[u/mrichter/AliRoot.git] / EMCAL / AliCaloRawAnalyzerNN.cxx

/**************************************************************************
 * This file is property of and copyright by the Experimental Nuclear     *
 * Physics Group, Dep. of Physics                                         *
 * University of Oslo, Norway, 2007                                       *
 *                                                                        *
 * Author: Per Thomas Hille <perthomas.hille@yale.edu>                    *
 * for the ALICE HLT Project.                                             * 
 * Contributors are mentioned in the code where appropriate.              *
 * Please report bugs to perthi@fys.uio.no                                *
 *                                                                        *
 * Permission to use, copy, modify and distribute this software and its   *
 * documentation strictly for non-commercial purposes is hereby granted   *
 * without fee, provided that the above copyright notice appears in all   *
 * copies and that both the copyright notice and this permission notice   *
 * appear in the supporting documentation. The authors make no claims     *
 * about the suitability of this software for any purpose. It is          *
 * provided "as is" without express or implied warranty.                  *
 **************************************************************************/

// Evaluation of peak position
// and amplitude using Neural Networks (NN)
// ------------------
// ------------------
// ------------------


#include "AliCaloRawAnalyzerNN.h"
#include "AliCaloNeuralFit.h"
#include "AliCaloFitResults.h"
#include "AliCaloBunchInfo.h"

#include <iostream>

using namespace std;

ClassImp( AliCaloRawAnalyzerNN )

AliCaloRawAnalyzerNN::AliCaloRawAnalyzerNN() : AliCaloRawAnalyzer("Neural Network", "NN"), fNeuralNet(0)
{
  // Comment

  fNeuralNet = new AliCaloNeuralFit();

  for(int i=0; i < 5 ; i++)
    {
      fNNInput[i]  = 0;
    }

}


AliCaloRawAnalyzerNN::~AliCaloRawAnalyzerNN()
{
  delete fNeuralNet;
}


AliCaloFitResults 
AliCaloRawAnalyzerNN::Evaluate( const vector<AliCaloBunchInfo> &bunchvector, 
				       const UInt_t altrocfg1,  const UInt_t altrocfg2 )
{
  // The eveluation of  Peak position and amplitude using the Neural Network
  if( bunchvector.size()  <=  0 )
    {
      return AliCaloFitResults(AliCaloFitResults::kInvalid, AliCaloFitResults::kInvalid);
    } 
 
  short maxampindex;
  short maxamp;

  int index = SelectBunch( bunchvector, &maxampindex , &maxamp ) ;
  
  if( index   < 0 )
    {
      return AliCaloFitResults(AliCaloFitResults::kInvalid, AliCaloFitResults::kInvalid);
    }
  
  Float_t ped = ReverseAndSubtractPed( &(bunchvector.at( index ) )  ,  altrocfg1, altrocfg2, fReversed  );  
  short timebinOffset = maxampindex - (bunchvector.at(index).GetLength()-1);
  double maxf =  maxamp - ped;

  if(  maxf < fAmpCut  ||  ( maxamp - ped) > fOverflowCut  ) // (maxamp - ped) > fOverflowCut = Close to saturation (use low gain then)
    {
      return  AliCaloFitResults( maxamp, ped, AliCaloFitResults::kCrude, maxf, timebinOffset);
    }

  int first = 0;
  int last = 0; 
  short maxrev = maxampindex  -  bunchvector.at(index).GetStartBin();
  SelectSubarray( fReversed,  bunchvector.at(index).GetLength(),  maxrev , &first, &last);

