#include // ClassImp(CaloLat); ClassImp(CaloLong); ClassImp(Calo2D); //////////////////////////////////////////////////////////////////////// /** * 1-dimension function describing lateral distribution of the * shower as viewed by calorimeter * (projection of 3d function in one direction) * * xi[0] = x or y coordinate relative to shower axis * parmin[0] = rt * parmin[1] = p * parmin[2] = rc * */ //////////////////////////////////////////////////////////////////////// Double_t cfradx(Double_t *xi, Double_t *parmin) { double fradxmin2,p,rt,rc,es,x,pig,norm,c; x=*xi; pig = acos(-1.); rt=parmin[0]; p=parmin[1]; rc=parmin[2]; norm=parmin[3]; c=parmin[4]; x=x-c; es=1.5; fradxmin2=p*pig*pow(rc,2)/pow((pow(x,2)+pow(rc,2)),es); fradxmin2=fradxmin2+(1-p)*pig*pow(rt,2)/pow((pow(x,2)+pow(rt,2)),es); fradxmin2=norm*fradxmin2/(2*pig); //cout<<"x,fradxmin2 "<< x<<" "<IsORB() ) printf(" WARNING: OrbitalInfo Tree is needed, the plugin could not work properly without it \n"); // OBT = 0; PKT = 0; atime = 0; // debug = false; // }; Calo2D::Calo2D(PamLevel2 *l2p){ // Clear(); // L2 = l2p; // if ( !L2->IsORB() ) printf(" WARNING: OrbitalInfo Tree is needed, the plugin could not work properly without it \n"); // OBT = 0; PKT = 0; atime = 0; // debug = false; // }; void CaloLat::Clear(){ // }; void Calo2D::Clear(){ // }; void CaloLat::Print(){ // Process(); // printf("==================== Calorimeter Lateral Profile =======================\n"); printf(" OBT: %u PKT: %u ATIME: %u \n",OBT,PKT,atime); // printf(" nx [number of X combination]:.. %i\n",nx); // printf(" ny [number of Y combination]:.. %i\n",ny); printf("========================================================================\n"); // }; void Calo2D::Print(){ // Process(); // printf("==================== Calorimeter 2D Profile =======================\n"); printf(" OBT: %u PKT: %u ATIME: %u \n",OBT,PKT,atime); // printf(" nx [number of X combination]:.. %i\n",nx); // printf(" ny [number of Y combination]:.. %i\n",ny); printf("========================================================================\n"); // }; void CaloLat::Draw(){ // Process(); Draw(-1,-1); }; void Calo2D::Draw(){ // Process(); Draw(-1); }; void CaloLat::Draw(Int_t view,Int_t plane){ // Int_t minv = 0; Int_t maxv = 0; Int_t minp = 0; Int_t maxp = 0; // if ( view == -1 ){ minv = 0; maxv = 2; } else { minv = view; maxv = view+1; }; if ( plane == -1 ){ minp = 0; maxp = 22; } else { minp = plane; maxp = plane+1; }; // Process(); // gStyle->SetLabelSize(0.04); gStyle->SetNdivisions(510,"XY"); // for (Int_t v=minv; v(gDirectory->FindObject(hid)); if ( tc ){ // tc->Clear(); } else { tc = new TCanvas(hid,hid); }; // TString thid = Form("hlatv%ip%i",v,p); TH1F *th = dynamic_cast(gDirectory->FindObject(thid)); if ( th ) th->Delete(); // th->Clear(); // th->Reset(); // } else { th = new TH1F(thid,thid,96,-0.5,95.5); // }; tc->cd(); // for (Int_t st=0;st<96;st++){ th->Fill(st,estrip[v][p][st]); }; th->Draw(); tc->Modified(); tc->Update(); }; }; // gStyle->SetLabelSize(0); gStyle->SetNdivisions(1,"XY"); // }; void