#include "MStarLight.hxx" using namespace std; MStarLight::MStarLight(Float_t fadc_slices_per_ns, Int_t response_slices_fadc) { // // default constructor // fBrightness = 0.; fTimeRange = TIMERANGE; fFadcSlicesPerNanosec = fadc_slices_per_ns; // "real" number of FADC slices per ns fResponseSlicesFadc = response_slices_fadc; // total number of bins in the histogram containing the response of the FADC to a // single photoelectron. The bins are narrower than the true FADC slices by a factor // equal to SUBBINS (see MFadcDefine.h) fBinsTrig = (Int_t)(TRIG_SLICES_PER_NSEC*TIMERANGE); // Default value 4*10000=40000 fTrigShape = 0; fAmplTrig = 0.; fFwhmTrig = 0.; fBinsFadc = (Int_t)(fFadcSlicesPerNanosec*TIMERANGE); // Default value 0.3*10000=3000 fFadcShape = 0; fIntegFadc = 0.; fFwhmFadc = 0.; fTrig = new Float_t[fBinsTrig]; fTrigResp = new Float_t[RESPONSE_SLICES_TRIG]; fFadc = new Float_t[fBinsFadc]; fFadcResp = new Float_t[fResponseSlicesFadc]; for (Int_t i= 0; i< fBinsTrig ; i++) fTrig[i] = 0. ; for (Int_t i= 0; i < fBinsFadc; i++) fFadc[i] = 0.; for (Int_t i = 0; i < RESPONSE_SLICES_TRIG; i++) fTrigResp[i] = 0.; for (Int_t i = 0; i < fResponseSlicesFadc; i++) fFadcResp[i] = 0.; } void MStarLight::Reset() { fBrightness = 0. ; fTimeRange = TIMERANGE; fTrigShape = 0; fAmplTrig = 0.; fFwhmTrig = 0.; fFadcShape = 0; fIntegFadc = 0.; fFwhmFadc = 0.; for (Int_t i= 0; i < fBinsTrig ; i++) fTrig[i] = 0.; for (Int_t i= 0; i < fBinsFadc; i++) fFadc[i] = 0.; for (Int_t i = 0; i < RESPONSE_SLICES_TRIG; i++) fTrigResp[i] = 0.; for (Int_t i = 0; i < fResponseSlicesFadc; i++) fFadcResp[i] = 0.; } Float_t MStarLight::GetBrightness () { return fBrightness; } void MStarLight::SetBrightness (Float_t in ) { fBrightness = in; } Float_t MStarLight::GetAmplTrig () { return fAmplTrig ; } void MStarLight::SetAmplTrig (Float_t in ) { fAmplTrig = in; } Float_t MStarLight::GetFwhmTrig () { return fFwhmTrig; } void MStarLight::SetFwhmTrig (Float_t in ) { fFwhmTrig = in; } void MStarLight::SetFadcSlicesPerNanosec (Float_t in) { fFadcSlicesPerNanosec = in; fBinsFadc = (Int_t)(fFadcSlicesPerNanosec*TIMERANGE); if (fFadc) delete [] fFadc; fFadc = new Float_t[fBinsFadc]; for (Int_t i= 0; i < fBinsFadc; i++) fFadc[i] = 0.; } Float_t MStarLight::GetIntegFadc () { return fIntegFadc; } void MStarLight::SetIntegFadc (Float_t in ) { fIntegFadc = in; } Float_t MStarLight::GetFwhmFadc () { return fFwhmFadc; } void MStarLight::SetFwhmFadc (Float_t in ) { fFwhmFadc = in; } void MStarLight::SetTrigResponse( Float_t *in ) { for (Int_t i = 0; i < RESPONSE_SLICES_TRIG; i++) fTrigResp[i] = in[i]; } void MStarLight::SetFadcResponse( Float_t *in ) { for (Int_t i = 0; i < fResponseSlicesFadc; i++) fFadcResp[i] = in[i]; } void MStarLight::FillResponse( Float_t ampl, Float_t time ) { // fill the trigger response Int_t startbin = (Int_t) (time * ((Float_t)fBinsTrig/TIMERANGE)); Int_t icount = 0; Int_t idata; for ( Int_t i = startbin ; i < startbin+RESPONSE_SLICES_TRIG ; i++) { if ( i < fBinsTrig ) idata = i; else if ( i >= fBinsTrig ) idata = i - fBinsTrig; fTrig[idata] = fTrig[idata] + ampl * fTrigResp[icount]; icount++ ; } // // fill the FADC content // startbin = (Int_t) ( time * ((Float_t)(fBinsFadc*SUBBINS)/TIMERANGE)); Int_t ichanfadc = 0 ; // // putting the response slices in the right sig slices. // Be careful, because both slices have different widths. // // // Changed, Jan 2004, A. Moralejo: now the FADC does not integrate all // the signal within each FADC slice, but measures just the signal height // at one point, like the real FADC does. By default, each FADC slice // contains SUBBINS bins of the response histogram // (fFadcResp). Warning: do not change this unless you do the corresponding // modifications also in MFadc.cxx, or the signal and the noise photoelectrons // will be treated differently!! // for ( Int_t i = 0 ; i < fResponseSlicesFadc; i += SUBBINS ) { ichanfadc = (Int_t) ((startbin+i)/(Float_t)SUBBINS); if ( ichanfadc < fBinsFadc ) idata = ichanfadc; else if ( ichanfadc >= fBinsFadc ) idata = ichanfadc-fBinsFadc; fFadc[idata] += (ampl * fFadcResp[i]); } } void MStarLight::ElecNoise ( Float_t noiseTrig, Float_t noiseFadc ) { // // putting some noise to the baseline // TRandom2 