- Timestamp:
- 02/15/05 15:36:45 (20 years ago)
- Location:
- trunk/MagicSoft/Mars/mtemp/mifae
- Files:
-
- 4 edited
Legend:
- Unmodified
- Added
- Removed
-
trunk/MagicSoft/Mars/mtemp/mifae/Changelog
r6465 r6486 19 19 -*-*- END OF LINE -*-*- 20 20 21 2005/02/10 Javier Rico 21 2005/02/15 Javier Rico 22 * library/MEffAreaAndCoeffCalc.[h,cc] 23 * macros/computeCoeff.C 24 - extend the energy bounds to compute weights 25 - add possibility to set the zenith angle binning from outside 26 27 2005/02/14 Javier Rico 22 28 * library/MEffAreaAndCoeffCalc.[h,cc] 23 29 * macros/computeCoeff.C -
trunk/MagicSoft/Mars/mtemp/mifae/library/MEffAreaAndCoeffCalc.cc
r6465 r6486 47 47 using namespace std; 48 48 49 const Int_t fNTbins = 2; 50 const Double_t fTbin[fNTbins+1] = {0,10,20}; 51 49 const Int_t ntbins=1; // default number of theta bins 50 const Double_t tbin[ntbins+1] = {0,90}; // default theta bins bounds 51 const Int_t nebins = 10; // default number of energy bins 52 const Float_t emin = 10.; // default minimum energy value 53 const Float_t emax = 10000.; // default maximum energy value 54 const Int_t nsubbins = 20; // default number of subbins per bin 55 const Char_t* deff = "4.e9*pow(x,-2.6+1)"; // default spectrum function 52 56 53 57 // ------------------------------------------------------------------------- … … 56 60 // 57 61 MEffAreaAndCoeffCalc::MEffAreaAndCoeffCalc() 58 : fSpec(NULL), fHorig(NULL), fEmin(10.), fEmax(10000.), fEbins(10), fEsubbins(20),59 f Coeff(NULL), fEffA(NULL), fFile(NULL)62 : fSpec(NULL), fEmin(emin), fEmax(emax), fEbins(nebins), fEsubbins(nsubbins), 63 fWeight(NULL), fCoeff(NULL), fEffA(NULL)//, fFile(NULL) 60 64 { 61 65 // set the default function 62 SetFunction( "4.e9*pow(x,-2.6+1)");66 SetFunction(deff); 63 67 64 68 // create the TChains 65 // OJO!! make sure they read the appropriate branch66 69 fCini = new TChain("OriginalMC"); 67 70 fCcut = new TChain("Events"); … … 76 79 fCcut->SetBranchAddress("MHillas.",&fHillas); 77 80 fCcut->SetBranchAddress("MMcEvt.",&fMcEvt); 81 82 // initial value of the zenith angle binning 83 SetThetaBinning(ntbins,tbin); 78 84 79 85 // borra 80 fFile = new TFile("test.root","RECREATE");86 // fFile = new TFile("coeftest.root","RECREATE"); 81 87 } 82 88 … … 90 96 delete fSpec; 91 97 98 if(fTbin) 99 delete [] fTbin; 100 92 101 if(fWeight) 93 102 delete [] fWeight; … … 99 108 delete fEffA; 100 109 101 if(fHorig)102 delete fHorig;103 110 104 111 delete fCini; 105 112 delete fCcut; 113 } 114 115 // ------------------------------------------------------------------------- 116 // 117 // Set the binning in zenith angle 118 // 119 void MEffAreaAndCoeffCalc::SetThetaBinning(Int_t n, const Double_t* binlist) 120 { 121 fNTbins=n; 122 if(fTbin) delete [] fTbin; 123 fTbin = new Double_t[n+1]; 124 for(Int_t i=0;i<n+1;i++) 125 fTbin[i] = binlist[i]; 106 126 } 107 127 … … 144 164 void MEffAreaAndCoeffCalc::FillOriginalSpectrum() 145 165 { 146 const Double_t logemin = TMath::Log10(fEmin);147 const Double_t logemax = TMath::Log10(fEmax);148 const Int_t esbins = fEbins*fEsubbins; // total number of subbins149 150 if(fHorig) delete fHorig;151 fHorig = new TH1F("fhorig","Original energy spectrum",esbins,logemin,logemax);152 fCini->Draw("logenergy>>fhorig","","goff");153 // borra154 fHorig->Write();155 166 } 156 167 … … 161 172 void MEffAreaAndCoeffCalc::ComputeWeights() 162 173 { 163 const Double_t logemin = TMath::Log10(fEmin); 164 const Double_t logemax = TMath::Log10(fEmax); 165 const Double_t de = (logemax-logemin)/fEbins; // bin size (in log) 166 const Double_t desub = de/fEsubbins; // subbin size (in log) 167 const Int_t esbins = fEbins*fEsubbins; // total number of subbins 168 174 // OJO!! maybe this should be hard-coded somewhere else 175 const Float_t abslogmin=0.; 176 const Float_t abslogmax=5.; 177 178 const Float_t logemin = TMath::Log10(fEmin); 179 const Float_t logemax = TMath::Log10(fEmax); 180 const Float_t de = (logemax-logemin)/fEbins; // bin size (in log) 181 const Float_t desub = de/fEsubbins; // subbin size (in log) 182 const Int_t esbins = fEbins*fEsubbins; // total number of subbins 183 184 // compute the binning for weights histogram 185 const Int_t nmindist = (logemin>abslogmin)? Int_t((logemin-abslogmin)/desub) : 0; 186 const Int_t nmaxdist = (logemax<abslogmax)? Int_t((abslogmax-logemax)/desub) : 0; 187 188 fLogEWmin = logemin-desub*nmindist; 189 fLogEWmax = logemax+desub*nmaxdist; 190 fEWbins = nmindist+esbins+nmaxdist; 191 169 192 // reset the weights array 170 193 if(fWeight) 171 194 delete [] fWeight; 172 fWeight = new Double_t[ esbins];195 fWeight = new Double_t[fEWbins]; 173 196 174 if(!fHorig) 175 FillOriginalSpectrum(); 176 177 // borra 178 TH1F hw("hw","hw",esbins,fEmin,fEmax); 179 for(Int_t i=0;i<esbins;i++) 180 { 181 const Double_t denom = fHorig->GetBinContent(i+1); // number of events in initial spectrum 182 const Double_t ew = TMath::Power(10,logemin+(i+0.5)*desub); // real energy 183 const Double_t numer = fSpec->Eval(ew); // number of events for the required spectrum 184 if(denom) 197 198 TH1F* horigs = new TH1F("horigs","Original energy spectrum",fEWbins,fLogEWmin,fLogEWmax); 199 fCini->Draw("logenergy>>horigs","","goff"); 200 // borra 201 // horigs->Write(); 202 203 // borra 204 // TH1F hw("hw","hw",fEWbins,fLogEWmin,fLogEWmax); 205 for(Int_t i=0;i<fEWbins;i++) 206 { 207 const Float_t denom = horigs->GetBinContent(i+1); // number of events in initial spectrum 208 const Float_t ew = TMath::Power(10,fLogEWmin+(i+0.5)*desub); // real energy 209 const Float_t numer = fSpec->Eval(ew); // number of events for the required spectrum 210 if(denom>10) 185 211 fWeight[i]=numer/denom; 186 212 else 187 213 { 188 cout << "MEffAreaAndCoeffCalc::ComputeWeights Warning: no statistic to compute weight for energy " << ew << ", setting it to -1 " << endl;214 // cout << "MEffAreaAndCoeffCalc::ComputeWeights Warning: no statistic to compute weight for energy " << ew << ", setting it to -1 " << endl; 189 215 fWeight[i]=-1; 190 216 } 191 217 // borra 192 hw.SetBinContent(i+1,fWeight[i]); 193 } 194 // borra 195 hw.Write(); 218 // hw.SetBinContent(i+1,fWeight[i]); 219 } 220 // borra 221 // hw.Write(); 222 223 delete horigs; 196 224 } 197 225 … … 208 236 } 209 237 210 const Double_t logemin = TMath::Log10(fEmin); 211 const Double_t logemax = TMath::Log10(fEmax); 212 const Double_t de = (logemax-logemin)/fEbins; // bin size (in log) 213 const Double_t desub = de/fEsubbins; // subbin size (in log) 214 const Int_t esbins = fEbins*fEsubbins; // total number of subbins 238 const Float_t logemin = TMath::Log10(fEmin); 239 const Float_t logemax = TMath::Log10(fEmax); 240 const Float_t de = (logemax-logemin)/fEbins; // bin size (in log) 241 const Float_t desub = de/fEsubbins; // subbin size (in log) 215 242 const Int_t nentries = Int_t(fCcut->GetEntries()); 216 243 … … 220 247 221 248 // borra 222 TH1F* hest1 = new TH1F("hest1","Estimated energy",fEbins,logemin,logemax);223 TH1F* hmc1 = new TH1F("hmc1","MC energy",fEbins,logemin,logemax);224 TH1F* coef1 = new TH1F("coef1","coefficients",fEbins,logemin,logemax);249 // TH1F* hest1 = new TH1F("hest1","Estimated energy",fEbins,logemin,logemax); 