Calo2D::Draw(Int_t plane){ // Int_t minp = 0; Int_t maxp = 0; // if ( plane == -1 ){ minp = 0; maxp = 23; } else { minp = plane; maxp = plane+1; }; // Process(); // gStyle->SetLabelSize(0.04); gStyle->SetNdivisions(510,"XY"); // for (Int_t p=minp; p(gDirectory->FindObject(hid)); if ( tc ){ // tc->Clear(); } else { tc = new TCanvas(hid,hid); }; // TString thid = Form("h2dp%i",p); TH2F *th = dynamic_cast(gDirectory->FindObject(thid)); if ( th ) th->Delete(); // th->Clear(); // th->Reset(); // } else { Int_t minx = smax[p] - 10; if ( minx < 0 ) minx = 0; Int_t maxx = minx + 20; if ( maxx > 95 ){ maxx = 95; minx = 75; }; Int_t miny = smay[p] - 10; if ( miny < 0 ) miny = 0; Int_t maxy = miny + 20; if ( maxy > 95 ){ maxy = 95; miny = 75; }; th = new TH2F(thid,thid,20,(Float_t)minx-0.5,(Float_t)maxx-0.5,20,(Float_t)miny-0.5,(Float_t)maxy-0.5); // th = new TH2F(thid,thid,96,-0.5,95.5,96,-0.5,95.5); // }; tc->cd(); // for (Int_t stx=minx;stxFill(stx,sty,estrip[p][stx][sty]); }; }; gStyle->SetPalette(1); // tc->SetLogz(); // th->Draw("colbox"); th->Draw("cont4"); tc->Modified(); tc->Update(); }; // gStyle->SetLabelSize(0); gStyle->SetNdivisions(1,"XY"); // }; void CaloLat::Delete(){ Clear(); //delete this; }; void Calo2D::Delete(){ Clear(); //delete this; }; void CaloLat::Process(){ // if ( !L2 ){ printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n"); printf(" ERROR: CaloHough variables not filled \n"); return; }; // Bool_t newentry = false; // if ( L2->IsORB() ){ if ( L2->GetOrbitalInfo()->pkt_num != PKT || L2->GetOrbitalInfo()->OBT != OBT || L2->GetOrbitalInfo()->absTime != atime ){ newentry = true; OBT = L2->GetOrbitalInfo()->OBT; PKT = L2->GetOrbitalInfo()->pkt_num; atime = L2->GetOrbitalInfo()->absTime; }; } else { newentry = true; }; // if ( !newentry ) return; // if ( debug ) printf(" Start processing event at OBT %u PKT %u time %u \n",OBT,PKT,atime); // Clear(); // // let's start // memset(estrip,0, 4224*sizeof(Float_t)); Float_t mip1 = 0.; Int_t view1 = 0; Int_t plane1 = 0; Int_t strip1 = 0; // for (Int_t i=0; iGetCaloLevel1()->istrip ; i++){ mip1 = L2->GetCaloLevel1()->DecodeEstrip(i,view1,plane1,strip1); estrip[view1][plane1][strip1] = mip1; }; // if ( debug ) this->Print(); if ( debug ) printf(" exit \n"); // }; void Calo2D::Process(){ // if ( !L2 ){ printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n"); printf(" ERROR: CaloHough variables not filled \n"); return; }; // Bool_t newentry = false; // if ( L2->IsORB() ){ if ( L2->GetOrbitalInfo()->pkt_num != PKT || L2->GetOrbitalInfo()->OBT != OBT || L2->GetOrbitalInfo()->absTime != atime ){ newentry = true; OBT = L2->GetOrbitalInfo()->OBT; PKT = L2->GetOrbitalInfo()->pkt_num; atime = L2->GetOrbitalInfo()->absTime; }; } else { newentry = true; }; // if ( !newentry ) return; // if ( debug ) printf(" Start processing event at OBT %u PKT %u time %u \n",OBT,PKT,atime); // Clear(); // // let's start // Float_t es[2][22][96]; memset(es,0, 