[u/mrichter/AliRoot.git] / PHOS / AliPHOSGeometry.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.                  *
 **************************************************************************/

/* $Id$ */

//_________________________________________________________________________
// Geometry class  for PHOS : singleton  
// PHOS consists of the electromagnetic calorimeter (EMCA)
// and a charged particle veto either in the Subatech's version (PPSD)
// or in the IHEP's one (CPV).
// The EMCA/PPSD/CPV modules are parametrized so that any configuration
// can be easily implemented 
// The title is used to identify the version of CPV used.
//                  
//*-- Author: Yves Schutz (SUBATECH) & Dmitri Peressounko (RRC "KI" & SUBATECH)

// --- ROOT system ---

#include "TVector3.h"
#include "TRotation.h" 
#include "TFolder.h" 
#include "TROOT.h" 

// --- Standard library ---

#include <iostream.h>
#include <stdlib.h>

// --- AliRoot header files ---

#include "AliPHOSGeometry.h"
#include "AliPHOSEMCAGeometry.h" 
#include "AliPHOSRecPoint.h"
#include "AliConst.h"

ClassImp(AliPHOSGeometry) ;

// these initialisations are needed for a singleton
AliPHOSGeometry * AliPHOSGeometry::fgGeom = 0 ;
Bool_t            AliPHOSGeometry::fgInit = kFALSE ;

//____________________________________________________________________________
AliPHOSGeometry::~AliPHOSGeometry(void)
{
  // dtor

  if (fRotMatrixArray) fRotMatrixArray->Delete() ; 
  if (fRotMatrixArray) delete fRotMatrixArray ; 
  if (fPHOSAngle     ) delete[] fPHOSAngle ; 
}
//____________________________________________________________________________

void AliPHOSGeometry::Init(void)
{
  // Initializes the PHOS parameters :
  //  IHEP is the Protvino CPV (cathode pad chambers)
  //  GPS2 is the Subatech Pre-Shower (two micromegas sandwiching a passive lead converter)
  //  MIXT 4 PHOS modules withe the IHEP CPV qnd one PHOS module with the Subatche Pre-Shower
  
  fgInit     = kTRUE ; 
  
  fNModules     = 5;
  fAngle        = 20;
  
  fGeometryEMCA = new AliPHOSEMCAGeometry();
  
  fGeometryCPV  = new AliPHOSCPVGeometry ();
  
  fGeometrySUPP = new AliPHOSSupportGeometry();
  
  fPHOSAngle = new Float_t[fNModules] ;
  
  Float_t * emcParams = fGeometryEMCA->GetEMCParams() ;
  
  fPHOSParams[0] =  TMath::Max((Double_t)fGeometryCPV->GetCPVBoxSize(0)/2., 
			       (Double_t)(emcParams[0]*(fGeometryCPV->GetCPVBoxSize(1)+emcParams[3]) - 
				emcParams[1]* fGeometryCPV->GetCPVBoxSize(1))/emcParams[3] ) ;
  fPHOSParams[1] = emcParams[1] ;
  fPHOSParams[2] = TMath::Max((Double_t)emcParams[2], (Double_t)fGeometryCPV->GetCPVBoxSize(2)/2.);
  fPHOSParams[3] = emcParams[3] + fGeometryCPV->GetCPVBoxSize(1)/2. ;
  
  fIPtoUpperCPVsurface = fGeometryEMCA->GetIPtoOuterCoverDistance() - fGeometryCPV->GetCPVBoxSize(1) ;
  
  Int_t index ;
  for ( index = 0; index < fNModules; index++ )
    fPHOSAngle[index] = 0.0 ; // Module position angles are set in CreateGeometry()
  
  this->SetPHOSAngles() ; 
  fRotMatrixArray = new TObjArray(fNModules) ; 
  
}


//____________________________________________________________________________
AliPHOSGeometry *  AliPHOSGeometry::GetInstance() 
{ 
  // Returns the pointer of the unique instance; singleton specific
  
  return (AliPHOSGeometry *) fgGeom ; 
}

//____________________________________________________________________________
AliPHOSGeometry *  AliPHOSGeometry::GetInstance(const Text_t* name, const Text_t* title) 
{
  // Returns the pointer of the unique instance
  // Creates it with the specified options (name, title) if it does not exist yet

  AliPHOSGeometry * rv = 0  ; 
  if ( fgGeom == 0 ) {
    if ( strcmp(name,"") == 0 ) 
      rv = 0 ;
    else {    
      fgGeom = new AliPHOSGeometry(name, title) ;
      if ( fgInit )
	rv = (AliPHOSGeometry * ) fgGeom ;
      else {
	rv = 0 ; 
	delete fgGeom ; 
	fgGeom = 0 ; 
      }
    }
  }
  else {
    if ( strcmp(fgGeom->GetName(), name) != 0 ) {
      cout << "AliPHOSGeometry <E> : current geometry is " << fgGeom->GetName() << endl
	   << "                      you cannot call     " << name << endl ; 
    }
    else
      rv = (AliPHOSGeometry *) fgGeom ; 
  } 
  return rv ; 
}

