/* ======================================================================== *\ ! ! * ! * This file is part of MARS, the MAGIC Analysis and Reconstruction ! * Software. It is distributed to you in the hope that it can be a useful ! * and timesaving tool in analysing Data of imaging Cerenkov telescopes. ! * It is distributed WITHOUT ANY WARRANTY. ! * ! * Permission to use, copy, modify and distribute this software and its ! * documentation for any purpose is hereby granted without fee, ! * provided that the above copyright notice appear in all copies and ! * that both that copyright notice and this permission notice appear ! * in supporting documentation. It is provided "as is" without express ! * or implied warranty. ! * ! ! ! Author(s): Josep Flix 04/2001 ! Author(s): Thomas Bretz 05/2001 ! Author(s): Sebastian Commichau 12/2003 ! Author(s): Javier Rico 01/2004 ! Author(s): Markus Gaug 01/2004 ! Author(s): Florian Goebel 06/2004 ! Author(s): Nepomuk Otte 10/2004 ! ! Copyright: MAGIC Software Development, 2000-2004 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MPedCalcLoGain // // This task derives from MExtractPedestal. // It calculates the pedestals using the low gain slices, whenever the difference // between the highest and the lowest slice in the high gain // slices is below a given threshold (SetMaxHiGainVar). In this case the receiver // boards do not switch to lo gain and the so called lo gain slices are actually // high gain slices. // // MPedCalcLoGain also fills the ABoffset in MPedestalPix which allows to correct // the 150 MHz clock noise. // // This task takes a pedestal run file and fills MPedestalCam during // the Process() with the pedestal and rms computed in an event basis. // In the PostProcess() MPedestalCam is finally filled with the pedestal // mean and rms computed in a run basis. // More than one run (file) can be merged // // MPedCalcPedRun applies the following formula (1): // // Pedestal per slice = sum(x_i) / n / slices // PedRMS per slice = Sqrt( ( sum(x_i^2) - sum(x_i)^2/n ) / n-1 / slices ) // // where x_i is the sum of "slices" FADC slices and sum means the sum over all // events. "n" is the number of events, "slices" is the number of summed FADC samples. // // Note that the slice-to-slice fluctuations are not Gaussian, but Poissonian, thus // asymmetric and they are correlated. // // It is important to know that the Pedestal per slice and PedRMS per slice depend // on the number of used FADC slices, as seen in the following plots: // //Begin_Html /* */ //End_Html // //Begin_Html /* */ //End_Html // // The plots show the inner and outer pixels, respectivly and have the following meaning: // // 1) The calculated mean pedestal per slice (from MPedCalcFromLoGain) // 2) The fitted mean pedestal per slice (from MHPedestalCam) // 3) The calculated pedestal RMS per slice (from MPedCalcFromLoGain) // 4) The fitted sigma of the pedestal distribution per slice // (from MHPedestalCam) // 5) The relative difference between calculation and histogram fit // for the mean // 6) The relative difference between calculation and histogram fit // for the sigma or RMS, respectively. // // The calculated means do not change significantly except for the case of 2 slices, // however the RMS changes from 5.7 per slice in the case of 2 extracted slices // to 8.3 per slice in the case of 26 extracted slices. This change is very significant. // // The plots have been produced on run 20123. You can reproduce them using // the macro