[u/mrichter/AliRoot.git] / EMCAL / AliEMCALRawUtils.h

#ifndef ALIEMCALRAWUTILS_H
#define ALIEMCALRAWUTILS_H
/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 * See cxx source for full Copyright notice     */

/* $Id$ */

//_________________________________________________________________________
//  Utility Class for handling Raw data
//  Does all transitions from Digits to Raw and vice versa, 
//  for simu and reconstruction
//
//  Note: the current version is still simplified. Only 
//    one raw signal per digit is generated; either high-gain or low-gain
//    Need to add concurrent high and low-gain info in the future
//    No pedestal is added to the raw signal.
//
//*-- Author: Marco van Leeuwen (LBL)
//
#include "TObject.h" // for ROOT types
#include <TString.h>
//#include "AliCaloRawStreamV3.h"
class AliCaloRawStreamV3;
class AliAltroMapping;
class TGraph;
class TF1;
class AliRawReader;
class AliEMCALGeometry;

class AliEMCALRawUtils : public TObject {
 public:
  AliEMCALRawUtils();
  AliEMCALRawUtils(AliEMCALGeometry *pGeometry);
  virtual ~AliEMCALRawUtils();

  AliEMCALRawUtils(const AliEMCALRawUtils& rawUtils);  //copy ctor
  AliEMCALRawUtils& operator =(const AliEMCALRawUtils& rawUtils);

  void Digits2Raw();
  void Raw2Digits(AliRawReader *reader,TClonesArray *digitsArr);

  void AddDigit(TClonesArray *digitsArr, Int_t id, Int_t lowGain, Int_t amp, Float_t time);

  // Signal shape parameters
  Double_t GetRawFormatHighLowGainFactor() const { return fHighLowGainFactor ;}
  Int_t GetRawFormatOrder()                const { return fOrder ; }   
  Double_t GetRawFormatTau()               const { return fTau ; }    
  Int_t GetNoiseThreshold()                const { return fNoiseThreshold; }
  Int_t GetNPedSamples()                   const { return fNPedSamples; }
  // get methods for fast fit simulation
  Double_t GetPedestalValue()  const {return fgPedestalValue;}
  Double_t GetFEENoise()       const {return fgFEENoise;}

  void SetRawFormatHighLowGainFactor(Double_t val) {fHighLowGainFactor=val;}
  void SetRawFormatOrder(Int_t val)                {fOrder=val; }   
  void SetRawFormatTau(Double_t val)               {fTau=val; }    
  void SetNoiseThreshold(Int_t val)                {fNoiseThreshold=val; }
  void SetNPedSamples(Int_t val)                   {fNPedSamples=val; }
  // set methods for fast fit simulation
  void SetFEENoise(Double_t val)                   {fgFEENoise = val;}
  void SetRawFormatTimeBins(Int_t val)             {fgTimeBins = val;}

  static Int_t GetRawFormatTimeBins() { return fgTimeBins ; }    
  static Double_t GetRawFormatTimeMax() { return fgTimeBins*fgTimeBinWidth; }   
  static Double_t GetRawFormatTimeBinWidth() { return fgTimeBinWidth; }   
  static Double_t GetRawFormatTimeBin() 
  { return GetRawFormatTimeMax() / GetRawFormatTimeBins(); }   
  Double_t GetRawFormatTimeTrigger() const { return fgTimeTrigger ; }
  Int_t GetRawFormatThreshold() const { return fgThreshold ; }       
  Int_t GetRawFormatDDLPerSuperModule() const { return fgDDLPerSuperModule ; } 

  virtual Option_t* GetOption() const { return fOption.Data(); }
  void SetOption(Option_t* opt) { fOption = opt; }