//____________________________________________________________________________
void AliPHOSGeometry::SetPHOSAngles() 
{ 
  // Calculates the position of the PHOS modules in ALICE global coordinate system
  
  Double_t const kRADDEG = 180.0 / kPI ;
  Float_t pphi =  2 * TMath::ATan( GetOuterBoxSize(0)  / ( 2.0 * GetIPtoUpperCPVsurface() ) ) ;
  pphi *= kRADDEG ;
  if (pphi > fAngle){ 
    cout << "AliPHOSGeometry: PHOS modules overlap!\n";
    cout <<  "pphi = " << pphi << " fAngle  " << fAngle << endl ;

  }
  pphi = fAngle;
  
  for( Int_t i = 1; i <= fNModules ; i++ ) {
    Float_t angle = pphi * ( i - fNModules / 2.0 - 0.5 ) ;
    fPHOSAngle[i-1] = -  angle ;
  } 
}

//____________________________________________________________________________
Bool_t AliPHOSGeometry::AbsToRelNumbering(const Int_t AbsId, Int_t * relid) const
{
  // Converts the absolute numbering into the following array/
  //  relid[0] = PHOS Module number 1:fNModules 
  //  relid[1] = 0 if PbW04
  //           = -1 if CPV
  //  relid[2] = Row number inside a PHOS module
  //  relid[3] = Column number inside a PHOS module

  Bool_t rv  = kTRUE ; 
  Float_t id = AbsId ;

  Int_t phosmodulenumber = (Int_t)TMath:: Ceil( id / GetNCristalsInModule() ) ; 
  
  if ( phosmodulenumber >  GetNModules() ) { // it is a CPV pad
    
    id -=  GetNPhi() * GetNZ() *  GetNModules() ; 
    Float_t nCPV  = GetNumberOfCPVPadsPhi() * GetNumberOfCPVPadsZ() ;
    relid[0] = (Int_t) TMath::Ceil( id / nCPV ) ;
    relid[1] = -1 ;
    id -= ( relid[0] - 1 ) * nCPV ; 
    relid[2] = (Int_t) TMath::Ceil( id / GetNumberOfCPVPadsZ() ) ;
    relid[3] = (Int_t) ( id - ( relid[2] - 1 ) * GetNumberOfCPVPadsZ() ) ; 
  } 
  else { // it is a PW04 crystal

    relid[0] = phosmodulenumber ;
    relid[1] = 0 ;
    id -= ( phosmodulenumber - 1 ) *  GetNPhi() * GetNZ() ; 
    relid[2] = (Int_t)TMath::Ceil( id / GetNZ() )  ;
    relid[3] = (Int_t)( id - ( relid[2] - 1 ) * GetNZ() ) ; 
  } 
  return rv ; 
}

//____________________________________________________________________________  
void AliPHOSGeometry::EmcModuleCoverage(const Int_t mod, Double_t & tm, Double_t & tM, Double_t & pm, Double_t & pM, Option_t * opt) const 
{
  // calculates the angular coverage in theta and phi of one EMC (=PHOS) module

 Double_t conv ; 
  if ( opt == Radian() ) 
    conv = 1. ; 
  else if ( opt == Degre() )
    conv = 180. / TMath::Pi() ; 
  else {
    cout << "<I>  AliPHOSGeometry::EmcXtalCoverage : " << opt << " unknown option; result in radian " << endl ; 
    conv = 1. ;
      }

  Float_t phi = GetPHOSAngle(mod) *  (TMath::Pi() / 180.)  ;  
  Float_t y0  = GetIPtoCrystalSurface() ; 
  Float_t * strip = fGeometryEMCA->GetStripHalfSize() ;
  Float_t x0  = fGeometryEMCA->GetNStripX()*strip[0] ;
  Float_t z0  = fGeometryEMCA->GetNStripZ()*strip[2] ;
  Double_t angle = TMath::ATan( x0 / y0 ) ;
  phi = phi + 1.5 * TMath::Pi() ; // to follow the convention of the particle generator(PHOS is between 220 and 320 deg.)
  Double_t max  = phi - angle ;
  Double_t min   = phi + angle ;
  pM = TMath::Max(max, min) * conv ;
  pm = TMath::Min(max, min) * conv ; 
  
  angle =  TMath::ATan( z0 /  y0 ) ;
  max  = TMath::Pi() / 2.  + angle ; // to follow the convention of the particle generator(PHOS is at 90 deg.)
  min  = TMath::Pi() / 2.  - angle ;
  tM = TMath::Max(max, min) * conv ;
  tm = TMath::Min(max, min) * conv ; 
 
}

//____________________________________________________________________________  
void AliPHOSGeometry::EmcXtalCoverage(Double_t & theta, Double_t & phi, Option_t * opt) const
{
  // calculates the angular coverage in theta and phi of a single crystal in a EMC(=PHOS) module

  Double_t conv ; 
  if ( opt == Radian() ) 
    conv = 1. ; 
  else if ( opt == Degre() )
    conv = 180. / TMath::Pi() ; 
  else {
    cout << "<I>  AliPHOSGeometry::EmcXtalCoverage : " << opt << " unknown option; result in radian " << endl ; 
    conv = 1. ;
      }

