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

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

////////////////////////////////////////////////
//  Geometry class  for PHOS : singleton      //
//  Version SUBATECH                          //
//  Author  Y. Schutz SUBATECH                //
//       geometry parametrized for any        //  
//       shape of modules                     //
////////////////////////////////////////////////

// --- ROOT system ---

#include "TNamed.h"
#include "TString.h"
#include "TObjArray.h"
#include "TVector3.h" 

// --- AliRoot header files ---

#include "AliGeometry.h"
#include "AliPHOSRecPoint.h"

static const TString kDegre("deg") ; 
static const TString kRadian("rad") ; 

class AliPHOSGeometry : public AliGeometry {

public: 

  AliPHOSGeometry() {} ;  // must be kept public for root persistency purposes
  virtual ~AliPHOSGeometry(void) ; 
  static AliPHOSGeometry * GetInstance(const Text_t* name, const Text_t* title) ; 
  static AliPHOSGeometry * GetInstance() ; 
  virtual void  GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos, TMatrix & gmat)  ;
  virtual void  GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos)  ; 

protected:

  AliPHOSGeometry(const Text_t* name, const Text_t* title) : AliGeometry(name, title) { Init() ; }  
  void Init(void) ;            // steering method for PHOS and CPV
  void InitPHOS(void) ;        // defines the various PHOS geometry parameters
  void InitPPSD(void) ;        // defines the various PPSD geometry parameters

public: 

  // General

  Bool_t AbsToRelNumbering(const Int_t AbsId, Int_t * RelId) ;           // converts the absolute PHOS numbering to a relative 
  void EmcModuleCoverage(const Int_t m, Double_t & tm, Double_t & tM, Double_t & pm, Double_t & pM, Option_t * opt = kRadian);    
                                                                         // calculates the angular coverage in theta and phi of a EMC module
  void EmcXtalCoverage(Double_t & theta, Double_t & phi, Option_t * opt = kRadian) ; 
                                                                         // calculates the angular coverage in theta and phi of a 
                                                                         // single crystal in a EMC module
  void ImpactOnEmc(const Double_t theta, const Double_t phi, Int_t & ModuleNumber, Double_t & x, Double_t & z) ; 
                                                                         // calculates the impact coordinates of a neutral particle  
                                                                         // emitted in direction theta and phi in ALICE
  void   RelPosInModule(const Int_t * RelId, Float_t & y, Float_t & z) ; // gets the position of element (pad or Xtal) relative to 
                                                                         // center of PHOS module  
  void   RelPosInAlice(const Int_t AbsId, TVector3 &  pos) ;             // gets the position of element (pad or Xtal) relative to 
                                                                         // Alice
  Bool_t RelToAbsNumbering(const Int_t * RelId, Int_t & AbsId) ;         // converts the absolute PHOS numbering to a relative 
                                                                         // inlines

  ///////////// PHOS related parameters

  Bool_t     IsInitialized(void)                  const { return fInit ; }  
  Float_t    GetAirFilledBoxSize(Int_t index)     const { return fAirFilledBoxSize[index] ;}
  Float_t    GetCrystalHolderThickness(void)      const { return fCrystalHolderThickness ; } 
  Float_t    GetCrystalSize(Int_t index)          const { return fXtlSize[index] ; }
  Float_t    GetCrystalSupportHeight(void)        const { return fCrystalSupportHeight ; } 
  Float_t    GetCrystalWrapThickness(void)        const { return fCrystalWrapThickness;}
  Float_t    GetGapBetweenCrystals(void)          const { return fGapBetweenCrystals ; }
  Float_t    GetIPtoCrystalSurface(void)          const { return fIPtoCrystalSurface ; }
  Float_t    GetIPtoOuterCoverDistance(void)      const { return fIPtoOuterCoverDistance ; }
  Float_t    GetIPtoTopLidDistance(void)          const { return fIPtoTopLidDistance ; }
  Float_t    GetLowerThermoPlateThickness(void)   const { return fLowerThermoPlateThickness ; }
  Float_t    GetLowerTextolitPlateThickness(void) const { return fLowerTextolitPlateThickness ; }
  Float_t    GetModuleBoxThickness(void)          const { return fModuleBoxThickness ; }
  Int_t      GetNPhi(void)                        const { return fNPhi ; }
  Int_t      GetNZ(void)                          const { return fNZ ; }
  Int_t      GetNModules(void)                    const { return fNModules ; }
  Float_t    GetOuterBoxSize(Int_t index)         const { return fOuterBoxSize[index] ;    }
  Float_t    GetOuterBoxThickness(Int_t index)    const { return fOuterBoxThickness[index] ; } 
  Float_t    GetPHOSAngle(Int_t index)            const { return fPHOSAngle[index-1] ; } 
  Float_t    GetPinDiodeSize(Int_t index)         const { return fPinDiodeSize[index] ; }
  Float_t    GetSecondUpperPlateThickness(void)   const { return fSecondUpperPlateThickness ; }
  Float_t    GetSupportPlateThickness(void)       const { return fSupportPlateThickness ; }    
  Float_t    GetTextolitBoxSize(Int_t index)      const { return fTextolitBoxSize[index] ; }
  Float_t    GetTextolitBoxThickness(Int_t index) const { return fTextolitBoxThickness[index]; } 
  Float_t    GetUpperPlateThickness(void)         const { return fUpperPlateThickness ; }
  Float_t    GetUpperCoolingPlateThickness(void)  const { return fUpperCoolingPlateThickness ; }

