyle(0); tpav1->SetTextAlign(11); tpav1->SetTextFont(42); tpav1->SetTextSize(0.04); tpav1->AddText("HT >500"); tpav1->AddText("#gamma p_{T} > 100 "); tpav1->AddText("NJets >=4"); tpav1->AddText("MHT>200"); tpav1->AddText("Btags=0"); tpav1->AddText("#Delta #Phi_{1,2,3,4}>(0.5,0.5,0.3,0.3)"); TPaveText *pCMS1 = new TPaveText(0.132107,0.9308003,0.8327759,0.9923583,"brNDC"); pCMS1->SetBorderSize(0); pCMS1->SetFillStyle(0); pCMS1->SetTextAlign(11); pCMS1->SetTextFont(42); pCMS1->SetTextSize(0.04); pCMS1->AddText("CMS #it{Preliminary} #sqrt{s}= 13 TeV"); TCanvas *cZgammaR=new TCanvas("cZGammaR","cZGammaR"); TH1F *h_ZgR = (TH1F*)h_NZinv18bin->Clone("h_ZgR"); h_ZgR->Divide(h_NGJets18bin); cZgammaR->cd(); h_ZgR->Draw("E2"); tpav1->Draw(); pCMS1->Draw(); cZgammaR->SaveAs("ZgammaRatioWOSF.png"); cZgammaR->SaveAs("ZgammaRatioWOSF.pdf"); cZgammaR->SaveAs("ZgammaRatioWOSF.gif"); ///////////////////////////////////Calculating ZGamma ratio end /////////////////////////////////////////////////////Dealing with Data barrel TH1F *h_DataSimEB = (TH1F*)h_Ndata18binEB->Clone("h_DataSimEB"); TH1F *h_DataSimEC = (TH1F*)h_Ndata18binEC->Clone("h_DataSimEC"); TH1F *h_DataSimEBforErr = (TH1F*)h_NGJets18binEB->Clone("h_DataSimEBforErr"); TH1F *h_DataSimECforErr = (TH1F*)h_NGJets18binEB->Clone("h_DataSimECforErr"); h_DataSimEBforErr->Scale((1/h_DataSimEBforErr->Integral())*h_Ndata18binEB->Integral()); h_DataSimECforErr->Scale((1/h_DataSimECforErr->Integral())*h_Ndata18binEC->Integral()); /////////////////////Fill the empty bins with simulated data for(int i=1;i<(nBinAN+1);i++){//loop over bins h_DataSimEB->SetBinError(i,0.); h_DataSimEC->SetBinError(i,0.); }//loop over bins TH1F *hEBPurity=new TH1F("hEBPurity","hEBPurity",nBinAN,0.5,nBinANmax); TH1F *hECPurity=new TH1F("hECPurity","hECPurity",nBinAN,0.5,nBinANmax); TH1F *hEBfrag=new TH1F("hEBfrag","hEBfrag",nBinAN,0.5,nBinANmax); TH1F *hECfrag=new TH1F("hECfrag","hECfrag",nBinAN,0.5,nBinANmax); //uncorel //corel double ebpErr=sqrt((0.009*0.009)+(0.03*0.03)); double ecpErr=sqrt((0.016*0.016)+(0.046*0.046)); double ebpErrCorel=0.03; double ebpErrUnCorel=0.009; double ecpErrCorel=0.046; double ecpErrUnCorel=0.016; for(int i=1;i<(nBinAN+1);i++){//set purity stuff hEBPurity->SetBinContent(i,0.967); hEBPurity->SetBinError(i,ebpErr); hECPurity->SetBinContent(i,0.956); hECPurity->SetBinError(i,ecpErr); hEBfrag->SetBinContent(i,0.92); hEBfrag->SetBinError(i,0.04); hECfrag->SetBinContent(i,0.92); hECfrag->SetBinError(i,0.04); }//set purity stuff const Int_t NumBins= nBinAN; double binNumber[nBinAN]; double YieldEstimated[nBinAN]; double YieldErrUp_Estimated[nBinAN]; double YieldErrLow_Estimated[nBinAN]; double YieldPredMC[nBinAN]; double YieldErrUp_PredMC[nBinAN]; double YieldErrLow_PredMC[nBinAN]; double XErrLow[nBinAN]; double