source: branches/MarsMoreSimulationTruth/mhcalib/MHCalibrationTestCam.cc

/* ======================================================================== *\
!
! *
! * 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): Markus Gaug   02/2004 <mailto:markus@ifae.es>
!              
!   Copyright: MAGIC Software Development, 2000-2004
!
!
\* ======================================================================== */
/////////////////////////////////////////////////////////////////////////////
//                                                                        
// MHCalibrationTestCam                                                
//                                                                        
// Fills the calibrated signal from an MSignalCam into 
// MHCalibrationPix for every:
//
// - Pixel, stored in the TObjArray's MHCalibrationCam::fHiGainArray  
//   or MHCalibrationCam::fHiGainArray, respectively.
//
// - Average pixel per AREA index (e.g. inner and outer for the MAGIC camera), 
//   stored in the TObjArray's MHCalibrationCam::fAverageHiGainAreas and 
//   MHCalibrationCam::fAverageHiGainAreas
//
// - Average pixel per camera SECTOR (e.g. sectors 1-6 for the MAGIC camera), 
//   stored in the TObjArray's MHCalibrationCam::fAverageHiGainSectors 
//   and MHCalibrationCam::fAverageHiGainSectors 
//
// The signals are filled into a histogram and an array, in order to perform 
// a Fourier analysis (see MHGausEvents). The signals are moreover averaged on an 
// event-by-event basis and written into the corresponding average pixels.
//
// The histograms are fitted to a Gaussian, mean and sigma with its errors 
// and the fit probability are extracted. If none of these values are NaN's and 
// if the probability is bigger than MHGausEvents::fProbLimit (default: 0.5%), 
// the fit is declared valid.
// Otherwise, the fit is repeated within ranges of the previous mean 
// +- MHCalibrationPix::fPickupLimit (default: 5) sigma (see MHCalibrationPix::RepeatFit())
// In case this does not make the fit valid, the histogram means and RMS's are 
// taken directly (see MHCalibrationPix::BypassFit()) and the following flags are set:
// - MBadPixelsPix::SetUncalibrated( MBadPixelsPix::kHiGainNotFitted ) and
// - MBadPixelsPix::SetUnsuitable(   MBadPixelsPix::kUnreliableRun    ) 
// 
// Outliers of more than MHCalibrationPix::fPickupLimit (default: 5) sigmas 
// from the mean are counted as Pickup events (stored in MHCalibrationPix::fPickup) 
//
// The class also fills arrays with the signal vs. event number, creates a fourier 
// spectrum (see MHGausEvents::CreateFourierSpectrum()) and investigates if the 
// projected fourier components follow an exponential distribution. 
// In case that the probability of the exponential fit is less than 
// MHGausEvents::fProbLimit (default: 0.5%), the following flags are set:
// - MBadPixelsPix::SetUncalibrated( MBadPixelsPix::kHiGainOscillating ) and
// - MBadPixelsPix::SetUnsuitable(   MBadPixelsPix::kUnreliableRun      )
// 
// This same procedure is performed for the average pixels.
//
// The following results are written into an MCalibrationCam:
//
// - MCalibrationPix::SetMean()
// - MCalibrationPix::SetMeanErr()
// - MCalibrationPix::SetSigma()
// - MCalibrationPix::SetSigmaErr()
// - MCalibrationPix::SetProb()
// - MCalibrationPix::SetNumPickup()
//
// For all averaged areas, the fitted sigma is multiplied with the square root of 
// the number involved pixels in order to be able to compare it to the average of 
// sigmas in the camera.
//                                                                         
/////////////////////////////////////////////////////////////////////////////
#include "MHCalibrationTestCam.h"

#include "MHCalibrationPix.h"

#include "MLog.h"
#include "MLogManip.h"

#include "MParList.h"

#include "MCalibrationCam.h"
#include "MCalibrationPix.h"

#include "MSignalCam.h"
#include "MSignalPix.h"

#include "MGeomCam.h"
#include "MGeomPix.h"

#include "MBadPixelsCam.h"
#include "MBadPixelsPix.h"

