[u/mrichter/AliRoot.git] / FMD / AliFMDMultNaiive.cxx

/**************************************************************************
 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 *                                                                        *
 * Author: The ALICE Off-line Project.                                    *
 * Contributors are mentioned in the code where appropriate.              *
 *                                                                        *
 * 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.                  *
 **************************************************************************/

/* $Id$ */

//____________________________________________________________________
// 
// Reconstruct charged particle multiplicity in the FMD 
// 
// [See also the AliFMDReconstructor class]
// 
// This class reconstructs the multiplicity based on the assumption
// that all particles are minimum ionizing. 
// 
#include "AliFMD.h"			// ALIFMD_H
#include "AliFMDMultNaiive.h"		// ALIFMDMULTNAIIVE_H
#include "AliFMDParameters.h"           // ALIFMDPARAMETERS_H
#include "AliFMDMultStrip.h"		// ALIFMDMULTNAIIVE_H
#include "AliFMDDigit.h"		// ALIFMDDIGIT_H
#include <TClonesArray.h>               // ROOT_TClonesArray
#include <TTree.h>               	// ROOT_TTree

//____________________________________________________________________
ClassImp(AliFMDMultNaiive)
#if 0
  ; // This is here to keep Emacs for indenting the next line
#endif

//____________________________________________________________________
AliFMDMultNaiive::AliFMDMultNaiive()
  : AliFMDMultAlgorithm("Naiive", "Naiive")
{
  // Default CTOR
  fMult = new TClonesArray("AliFMDMultStrip", 1000);
}

//____________________________________________________________________
void
AliFMDMultNaiive::PreRun(AliFMD* fmd) 
{
  // Initialise before a run 
  AliFMDMultAlgorithm::PreRun(fmd);
  AliFMDParameters* pars = AliFMDParameters::Instance();
  fEdepMip = pars->GetEdepMip();
  fGain = (Float_t(pars->GetVA1MipRange()) / pars->GetAltroChannelSize() 
	   * fEdepMip);
}

//____________________________________________________________________
void
AliFMDMultNaiive::PreEvent(TTree* treeR, Float_t ipZ) 
{
  // Reset internal data 
  AliFMDMultAlgorithm::PreEvent(treeR, ipZ);  
  fTreeR->Branch("FMDNaiive", &fMult);
}

//____________________________________________________________________
void
AliFMDMultNaiive::ProcessDigit(AliFMDDigit* digit, 
			       Float_t eta, 
			       Float_t phi, 
			       UShort_t count)
{
  // Process one digit. 
  // 
  // Parameters: 
  //    
  //   digit		Digit to process 
  //   eta              Pseudo-rapidity of digit
  //   phi              Azimuthal angle of digit
  //   count            ADC (corrected for the pedestal)
  //
  // This calculates the energy deposited and the number of MIPs that
  // this energy deposition corresponds to 
  // 
  //   EnergyDeposited = cos(theta) * gain * count 
  //   Multiplicity    = EnergyDeposited / EnergyDepositedPerMIP
  // 
  // where gain is a conversion factor from number of counts to an
  // energy:
  //          Pre_Amp_MIP_Range           1
  //   gain = ----------------- * ---------------------
  //          ADC_channel_size    EnergyDepositedPerMip
  // 
  // and theta is the particles incident angle on the strip, given by 
  //
  //   theta = 2 * atan(exp(-eta))
  //
  // The cos(theta) factor corrects for the fact that the particle may
  // traverse the strip at an angle, and therefor have a longer flight
  // length, leading to a larger energy deposition. 
  // 
  if (!digit) return;
  Double_t edep  = Adc2Energy(digit, eta, count);
  Double_t mult  = Energy2Multiplicity(digit, edep);
  