XErrUp[nBinAN]; double ZgRwSF[nBinAN]; double ZgRwSF_sys_ErrUp[nBinAN]; double ZgRwSF_sys_ErrLow[nBinAN]; double ZgRwSF_stat_Err[nBinAN]; for(int ibin=1;ibin<(nBinAN+1);ibin++){//loop over bin error calculation double SF=0.98; double SFup=1.03; double SFlow=0.93; double ZgRcentral=h_ZgR->GetBinContent(ibin)/0.98; double ZgRup=h_ZgR->GetBinContent(ibin)/1.03; double ZgRlow=h_ZgR->GetBinContent(ibin)/0.93; double ZgRcorelErrup=fabs(ZgRcentral-ZgRlow); double ZgRcorelErrlow=fabs(ZgRcentral-ZgRup); double ZgRsymErr=0.5*(sqrt((ZgRcorelErrup*ZgRcorelErrup)+(ZgRcorelErrlow*ZgRcorelErrlow))); double ZgRcorel_Rel_Errup=ZgRcorelErrup/ZgRcentral; double ZgRcorel_Rel_Errlow=ZgRcorelErrlow/ZgRcentral; //double ZgRcorelErr=sqrt((ZgRcorelErrup*ZgRcorelErrup)+(ZgRcorelErrlow*ZgRcorelErrlow)); double ZgRuncorelErr=h_ZgR->GetBinError(ibin)/SF; double ZgRuncorel_Rel_Err=ZgRuncorelErr/ZgRcentral; double ZgRsymErrStat=h_ZgR->GetBinError(ibin)/SF;//h_ZgR->GetBinError(ibin); double ZgRallSymErr=sqrt((ZgRsymErr*ZgRsymErr)+(ZgRsymErrStat*ZgRsymErrStat)); //important lines to be changed double ZgR=ZgRcentral; double ZgRerr=ZgRallSymErr; double ZgRerrUp=sqrt((ZgRcorelErrup*ZgRcorelErrup)+(ZgRuncorelErr*ZgRuncorelErr)); double ZgRerrLow=sqrt((ZgRcorelErrlow*ZgRcorelErrlow)+(ZgRuncorelErr*ZgRuncorelErr)); ////////////////////////////////////barrel starts int EBobs=h_DataSimEB->GetBinContent(ibin); double EBobsErr=h_DataSimEB->GetBinError(ibin); double pEB=hEBPurity->GetBinContent(ibin); double pEBerr=hEBPurity->GetBinError(ibin); double pEB_Rel_err=pEBerr/pEB; int ECobs=h_DataSimEC->GetBinContent(ibin); double ECobsErr=h_DataSimEC->GetBinError(ibin); double pEC=hECPurity->GetBinContent(ibin); double pECerr=hECPurity->GetBinError(ibin); double pEC_Rel_err=pECerr/pEC; double f=0.92; double ferr=0.04; double f_Rel_err=ferr/f; double YieldTotal=ZgR*(EBobs*pEB+ECobs*pEC)*f; double YieldTotalErr=0; double YieldTotal_Rel_Err=0; double YieldTotalErrUp=0; double YieldTotal_Rel_ErrUp=0; double YieldTotalErrLow=0; double YieldTotal_Rel_ErrLow=0; int Nobserved=EBobs+ECobs; double totalPurity=0; double totalPurityErr=0; double totalPurity_Rel_Err=0; double ZinvMCYield=h_NZinv18binC->GetBinContent(ibin); double ZinvMCYieldErr=h_NZinv18binC->GetBinError(ibin); double ZinvMCYield_Rel_Err=ZinvMCYieldErr/ZinvMCYield; if(Nobserved !=0){ totalPurity=((EBobs*pEB+ECobs*pEC)*f)/Nobserved; double totalPurityErr1=(EBobs*pEBerr+ECobs*pECerr)/Nobserved; double totalPurityErr2=ferr; totalPurityErr=sqrt((totalPurityErr1*totalPurityErr1)+(totalPurityErr2*totalPurityErr2)); totalPurity_Rel_Err=totalPurityErr/totalPurity; YieldTotalErr=Nobserved*(sqrt((ZgR*ZgR*totalPurityErr*totalPurityErr)+(totalPurity*totalPurity*ZgRerr*ZgRerr))); YieldTotal_Rel_Err=YieldTotalErr/YieldTotal; YieldTotalErrUp=Nobserved*(sqrt((ZgR*ZgR*totalPurityErr*totalPurityErr)+(totalPurity*totalPurity*ZgRerrUp*ZgRerrUp))); YieldTotal_Rel_ErrUp=YieldTotalErrUp/YieldTotal; YieldTotalErrLow=Nobserved*(sqrt((ZgR*ZgR*totalPurityErr*totalPurityErr)+(totalPurity*totalPurity*ZgRerrLow*ZgRerrLow))); YieldTotal_Rel_ErrLow=YieldTotalErrLow/YieldTotal; } if(Nobserved ==0){ double NobservedNew=h_DataSimEBforErr->GetBinContent(ibin)+h_DataSimECforErr->GetBinContent(ibin); double EBobsNew=h_DataSimEBforErr->GetBinContent(ibin); double ECobsNew=h_DataSimECforErr->GetBinContent(ibin); totalPurity=((EBobsNew*pEB+ECobsNew*pEC)*f)/NobservedNew; double totalPurityErr1=(EBobsNew*pEBerr+ECobsNew*pECerr)/NobservedNew; double totalPurityErr2=ferr; totalPurityErr=sqrt((totalPurityErr1*totalPurityErr1)+(totalPurityErr2*totalPurityErr2)); totalPurity_Rel_Err=totalPurityErr/totalPurity; YieldTotalErr=NobservedNew*(sqrt((ZgR*ZgR*totalPurityErr*totalPurityErr)+(totalPurity*totalPurity*ZgRerr*ZgRerr))); double YieldTotalNew=ZgR*(EBobsNew*pEB+ECobsNew*pEC)*f; YieldTotal_Rel_Err=YieldTotalErr/YieldTotalNew; YieldTotalErrUp=NobservedNew*(sqrt((ZgR*ZgR*totalPurityErr*totalPurityErr)+(totalPurity*totalPurity*ZgRerrUp*ZgRerrUp))); YieldTotal_Rel_ErrUp=YieldTotalErrUp/YieldTotalNew; YieldTotalErrLow=NobservedNew*(sqrt((ZgR*ZgR*totalPurityErr*totalPurityErr)+(totalPurity*totalPurity*ZgRerrLow*ZgRerrLow))); YieldTotal_Rel_ErrLow=YieldTotalErrLow/YieldTotalNew; } double YieldErrWithStat=0; double YieldErrWithStatUp=0; double YieldErrWithStatLow=0; double NobsErr=sqrt(Nobserved); YieldErrWithStat=sqrt((ZgR*totalPurity*NobsErr)*(ZgR*totalPurity*NobsErr) + (Nobserved*totalPurity*ZgRerr)*(Nobserved*totalPurity*ZgRerr) + (Nobserved*ZgR*totalPurityErr)*(Nobserved*ZgR*totalPurityErr)); YieldErrWithStatUp=sqrt((ZgR*totalPurity*NobsErr)*(ZgR*totalPurity*NobsErr) + (Nobserved*totalPurity*ZgRerrUp)*(Nobserved*totalPurity*ZgRerrUp) + (Nobserved*ZgR*totalPurityErr)*(Nobserved*ZgR*totalPurityErr)); YieldErrWithStatLow=sqrt((ZgR*totalPurity*NobsErr)*(ZgR*totalPurity*NobsErr) + (Nobserved*totalPurity*ZgRerrLow)*(Nobserved*totalPurity*ZgRerrLow) + (Nobserved*ZgR*totalPurityErr)*(Nobserved*ZgR*totalPurityErr)); ZgRwSF[ibin-1]=ZgR; ZgRwSF_sys_ErrUp[ibin-1]=ZgRcorelErrup; ZgRwSF_sys_ErrLow[ibin-1]=ZgRcorelErrlow; ZgRwSF_stat_Err[ibin-1]=ZgRuncorelErr; binNumber[ibin-1]=ibin; YieldEstimated[ibin-1]=YieldTotal; YieldErrUp_Estimated[ibin-1]=YieldErrWithStatUp; YieldErrLow_Estimated[ibin-1]=YieldErrWithStatLow; YieldPredMC[ibin-1]=ZinvMCYield; YieldErrUp_PredMC[ibin-1]=ZinvMCYieldErr; YieldErrLow_PredMC[ibin-1]=ZinvMCYieldErr; XErrLow[ibin-1]=0.5; XErrUp[ibin-1]=0.5; printf(" %i :%i |%i| %4.3f(%4.3f) |%i| %4.3f(%4.3f) |%4.3f(%4.3f,+%4.3f-%4.3f)| %4.3f(%4.3f) |%4.3f(%4.3f)| %4.3f(+%4.3f-%4.3f) |%4.3f(%4.3f)",ibin,Nobserved, EBobs,pEB,pEB_Rel_err,ECobs,pEC,pEC_Rel_err, ZgR,ZgRuncorel_Rel_Err,ZgRcorel_Rel_Errup,ZgRcorel_Rel_Errlow,f,f_Rel_err,totalPurity,totalPurity_Rel_Err,YieldTotal,YieldTotal_Rel_ErrUp,YieldTotal_Rel_ErrLow,ZinvMCYield,ZinvMCYield_Rel_Err); //printf("%4.3f",ZinvMCYield); //printf("bin %i :%i | %4.3f(%4.3f) | %4.3f(%4.3f) | %4.2f(%4.3f) ",ibin,Nobserved,ZgR,ZgRerr,totalPurity,totalPurityErr,YieldTotal,YieldTotalErr); //printf("bin %i :%i | %4.3f(%4.3f,+%4.3f-%4.3f) | %4.3f(%4.3f) | %4.2f(+%4.3f-%4.3f) ",ibin,Nobserved,ZgR,ZgRuncorel_Rel_Err,ZgRcorel_Rel_Errup,ZgRcorel_Rel_Errlow,totalPurity,totalPurity_Rel_Err,YieldTotal,YieldTotal_Rel_ErrUp,YieldTotal_Rel_ErrLow); cout<<endl; double Percent=(int)round(100*(YieldTotalErr/YieldTotal)); double maxErrorYield=max(YieldErrWithStatUp,YieldErrWithStatLow); ZinvEstimate->SetBinContent(ibin,YieldTotal); ZinvEstimate->SetBinError(ibin,maxErrorYield); /////////////////endcap ends }//loop over bin error calculation ////////////////////////Pred vs Estimated TPaveText *tpa = new TPaveText(0.5056522,0.6247818,0.829097,0.8970332,"brNDC"); tpa->SetBorderSize(0); tpa->SetFillStyle(0); tpa->SetTextAlign(11); tpa->SetTextFont(42); tpa->SetTextSize(0.04); tpa->AddText("HT >500"); tpa->AddText("N_{jets} >=4"); tpa->AddText("MHT>200"); tpa->AddText("Btags=0"); tpa->AddText("#Delta #Phi_{1,2,3,4}>(0.5,0.5,0.3,0.3)"); TPaveText *pCMS = new TPaveText(0.132107,0.9308003,0.8327759,0.9923583,"brNDC"); pCMS->SetBorderSize(0); pCMS->SetFillStyle(0); pCMS->SetTextAlign(11); pCMS->SetTextFont(42); pCMS->SetTextSize(0.04); pCMS->AddText("CMS #it{Preliminary} 1.3 fb^{-1} #sqrt{s}= 13 TeV"); TLegend *legP = new TLegend(0.2173913,0.2478185,0.5167224,0.4363002,NULL,"brNDC"); legP->SetBorderSize(0); legP->SetTextFont(62); legP->SetTextSize(0.03); legP->SetLineColor(1); legP->SetLineStyle(1); legP->SetLineWidth(3); legP->SetFillColor(0); legP->SetFillStyle(1001); cout<<"Est: "<<ZinvEstimate->Integral()<<endl; cout<<"Pred: "<<h_NZinv18binC->Integral()<<endl; //////////////////////////////////ZGammaRatio c_ZgRwSF = new TCanvas("c_ZgRwSF","c_ZgRwSF"); c_ZgRwSF->cd(); gr_ZgRwSFsys = new TGraphAsymmErrors(NumBins,binNumber,ZgRwSF,XErrLow,XErrUp,ZgRwSF_sys_ErrLow,ZgRwSF_sys_ErrUp); gr_ZgRwSFsys->SetTitle("ZgammaRatio"); gr_ZgRwSFsys->SetMarkerColor(4); gr_ZgRwSFsys->SetLineColor(4); gr_ZgRwSFsys->SetMarkerStyle(21); gr_ZgRwSFstat = new TGraphAsymmErrors(NumBins,binNumber,ZgRwSF,XErrLow,XErrUp,ZgRwSF_stat_Err,ZgRwSF_stat_Err); gr_ZgRwSFstat->SetTitle("ZgammaRatio"); gr_ZgRwSFstat->SetMarkerColor(2); gr_ZgRwSFstat->SetLineColor(2); gr_ZgRwSFstat->SetMarkerStyle(21); TLegend *legPZgR = new TLegend(0.2173913,0.7478185,0.5167224,0.8563002,NULL,"brNDC"); legPZgR->SetBorderSize(0); legPZgR->SetTextFont(62); legPZgR->SetTextSize(0.03); legPZgR->SetLineColor(1); legPZgR->SetLineStyle(1); legPZgR->SetLineWidth(3); legPZgR->SetFillColor(0); legPZgR->SetFillStyle(1001); legPZgR->AddEntry(gr_ZgRwSFsys,"Sys