pedestalstudies.C // // Usage of this class: // ==================== // // // fCheckWinFirst = fgCheckWinFirst = 0 // fCheckWinLast = fgCheckWinLast = 29 // fExtractWinFirst = fgExtractWinFirst = 17 // fExtractWinSize = fgExtractWinSize = 6 // fMaxSignalVar = fgMaxSignalVar = 40; // // Call: // SetCheckRange(fCheckWinFirst,fCheckWinLast); // to set the Window in which a signal is searched // // SetExtractWindow(fExtractWinFirst,fExtractWinSize); // to set the Window from which a signal is extracted // // SetMaxSignalVar(fMaxSignalVar); // set the maximum allowed difference between maximum and minimal signal in CheckWindow // // Variables: // fgCheckWinFirst; First FADC slice to check for signal (currently set to: 0) // fgCheckWinLast: Last FADC slice to check for signal (currently set to: 29) // fgExtractWinFirst: First FADC slice to be used for pedestal extraction (currently set to: 15) // fgExtractWinSize: Window size in slices used for pedestal extraction (currently set to: 6) // fgMaxSignalVar: The maximum difference between the highest and lowest slice // in the check window allowed in order to use event // // Input Containers: // MRawEvtData // MRawRunHeader // MGeomCam // // Output Containers: // MPedestalCam // // See also: MPedestalCam, MPedestalPix, MHPedestalCam, MExtractor // ///////////////////////////////////////////////////////////////////////////// #include "MPedCalcFromLoGain.h" #include "MParList.h" #include "MLog.h" #include "MLogManip.h" #include "MRawRunHeader.h" #include "MRawEvtPixelIter.h" #include "MRawEvtData.h" #include "MPedestalPix.h" #include "MPedestalCam.h" #include "MGeomPix.h" #include "MGeomCam.h" #include "MExtractPedestal.h" #include "MExtractTimeAndCharge.h" ClassImp(MPedCalcFromLoGain); using namespace std; const UShort_t MPedCalcFromLoGain::fgCheckWinFirst = 0; const UShort_t MPedCalcFromLoGain::fgCheckWinLast = 29; const UShort_t MPedCalcFromLoGain::fgExtractWinFirst = 17; const UShort_t MPedCalcFromLoGain::fgExtractWinSize = 6; const UShort_t MPedCalcFromLoGain::fgMaxSignalVar = 40; // -------------------------------------------------------------------------- // // Default constructor: // // Sets: // - all pointers to NULL // // Calls: // - AddToBranchList("fHiGainPixId"); // - AddToBranchList("fHiGainFadcSamples"); // - SetCheckRange(fgCheckWinFirst, fgCheckWinLast, fgExtractWinFirst, fgExtractWinSize) // MPedCalcFromLoGain::MPedCalcFromLoGain(const char *name, const char *title) { fName = name ? name : "MPedCalcFromLoGain"; fTitle = title ? title : "Task to calculate pedestals from lo-gains"; SetCheckRange(fgCheckWinFirst, fgCheckWinLast); SetExtractWindow(fgExtractWinFirst, fgExtractWinSize); SetMaxSignalVar(fgMaxSignalVar); } void MPedCalcFromLoGain::ResetArrays() { MExtractPedestal::ResetArrays(); fNumEventsUsed.Reset(); fTotalCounter.Reset(); } // -------------------------------------------------------------------------- // // SetCheckRange: // // Exits, if the first argument is smaller than 0 // Exits, if the the last argument is smaller than the first // Bool_t MPedCalcFromLoGain::SetCheckRange(UShort_t chfirst, UShort_t chlast) { Bool_t rc = kTRUE; if (chlast<=chfirst) { *fLog << warn << GetDescriptor(); *fLog << " - WARNING: Last slice in SetCheckRange smaller than first slice... set to first+2" << endl; chlast = chfirst+1; rc = kFALSE; } fCheckWinFirst = chfirst; fCheckWinLast = chlast; return rc; } // --------------------------------------------------------------------------------- // // Checks: // - if the number of available slices // (fRunHeader->GetNumSamplesHiGain()+(Int_t)fRunHeader->GetNumSamplesLoGain()-1) // is smaller than the number of used slices // (fExtractWinSize+ fExtractWinFirst-1) or // fCheckWinLast // Bool_t MPedCalcFromLoGain::ReInit(MParList *pList) { const UShort_t hisamples = fRunHeader->GetNumSamplesHiGain(); const UShort_t losamples = fRunHeader->GetNumSamplesLoGain(); fSlices.Set(hisamples+losamples); UShort_t lastavailable = hisamples+losamples-1; if (fExtractor) fExtractWinLast = fExtractWinFirst + fExtractor->GetWindowSizeHiGain() - 1; // If the size is not yet set, set the size if (fSumx.GetSize()==0) { const Int_t npixels = fPedestalsOut->GetSize(); fNumEventsUsed.Set(npixels); fTotalCounter.Set(npixels); } if (fCheckWinLast > lastavailable) //changed to override check { *fLog << warn << GetDescriptor(); *fLog << " - WARNING: Last Check Window slice out of range...adjusting to last available slice "; *fLog << lastavailable << endl; fCheckWinLast = lastavailable; } if (fExtractWinLast > lastavailable) { if (fExtractor) { *fLog << err << GetDescriptor(); *fLog << " - ERROR: Selected Last Extraction Window: " << fExtractWinFirst + fExtractor->GetWindowSizeHiGain()-1 << "ranges out of range: " << lastavailable-1 << endl; return kFALSE; } else { const UShort_t diff = fExtractWinLast - lastavailable; *fLog << warn << GetDescriptor(); *fLog << " - WARNING: Selected Extract Window ranges out of range...adjusting to last available slice "; *fLog << lastavailable << endl; fExtractWinLast -= diff; fExtractWinSize -= diff; } } return MExtractPedestal::ReInit(pList); } // -------------------------------------------------------------------------- // // Fill the MPedestalCam container with the signal mean and rms for the event. // Store the measured signal in arrays fSumx and fSumx2 so that we can // calculate the overall mean and rms in the PostProcess() // Int_t MPedCalcFromLoGain::Calc() { // This is the workaround to put hi- and lo-gains together const Int_t nhigain = fRunHeader->GetNumSamplesHiGain(); const Int_t nlogain = fRunHeader->GetNumSamplesLoGain(); Byte_t *slices = fSlices.GetArray(); // Real Process MRawEvtPixelIter pixel(fRawEvt); while (pixel.Next()) { // This is the fast workaround to put hi- and lo-gains together memcpy(slices, pixel.GetHiGainSamples(), nhigain); memcpy(slices+nhigain, pixel.GetLoGainSamples(), nlogain); // Start 'real' work const UInt_t idx = pixel.GetPixelId(); const UInt_t aidx = (*fGeom)[idx].GetAidx(); const UInt_t sector = (*fGeom)[idx].GetSector(); UShort_t max = 0; UShort_t min = (UShort_t)-1; // Find the maximum and minimum signal per slice in the high gain window for (Byte_t *slice=slices+fCheckWinFirst; slice<=slices+fCheckWinLast; slice++) { if (*slice > max) max = *slice; if (*slice < min) min = *slice; } // If the maximum in the high gain window is smaller than if (max-min>=fMaxSignalVar || max>=250) continue; Float_t sum = 0.; //extract pedestal if (fExtractor) CalcExtractor(pixel, sum, (*fPedestalsIn)[idx]); else { UInt_t sumi = 0; for(Byte_t *slice=slices+fExtractWinFirst; slice<=slices+fExtractWinLast; slice++) sumi += *slice; sum = (Float_t)sumi; } const Float_t sqrsum = sum*sum; fSumx[idx] += sum; fSumx2[idx] += sqrsum; fAreaSumx[aidx] += sum; fAreaSumx2[aidx] += sqrsum; fSectorSumx[sector] += sum; fSectorSumx2[sector] += sqrsum; if (fIntermediateStorage) (*fPedestalsInter)[idx].Set(sum,0.,0.,fNumEventsUsed[idx]); fNumEventsUsed[idx] ++; fAreaFilled [aidx] ++; fSectorFilled [sector]++; if (!fExtractor) { // // Calculate the amplitude of the 150MHz "AB" noise // const UShort_t abFlag = (fExtractWinFirst + pixel.HasABFlag()) & 0x1; for (Byte_t *slice=slices+fExtractWinFirst; slice<=slices+fExtractWinLast; slice+=2) { const UShort_t ab0 = *(slice + abFlag); const UShort_t ab1 = *(slice - abFlag + 1); fSumAB0[idx] += ab0; fSumAB1[idx] += ab1; fAreaSumAB0[aidx] += ab0; fAreaSumAB1[aidx] += ab1; fSectorSumAB0[aidx] += ab0; fSectorSumAB1[aidx] += ab1; } } if (!fPedestalUpdate || (UInt_t)fNumEventsUsed[idx]SetReadyToSave(); return kTRUE; } // -------------------------------------------------------------------------- // // Loop over the sector indices to get the averaged pedestal per sector // void MPedCalcFromLoGain::CalcSectorResult() { for (UInt_t sector=0; sector0) CalcSectorResults(fSectorFilled[sector], fSectorValid[sector], sector); } // -------------------------------------------------------------------------- // // Loop over the (two) area indices to get the averaged pedestal per aidx // void MPedCalcFromLoGain::CalcAreaResult() { for (UInt_t aidx=0; aidx0) CalcAreaResults(fAreaFilled[aidx], fAreaValid[aidx], aidx); } void MPedCalcFromLoGain::CalcExtractor(const MRawEvtPixelIter &pixel, Float_t &sum, MPedestalPix &ped) { Byte_t sat = 0; Byte_t *logain = pixel.GetLoGainSamples() + fExtractWinFirst; const Bool_t logainabflag = (pixel.HasABFlag() + pixel.GetNumHiGainSamples()) & 0x1; Float_t dummy; fExtractor->FindTimeAndChargeHiGain(logain,logain,sum,dummy,dummy,dummy,sat,ped,logainabflag); } // -------------------------------------------------------------------------- // // Compute signal mean and rms in the whole run and store it in MPedestalCam // Int_t MPedCalcFromLoGain::PostProcess() { // Compute pedestals and rms from the whole run if (fPedestalUpdate) return kTRUE; *fLog << flush << inf << "Calculating Pedestals..." << flush; const Int_t npix = fGeom->GetNumPixels(); for (Int_t idx=0; idx1) { CalcPixResults(n, idx); fTotalCounter[idx]++; } } CalcAreaResult(); CalcSectorResult(); fPedestalsOut->SetReadyToSave(); return MExtractPedestal::PostProcess(); } // -------------------------------------------------------------------------- // // The following resources are available: // FirstCheckWindowSlice: 0 // LastCheckWindowSlice: 29 // MaxSignalVar: 40 // Int_t MPedCalcFromLoGain::ReadEnv(const TEnv &env, TString prefix, Bool_t print) { Bool_t rc=kFALSE; // Find resources for CheckWindow Int_t fs = fCheckWinFirst; Int_t ls = fCheckWinLast; if (IsEnvDefined(env, prefix, "CheckWinFirst", print)) { fs = GetEnvValue(env, prefix, "CheckWinFirst", fs); rc = kTRUE; } if (IsEnvDefined(env, prefix, "CheckWinLast", print)) { ls = GetEnvValue(env, prefix, "CheckWinLast", ls); rc = kTRUE; } SetCheckRange(fs,ls); // find resource for maximum signal variation if (IsEnvDefined(env, prefix, "MaxSignalVar", print)) { SetMaxSignalVar(GetEnvValue(env, prefix, "MaxSignalVar", fMaxSignalVar)); rc = kTRUE; } return MExtractPedestal::ReadEnv(env,prefix,print) ? kTRUE : rc; } void MPedCalcFromLoGain::Print(Option_t *o) const { MExtractPedestal::Print(o); const Int_t last = fExtractor ? fExtractWinFirst + fExtractor->GetWindowSizeHiGain() -1 : fExtractWinLast; *fLog << "ExtractWindow from slice " << fExtractWinFirst << " to " << last << " incl." << endl; *fLog << "Max.allowed signal variation: " << fMaxSignalVar << endl; *fLog << "CheckWindow from slice " << fCheckWinFirst << " to " << fCheckWinLast << " incl." << endl; }