private:

  void       SetPHOSAngles() ; // calculates the PHOS modules PHI angle

public: 
 
  ///////////// PPSD (PHOS PRE SHOWER DETECTOR)  related parameters


  Float_t GetAnodeThickness(void)          const { return fAnodeThickness ; } 
  Float_t GetAvalancheGap(void)            const { return fAvalancheGap ; }
  Float_t GetCathodeThickness(void)        const { return fCathodeThickness ; } 
  Float_t GetCompositeThickness(void)      const { return fCompositeThickness ; } 
  Float_t GetConversionGap(void)           const { return fConversionGap ; } 
  Float_t GetLeadConverterThickness(void)  const { return fLeadConverterThickness ; }
  Float_t GetLeadToMicro2Gap(void)         const { return fLeadToMicro2Gap ; }       
  Float_t GetLidThickness(void)            const { return fLidThickness ; }
  Float_t GetMicromegas1Thickness(void)    const { return fMicromegas1Thickness ; } 
  Float_t GetMicromegas2Thickness(void)    const { return fMicromegas2Thickness ; } 
  Float_t GetMicromegasWallThickness(void) const { return fMicromegasWallThickness ; } 
  Float_t GetMicro1ToLeadGap(void)         const { return fMicro1ToLeadGap ; } 
  Int_t   GetNumberOfPadsPhi(void)         const { return fNumberOfPadsPhi ; }
  Int_t   GetNumberOfPadsZ(void)           const { return fNumberOfPadsZ ; }
  Int_t   GetNumberOfModulesPhi(void)      const { return fNumberOfModulesPhi ; }          
  Int_t   GetNumberOfModulesZ(void)        const { return fNumberOfModulesZ ; }               
  Float_t GetPCThickness(void)             const { return fPCThickness ; }   
  Float_t GetPhiDisplacement(void)         const { return fPhiDisplacement ; }                           
  Float_t GetPPSDBoxSize(Int_t index)      const { return fPPSDBoxSize[index] ; }
  Float_t GetPPSDModuleSize(Int_t index)   const { return fPPSDModuleSize[index] ; } 
  Float_t GetZDisplacement(void)           const { return fZDisplacement ; }                           

private:
  
  ///////////// PHOS related parameters

  Float_t fAirFilledBoxSize[3] ;          // Air filled box containing one module
  Float_t fAirThickness[3] ;              // Space filled with air between the module box and the Textolit box
  Float_t fCrystalSupportHeight ;         // Height of the support of the crystal    
  Float_t fCrystalWrapThickness ;         // Thickness of Tyvek wrapping the crystal
  Float_t fCrystalHolderThickness ;       // Titanium holder of the crystal
  Float_t fGapBetweenCrystals ;           // Total Gap between two adjacent crystals 
  Bool_t  fInit ;                         // Tells if geometry has been succesfully set up 
  Float_t fIPtoOuterCoverDistance ;       // Distances from interaction point to outer cover 
  Float_t fIPtoCrystalSurface ;           // Distances from interaction point to Xtal surface
  Float_t fModuleBoxThickness ;           // Thickness of the thermo insulating box containing one crystals module 
  Float_t fLowerTextolitPlateThickness ;  // Thickness of lower textolit plate
  Float_t fLowerThermoPlateThickness ;    // Thickness of lower thermo insulating plate
  Int_t   fNModules ;                     // Number of modules constituing PHOS
  Int_t   fNPhi ;                         // Number of crystal units in X (phi) direction
  Int_t   fNZ ;                           // Number of crystal units in Z direction
  Float_t fOuterBoxSize[3] ;              // Size of the outer  thermo insulating foam box
  Float_t fOuterBoxThickness[3] ;         // Thickness of the outer thermo insulating foam box
  Float_t fPHOSAngle[4] ;                 // Position angles of modules
  Float_t fPinDiodeSize[3] ;              // Size of the PIN Diode 
  TObjArray *  fRotMatrixArray ;          // Liste of rotation matrices (one per phos module)
  Float_t fSecondUpperPlateThickness ;    // Thickness of  upper polystyrene foam plate
  Float_t fSupportPlateThickness ;        // Thickness of the Aluminium support plate  
  Float_t fUpperCoolingPlateThickness ;   // Thickness of the upper cooling plate 
  Float_t fUpperPlateThickness ;          // Thickness of the uper thermo insulating foam plate 
  Float_t fTextolitBoxSize[3] ;           // Size of the Textolit box inside the insulating foam box
  Float_t fTextolitBoxThickness[3] ;      // Thicknesses of th Textolit box
  Float_t fXtlSize[3] ;                   // PWO4 crystal dimensions