wuerfel( (UInt_t) (noiseTrig*100) ) ; for (Int_t i=0; i< fBinsTrig ; i++ ) fTrig[i] += wuerfel.Gaus(0., noiseTrig ); for (Int_t i=0; i< fBinsFadc ; i++ ) fFadc[i] += wuerfel.Gaus(0., noiseFadc ); } Float_t MStarLight::GetTrig( Int_t i) { //------------------------------------------------------------------ // // It gets the value of the simulated trigger in the i bin // return fTrig[i]; } Float_t MStarLight::GetFadc( Int_t i) { //------------------------------------------------------------------ // // It gets the value of the simulated FADC signal in the i bin // return fFadc[i]; } void MStarLight::StoreHisto( char *filename) { Float_t baseline = 0.; // first the histograms for trigger // // the calculated trigger signal before baseline // TH1F trigresp ("trigresp", "Trigger Response", fBinsTrig, 0., TIMERANGE); for (Int_t i=0; i< fBinsTrig ; i++ ) { trigresp.SetBinContent(i+1, fTrig[i]); baseline += fTrig[i]; } baseline /= fBinsTrig; TH1F trigbase ("trigbase", "Response after Baseline shift", fBinsTrig, 0., TIMERANGE) ; for (Int_t i = 0; i < fBinsTrig ; i++) trigbase.SetBinContent(i+1, fTrig[i]-baseline ); TH1F trigdist ("trigdist", "Noise on the baseline", 1000, -25., 25. ); for (Int_t i = 0; i < fBinsTrig ; i++) trigdist.Fill( (Float_t) trigbase.GetBinContent(i+1) ); // // Now the histograms for the fadc // TH1F fadcresp ("fadcresp", "Fadc Response", fBinsFadc, 0., TIMERANGE); baseline = 0.; for (Int_t i=0; i < fBinsFadc; i++) { fadcresp.SetBinContent(i+1, fFadc[i]); baseline += fFadc[i]; } baseline /= fBinsFadc; TH1F fadcbase ("fadcbase", "Fadc after Baseline shift", fBinsFadc, 0., TIMERANGE) ; for (Int_t i=0; i< fBinsFadc ; i++ ) fadcbase.SetBinContent(i+1, fFadc[i]-baseline ); TH1F fadcdist ("fadcdist", "Noise on fadc", 1000, -100., 100. ) ; for (Int_t i=0; i< fBinsFadc ; i++ ) fadcdist.Fill( (Float_t) fadcbase.GetBinContent(i+1) ); TFile outfile( filename, "RECREATE"); trigresp.Write(); trigbase.Write(); trigdist.Write(); fadcresp.Write(); fadcbase.Write(); fadcdist.Write(); outfile.Close(); } void MStarLight::WriteBinary( char *filename) { // // write the information to the binary file FILE *datei ; datei = fopen ( filename, "w" ) ; if ( ! datei ) { cout << " ERROR: Can't open the file " << filename << endl; exit (230); } Float_t version = VERSIONSR; // write them out fwrite ( &version, sizeof(Float_t), 1, datei ); fwrite ( &fBrightness, sizeof(Float_t), 1, datei ); fwrite ( &fTimeRange, sizeof(Float_t), 1, datei ); fwrite ( &fFadcSlicesPerNanosec, sizeof(Float_t), 1, datei ); fwrite ( &fBinsTrig , sizeof(Int_t), 1, datei ); fwrite ( &fTrigShape , sizeof(Int_t), 1, datei ); fwrite ( &fAmplTrig , sizeof(Float_t), 1, datei ); fwrite ( &fFwhmTrig , sizeof(Float_t), 1, datei ); fwrite ( &fBinsFadc , sizeof(Int_t), 1, datei ); fwrite ( &fFadcShape , sizeof(Int_t), 1, datei ); fwrite ( &fIntegFadc , sizeof(Float_t), 1, datei ); fwrite ( &fFwhmFadc , sizeof(Float_t), 1, datei ); fwrite (fTrig, sizeof(Float_t), fBinsTrig, datei); // We want to store the FADC signal taking into account the AC // coupling // // We calculate and substract the baseline // Float_t baseline = 0.; for (Int_t i=0; i< fBinsFadc ; i++ ) baseline += fFadc[i]; baseline /= fBinsFadc; Float_t *temp = new Float_t[fBinsFadc]; for (Int_t i=0; i < fBinsFadc; i++ ) temp[i] = fFadc[i]-baseline; fwrite (temp, sizeof(Float_t), fBinsFadc, datei); delete [] temp; fclose ( datei ); } void MStarLight::ReadBinary( char *filename) { // // read the things from the binary file FILE *datei ; datei = fopen ( filename, "r" ) ; if ( ! datei ) { cout << " ERROR: Can't open the file " << filename << endl ; cout<< " The database for the NSB may be too small. " << endl; cout<< " See the How to Use of the Camera simulation for more information" << endl; exit (230) ; } Float_t read_version; Float_t current_version = VERSIONSR; // Check that we read the right version of the Database fread ( &read_version, sizeof(Float_t), 1, datei ) ; if(Int_t(read_version)!=Int_t(current_version)){ cout<<" ERROR: You are trying to read database VERSION "<< read_version << endl; cout<<" You must generate a database for the current VERSION "<< current_version << endl; cout<<" See the NSB database section in the Camera How to Use note." <