  Float_t chi2 = 0;
  Int_t ndf = 0;
  if(maxrev  < 1000 )
    {
      if (  ( maxrev   - first) < 2  &&  (last -   maxrev ) < 2)
	{
	  chi2 = CalculateChi2(maxf, maxrev, first, last);
	  ndf = last - first - 1; // nsamples - 2
	  return AliCaloFitResults( maxamp, ped, AliCaloFitResults::kCrude, maxf, timebinOffset,
				    timebinOffset, chi2, ndf, AliCaloFitResults::kDummy, AliCaloFitSubarray(index, maxrev, first, last) ); 
	}
      else
	{

	  for(int i=0; i < 5 ; i++)
	    {
	      fNNInput[i]  = fReversed[maxrev-2 +i]/(maxamp -ped);
	    } 

	  	  
	  double amp = (maxamp - ped)*fNeuralNet->Value( 0,  fNNInput[0],  fNNInput[1], fNNInput[2], fNNInput[3], fNNInput[4]);
	  double tof = (fNeuralNet->Value( 1,  fNNInput[0],  fNNInput[1], fNNInput[2], fNNInput[3], fNNInput[4]) + timebinOffset ) ;

	  // use local-array time for chi2 estimate
	  chi2 = CalculateChi2(amp, tof-timebinOffset+maxrev, first, last);
	  ndf = last - first - 1; // nsamples - 2
	  return AliCaloFitResults( maxamp, ped , AliCaloFitResults::kFitPar, amp , tof, timebinOffset, chi2, ndf,
				    AliCaloFitResults::kDummy, AliCaloFitSubarray(index, maxrev, first, last) );

	}
    }
  chi2 = CalculateChi2(maxf, maxrev, first, last);
  ndf = last - first - 1; // nsamples - 2
  return AliCaloFitResults( maxamp, ped, AliCaloFitResults::kCrude, maxf, timebinOffset,
			    timebinOffset, chi2, ndf, AliCaloFitResults::kDummy, AliCaloFitSubarray(index, maxrev, first, last) ); 