  AliFMDMultStrip* m = 
    new ((*fMult)[fNMult]) AliFMDMultStrip(digit->Detector(), 
					   digit->Ring(), 
					   digit->Sector(),
					   digit->Strip(),
					   eta, phi, 
					   edep, mult,
				   AliFMDMult::kNaiive);
  (void)m;
  fNMult++;
}
//____________________________________________________________________
Float_t
AliFMDMultNaiive::Adc2Energy(AliFMDDigit* /* digit */, 
			     Float_t      eta, 
			     UShort_t     count) 
{
  // Converts number of ADC counts to energy deposited. 
  // Note, that this member function can be overloaded by derived
  // classes to do strip-specific look-ups in databases or the like,
  // to find the proper gain for a strip. 
  // 
  // In this simple version, we calculate the energy deposited as 
  // 
  //    EnergyDeposited = cos(theta) * gain * count
  // 
  // where 
  // 
  //           Pre_amp_MIP_Range
  //    gain = ----------------- * Energy_deposited_per_MIP
  //           ADC_channel_size    
  // 
  // is constant and the same for all strips. 
  Double_t theta = 2 * TMath::ATan(TMath::Exp(-eta));
  Double_t edep  = TMath::Abs(TMath::Cos(theta)) * fGain * count;
  return edep;
}

//____________________________________________________________________
Float_t
AliFMDMultNaiive::Energy2Multiplicity(AliFMDDigit* /* digit */, 
				      Float_t      edep)
{
  // Converts an energy signal to number of particles. 
  // Note, that this member function can be overloaded by derived
  // classes to do strip-specific look-ups in databases or the like,
  // to find the proper gain for a strip. 
  // 
  // In this simple version, we calculate the multiplicity as 
  // 
  //   multiplicity = Energy_deposited / Energy_deposited_per_MIP
  // 
  // where 
  //
  //   Energy_deposited_per_MIP = 1.664 * SI_density * SI_thickness 
  // 
  // is constant and the same for all strips 
  return edep / fEdepMip;
}