  Float_t y0  = GetIPtoCrystalSurface() ; 
  theta = 2 * TMath::ATan( GetCrystalSize(2) / (2 * y0) ) * conv ;
  phi   = 2 * TMath::ATan( GetCrystalSize(0) / (2 * y0) ) * conv ;
}
 

//____________________________________________________________________________
void AliPHOSGeometry::GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos, TMatrix & gmat) const
{
  // Calculates the coordinates of a RecPoint and the error matrix in the ALICE global coordinate system
 
  AliPHOSRecPoint * tmpPHOS = (AliPHOSRecPoint *) RecPoint ;  
  TVector3 localposition ;

  tmpPHOS->GetLocalPosition(gpos) ;


  if ( tmpPHOS->IsEmc() ) // it is a EMC crystal 
    {  gpos.SetY( - GetIPtoCrystalSurface()) ;  

    }
  else
    { // it is a CPV
      gpos.SetY(- GetIPtoUpperCPVsurface()  ) ; 
    }  

  Float_t phi           = GetPHOSAngle( tmpPHOS->GetPHOSMod()) ; 
  Double_t const kRADDEG = 180.0 / kPI ;
  Float_t rphi          = phi / kRADDEG ; 
  
  TRotation rot ;
  rot.RotateZ(-rphi) ; // a rotation around Z by angle  
  
  TRotation dummy = rot.Invert() ;  // to transform from original frame to rotate frame
  gpos.Transform(rot) ; // rotate the baby 

}

//____________________________________________________________________________
void AliPHOSGeometry::GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos) const 
{
  // Calculates the coordinates of a RecPoint in the ALICE global coordinate system 

  AliPHOSRecPoint * tmpPHOS = (AliPHOSRecPoint *) RecPoint ;  
  TVector3 localposition ;
  tmpPHOS->GetLocalPosition(gpos) ;


  if ( tmpPHOS->IsEmc() ) // it is a EMC crystal 
    {  gpos.SetY( - GetIPtoCrystalSurface()  ) ;  
    }
  else
    { // it is a CPV
	  gpos.SetY(- GetIPtoUpperCPVsurface()  ) ; 
    }  

  Float_t phi           = GetPHOSAngle( tmpPHOS->GetPHOSMod()) ; 
  Double_t const kRADDEG = 180.0 / kPI ;
  Float_t rphi          = phi / kRADDEG ; 
  
  TRotation rot ;
  rot.RotateZ(-rphi) ; // a rotation around Z by angle  
  
  TRotation dummy = rot.Invert() ;  // to transform from original frame to rotate frame
  gpos.Transform(rot) ; // rotate the baby 
}

//____________________________________________________________________________
void AliPHOSGeometry::ImpactOnEmc(const Double_t theta, const Double_t phi, Int_t & ModuleNumber, Double_t & z, Double_t & x) const
{
  // calculates the impact coordinates on PHOS of a neutral particle  
  // emitted in the direction theta and phi in the ALICE global coordinate system

  // searches for the PHOS EMC module
  ModuleNumber = 0 ; 
  Double_t tm, tM, pm, pM ; 
  Int_t index = 1 ; 
  while ( ModuleNumber == 0 && index <= GetNModules() ) { 
    EmcModuleCoverage(index, tm, tM, pm, pM) ; 
    if ( (theta >= tm && theta <= tM) && (phi >= pm && phi <= pM ) ) 
      ModuleNumber = index ; 
    index++ ;    
  }
  if ( ModuleNumber != 0 ) {
    Float_t phi0 =  GetPHOSAngle(ModuleNumber) *  (TMath::Pi() / 180.) + 1.5 * TMath::Pi()  ;  
    Float_t y0  =  GetIPtoCrystalSurface()  ;   
    Double_t angle = phi - phi0; 
    x = y0 * TMath::Tan(angle) ; 
    angle = theta - TMath::Pi() / 2 ; 
    z = y0 * TMath::Tan(angle) ; 
  }
}

//____________________________________________________________________________
Bool_t AliPHOSGeometry::RelToAbsNumbering(const Int_t * relid, Int_t &  AbsId) const
{
  // Converts the relative numbering into the absolute numbering
  // EMCA crystals:
  //  AbsId = from 1 to fNModules * fNPhi * fNZ
  // CPV pad:
  //  AbsId = from N(total PHOS crystals) + 1
  //          to NCPVModules * fNumberOfCPVPadsPhi * fNumberOfCPVPadsZ