}
Commit	Line	Data
e37e3c84	1	/**************************************************************************
	2	* This file is property of and copyright by the Experimental Nuclear *
	3	* Physics Group, Dep. of Physics *
	4	* University of Oslo, Norway, 2007 *
	5	* *
	6	* Author: Per Thomas Hille <perthomas.hille@yale.edu> *
	7	* for the ALICE HLT Project. *
	8	* Contributors are mentioned in the code where appropriate. *
	9	* Please report bugs to perthi@fys.uio.no *
	10	* *
	11	* Permission to use, copy, modify and distribute this software and its *
	12	* documentation strictly for non-commercial purposes is hereby granted *
	13	* without fee, provided that the above copyright notice appears in all *
	14	* copies and that both the copyright notice and this permission notice *
	15	* appear in the supporting documentation. The authors make no claims *
	16	* about the suitability of this software for any purpose. It is *
	17	* provided "as is" without express or implied warranty. *
	18	**************************************************************************/
	19
	20	// Evaluation of peak position
	21	// and amplitude using Neural Networks (NN)
	22	// ------------------
	23	// ------------------
	24	// ------------------
	25
	26
	27	#include "AliCaloRawAnalyzerNN.h"
	28	#include "AliCaloNeuralFit.h"
	29	#include "AliCaloFitResults.h"
	30	#include "AliCaloBunchInfo.h"
	31
	32	#include <iostream>
	33
	34	using namespace std;
	35
	36	ClassImp( AliCaloRawAnalyzerNN )
	37
48a2e3eb	38	AliCaloRawAnalyzerNN::AliCaloRawAnalyzerNN() : AliCaloRawAnalyzer("Neural Network", "NN"), fNeuralNet(0)
e37e3c84	39	{
	40	// Comment
	41
	42	fNeuralNet = new AliCaloNeuralFit();
	43
	44	for(int i=0; i < 5 ; i++)
	45	{
	46	fNNInput[i] = 0;
	47	}
	48
	49	}
	50
	51
	52	AliCaloRawAnalyzerNN::~AliCaloRawAnalyzerNN()
	53	{
	54	delete fNeuralNet;
	55	}
	56
	57
	58	AliCaloFitResults
	59	AliCaloRawAnalyzerNN::Evaluate( const vector<AliCaloBunchInfo> &bunchvector,
	60	const UInt_t altrocfg1, const UInt_t altrocfg2 )
	61	{
	62	// The eveluation of Peak position and amplitude using the Neural Network
	63	if( bunchvector.size() <= 0 )
	64	{
507751ce	65	return AliCaloFitResults(AliCaloFitResults::kInvalid, AliCaloFitResults::kInvalid);
e37e3c84	66	}
e37e3c84	67
f57baa2d	68	short maxampindex;
e37e3c84	69	short maxamp;
e37e3c84	70
f57baa2d	71	int index = SelectBunch( bunchvector, &maxampindex , &maxamp ) ;
e37e3c84	72
f57baa2d	73	if( index < 0 )
e37e3c84	74	{
f57baa2d	75	return AliCaloFitResults(AliCaloFitResults::kInvalid, AliCaloFitResults::kInvalid);
e37e3c84	76	}
e37e3c84	77
2cd0ffda	78	Float_t ped = ReverseAndSubtractPed( &(bunchvector.at( index ) ) , altrocfg1, altrocfg2, fReversed );
f57baa2d	79	short timebinOffset = maxampindex - (bunchvector.at(index).GetLength()-1);
	80	double maxf = maxamp - ped;
	81
2cd0ffda	82	if( maxf < fAmpCut \|\| ( maxamp - ped) > fOverflowCut ) // (maxamp - ped) > fOverflowCut = Close to saturation (use low gain then)
	83	{
	84	return AliCaloFitResults( maxamp, ped, AliCaloFitResults::kCrude, maxf, timebinOffset);
	85	}
	86
	87	int first = 0;
	88	int last = 0;
	89	short maxrev = maxampindex - bunchvector.at(index).GetStartBin();
f57baa2d	90	SelectSubarray( fReversed, bunchvector.at(index).GetLength(), maxrev , &first, &last);
e37e3c84	91
2cd0ffda	92	Float_t chi2 = 0;
2cd0ffda	93	Int_t ndf = 0;
e37e3c84	94	if(maxrev < 1000 )
	95	{
	96	if ( ( maxrev - first) < 2 && (last - maxrev ) < 2)
	97	{
2cd0ffda	98	chi2 = CalculateChi2(maxf, maxrev, first, last);
	99	ndf = last - first - 1; // nsamples - 2
	100	return AliCaloFitResults( maxamp, ped, AliCaloFitResults::kCrude, maxf, timebinOffset,
	101	timebinOffset, chi2, ndf, AliCaloFitResults::kDummy, AliCaloFitSubarray(index, maxrev, first, last) );
e37e3c84	102	}
	103	else
	104	{
e37e3c84	105
	106	for(int i=0; i < 5 ; i++)
	107	{
	108	fNNInput[i] = fReversed[maxrev-2 +i]/(maxamp -ped);
	109	}
	110
3b8fd9fe	111
a9ebbc7a	112	double amp = (maxamp - ped)*fNeuralNet->Value( 0, fNNInput[0], fNNInput[1], fNNInput[2], fNNInput[3], fNNInput[4]);
3b8fd9fe	113	double tof = (fNeuralNet->Value( 1, fNNInput[0], fNNInput[1], fNNInput[2], fNNInput[3], fNNInput[4]) + timebinOffset ) ;
e37e3c84	114
2cd0ffda	115	// use local-array time for chi2 estimate
	116	chi2 = CalculateChi2(amp, tof-timebinOffset+maxrev, first, last);
	117	ndf = last - first - 1; // nsamples - 2
	118	return AliCaloFitResults( maxamp, ped , AliCaloFitResults::kFitPar, amp , tof, timebinOffset, chi2, ndf,
f57baa2d	119	AliCaloFitResults::kDummy, AliCaloFitSubarray(index, maxrev, first, last) );
e37e3c84	120
	121	}
	122	}
2cd0ffda	123	chi2 = CalculateChi2(maxf, maxrev, first, last);
	124	ndf = last - first - 1; // nsamples - 2
	125	return AliCaloFitResults( maxamp, ped, AliCaloFitResults::kCrude, maxf, timebinOffset,
	126	timebinOffset, chi2, ndf, AliCaloFitResults::kDummy, AliCaloFitSubarray(index, maxrev, first, last) );
	127
e37e3c84	128	}
e37e3c84	129
e37e3c84	130