Error","l"); legPZgR->AddEntry(gr_ZgRwSFstat,"Stat Error","l"); TMultiGraph *mgZgR=new TMultiGraph(); mgZgR->SetTitle(" ;ith Bin ; Z/#gamma Ratio "); mgZgR->Add(gr_ZgRwSFstat); mgZgR->Add(gr_ZgRwSFsys); mgZgR->Draw("AP"); tpa->Draw(); pCMS->Draw(); legPZgR->Draw(); c_ZgRwSF->SaveAs("ZGammaRatioWSF.png"); c_ZgRwSF->SaveAs("ZGammaRatioWSF.pdf"); c_ZgRwSF->SaveAs("ZGammaRatioWSF.gif"); ///////////////////////////////ZGammaRatio cPredVsEstimated = new TCanvas("estvspred","estvspred"); TPad *pad1 = new TPad("pad1", "pad1", 0, 0.3, 1, 1.0); pad1->SetBottomMargin(0); // Upperand lower plot are joined pad1->Draw(); // Draw the upper pad: pad1 gPad->Update(); pad1->cd(); // pad1 becomes the current pad gPad->DrawFrame(0.5, 0.01, 18.5, 2000, "PredVsEst;ith Bin;Events"); gPad->SetLogy(); gr_estimated = new TGraphAsymmErrors(NumBins,binNumber,YieldEstimated,XErrLow,XErrUp,YieldErrLow_Estimated,YieldErrUp_Estimated); gr_estimated->SetTitle("Estimated"); gr_estimated->SetMarkerColor(4); gr_estimated->SetLineColor(4); gr_estimated->SetMarkerStyle(21); gr_mcPred = new TGraphAsymmErrors(NumBins,binNumber,YieldPredMC,XErrLow,XErrUp,YieldErrLow_PredMC,YieldErrUp_PredMC); gr_mcPred->SetTitle("MC predicted"); gr_mcPred->SetMarkerColor(2); gr_mcPred->SetLineColor(2); gr_mcPred->SetMarkerStyle(8); legP->AddEntry(gr_mcPred,"Zinv MC Pred ","P"); legP->AddEntry(gr_estimated,"Estimated(from #gamma +Jets)","P"); char TMgname1[100]; TMultiGraph *TMg_1D[2]; for(int k0=0;k0<2;k0++){ sprintf(TMgname1,"TMg_1D%i",k0); TMg_1D[k0]=new TMultiGraph(); } for(int j0=0;j0<2;j0++){ TMg_1D[j0]->SetMinimum(0.01); TMg_1D[j0]->SetMaximum(2000); } TMg_1D[0]->SetTitle(" ;ith Bin ; Events "); TMg_1D[0]->Add(gr_mcPred); TMg_1D[0]->Add(gr_estimated); TMg_1D[0]->Draw("AP"); TMg_1D[0]->GetXaxis()->SetLimits(0.5,18.5); tpa->Draw(); pCMS->Draw(); legP->Draw(); TGaxis *axis = new TGaxis( -5, 20, -5, 220, 20,220,510,""); axis->SetLabelFont(43); // Absolute font size in pixel (precision 3) axis->SetLabelSize(15); axis->Draw(); cPredVsEstimated->cd(); TPad *pad2 = new TPad("pad2", "pad2", 0, 0.05, 1, 0.3); pad2->SetTopMargin(0); pad2->SetBottomMargin(0.2); pad2->SetGridy(); // vertical grid pad2->Draw(); pad2->cd(); // pad2 becomes the current pad TH1F *h3 = (TH1F*)h_NZinv18binC->Clone("h3"); h3->SetLineColor(kBlack); h3->SetMinimum(-1); // Define Y .. h3->SetMaximum(3); // .. range h3->Sumw2(); h3->SetStats(0); // No statistics on lower plot h3->Divide(ZinvEstimate); h3->SetMarkerStyle(21); h3->SetMarkerColor(1); h3->Draw("ep"); // Draw the r h3->GetXaxis()->SetTitle("ith Bin"); // Remove the ratio title // Y axis ratio plot settings