  Bool_t rv = kTRUE ; 
  
  if ( relid[1] ==  0 ) {                            // it is a Phos crystal
    AbsId =
      ( relid[0] - 1 ) * GetNPhi() * GetNZ()         // the offset of PHOS modules
      + ( relid[2] - 1 ) * GetNZ()                   // the offset along phi
      +   relid[3] ;                                 // the offset along z
  }
  else { // it is a CPV pad
    AbsId =    GetNPhi() * GetNZ() *  GetNModules()         // the offset to separate EMCA crystals from CPV pads
      + ( relid[0] - 1 ) * GetNumberOfCPVPadsPhi() * GetNumberOfCPVPadsZ()   // the pads offset of PHOS modules 
      + ( relid[2] - 1 ) * GetNumberOfCPVPadsZ()                             // the pads offset of a CPV row
      +   relid[3] ;                                                         // the column number
  }
  
  return rv ; 
}

//____________________________________________________________________________

void AliPHOSGeometry::RelPosInAlice(const Int_t id, TVector3 & pos ) const
{
  // Converts the absolute numbering into the global ALICE coordinate system
  
    
    Int_t relid[4] ;
    
    AbsToRelNumbering(id , relid) ;
    
    Int_t phosmodule = relid[0] ; 
    
    Float_t y0 = 0 ; 
    
    if ( relid[1] == 0 )  // it is a PbW04 crystal 
      y0 =  - GetIPtoCrystalSurface() ;  
    else
      y0 =  - GetIPtoUpperCPVsurface() ; 

    Float_t x, z ; 
    RelPosInModule(relid, x, z) ; 
    
    pos.SetX(x) ;
    pos.SetZ(z) ;
    pos.SetY(y0) ;
    
    Float_t phi           = GetPHOSAngle( phosmodule) ; 
    Double_t const kRADDEG = 180.0 / kPI ;
    Float_t rphi          = phi / kRADDEG ; 
    
    TRotation rot ;
    rot.RotateZ(-rphi) ; // a rotation around Z by angle  
    
    TRotation dummy = rot.Invert() ;  // to transform from original frame to rotate frame
    
    pos.Transform(rot) ; // rotate the baby 
} 

//____________________________________________________________________________
void AliPHOSGeometry::RelPosInModule(const Int_t * relid, Float_t & x, Float_t & z) const 
{
  // Converts the relative numbering into the local PHOS-module (x, z) coordinates
  // Note: sign of z differs from that in the previous version (Yu.Kharlov, 12 Oct 2000)
  
  Int_t row        = relid[2] ; //offset along x axis
  Int_t column     = relid[3] ; //offset along z axis