#include <TOrdCollection.h>

ClassImp(MHCalibrationTestCam);

using namespace std;

const Int_t   MHCalibrationTestCam::fgNbins    = 1000;
const Axis_t  MHCalibrationTestCam::fgFirst    = -1.;
const Axis_t  MHCalibrationTestCam::fgLast     = 1999.;
const Float_t MHCalibrationTestCam::fgProbLimit  = 0.00000001;
const TString MHCalibrationTestCam::gsHistName   = "Test";
const TString MHCalibrationTestCam::gsHistTitle  = "Calibrated Calibration Signals";  
const TString MHCalibrationTestCam::gsHistXTitle = "Nr. Photons";
const TString MHCalibrationTestCam::gsHistYTitle = "Nr. events";
// --------------------------------------------------------------------------
//
// Default Constructor. 
//
// Sets: 
// - fNbins to fgNbins
// - fFirst to fgFirst
// - fLast  to fgLast 
//
// - fHistName   to gsHistName  
// - fHistTitle  to gsHistTitle 
// - fHistXTitle to gsHistXTitle
// - fHistYTitle to gsHistYTitle
//
MHCalibrationTestCam::MHCalibrationTestCam(const char *name, const char *title) 
{

  fName  = name  ? name  : "MHCalibrationTestCam";
  fTitle = title ? title : "Histogram class for testing the calibration";
  
  SetBinning(fgNbins, fgFirst, fgLast);

  SetProbLimit(fgProbLimit);

  SetHistName  (gsHistName  .Data());
  SetHistTitle (gsHistTitle .Data());
  SetHistXTitle(gsHistXTitle.Data());
  SetHistYTitle(gsHistYTitle.Data());

  SetLoGain(kFALSE);
  
}

// --------------------------------------------------------------------------
//
// Searches pointer to:
// - MSignalCam
//
// Calls:
// - MHCalibrationCam::InitHiGainArrays()
// 
// Sets: 
// - SetLoGain(kFALSE);
// - fMeanMeanPhotPerArea to nareas
// - fRmsMeanPhotPerArea  to nareas
// - fMeanSigmaPhotPerArea to nareas
// - fRmsSigmaPhotPerArea  to nareas
//
Bool_t MHCalibrationTestCam::ReInitHists(MParList *pList)
{

  if (!InitCams(pList,"Test"))
    return kFALSE;


  MSignalCam *signal = (MSignalCam*)pList->FindObject("MSignalCam");
  if (!signal)
  {
      *fLog << err << "MSignalCam not found... abort." << endl;
      return kFALSE;
  }


  const Int_t npixels  = fGeom->GetNumPixels();
  const Int_t nsectors = fGeom->GetNumSectors();
  const Int_t nareas   = fGeom->GetNumAreas();

  InitHiGainArrays(npixels,nareas,nsectors);
  InitLoGainArrays(npixels,nareas,nsectors);

  fMeanMeanPhotPerArea.Set(nareas);   
  fRmsMeanPhotPerArea .Set(nareas); 
  fMeanSigmaPhotPerArea.Set(nareas);  
  fRmsSigmaPhotPerArea.Set(nareas);

  return kTRUE;
}

// -------------------------------------------------------------------------------
//
// Retrieves pointer to MSignalCam:
//
// Retrieves from MGeomCam:
// - number of pixels
// - number of pixel areas
// - number of sectors
//
// Fills HiGain histograms (MHGausEvents::FillHistAndArray())
// with:
// - MSignalPix::GetNumPhotons(pixid);
//
Bool_t MHCalibrationTestCam::FillHists(const MParContainer *par, const Stat_t w)
{

  MSignalCam *calibration = (MSignalCam*)par;
  if (!calibration)
    {
      gLog << err << "No argument in MHCalibrationTestCam::Fill... abort." << endl;
      return kFALSE;
    }

  const Int_t npixels  = fGeom->GetNumPixels();
  const Int_t nareas   = fGeom->GetNumAreas();
  const Int_t nsectors = fGeom->GetNumSectors();

  TArrayF sumareahi  (nareas); 
  TArrayF sumsectorhi(nsectors);
  TArrayI numareahi  (nareas); 
  TArrayI numsectorhi(nsectors);
  
  for (Int_t i=0; i<npixels; i++)
    {

      const MSignalPix &pix = (*calibration)[i];

      const Float_t signal = pix.GetNumPhotons();
      if (signal < 0.0001)
          continue;

      const Int_t aidx   = (*fGeom)[i].GetAidx();
      const Int_t sector = (*fGeom)[i].GetSector();