h3->GetYaxis()->SetTitle("Pred/Est"); h3->GetYaxis()->SetNdivisions(505); h3->GetYaxis()->SetTitleSize(20); h3->GetYaxis()->SetTitleFont(43); h3->GetYaxis()->SetTitleOffset(1.55); h3->GetYaxis()->SetLabelFont(43); // Absolute font size in pixel (precision 3) h3->GetYaxis()->SetLabelSize(15); // X axis ratio plot settings h3->GetXaxis()->SetTitleSize(20); h3->GetXaxis()->SetTitleFont(43); h3->GetXaxis()->SetTitleOffset(3.); h3->GetXaxis()->SetLabelFont(43); // Absolute font size in pixel (precision 3) h3->GetXaxis()->SetLabelSize(15); cPredVsEstimated->SaveAs("PredVsEstimated.png"); cPredVsEstimated->SaveAs("PredVsEstimated.gif"); cPredVsEstimated->SaveAs("ZPredVsEstimated.pdf"); /////////////////////////////Fill the empty bins with simulated data TCanvas *c[20]; int a; double promptfrac=hSieta_GJetsEB->Integral()/(hSieta_GJetsEB->Integral()+hSieta_QCDEB->Integral()); cout<<"prompt fraction: "<<promptfrac<<endl; plot.plotHist(hHT_Data,hHT_GJets,hHT_QCD,c[0],"","Data","MC","HT"); plot.plotHist(hMHT_Data,hMHT_GJets,hMHT_QCD,c[1],"","Data","MC","MHT"); plot.plotHist(hNJets_Data,hNJets_GJets,hNJets_QCD,c[2],"","Data","MC","Njets"); plot.plotHist(hSieta_DataEB,hSieta_GJetsEB,hSieta_QCDEB,c[3],"EB","Data","MC","SigmaIetaIeta_EB"); plot.plotHist(hSieta_DataEBLow,hSieta_GJetsEBLow,hSieta_QCDEBLow,c[4],"Low-MHT-EB","Data","MC","SigmaIetaIeta_EB"); plot.plotHist(hSieta_DataEBMed,hSieta_GJetsEBMed,hSieta_QCDEBMed,c[5],"Med-MHT-EB","Data","MC","SigmaIetaIeta_EB"); plot.plotHist(hSieta_DataEBHigh,hSieta_GJetsEBHigh,hSieta_QCDEBHigh,c[6],"High-MHT-EB","Data","MC","SigmaIetaIeta_EB"); plot.plotHist(hSieta_DataEC,hSieta_GJetsEC,hSieta_QCDEC,c[7],"EE","Data","MC","SigmaIetaIeta_EE"); plot.plotHist(hSieta_DataECLow,hSieta_GJetsECLow,hSieta_QCDECLow,c[8],"Low-MHT-EE","Data","MC","SigmaIetaIeta_EE"); plot.plotHist(hSieta_DataECMed,hSieta_GJetsECMed,hSieta_QCDECMed,c[9],"Med-MHT-EE","Data","MC","SigmaIetaIeta_EE"); plot.plotHist(hSieta_DataECHigh,hSieta_GJetsECHigh,hSieta_QCDECHigh,c[10],"High-MHT-EE","Data","MC","SigmaIetaIeta_EE"); plot.plotHist(hPhPt_DataEB,hPhPt_GJetsEB,hPhPt_QCDEB,c[11],"EB","Data","MC","PhotonPt_EB"); plot.plotHist(hPhPt_DataEC,hPhPt_GJetsEC,hPhPt_QCDEC,c[12],"EE","Data","MC","PhotonPt_EE"); plot.plotHist(h_Ndata18binEB,h_NGJets18binEB,h_NQCD18binEB,c[13],"EB","Data","MC","ith-Bin-EB"); plot.plotHist(h_Ndata18binEC,h_NGJets18binEC,h_NQCD18binEC,c[14],"EE","Data","MC","ith-Bin-EE"); }//main programme