4224*sizeof(Float_t)); memset(estrip,0, 4224*sizeof(Float_t)); Float_t mip1 = 0.; Int_t view1 = 0; Int_t plane1 = 0; Int_t strip1 = 0; // for (Int_t i=0; iGetCaloLevel1()->istrip ; i++){ mip1 = L2->GetCaloLevel1()->DecodeEstrip(i,view1,plane1,strip1); es[view1][plane1][strip1] = mip1; }; // Int_t plane2 = 0; Float_t emax[23]; memset(emax,0,sizeof(Float_t)*23); memset(smax,0,sizeof(Int_t)*23); memset(smay,0,sizeof(Int_t)*23); // // for (Int_t p=0; p < 23 ; p++){ // plane1 = p-1; plane2 = p; // if ( p == 0 ){ plane1 = -1; plane2 = 0; }; if ( p == 22 ){ plane1 = 21; plane2 = -1; }; // for (Int_t s=0; s < 96 ; s++){ // x for (Int_t ss=0; ss < 96 ; ss++){ // y if ( p == 0 ){ estrip[p][s][ss] += es[1][plane2][ss]; if ( (es[1][plane2][ss]) > emax[p] ){ smax[p] = 45; smay[p] = ss; emax[p] = es[1][plane2][ss] ; }; }; if ( p > 0 && p < 22 ){ estrip[p][s][ss] += es[0][plane1][s] + es[1][plane2][ss]; if ( (es[0][plane1][s] + es[1][plane2][ss]) > emax[p] ){ smax[p] = s; smay[p] = ss; emax[p] = es[0][plane1][s] + es[1][plane2][ss] ; }; }; if ( p == 22 ){ estrip[p][s][ss] += es[0][plane1][s]; if ( (es[1][plane2][s]) > emax[p] ){ smax[p] = s; smay[p] = 45; emax[p] = es[1][plane2][s] ; }; }; }; }; // }; // if ( debug ) this->Print(); if ( debug ) printf(" exit \n"); // }; /** * Default constructor */ CaloLong::CaloLong(){ Clear(); }; CaloLong::CaloLong(PamLevel2 *l2p){ // Clear(); // L2 = l2p; // if ( !L2->IsORB() ) printf(" WARNING: OrbitalInfo Tree is needed, the plugin could not work properly without it \n"); // OBT = 0; PKT = 0; atime = 0; // sel = true; cont = false; N = 0; NC = 22; mask18b = -1; // no18x = true; debug = false; // }; void CaloLong::Clear(){ // memset(eplane,0, 2*22*sizeof(Float_t)); // chi2 = 0.; ndf = 0.; E0 = 0.; a = 0.; b = 0.; errE0 = 0.; erra = 0.; errb = 0.; etmax = 0.; asymm = 0.; fitresult = 0; // X0pl = 0.76; // }; void CaloLong::Print(){ // Process(); // printf("==================== Calorimeter Longitudinal Profile =======================\n"); printf(" OBT: %u PKT: %u ATIME: %u \n",OBT,PKT,atime); printf(" fitresult:.. %i\n",fitresult); printf(" chi2 :.. %f\n",chi2); printf(" ndf :.. %f\n",ndf); printf(" nchi2 :.. %f\n",chi2/ndf); printf(" E0 :.. %f\n",E0); printf(" E0/260. :.. %f\n",E0/260.); printf(" a :.. %f\n",a); printf(" b :.. %f\n",b); printf(" errE0 :.. %f\n",errE0); printf(" erra :.. %f\n",erra); printf(" errb :.. %f\n",errb); printf(" asymm :.. %f\n",asymm); printf(" tmax :.. %f\n",((a-1.)/b)); printf(" etmax :.. %f\n",etmax); printf(" X0pl :.. %f\n",X0pl); printf("========================================================================\n"); // }; void CaloLong::SetNoWpreSampler(Int_t n){ // if ( NC+n <= 22 && NC+n >= 0 ){ N = n; } else { printf(" ERROR! Calorimeter is made of 22 W planes\n"); printf(" you are giving N presampler = %i and N calo = %i \n",n,NC); printf(" WARNING: using default values NWpre = 0, NWcalo = 22\n"); NC = 22; N = 0; }; } void CaloLong::SetNoWcalo(Int_t n){ if ( N+n <= 22 && N+n >= 0 ){ NC = n; } else { printf(" ERROR! Calorimeter is made of 22 W planes\n"); printf(" you are giving N W presampler = %i and N W calo = %i \n",N,n); printf(" WARNING: using default values NWpre = 0, NWcalo = 22\n"); NC = 22; N = 0; }; } void CaloLong::SplitInto(Int_t NoWpreSampler, Int_t NoWcalo){ this->SetNoWpreSampler(0); this->SetNoWcalo(0); if ( NoWpreSampler < NoWcalo ){ this->SetNoWpreSampler(NoWpreSampler); this->SetNoWcalo(NoWcalo); } else { this->SetNoWcalo(NoWcalo); this->SetNoWpreSampler(NoWpreSampler); }; } void CaloLong::Process(){ // if ( !L2 ){ printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n"); printf(" ERROR: CaloHough variables not filled \n"); return; }; // Bool_t newentry = false; // if ( L2->IsORB() ){ if ( L2->GetOrbitalInfo()->pkt_num != PKT || L2->GetOrbitalInfo()->OBT != OBT || L2->GetOrbitalInfo()->absTime != atime ){ newentry = true; OBT = L2->GetOrbitalInfo()->OBT; PKT = L2->GetOrbitalInfo()->pkt_num; atime = L2->GetOrbitalInfo()->absTime; }; } else { newentry = true; }; // if ( !newentry ) return; // if ( debug ) printf(" Start processing event at OBT %u PKT %u time %u \n",OBT,PKT,atime); // Clear(); // // let's start // if ( cont ){ for (Int_t i=0; i<22; i++){ if ( i == (18+N) ){ mask18b = 18 + N; break; }; }; }; // if ( sel ){ for (Int_t i=0; i<22; i++){ if ( i == (18-N) ){ mask18b = 18 - N; break; }; }; }; // // if ( mask18b == 18 ) mask18b = -1; // Int_t view = 0; Int_t plane = 0; Int_t strip = 0; Float_t mip = 0.; for (Int_t i=0; i < L2->GetCaloLevel1()->istrip; i++){ mip = L2->GetCaloLevel1()->DecodeEstrip(i,view,plane,strip); eplane[view][plane] += mip; }; // // inclination factor (stolen from Daniele's code) // Float_t ytgx = 0; Float_t ytgy = 0; ytgx = 0.76 * L2->GetCaloLevel2()->tanx[0]; ytgy = 0.76 * L2->GetCaloLevel2()->tany[0]; X0pl = sqrt( pow(0.76,2.) + pow(ytgx,2.) + pow(ytgy,2.) ); // // Find experimental plane of maximum // Int_t pmax = 0; Int_t vmax = 0; Float_t emax = 0.; for (Int_t v=0; v<2; v++){ for (Int_t i=0; i<22; i++){ if ( eplane[v][i] > emax ){ emax = eplane[v][i]; vmax = v; pmax = i; }; }; }; // // // if ( vmax == 0 ) pmax++; etmax = pmax * X0pl; // if ( debug ) this->Print(); if ( debug ) printf(" exit \n"); // }; Double_t ccurve(Double_t *ti,Double_t *par){ // Double_t t = *ti; Double_t cE0 = par[0]; Double_t ca = par[1]; Double_t cb = par[2]; Double_t gammaa = TMath::Gamma(ca); // Double_t value = cE0 * cb * ( pow((cb * t),(ca - 1)) * exp( -cb * t ) ) / gammaa; // return value; // } void CaloLong::Fit(){ this->Fit(false); }; void CaloLong::Fit(Bool_t draw){ // Process(); // // if ( !L2 ){ printf(" ERROR: cannot find PamLevel2 object, use the correct constructor or check your program!