      (*this)[i].FillHistAndArray(signal);

      sumareahi  [aidx]   += signal;
      numareahi  [aidx]   ++;
      sumsectorhi[sector] += signal;
      numsectorhi[sector] ++;
    }
  
  for (Int_t j=0; j<nareas; j++)
    {
      MHCalibrationPix &histhi = GetAverageHiGainArea(j);
      histhi.FillHistAndArray(numareahi[j] == 0 ? 0. : sumareahi[j]/numareahi[j]);
    }
  
  for (Int_t j=0; j<nsectors; j++)
    {
      MHCalibrationPix &histhi = GetAverageHiGainSector(j);
      histhi.FillHistAndArray(numsectorhi[j] == 0 ? 0. : sumsectorhi[j]/numsectorhi[j]);

    }

  return kTRUE;
}

// --------------------------------------------------------------------------
//
// Calls:
// - MHCalibrationCam::FitHiGainArrays() with flags:
//   MBadPixelsPix::kTestNotFitted and MBadPixelsPix::kTestOscillating
// 
Bool_t MHCalibrationTestCam::FinalizeHists()
{

  *fLog << endl;

  TArrayI numaidx;
  numaidx.Set(fGeom->GetNumAreas());

  for (Int_t i=0; i<fHiGainArray->GetSize(); i++)
    {
      
      MHCalibrationPix &hist = (*this)[i];
      
      if (hist.IsEmpty())
        continue;

      if (!hist.FitGaus())
        if (!hist.RepeatFit())
          hist.BypassFit();
      
      hist.CreateFourierSpectrum();
      
      const Float_t area = (*fGeom)[i].GetA();
      const Int_t   aidx = (*fGeom)[i].GetAidx();

      fMeanMeanPhotPerArea[aidx]  += hist.GetMean() / area;
      fRmsMeanPhotPerArea [aidx]  += hist.GetMean() / area * hist.GetMean()  / area;
      fMeanSigmaPhotPerArea[aidx] += hist.GetSigma()/ area;
      fRmsSigmaPhotPerArea [aidx] += hist.GetSigma()/ area * hist.GetSigma() / area;
      numaidx[aidx]++;
    }


  for (Int_t j=0; j<fAverageHiGainAreas->GetSize(); j++)
    {
      
      MHCalibrationPix     &hist = GetAverageHiGainArea(j);      
      if (hist.IsEmpty())
        continue;
      
      if (!hist.FitGaus())
        if (!hist.RepeatFit())
          hist.BypassFit();
      
      hist.CreateFourierSpectrum();
      
      fRmsMeanPhotPerArea [j]  -= fMeanMeanPhotPerArea [j]*fMeanMeanPhotPerArea [j]/numaidx[j];
      fRmsSigmaPhotPerArea[j]  -= fMeanSigmaPhotPerArea[j]*fMeanSigmaPhotPerArea[j]/numaidx[j];

      fMeanMeanPhotPerArea [j]  /=  numaidx[j];
      fMeanSigmaPhotPerArea[j]  /=  numaidx[j];
      fRmsMeanPhotPerArea  [j]  /=  numaidx[j]-1.;
      fRmsSigmaPhotPerArea [j]  /=  numaidx[j]-1.; 

      if (fRmsMeanPhotPerArea  [j] > 0.)
        fRmsMeanPhotPerArea  [j]  =  TMath::Sqrt(fRmsMeanPhotPerArea  [j]);
      if (fRmsSigmaPhotPerArea [j] > 0.)
        fRmsSigmaPhotPerArea [j]  =  TMath::Sqrt(fRmsSigmaPhotPerArea [j]);
  }

  for (Int_t j=0; j<fAverageHiGainSectors->GetSize(); j++)
    {
      
      MHCalibrationPix     &hist = GetAverageHiGainSector(j);      
      if (hist.IsEmpty())
        continue;
      
      if (!hist.FitGaus())
        if (!hist.RepeatFit())
          hist.BypassFit();