  
  if ( relid[1] == 0 ) { // its a PbW04 crystal 
    x = - ( GetNPhi()/2. - row    + 0.5 ) *  GetCrystalSize(0) ; // position of Xtal with respect
    z =   ( GetNZ()  /2. - column + 0.5 ) *  GetCrystalSize(2) ; // of center of PHOS module  
  }  
  else  {    
    x = - ( GetNumberOfCPVPadsPhi()/2. - row    - 0.5 ) * GetPadSizePhi()  ; // position of pad  with respect
    z =   ( GetNumberOfCPVPadsZ()  /2. - column - 0.5 ) * GetPadSizeZ()  ; // of center of PHOS module  
  }
}
Commit	Line	Data
d15a28e7	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
b2a60966	16	/* $Id$ */
b2a60966	17
d15a28e7	18	//_________________________________________________________________________
b2a60966	19	// Geometry class for PHOS : singleton
a3dfe79c	20	// PHOS consists of the electromagnetic calorimeter (EMCA)
	21	// and a charged particle veto either in the Subatech's version (PPSD)
	22	// or in the IHEP's one (CPV).
	23	// The EMCA/PPSD/CPV modules are parametrized so that any configuration
	24	// can be easily implemented
	25	// The title is used to identify the version of CPV used.
b2a60966	26	//
710f859a	27	//*-- Author: Yves Schutz (SUBATECH) & Dmitri Peressounko (RRC "KI" & SUBATECH)
d15a28e7	28
	29	// --- ROOT system ---
	30
	31	#include "TVector3.h"
	32	#include "TRotation.h"
fa7cce36	33	#include "TFolder.h"
fa7cce36	34	#include "TROOT.h"
d15a28e7	35
	36	// --- Standard library ---
	37
de9ec31b	38	#include <iostream.h>
4410223b	39	#include <stdlib.h>
d15a28e7	40
	41	// --- AliRoot header files ---
	42
	43	#include "AliPHOSGeometry.h"
468794ea	44	#include "AliPHOSEMCAGeometry.h"
710f859a	45	#include "AliPHOSRecPoint.h"
d15a28e7	46	#include "AliConst.h"
d15a28e7	47
9ec91567	48	ClassImp(AliPHOSGeometry) ;
d15a28e7	49
a4e98857	50	// these initialisations are needed for a singleton
9ec91567	51	AliPHOSGeometry * AliPHOSGeometry::fgGeom = 0 ;
282c5906	52	Bool_t AliPHOSGeometry::fgInit = kFALSE ;
9ec91567	53
d15a28e7	54	//____________________________________________________________________________
	55	AliPHOSGeometry::~AliPHOSGeometry(void)
	56	{
b2a60966	57	// dtor
b2a60966	58
52a36ffd	59	if (fRotMatrixArray) fRotMatrixArray->Delete() ;
52a36ffd	60	if (fRotMatrixArray) delete fRotMatrixArray ;
fa0bc588	61	if (fPHOSAngle ) delete[] fPHOSAngle ;
52a36ffd	62	}
52a36ffd	63	//____________________________________________________________________________
	64
	65	void AliPHOSGeometry::Init(void)
	66	{
a4e98857	67	// Initializes the PHOS parameters :
	68	// IHEP is the Protvino CPV (cathode pad chambers)
	69	// GPS2 is the Subatech Pre-Shower (two micromegas sandwiching a passive lead converter)
	70	// MIXT 4 PHOS modules withe the IHEP CPV qnd one PHOS module with the Subatche Pre-Shower
710f859a	71
	72	fgInit = kTRUE ;
	73
	74	fNModules = 5;
	75	fAngle = 20;
	76
	77	fGeometryEMCA = new AliPHOSEMCAGeometry();
	78
	79	fGeometryCPV = new AliPHOSCPVGeometry ();
	80
	81	fGeometrySUPP = new AliPHOSSupportGeometry();
	82
	83	fPHOSAngle = new Float_t[fNModules] ;
	84
	85	Float_t * emcParams = fGeometryEMCA->GetEMCParams() ;
	86
581e32d4	87	fPHOSParams[0] = TMath::Max((Double_t)fGeometryCPV->GetCPVBoxSize(0)/2.,
581e32d4	88	(Double_t)(emcParams[0]*(fGeometryCPV->GetCPVBoxSize(1)+emcParams[3]) -
710f859a	89	emcParams[1]* fGeometryCPV->GetCPVBoxSize(1))/emcParams[3] ) ;
710f859a	90	fPHOSParams[1] = emcParams[1] ;
581e32d4	91	fPHOSParams[2] = TMath::Max((Double_t)emcParams[2], (Double_t)fGeometryCPV->GetCPVBoxSize(2)/2.);
710f859a	92	fPHOSParams[3] = emcParams[3] + fGeometryCPV->GetCPVBoxSize(1)/2. ;
	93
	94	fIPtoUpperCPVsurface = fGeometryEMCA->GetIPtoOuterCoverDistance() - fGeometryCPV->GetCPVBoxSize(1) ;
	95
	96	Int_t index ;
	97	for ( index = 0; index < fNModules; index++ )
52a36ffd	98	fPHOSAngle[index] = 0.0 ; // Module position angles are set in CreateGeometry()
710f859a	99
	100	this->SetPHOSAngles() ;
	101	fRotMatrixArray = new TObjArray(fNModules) ;
	102
52a36ffd	103	}
52a36ffd	104
5ccb0008	105
52a36ffd	106	//____________________________________________________________________________
	107	AliPHOSGeometry * AliPHOSGeometry::GetInstance()
	108	{
a4e98857	109	// Returns the pointer of the unique instance; singleton specific
a4e98857	110
52a36ffd	111	return (AliPHOSGeometry *) fgGeom ;
	112	}
	113