  // Signal shape functions
  void FitRaw(TGraph * gSig, TF1* signalF, Float_t & amp, Float_t & time) const ;
  static Double_t RawResponseFunction(Double_t *x, Double_t *par); 
  Bool_t   RawSampledResponse(Double_t dtime, Double_t damp, Int_t * adcH, Int_t * adcL) const;  


 private:
  Double_t fHighLowGainFactor ;         // high to low gain factor for the raw RO signal
  Int_t fOrder ;                        // order of the gamma function for the RO signal
  Double_t fTau ;                       // tau parameter of gamma function for the RO signal
  Int_t fNoiseThreshold;                // threshold to consider signal or noise
  Int_t fNPedSamples;                   // number of samples to use in pedestal calculation

  static const Int_t fgkOverflowCut = 950;  // cut to discriminate overflowed channels
  static const Int_t fgkRawSignalOverflow = 0x3FF; // maximum signal (10 bits)
  static Int_t fgTimeBins; // number of sampling bins of the raw RO signal  

  static Double_t fgTimeTrigger ;       // time of the trigger for the RO signal 
  static Double_t fgTimeBinWidth;       // maximum sampled time of the raw RO signal                             
  static Int_t fgThreshold;             // threshold
  static Int_t fgDDLPerSuperModule;     // number of DDL per SuperModule
  static Int_t fgPedestalValue;         // pedestal value for Digits2Raw
  static Double_t fgFEENoise;           // electronics noise in ADC units

  AliEMCALGeometry* fGeom;         //geometry
  AliAltroMapping*  fMapping[4];   //only two for now

  TString fOption;                      //! option passed from Reconstructor

  ClassDef(AliEMCALRawUtils,3)          // utilities for raw signal fitting
};