void drawintlen_DBD(char* FILEN) { //char* title = "Material budget for ILD_O1_v05" ; double M_PI = 3.14159265358979312e+00 ; // 180./pi = 57.295779 ; //ntuple variables // float theta, nrvxd, nrsit, nrtpc, nrset, thedeg; // float theta, nlyoke,nlcoil,nlhcal,nlecal,nlset Float_t thedeg,theta,eta,nlset,nlecal,nlhcal,nlcoil,nlyoke ; // stuff for histograms const int nhist = 5; TString htitle[nhist]; htitle[0] = "Ecal (Lcal)"; htitle[1] = "Hcal (LHcal/bcal)"; htitle[2] = "Coil"; htitle[3] = ""; htitle[4] = "dummy"; TString hname[nhist]; hname[0] = "ECAL"; hname[1] = "HCAL"; hname[2] = "SIT"; hname[3] = "VTX"; hname[4] = "dummy"; int nbin = 180; float xmin = -90; float xmax = -0; // int color[nhist] = {9,8,2,38,1}; int color[nhist] = {8,2,38,1,9}; TString option[nhist]; option[0] = "same"; option[1] = "same"; option[2] = ""; option[3] = ""; option[4] = ""; // TLegend *leg = new TLegend (0.25, 0.6, 0.5, 0.85); TLegend *leg = new TLegend (0.25, 0.3, 0.6, 0.55); leg->SetFillStyle(0); // stuff for histograms TH1F* hmat[nhist]; for (int ihist = 0; ihist < nhist; ihist++) { hmat[ihist] = new TH1F(hname[ihist],"",nbin,xmin,xmax); //// ensure proper errors // hmat[ihist]->Sumw2(); hmat[ihist]->SetLineColor(color[ihist]); hmat[ihist]->SetLineWidth(3); hmat[ihist]->SetTitle(";#theta / degrees;Interaction Lengths"); } // read tree TFile* file = new TFile ( FILEN ) ; TTree* tree = (TTree *) file->Get("ntuple"); if (!tree) { cout << "ERROR: Couldn't open tree ntuple on file: "<< FILEN << endl; return 1; } tree->SetBranchAddress("theta", &theta); tree->SetBranchAddress("thedeg",&thedeg); tree->SetBranchAddress("nlset", &nlset); tree->SetBranchAddress("nlecal", &nlecal); tree->SetBranchAddress("nlhcal", &nlhcal); tree->SetBranchAddress("nlcoil", &nlcoil); tree->SetBranchAddress("nlyoke", &nlyoke); int entries = tree->GetEntries(); cout << "tree has " << entries << " entries" << endl; // event loop for (int ievt = 0; ievt < entries; ++ievt) { tree->GetEntry(ievt); //, if (thedeg < 4.41) continue; // ??? hmat[0]->Fill(-thedeg,nlecal); hmat[1]->Fill(-thedeg,nlhcal); hmat[2]->Fill(-thedeg,nlcoil); hmat[3]->Fill(-thedeg,nlyoke); hmat[4]->Fill(-thedeg,1); } // for (int ibin = 0; ibin < nbin+1; ++ibin) { // cout << "Bin " << ibin << " has " << hmat[4]->GetBinContent(ibin) << " entries" << endl; // } c1 = new TCanvas("c1","c1",600,600); hmat[2]->GetYaxis()->SetRangeUser(0.,14.) ; // for (int ihist = 0; ihist < nhist-2; ihist++) { for (int ihist = nhist-3 ; ihist >=0 ; --ihist) { // average double counts hmat[ihist]->Divide( hmat[4] ) ; // draw hmat[ihist]->Draw(option[ihist]); if( ihist == nhist-3 ){ c1->Update() ; TF1 *f1 = new TF1("f1","-x",0,90); hmat[ihist]->GetXaxis()->SetLabelOffset(99); Double_t x_min = c1->GetUxmin(); Double_t x_max = c1->GetUxmax(); Double_t y_min = c1->GetUymin(); //std::cout << "x_min " << x_min << " x_max " << x_max << " y_min " << y_min << std::endl ; TGaxis *axis = new TGaxis( x_min, y_min, x_max, y_min, "f1", 5); axis->SetLabelSize( 0.06 ); axis->SetLabelFont( 42 ); axis->Draw(); } leg->AddEntry(hmat[ihist],htitle[ihist],"L"); } leg->Draw(); std::string pdfFile( std::string( FILEN ) + std::string( ".pdf" ) ) ; c1->Print( pdfFile.c_str() ) ; }