	114	//____________________________________________________________________________
	115	AliPHOSGeometry * AliPHOSGeometry::GetInstance(const Text_t* name, const Text_t* title)
	116	{
	117	// Returns the pointer of the unique instance
a4e98857	118	// Creates it with the specified options (name, title) if it does not exist yet
a4e98857	119
52a36ffd	120	AliPHOSGeometry * rv = 0 ;
	121	if ( fgGeom == 0 ) {
	122	if ( strcmp(name,"") == 0 )
	123	rv = 0 ;
	124	else {
	125	fgGeom = new AliPHOSGeometry(name, title) ;
	126	if ( fgInit )
	127	rv = (AliPHOSGeometry * ) fgGeom ;
	128	else {
	129	rv = 0 ;
	130	delete fgGeom ;
	131	fgGeom = 0 ;
	132	}
	133	}
	134	}
	135	else {
	136	if ( strcmp(fgGeom->GetName(), name) != 0 ) {
	137	cout << "AliPHOSGeometry <E> : current geometry is " << fgGeom->GetName() << endl
	138	<< " you cannot call " << name << endl ;
	139	}
	140	else
	141	rv = (AliPHOSGeometry *) fgGeom ;
	142	}
	143	return rv ;
	144	}
4697edca	145
52a36ffd	146	//____________________________________________________________________________
	147	void AliPHOSGeometry::SetPHOSAngles()
	148	{
a4e98857	149	// Calculates the position of the PHOS modules in ALICE global coordinate system
52a36ffd	150
52a36ffd	151	Double_t const kRADDEG = 180.0 / kPI ;
710f859a	152	Float_t pphi = 2 * TMath::ATan( GetOuterBoxSize(0) / ( 2.0 * GetIPtoUpperCPVsurface() ) ) ;
52a36ffd	153	pphi *= kRADDEG ;
710f859a	154	if (pphi > fAngle){
	155	cout << "AliPHOSGeometry: PHOS modules overlap!\n";
	156	cout << "pphi = " << pphi << " fAngle " << fAngle << endl ;
	157
	158	}
ed4205d8	159	pphi = fAngle;
52a36ffd	160
52a36ffd	161	for( Int_t i = 1; i <= fNModules ; i++ ) {
ed4205d8	162	Float_t angle = pphi * ( i - fNModules / 2.0 - 0.5 ) ;
52a36ffd	163	fPHOSAngle[i-1] = - angle ;
52a36ffd	164	}
d15a28e7	165	}
	166
	167	//____________________________________________________________________________
7b7c1533	168	Bool_t AliPHOSGeometry::AbsToRelNumbering(const Int_t AbsId, Int_t * relid) const
d15a28e7	169	{
b2a60966	170	// Converts the absolute numbering into the following array/
	171	// relid[0] = PHOS Module number 1:fNModules
	172	// relid[1] = 0 if PbW04
710f859a	173	// = -1 if CPV
	174	// relid[2] = Row number inside a PHOS module
	175	// relid[3] = Column number inside a PHOS module
d15a28e7	176
d15a28e7	177	Bool_t rv = kTRUE ;
92862013	178	Float_t id = AbsId ;
d15a28e7	179
710f859a	180	Int_t phosmodulenumber = (Int_t)TMath:: Ceil( id / GetNCristalsInModule() ) ;
d15a28e7	181
710f859a	182	if ( phosmodulenumber > GetNModules() ) { // it is a CPV pad
	183
	184	id -= GetNPhi() * GetNZ() * GetNModules() ;
	185	Float_t nCPV = GetNumberOfCPVPadsPhi() * GetNumberOfCPVPadsZ() ;
	186	relid[0] = (Int_t) TMath::Ceil( id / nCPV ) ;
	187	relid[1] = -1 ;
	188	id -= ( relid[0] - 1 ) * nCPV ;
	189	relid[2] = (Int_t) TMath::Ceil( id / GetNumberOfCPVPadsZ() ) ;
	190	relid[3] = (Int_t) ( id - ( relid[2] - 1 ) * GetNumberOfCPVPadsZ() ) ;
d15a28e7	191	}
710f859a	192	else { // it is a PW04 crystal
d15a28e7	193
92862013	194	relid[0] = phosmodulenumber ;
	195	relid[1] = 0 ;
	196	id -= ( phosmodulenumber - 1 ) * GetNPhi() * GetNZ() ;
710f859a	197	relid[2] = (Int_t)TMath::Ceil( id / GetNZ() ) ;
710f859a	198	relid[3] = (Int_t)( id - ( relid[2] - 1 ) * GetNZ() ) ;
d15a28e7	199	}
	200	return rv ;
	201	}
52a36ffd	202
9f616d61	203	//____________________________________________________________________________
7b7c1533	204	void AliPHOSGeometry::EmcModuleCoverage(const Int_t mod, Double_t & tm, Double_t & tM, Double_t & pm, Double_t & pM, Option_t * opt) const
9f616d61	205	{
a4e98857	206	// calculates the angular coverage in theta and phi of one EMC (=PHOS) module
9f616d61	207
9f616d61	208	Double_t conv ;
cf0c2bc1	209	if ( opt == Radian() )
9f616d61	210	conv = 1. ;
cf0c2bc1	211	else if ( opt == Degre() )
9f616d61	212	conv = 180. / TMath::Pi() ;
	213	else {
	214	cout << "<I> AliPHOSGeometry::EmcXtalCoverage : " << opt << " unknown option; result in radian " << endl ;
	215	conv = 1. ;
	216	}
	217
710f859a	218	Float_t phi = GetPHOSAngle(mod) * (TMath::Pi() / 180.) ;
	219	Float_t y0 = GetIPtoCrystalSurface() ;
	220	Float_t * strip = fGeometryEMCA->GetStripHalfSize() ;
	221	Float_t x0 = fGeometryEMCA->GetNStripX()*strip[0] ;
	222	Float_t z0 = fGeometryEMCA->GetNStripZ()*strip[2] ;