#endif
Commit	Line	Data
ee299369	1	#ifndef ALIEMCALRAWUTILS_H
	2	#define ALIEMCALRAWUTILS_H
	3	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
	5
	6	/* $Id$ */
e5bbbc4e	7
ee299369	8	//_________________________________________________________________________
	9	// Utility Class for handling Raw data
	10	// Does all transitions from Digits to Raw and vice versa,
	11	// for simu and reconstruction
	12	//
	13	// Note: the current version is still simplified. Only
	14	// one raw signal per digit is generated; either high-gain or low-gain
	15	// Need to add concurrent high and low-gain info in the future
	16	// No pedestal is added to the raw signal.
	17	//
	18	//*-- Author: Marco van Leeuwen (LBL)
	19	//
	20	#include "TObject.h" // for ROOT types
feedcab9	21	#include <TString.h>
32cd4c24	22	//#include "AliCaloRawStreamV3.h"
32cd4c24	23	class AliCaloRawStreamV3;
e5bbbc4e	24	class AliAltroMapping;
ee299369	25	class TGraph;
	26	class TF1;
	27	class AliRawReader;
65bdc82f	28	class AliEMCALGeometry;
ee299369	29
	30	class AliEMCALRawUtils : public TObject {
	31	public:
	32	AliEMCALRawUtils();
5544799a	33	AliEMCALRawUtils(AliEMCALGeometry *pGeometry);
ee299369	34	virtual ~AliEMCALRawUtils();
ee299369	35
65bdc82f	36	AliEMCALRawUtils(const AliEMCALRawUtils& rawUtils); //copy ctor
	37	AliEMCALRawUtils& operator =(const AliEMCALRawUtils& rawUtils);
	38
	39	void Digits2Raw();
	40	void Raw2Digits(AliRawReader reader,TClonesArray digitsArr);
	41
82cbdfca	42	void AddDigit(TClonesArray *digitsArr, Int_t id, Int_t lowGain, Int_t amp, Float_t time);
ee299369	43
ee299369	44	// Signal shape parameters
b4133f05	45	Double_t GetRawFormatHighLowGainFactor() const { return fHighLowGainFactor ;}
09974781	46	Int_t GetRawFormatOrder() const { return fOrder ; }
b4133f05	47	Double_t GetRawFormatTau() const { return fTau ; }
09974781	48	Int_t GetNoiseThreshold() const { return fNoiseThreshold; }
09974781	49	Int_t GetNPedSamples() const { return fNPedSamples; }
e2c2134b	50	// get methods for fast fit simulation
	51	Double_t GetPedestalValue() const {return fgPedestalValue;}
	52	Double_t GetFEENoise() const {return fgFEENoise;}
b4133f05	53
	54	void SetRawFormatHighLowGainFactor(Double_t val) {fHighLowGainFactor=val;}
	55	void SetRawFormatOrder(Int_t val) {fOrder=val; }
	56	void SetRawFormatTau(Double_t val) {fTau=val; }
	57	void SetNoiseThreshold(Int_t val) {fNoiseThreshold=val; }
	58	void SetNPedSamples(Int_t val) {fNPedSamples=val; }
e2c2134b	59	// set methods for fast fit simulation
	60	void SetFEENoise(Double_t val) {fgFEENoise = val;}
	61	void SetRawFormatTimeBins(Int_t val) {fgTimeBins = val;}
	62
	63	static Int_t GetRawFormatTimeBins() { return fgTimeBins ; }
	64	static Double_t GetRawFormatTimeMax() { return fgTimeBins*fgTimeBinWidth; }
82cbdfca	65	static Double_t GetRawFormatTimeBinWidth() { return fgTimeBinWidth; }
85c25c2e	66	static Double_t GetRawFormatTimeBin()
85c25c2e	67	{ return GetRawFormatTimeMax() / GetRawFormatTimeBins(); }
ee299369	68	Double_t GetRawFormatTimeTrigger() const { return fgTimeTrigger ; }
	69	Int_t GetRawFormatThreshold() const { return fgThreshold ; }
	70	Int_t GetRawFormatDDLPerSuperModule() const { return fgDDLPerSuperModule ; }
	71
feedcab9	72	virtual Option_t* GetOption() const { return fOption.Data(); }
	73	void SetOption(Option_t* opt) { fOption = opt; }
	74
ee299369	75	// Signal shape functions
e5bbbc4e	76	void FitRaw(TGraph * gSig, TF1* signalF, Float_t & amp, Float_t & time) const ;
ee299369	77	static Double_t RawResponseFunction(Double_t x, Double_t par);
	78	Bool_t RawSampledResponse(Double_t dtime, Double_t damp, Int_t * adcH, Int_t * adcL) const;
	79
ee299369	80
	81	private:
	82	Double_t fHighLowGainFactor ; // high to low gain factor for the raw RO signal
b4133f05	83	Int_t fOrder ; // order of the gamma function for the RO signal
	84	Double_t fTau ; // tau parameter of gamma function for the RO signal
	85	Int_t fNoiseThreshold; // threshold to consider signal or noise
	86	Int_t fNPedSamples; // number of samples to use in pedestal calculation
ee299369	87
b4133f05	88	static const Int_t fgkOverflowCut = 950; // cut to discriminate overflowed channels
b4133f05	89	static const Int_t fgkRawSignalOverflow = 0x3FF; // maximum signal (10 bits)
e2c2134b	90	static Int_t fgTimeBins; // number of sampling bins of the raw RO signal
b4133f05	91
b4133f05	92	static Double_t fgTimeTrigger ; // time of the trigger for the RO signal
82cbdfca	93	static Double_t fgTimeBinWidth; // maximum sampled time of the raw RO signal
ee299369	94	static Int_t fgThreshold; // threshold
ee299369	95	static Int_t fgDDLPerSuperModule; // number of DDL per SuperModule
fe93d365	96	static Int_t fgPedestalValue; // pedestal value for Digits2Raw
fe93d365	97	static Double_t fgFEENoise; // electronics noise in ADC units
feedcab9	98
65bdc82f	99	AliEMCALGeometry* fGeom; //geometry
21cad85c	100	AliAltroMapping* fMapping[4]; //only two for now
65bdc82f	101
feedcab9	102	TString fOption; //! option passed from Reconstructor
b4133f05	103
fe93d365	104	ClassDef(AliEMCALRawUtils,3) // utilities for raw signal fitting
ee299369	105	};
	106
	107	#endif