      hist.CreateFourierSpectrum();
    }

  return kTRUE;
}


// --------------------------------------------------------------------------
//
// The types are as follows:
// 
// Fitted values:
// ============== 
//
// 0: Fitted Mean Test Calibration (MHGausEvents::GetMean())
// 1: Error Mean Test Calibration  (MHGausEvents::GetMeanErr())
// 2: Sigma fitted Test Calibration (MHGausEvents::GetSigma())
// 3: Error Sigma Test Calibration (MHGausEvents::GetSigmaErr())
//
// Useful variables derived from the fit results:
// =============================================
//
// 4: Returned probability of Gauss fit              (calls: MHGausEvents::GetProb())
//
// Localized defects:
// ==================
//
// 5: Gaus fit not OK                               (calls: MHGausEvents::IsGausFitOK())
// 6: Fourier spectrum not OK                       (calls: MHGausEvents::IsFourierSpectrumOK())
//
// Converted values:
// =================
//
// 7:  Fitted Mean Test Calibration   (MHGausEvents::GetMean())     by MGeomPix::GetA()
// 8:  Fitted Mean Error Calibration  (MHGausEvents::GetMeanErr())  by MGeomPix::GetA()
// 9:  Fitted Sigma Test Calibration  (MHGausEvents::GetSigma())    by MGeomPix::GetA()
// 10: Fitted Sigma Error Calibration (MHGausEvents::GetSigmaErr()) by MGeomPix::GetA()
//
Bool_t MHCalibrationTestCam::GetPixelContent(Double_t &val, Int_t idx, const MGeomCam &cam, Int_t type) const
{

  if (fHiGainArray->GetSize() <= idx)
    return kFALSE;

  const MHCalibrationPix &pix = (*this)[idx];

  if (pix.IsEmpty())
    return kFALSE;

  switch (type)
    {
    case 0:
      val = pix.GetMean();
      break;
    case 1:
      val = pix.GetMeanErr();
      break;
    case 2:
      val = pix.GetSigma();
      break;
    case 3:
      val = pix.GetSigmaErr();
      break;
    case 4:
      val = pix.GetProb();
      break;
    case 5:
      if (!pix.IsGausFitOK())
        val = 1.;
      break;
    case 6:
      if (!pix.IsFourierSpectrumOK())
        val = 1.;
      break;
    case 7:
      val = pix.GetMean()/cam[idx].GetA();
      break;
    case 8:
      val = pix.GetMeanErr()/cam[idx].GetA();
      break;
    case 9:
      val = pix.GetSigma()/cam[idx].GetA();
      break;
    case 10:
      val = pix.GetSigmaErr()/cam[idx].GetA();
      break;
    default:
      return kFALSE;
    }
  return kTRUE;
}

// --------------------------------------------------------------------------
//
// Calls MHCalibrationPix::DrawClone() for pixel idx
//
void MHCalibrationTestCam::DrawPixelContent(Int_t idx) const
{
 (*this)[idx].DrawClone();
}


//------------------------------------------------------------
//
// For all averaged areas, the fitted sigma is multiplied with the square root of 
// the number involved pixels
//
void MHCalibrationTestCam::CalcAverageSigma()
{
  
  for (UInt_t j=0; j<fGeom->GetNumAreas(); j++)
    {
  
      MHCalibrationPix &hist    = GetAverageHiGainArea(j);

      const Float_t numsqr    = TMath::Sqrt((Float_t)fAverageAreaNum[j]);
      fAverageAreaSigma[j]    = hist.GetSigma    () * numsqr;
      fAverageAreaSigmaVar[j] = hist.GetSigmaErr () * hist.GetSigmaErr() * numsqr;

      fAverageAreaRelSigma   [j]  = fAverageAreaSigma[j]    / hist.GetMean();
      fAverageAreaRelSigmaVar[j]  = fAverageAreaSigmaVar[j] / (fAverageAreaSigma[j]*fAverageAreaSigma[j]);
      fAverageAreaRelSigmaVar[j] += hist.GetMeanErr()*hist.GetMeanErr()/hist.GetMean()/hist.GetMean();
      fAverageAreaRelSigmaVar[j] *= fAverageAreaRelSigma[j];
    }
}