	223	Double_t angle = TMath::ATan( x0 / y0 ) ;
	224	phi = phi + 1.5 * TMath::Pi() ; // to follow the convention of the particle generator(PHOS is between 220 and 320 deg.)
92862013	225	Double_t max = phi - angle ;
	226	Double_t min = phi + angle ;
	227	pM = TMath::Max(max, min) * conv ;
	228	pm = TMath::Min(max, min) * conv ;
9f616d61	229
710f859a	230	angle = TMath::ATan( z0 / y0 ) ;
92862013	231	max = TMath::Pi() / 2. + angle ; // to follow the convention of the particle generator(PHOS is at 90 deg.)
	232	min = TMath::Pi() / 2. - angle ;
	233	tM = TMath::Max(max, min) * conv ;
	234	tm = TMath::Min(max, min) * conv ;
9f616d61	235
	236	}
	237
	238	//____________________________________________________________________________
7b7c1533	239	void AliPHOSGeometry::EmcXtalCoverage(Double_t & theta, Double_t & phi, Option_t * opt) const
9f616d61	240	{
a4e98857	241	// calculates the angular coverage in theta and phi of a single crystal in a EMC(=PHOS) module
9f616d61	242
9f616d61	243	Double_t conv ;
cf0c2bc1	244	if ( opt == Radian() )
9f616d61	245	conv = 1. ;
cf0c2bc1	246	else if ( opt == Degre() )
9f616d61	247	conv = 180. / TMath::Pi() ;
	248	else {
	249	cout << "<I> AliPHOSGeometry::EmcXtalCoverage : " << opt << " unknown option; result in radian " << endl ;
	250	conv = 1. ;
	251	}
	252
710f859a	253	Float_t y0 = GetIPtoCrystalSurface() ;
92862013	254	theta = 2 * TMath::ATan( GetCrystalSize(2) / (2 * y0) ) * conv ;
92862013	255	phi = 2 * TMath::ATan( GetCrystalSize(0) / (2 * y0) ) * conv ;
9f616d61	256	}
	257
	258
	259	//____________________________________________________________________________
52a36ffd	260	void AliPHOSGeometry::GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos, TMatrix & gmat) const
d15a28e7	261	{
a4e98857	262	// Calculates the coordinates of a RecPoint and the error matrix in the ALICE global coordinate system
b2a60966	263
d15a28e7	264	AliPHOSRecPoint * tmpPHOS = (AliPHOSRecPoint *) RecPoint ;
92862013	265	TVector3 localposition ;
d15a28e7	266
	267	tmpPHOS->GetLocalPosition(gpos) ;
	268
	269
	270	if ( tmpPHOS->IsEmc() ) // it is a EMC crystal
710f859a	271	{ gpos.SetY( - GetIPtoCrystalSurface()) ;
d15a28e7	272
	273	}
	274	else
710f859a	275	{ // it is a CPV
710f859a	276	gpos.SetY(- GetIPtoUpperCPVsurface() ) ;
d15a28e7	277	}
d15a28e7	278
92862013	279	Float_t phi = GetPHOSAngle( tmpPHOS->GetPHOSMod()) ;
	280	Double_t const kRADDEG = 180.0 / kPI ;
	281	Float_t rphi = phi / kRADDEG ;
d15a28e7	282
92862013	283	TRotation rot ;
92862013	284	rot.RotateZ(-rphi) ; // a rotation around Z by angle
d15a28e7	285
92862013	286	TRotation dummy = rot.Invert() ; // to transform from original frame to rotate frame
92862013	287	gpos.Transform(rot) ; // rotate the baby
6ad0bfa0	288
d15a28e7	289	}
	290
	291	//____________________________________________________________________________
5cda30f6	292	void AliPHOSGeometry::GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos) const
d15a28e7	293	{
a4e98857	294	// Calculates the coordinates of a RecPoint in the ALICE global coordinate system
b2a60966	295
d15a28e7	296	AliPHOSRecPoint * tmpPHOS = (AliPHOSRecPoint *) RecPoint ;
92862013	297	TVector3 localposition ;
d15a28e7	298	tmpPHOS->GetLocalPosition(gpos) ;
	299
	300
	301	if ( tmpPHOS->IsEmc() ) // it is a EMC crystal
710f859a	302	{ gpos.SetY( - GetIPtoCrystalSurface() ) ;
d15a28e7	303	}
d15a28e7	304	else
710f859a	305	{ // it is a CPV
710f859a	306	gpos.SetY(- GetIPtoUpperCPVsurface() ) ;
d15a28e7	307	}
d15a28e7	308
92862013	309	Float_t phi = GetPHOSAngle( tmpPHOS->GetPHOSMod()) ;
	310	Double_t const kRADDEG = 180.0 / kPI ;
	311	Float_t rphi = phi / kRADDEG ;
d15a28e7	312
92862013	313	TRotation rot ;
92862013	314	rot.RotateZ(-rphi) ; // a rotation around Z by angle
d15a28e7	315
92862013	316	TRotation dummy = rot.Invert() ; // to transform from original frame to rotate frame
92862013	317	gpos.Transform(rot) ; // rotate the baby
d15a28e7	318	}
	319
	320	//____________________________________________________________________________
7b7c1533	321	void AliPHOSGeometry::ImpactOnEmc(const Double_t theta, const Double_t phi, Int_t & ModuleNumber, Double_t & z, Double_t & x) const
d15a28e7	322	{
a4e98857	323	// calculates the impact coordinates on PHOS of a neutral particle