250 // TH1F* hmc1 = new TH1F("hmc1","MC energy",fEbins,logemin,logemax); 251 // TH1F* coef1 = new TH1F("coef1","coefficients",fEbins,logemin,logemax); 225 252 226 253 // reset the coefficients … … 238 265 Float_t emc = fMcEvt->GetEnergy(); 239 266 Float_t estim = fHillas->GetSize()/0.18/15.; 267 268 if((emc<fEmin && estim<fEmin) || (emc>fEmax && estim>fEmax) || 269 (emc<fEmin && estim>fEmax) || (emc>fEmax && estim<fEmin)) 270 continue; 271 240 272 Float_t theta = fMcEvt->GetTheta()*180./3.14159; // zenith angle (in degrees) 241 273 242 274 // compute the bin where the weight is taken from 243 Int_t wbin = Int_t((TMath::Log10(emc)- logemin)/desub);275 Int_t wbin = Int_t((TMath::Log10(emc)-fLogEWmin)/desub); 244 276 245 277 // fill the histograms 246 if(wbin< esbins)278 if(wbin<fEWbins) 247 279 { 248 hest->Fill(TMath::Log10(estim),theta,fWeight[wbin]); 249 hmc->Fill(TMath::Log10(emc),theta,fWeight[wbin]); 250 // borra 251 if(theta<fTbin[1]) 280 if(fWeight[wbin]>0) 252 281 { 253 hest1->Fill(TMath::Log10(estim),fWeight[wbin]); 254 hmc1->Fill(TMath::Log10(emc),fWeight[wbin]); 282 hest->Fill(TMath::Log10(estim),theta,fWeight[wbin]); 283 hmc->Fill(TMath::Log10(emc),theta,fWeight[wbin]); 284 // borra 285 // if(theta<fTbin[1]) 286 // { 287 // hest1->Fill(TMath::Log10(estim),fWeight[wbin]); 288 // hmc1->Fill(TMath::Log10(emc),fWeight[wbin]); 289 // } 255 290 } 291 else 292 cout << "MEffAreaAndCoeffCalc::ComputeCoefficients Warning: event " << i << " with energy " << emc << " has no computed weight (lack of MC statistics), skipping" << endl; 256 293 } 257 294 else 258 cout << "MEffAreaAndCoeffCalc::ComputeCoefficients Warning: event " << i << " with energy " << emc << " has energy out of bounds, skipping" << endl;295 cout << "MEffAreaAndCoeffCalc::ComputeCoefficients Warning: event " << i << " with energy " << emc << " has energy out of bounds, skipping" << endl; 259 296 } 260 297 … … 266 303 const Float_t den = hest->GetBinContent(i+1,j+1); 267 304 //borra 268 const Float_t num1 = hmc1->GetBinContent(i+1);269 const Float_t den1 = hest1->GetBinContent(i+1);305 // const Float_t num1 = hmc1->GetBinContent(i+1); 306 // const Float_t den1 = hest1->GetBinContent(i+1); 270 307 if(den) 271 308 { 272 309 fCoeff->SetBinContent(i+1,j+1,num/den); 273 310 //borra 274 if(j==0 && den1)275 coef1->SetBinContent(i+1,num1/den1);311 // if(j==0 && den1) 312 // coef1->SetBinContent(i+1,num1/den1); 276 313 } 277 314 else … … 284 321 285 322 //borra 286 hmc1->Write();287 hest1->Write();288 coef1->Write();323 // hmc1->Write(); 324 // hest1->Write(); 325 // coef1->Write(); 289 326 290 327 delete hmc; … … 305 342 306 343 //OJO!! radius should be read from somewhere! 307 const Double_t radius = 30000.; // generation radius (in cm) 308 // const Double_t Atot = 3.14159*radius*radius; //total area (in cm^2) 309 const Double_t Atot = 1.; //total area (in cm^2) 310 const Double_t logemin = TMath::Log10(fEmin); 311 const Double_t logemax = TMath::Log10(fEmax); 344 const Float_t radius = 30000.; // generation radius (in cm) 345 const Float_t Atot = 3.14159*radius*radius; //total area (in cm^2) 346 const Float_t logemin = TMath::Log10(fEmin); 347 const Float_t logemax = TMath::Log10(fEmax); 312 348 const Int_t esbins = fEbins*fEsubbins; // total number of subbins 313 const Double_t de = (logemax-logemin)/fEbins; // bin size (in log)314 const Double_t desub = de/fEsubbins; // subbin size (in log)349 const Float_t de = (logemax-logemin)/fEbins; // bin size (in log) 350 const Float_t desub = de/fEsubbins; // subbin size (in log) 315 351 316 352 // reset the effective areas … … 319 355 fEffA = new TH2F("feffa","Effective area",fEbins,logemin,logemax,fNTbins,fTbin); 320 356 //borra 321 TH1F eff("eff","Effective area",fEbins,logemin,logemax);357 // TH1F eff("eff","Effective area",fEbins,logemin,logemax); 322 358 323 359 // fill the spectrum of the survivors … … 343 379 else 344 380 { 345 const Double_t ew = TMath::Power(10,logemin+(i*fEsubbins+k+0.5)*desub);346 const Double_t ww = fSpec->Eval(ew);381 const Float_t ew = TMath::Power(10,logemin+(i*fEsubbins+k+0.5)*desub); 382 const Float_t ww = fSpec->Eval(ew); 347 383 effarea+=Atot*numerator/denominator*ww; 348 384 wtot += ww; … … 357 393 { 358 394 fEffA->SetBinContent(i+1,j+1,effarea/wtot); 359 if(j==0) 360 { 361 cout << "*****" << i << ": " << effarea/wtot << endl; 362 eff.SetBinContent(i+1,effarea/wtot); 363 } 395 // borra 396 // if(j==0) 397 // { 398 // // cout << "*****" << i << ": " << effarea/wtot << endl; 399 // eff.SetBinContent(i+1,effarea/wtot); 400 // } 364 401 } 365 402 } 366 403 367 404 // borra 368 eff.Write();405 // eff.Write(); 369 406 370 407 delete hpass; -
trunk/MagicSoft/Mars/mtemp/mifae/library/MEffAreaAndCoeffCalc.h
r6465 r6486 19 19 20 20 TF1* fSpec; // function used to parametrize the spectrum 21 TH1F* fHorig; // histogram with the original sample energy spectrum22 21 23 Double_t fEmin; // Minimum energy in GeV24 Double_t fEmax; // Maximum energy in GeV22 Float_t fEmin; // Minimum energy in GeV 23 Float_t fEmax; // Maximum energy in GeV 25 24 Int_t fEbins; // number of bins to build spectrum 26 25 Int_t fEsubbins; // number of subbins per big bin (to compute weights, eff areas...) 26 27 Float_t fLogEWmin; // Log Minimum energy for weights (in GeV) 28 Float_t fLogEWmax; // Log Maximum energy for weights (in GeV) 29 Int_t fEWbins; // Number of bins for weights 30 31 Int_t fNTbins; // Number of bins in zenith angle 32 Double_t* fTbin; // array containing bin boundaries (size must be fNTbins+) 27 33 28 34 Double_t* fWeight; // array containing weights … … 58 64 void SetEmax(Float_t x) {fEmax=x;} 59 65 66 void SetThetaBinning(Int_t n, const Double_t* binlist); 67 60 68 void AddFile(const Char_t* name) {fCini->Add(name); fCcut->Add(name);} 61 69 -
trunk/MagicSoft/Mars/mtemp/mifae/macros/computeCoeff.C
r6465 r6486 10 10 /* now it's just a cross check with the same MC */ 11 11 /************************************************/ 12 const Int_t ebins = 10; // number of bins to build spectrum12 const Int_t ebins = 20; // number of bins to build spectrum 13 13 const Double_t emin=10; 14 const Double_t emax= 600;15 const Double_t logemin = TMath::Log10(emin);16 const Double_t logemax = TMath::Log10(emax);14 const Double_t emax=200; 15 const Int_t tbins = 2; 16 const Double_t thetab[tbins+1] = {0,10,20}; 17 17 calc.SetEbins(ebins); 18 // calc.SetEsubbins(1); 19 18 calc.SetEmin(emin); 19 calc.SetEmax(emax); 20 calc.SetThetaBinning(tbins,thetab); 21 20 22 // define the funtion of the desired spectrum 21 calc.SetFunction("4.e9*pow(x,-2.6+1)" ,emin,emax);23 calc.SetFunction("4.e9*pow(x,-2.6+1)"); 22 24 calc.ComputeAllFactors(); 23 25 … … 31 33 ccut->SetAlias("theta","MMcEvt.fTelescopeTheta*180./3.14159"); 32 34 35 36 const Double_t logemin = TMath::Log10(emin); 37 const Double_t logemax = TMath::Log10(emax); 33 38 TH1D* hspec = new TH1D("hspec","Spectrum",ebins,logemin,logemax); 34 39 hspec->Sumw2(); … … 42 47 Float_t corrval; 43 48 if(effa) 44 corrval = uncorrval*unfold/effa ;49 corrval = uncorrval*unfold/effa*1e9; 45 50 else 46 51 corrval = 0;
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