//____________________________________________________________________
// 
// EOF
//
Commit	Line	Data
56b1929b	1	/**************************************************************************
	2	* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	3	* *
	4	* Author: The ALICE Off-line Project. *
	5	* Contributors are mentioned in the code where appropriate. *
	6	* *
	7	* Permission to use, copy, modify and distribute this software and its *
	8	* documentation strictly for non-commercial purposes is hereby granted *
	9	* without fee, provided that the above copyright notice appears in all *
	10	* copies and that both the copyright notice and this permission notice *
	11	* appear in the supporting documentation. The authors make no claims *
	12	* about the suitability of this software for any purpose. It is *
	13	* provided "as is" without express or implied warranty. *
	14	**************************************************************************/
	15
	16	/* $Id$ */
	17
	18	//____________________________________________________________________
	19	//
7684b53c	20	// Reconstruct charged particle multiplicity in the FMD
	21	//
	22	// [See also the AliFMDReconstructor class]
	23	//
	24	// This class reconstructs the multiplicity based on the assumption
	25	// that all particles are minimum ionizing.
56b1929b	26	//
	27	#include "AliFMD.h" // ALIFMD_H
	28	#include "AliFMDMultNaiive.h" // ALIFMDMULTNAIIVE_H
1a1fdef7	29	#include "AliFMDParameters.h" // ALIFMDPARAMETERS_H
56b1929b	30	#include "AliFMDMultStrip.h" // ALIFMDMULTNAIIVE_H
	31	#include "AliFMDDigit.h" // ALIFMDDIGIT_H
	32	#include <TClonesArray.h> // ROOT_TClonesArray
	33	#include <TTree.h> // ROOT_TTree
	34
	35	//____________________________________________________________________
925e6570	36	ClassImp(AliFMDMultNaiive)
1a1fdef7	37	#if 0
	38	; // This is here to keep Emacs for indenting the next line
	39	#endif
56b1929b	40
	41	//____________________________________________________________________
	42	AliFMDMultNaiive::AliFMDMultNaiive()
	43	: AliFMDMultAlgorithm("Naiive", "Naiive")
	44	{
	45	// Default CTOR
	46	fMult = new TClonesArray("AliFMDMultStrip", 1000);
	47	}
	48
	49	//____________________________________________________________________
	50	void
	51	AliFMDMultNaiive::PreRun(AliFMD* fmd)
	52	{
	53	// Initialise before a run
	54	AliFMDMultAlgorithm::PreRun(fmd);
1a1fdef7	55	AliFMDParameters* pars = AliFMDParameters::Instance();
	56	fEdepMip = pars->GetEdepMip();
	57	fGain = (Float_t(pars->GetVA1MipRange()) / pars->GetAltroChannelSize()
56b1929b	58	* fEdepMip);
	59	}
	60
	61	//____________________________________________________________________
	62	void
	63	AliFMDMultNaiive::PreEvent(TTree* treeR, Float_t ipZ)
	64	{
	65	// Reset internal data
	66	AliFMDMultAlgorithm::PreEvent(treeR, ipZ);
	67	fTreeR->Branch("FMDNaiive", &fMult);
	68	}
	69
	70	//____________________________________________________________________
	71	void
	72	AliFMDMultNaiive::ProcessDigit(AliFMDDigit* digit,
	73	Float_t eta,
	74	Float_t phi,
	75	UShort_t count)
	76	{
	77	// Process one digit.
	78	//
	79	// Parameters:
	80	//
	81	// digit Digit to process
	82	// eta Pseudo-rapidity of digit
	83	// phi Azimuthal angle of digit
	84	// count ADC (corrected for the pedestal)
	85	//
	86	// This calculates the energy deposited and the number of MIPs that
	87	// this energy deposition corresponds to
	88	//
	89	// EnergyDeposited = cos(theta) * gain * count
	90	// Multiplicity = EnergyDeposited / EnergyDepositedPerMIP
	91	//
	92	// where gain is a conversion factor from number of counts to an
	93	// energy:
	94	// Pre_Amp_MIP_Range 1
	95	// gain = ----------------- * ---------------------
	96	// ADC_channel_size EnergyDepositedPerMip
	97	//
	98	// and theta is the particles incident angle on the strip, given by
	99	//
	100	// theta = 2 * atan(exp(-eta))
	101	//
	102	// The cos(theta) factor corrects for the fact that the particle may
	103	// traverse the strip at an angle, and therefor have a longer flight
	104	// length, leading to a larger energy deposition.
	105	//
	106	if (!digit) return;
	107	Double_t edep = Adc2Energy(digit, eta, count);
	108	Double_t mult = Energy2Multiplicity(digit, edep);
7684b53c	109
	110	AliFMDMultStrip* m =
	111	new ((*fMult)[fNMult]) AliFMDMultStrip(digit->Detector(),
	112	digit->Ring(),
	113	digit->Sector(),
	114	digit->Strip(),
	115	eta, phi,
	116	edep, mult,
	117	AliFMDMult::kNaiive);
	118	(void)m;
56b1929b	119	fNMult++;
	120	}
	121	//____________________________________________________________________
	122	Float_t
	123	AliFMDMultNaiive::Adc2Energy(AliFMDDigit* /* digit */,
	124	Float_t eta,
	125	UShort_t count)
	126	{
	127	// Converts number of ADC counts to energy deposited.
	128	// Note, that this member function can be overloaded by derived
	129	// classes to do strip-specific look-ups in databases or the like,
	130	// to find the proper gain for a strip.
	131	//
	132	// In this simple version, we calculate the energy deposited as
	133	//
	134	// EnergyDeposited = cos(theta) * gain * count
	135	//
	136	// where
	137	//
	138	// Pre_amp_MIP_Range
	139	// gain = ----------------- * Energy_deposited_per_MIP
	140	// ADC_channel_size
	141	//
	142	// is constant and the same for all strips.
21888c5f	143	Double_t theta = 2 * TMath::ATan(TMath::Exp(-eta));
c263f0ab	144	Double_t edep = TMath::Abs(TMath::Cos(theta)) * fGain * count;
56b1929b	145	return edep;
	146	}
	147
	148	//____________________________________________________________________
	149	Float_t
	150	AliFMDMultNaiive::Energy2Multiplicity(AliFMDDigit* /* digit */,
	151	Float_t edep)
	152	{
	153	// Converts an energy signal to number of particles.
	154	// Note, that this member function can be overloaded by derived
	155	// classes to do strip-specific look-ups in databases or the like,
	156	// to find the proper gain for a strip.
	157	//
	158	// In this simple version, we calculate the multiplicity as
	159	//
	160	// multiplicity = Energy_deposited / Energy_deposited_per_MIP
	161	//
	162	// where
	163	//
	164	// Energy_deposited_per_MIP = 1.664 * SI_density * SI_thickness
	165	//
	166	// is constant and the same for all strips
	167	return edep / fEdepMip;
	168	}
	169
	170
	171
	172	//____________________________________________________________________
	173	//
	174	// EOF
	175	//