a4e98857	324	// emitted in the direction theta and phi in the ALICE global coordinate system
d15a28e7	325
52a36ffd	326	// searches for the PHOS EMC module
	327	ModuleNumber = 0 ;
	328	Double_t tm, tM, pm, pM ;
	329	Int_t index = 1 ;
	330	while ( ModuleNumber == 0 && index <= GetNModules() ) {
	331	EmcModuleCoverage(index, tm, tM, pm, pM) ;
	332	if ( (theta >= tm && theta <= tM) && (phi >= pm && phi <= pM ) )
	333	ModuleNumber = index ;
	334	index++ ;
d15a28e7	335	}
52a36ffd	336	if ( ModuleNumber != 0 ) {
52a36ffd	337	Float_t phi0 = GetPHOSAngle(ModuleNumber) * (TMath::Pi() / 180.) + 1.5 * TMath::Pi() ;
710f859a	338	Float_t y0 = GetIPtoCrystalSurface() ;
52a36ffd	339	Double_t angle = phi - phi0;
	340	x = y0 * TMath::Tan(angle) ;
	341	angle = theta - TMath::Pi() / 2 ;
	342	z = y0 * TMath::Tan(angle) ;
d15a28e7	343	}
d15a28e7	344	}
	345
	346	//____________________________________________________________________________
7b7c1533	347	Bool_t AliPHOSGeometry::RelToAbsNumbering(const Int_t * relid, Int_t & AbsId) const
d15a28e7	348	{
b2a60966	349	// Converts the relative numbering into the absolute numbering
ed4205d8	350	// EMCA crystals:
ed4205d8	351	// AbsId = from 1 to fNModules * fNPhi * fNZ
ed4205d8	352	// CPV pad:
	353	// AbsId = from N(total PHOS crystals) + 1
	354	// to NCPVModules * fNumberOfCPVPadsPhi * fNumberOfCPVPadsZ
d15a28e7	355
d15a28e7	356	Bool_t rv = kTRUE ;
710f859a	357
710f859a	358	if ( relid[1] == 0 ) { // it is a Phos crystal
52a36ffd	359	AbsId =
710f859a	360	( relid[0] - 1 ) * GetNPhi() * GetNZ() // the offset of PHOS modules
	361	+ ( relid[2] - 1 ) * GetNZ() // the offset along phi
	362	+ relid[3] ; // the offset along z
d15a28e7	363	}
710f859a	364	else { // it is a CPV pad
	365	AbsId = GetNPhi() * GetNZ() * GetNModules() // the offset to separate EMCA crystals from CPV pads
	366	+ ( relid[0] - 1 ) * GetNumberOfCPVPadsPhi() * GetNumberOfCPVPadsZ() // the pads offset of PHOS modules
	367	+ ( relid[2] - 1 ) * GetNumberOfCPVPadsZ() // the pads offset of a CPV row
52a36ffd	368	+ relid[3] ; // the column number
	369	}
	370
d15a28e7	371	return rv ;
	372	}
	373
	374	//____________________________________________________________________________
	375
7b7c1533	376	void AliPHOSGeometry::RelPosInAlice(const Int_t id, TVector3 & pos ) const
d15a28e7	377	{
a4e98857	378	// Converts the absolute numbering into the global ALICE coordinate system
b2a60966	379
ed4205d8	380
	381	Int_t relid[4] ;
	382
	383	AbsToRelNumbering(id , relid) ;
	384
	385	Int_t phosmodule = relid[0] ;
	386
	387	Float_t y0 = 0 ;
	388
710f859a	389	if ( relid[1] == 0 ) // it is a PbW04 crystal
	390	y0 = - GetIPtoCrystalSurface() ;
	391	else
	392	y0 = - GetIPtoUpperCPVsurface() ;
	393
ed4205d8	394	Float_t x, z ;
	395	RelPosInModule(relid, x, z) ;
	396
	397	pos.SetX(x) ;
	398	pos.SetZ(z) ;
710f859a	399	pos.SetY(y0) ;
ed4205d8	400
	401	Float_t phi = GetPHOSAngle( phosmodule) ;
	402	Double_t const kRADDEG = 180.0 / kPI ;
	403	Float_t rphi = phi / kRADDEG ;
	404
	405	TRotation rot ;
	406	rot.RotateZ(-rphi) ; // a rotation around Z by angle
	407
	408	TRotation dummy = rot.Invert() ; // to transform from original frame to rotate frame
	409
	410	pos.Transform(rot) ; // rotate the baby
d15a28e7	411	}
	412
	413	//____________________________________________________________________________
7b7c1533	414	void AliPHOSGeometry::RelPosInModule(const Int_t * relid, Float_t & x, Float_t & z) const
d15a28e7	415	{
b2a60966	416	// Converts the relative numbering into the local PHOS-module (x, z) coordinates
52a36ffd	417	// Note: sign of z differs from that in the previous version (Yu.Kharlov, 12 Oct 2000)
b2a60966	418
786222b3	419	Int_t row = relid[2] ; //offset along x axis
786222b3	420	Int_t column = relid[3] ; //offset along z axis
d15a28e7	421
ed4205d8	422
92862013	423	if ( relid[1] == 0 ) { // its a PbW04 crystal
786222b3	424	x = - ( GetNPhi()/2. - row + 0.5 ) * GetCrystalSize(0) ; // position of Xtal with respect
52a36ffd	425	z = ( GetNZ() /2. - column + 0.5 ) * GetCrystalSize(2) ; // of center of PHOS module
	426	}
	427	else {
710f859a	428	x = - ( GetNumberOfCPVPadsPhi()/2. - row - 0.5 ) * GetPadSizePhi() ; // position of pad with respect
710f859a	429	z = ( GetNumberOfCPVPadsZ() /2. - column - 0.5 ) * GetPadSizeZ() ; // of center of PHOS module
52a36ffd	430	}
2f3366b6	431	}