\n"); printf(" ERROR: CaloHough variables not filled \n"); return; }; // Bool_t newentry = false; // if ( L2->IsORB() ){ if ( L2->GetOrbitalInfo()->pkt_num != fPKT || L2->GetOrbitalInfo()->OBT != fOBT || L2->GetOrbitalInfo()->absTime != fatime ){ newentry = true; fOBT = L2->GetOrbitalInfo()->OBT; fPKT = L2->GetOrbitalInfo()->pkt_num; fatime = L2->GetOrbitalInfo()->absTime; }; } else { newentry = true; }; // if ( !newentry ) return; // if ( debug ) printf(" Start fitting event at OBT %u PKT %u time %u \n",fOBT,fPKT,fatime); // if ( draw ){ gStyle->SetLabelSize(0.04); gStyle->SetNdivisions(510,"XY"); }; // TString hid = Form("clongfit"); TCanvas *tc = dynamic_cast(gDirectory->FindObject(hid)); // if ( tc ) tc->Delete(); // if ( tc ) tc->Close(); if ( !tc && draw ){ tc = new TCanvas(hid,hid); } else { if ( tc ) tc->cd(); }; // TString thid = Form("hlongfit"); TH1F *th = dynamic_cast(gDirectory->FindObject(thid)); if ( th ) th->Delete(); Float_t xpos = 0.; Float_t enemip = 0.; Float_t xmax = NC * X0pl + 0.2; // th = new TH1F(thid,thid,int(NC*1.5),-0.2,xmax); th = new TH1F(thid,thid,100,-0.2,xmax); // // AGH, BUG! // Int_t mmin = 0; Int_t mmax = 0; if ( cont ){ mmin = N; mmax = NC+N; } else { mmin = 0; mmax = NC; }; // Float_t qtotparz = 0.; for (Int_t st=mmin;st mmin && st < mmax ){ if ( no18x && ( st == 18+1 || st == mask18b+1 )){ enemip = 2. * eplane[1][st]; } else { enemip = eplane[0][st-1] + eplane[1][st]; }; } else { if ( st == mmin ) enemip = 2. * eplane[1][st]; if ( st == mmax ) enemip = 2. * eplane[0][st-1]; }; // qtotparz += enemip; if ( enemip > 0. ){ th->Fill(xpos,enemip); if ( debug ) printf(" Filling: st %i xpos %f energy %f \n",st,xpos,enemip); }; // // for (Int_t v=1; v>=0;v--)// { // // // if ( v == 1 ){ // xpos = (st - N) * X0pl; // } else { // xpos = (st + 1 - N) * X0pl; // }; // // // if ( no18x && st == 18 && v == 0 ){ // // skip plane 18x // } else { // if ( v == 1 && st == mask18b ){ // // emulate plane 18x // } else { // if ( eplane[v][st] > 0. ){ // th->Fill(xpos,eplane[v][st]); // if ( debug ) printf(" Filling: st %i v %i xpos %f energy %f \n",st,v,xpos,eplane[v][st]); // }; // }; // }; // // // }; }; // TF1 *lfit = new TF1("lfit",ccurve,0.,xmax,3); if ( debug ) printf("qtot %f qtotparz %f \n",L2->GetCaloLevel2()->qtot,qtotparz); E0 = qtotparz; // E0 = L2->GetCaloLevel2()->qtot; a = 5.; b = 0.5; if ( debug ) printf(" STARTING PARAMETERS: E0 %f a %f b %f \n",E0,a,b); lfit->SetParameters(E0,a,b); // lfit->SetParLimits(0,0.,1000.); // lfit->SetParLimits(1,-1.,80.); // lfit->SetParLimits(2,-1.,10.); TString optio; if ( debug ){ // optio = "MERBOV"; // optio = "MEROV"; // optio = "EROV"; optio = "RNOV"; if ( draw ) optio = "ROV"; } else { // optio = "MERNOQ"; // optio = "ERNOQ"; optio = "RNOQ"; if ( draw ) optio = "ROQ"; }; // if ( debug ) printf(" OK, start the fitting procedure...\n"); // fitresult = th->Fit("lfit",optio); // if ( debug ) printf(" the fit is done! result: %i \n",fitresult); // E0 = lfit->GetParameter(0); a = lfit->GetParameter(1); b = lfit->GetParameter(2); errE0 = lfit->GetParError(0); erra = lfit->GetParError(1); errb = lfit->GetParError(2); chi2 = lfit->GetChisquare(); ndf = lfit->GetNDF(); Float_t tmax = 0.; if ( debug ) printf(" Parameters are retrieved \n"); if ( b != 0 ) tmax = (a - 1.)/b; // if ( fitresult != 0 ){ if ( debug ) printf(" The fit failed, no integrals calculation and asymm is set to -1. \n"); asymm = -1.; } else { Int_t npp = 1000; double *xp=new double[npp]; double *wp=new double[npp]; lfit->CalcGaussLegendreSamplingPoints(npp,xp,wp,1e-12); Float_t imax = lfit->IntegralFast(npp,xp,wp,0.,tmax); // Float_t imax = lfit->Integral(0.,tmax); if ( debug ) printf(" Integral till maximum (%f): %f \n",tmax,imax); Int_t np = 1000; double *x=new double[np]; double *w=new double[np]; lfit->CalcGaussLegendreSamplingPoints(np,x,w,1e-12); Float_t i10max = lfit->IntegralFast(np,x,w,0.,10.*tmax); delete x; delete w; delete xp; delete wp; // Float_t i10max = lfit->Integral(0.,10.*tmax); if ( debug ) printf(" Integral: %f \n",i10max); // if ( i10max != imax ){ asymm = imax / (i10max-imax); } else { if ( debug ) printf(" i10max == imax, asymm undefined\n"); asymm = -2.; }; if ( asymm != asymm ){ if ( debug ) printf(" asymm is nan \n"); asymm = -3.; }; //lfit->Integral(0.,tmax)/(lfit->Integral(0.,10.*tmax)-lfit->Integral(0.,tmax)); if ( debug ) printf(" Asymmetry has been calculated \n"); }; // if ( asymm < 0. || ndf <= 0. || chi2 < 0. || tmax < 0. ){ if ( debug ) printf(" Funny asymm||ndf||chi2||tmax values, fit failed \n"); fitresult = 100; }; // if ( draw ){ // tc->cd(); // gStyle->SetOptStat(11111); tc->SetTitle(); th->SetTitle(""); th->SetName(""); th->SetMarkerStyle(20); // axis titles th->SetXTitle("Depth [X0]"); th->SetYTitle("Energy [MIP]"); th->DrawCopy("Perror"); lfit->Draw("same"); tc->Modified(); tc->Update(); // gStyle->SetLabelSize(0); gStyle->SetNdivisions(1,"XY"); // } else { if ( th ) th->Delete(); }; // delete lfit; // }; void CaloLong::Draw(){ // Process(); Draw(-1); }; void CaloLong::Draw(Int_t view){ // Int_t minv = 0; Int_t maxv = 0; // if ( view == -1 ){ maxv = -1; } else { minv = view; maxv = view+1; }; // Process(); // gStyle->SetLabelSize(0.04); gStyle->SetNdivisions(510,"XY"); // if ( maxv != -1 ){ for (Int_t v=minv; v(gDirectory->FindObject(hid)); if ( tc ){ // tc->Clear(); } else { tc = new TCanvas(hid,hid); }; // TString thid = Form("hlongv%i",v); TH1F *th = dynamic_cast(gDirectory->FindObject(thid)); if ( th ) th->Delete(); // th->Clear(); // th->Reset(); // } else { th = new TH1F(thid,thid,22,-0.5,21.5); // }; tc->cd(); // for (Int_t st=0;st<22;st++){ th->Fill(st,eplane[v][st]); }; th->Draw(); tc->Modified(); tc->Update(); }; } else { // TString hid = Form("clongvyvx"); TCanvas *tc = dynamic_cast(gDirectory->FindObject(hid)); if ( tc ){ } else { tc = new TCanvas(hid,hid); }; // TString thid = Form("hlongvyvx"); TH1F *th = dynamic_cast(gDirectory->FindObject(thid)); if ( th ) th->Delete(); th = new TH1F(thid,thid,44,-0.5,43.5); tc->cd(); Int_t pp=0; for (Int_t st=0;st<22;st++){ for (Int_t v=1; v>=0;v--){ // th->Fill(pp,eplane[v][st]); // pp++; }; }; th->Draw(); tc->Modified(); tc->Update(); }; // gStyle->SetLabelSize(0); gStyle->SetNdivisions(1,"XY"); // }; void CaloLong::Delete(){ Clear(); //delete this; };