  ///////////// PPSD (PHOS PRE SHOWER DETECTOR)  related parameters

  Float_t fAnodeThickness ;               // Thickness of the copper layer which makes the anode 
  Float_t fAvalancheGap ;                 // Thickness of the gas in the avalanche stage
  Float_t fCathodeThickness ;             // Thickeness of composite material ensuring rigidity of cathode
  Float_t fCompositeThickness ;           // Thickeness of composite material ensuring rigidity of anode
  Float_t fConversionGap ;                // Thickness of the gas in the conversion stage
  Float_t fIPtoTopLidDistance ;           // Distance from interaction point to top lid of PPSD
  Float_t fLeadConverterThickness ;       // Thickness of the Lead converter 
  Float_t fLeadToMicro2Gap ;              // Thickness of the air gap between the Lead and Micromegas 2        
  Float_t fLidThickness ;                 // Thickness of top lid 
  Float_t fMicromegas1Thickness ;         // Thickness of the first downstream Micromegas 
  Float_t fMicromegas2Thickness ;         // Thickness of the second downstream Micromegas 
  Float_t fMicromegasWallThickness ;      // Thickness of the Micromegas leak tight box
  Float_t fMicro1ToLeadGap ;              // Thickness of the air gap between Micromegas 1 and the Lead
  Int_t   fNumberOfPadsPhi ;              // Number of pads on a micromegas module ;  
  Int_t   fNumberOfPadsZ ;                // Number of pads on a micromegas module ;  
  Int_t   fNumberOfModulesPhi ;           // Number of micromegas modules in phi
  Int_t   fNumberOfModulesZ ;             // Number of micromegas modules in z
  Float_t fPCThickness ;                  // Thickness of the printed circuit board of the anode   
  Float_t fPhiDisplacement ;              // Phi displacement of micromegas1 with respect to micromegas2  
  Float_t fPPSDBoxSize[3] ;               // Size of large box which contains PPSD; matches PHOS module size
  Float_t fPPSDModuleSize[3] ;            // Size of an individual micromegas module
  Float_t fZDisplacement ;                // Z displacement of micromegas1 with respect to micromegas2  

  static AliPHOSGeometry * fGeom ; // pointer to the unique instance of the singleton 

  ClassDef(AliPHOSGeometry,1)  // PHOS geometry class , version subatech

} ;

#endif // AliPHOSGEOMETRY_H
Commit	Line	Data
daa2ae2f	1	#ifndef ALIPHOSGEOMETRY_H
	2	#define ALIPHOSGEOMETRY_H
	3	/* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
	4	* See cxx source for full Copyright notice */
	5
	6	////////////////////////////////////////////////
	7	// Geometry class for PHOS : singleton //
	8	// Version SUBATECH //
	9	// Author Y. Schutz SUBATECH //
	10	// geometry parametrized for any //
	11	// shape of modules //
	12	////////////////////////////////////////////////
d15a28e7	13
	14	// --- ROOT system ---
	15
daa2ae2f	16	#include "TNamed.h"
	17	#include "TString.h"
	18	#include "TObjArray.h"
	19	#include "TVector3.h"
d15a28e7	20
	21	// --- AliRoot header files ---
	22
daa2ae2f	23	#include "AliGeometry.h"
	24	#include "AliPHOSRecPoint.h"
	25
9f616d61	26	static const TString kDegre("deg") ;
	27	static const TString kRadian("rad") ;
	28
daa2ae2f	29	class AliPHOSGeometry : public AliGeometry {
	30
	31	public:
	32
	33	AliPHOSGeometry() {} ; // must be kept public for root persistency purposes
	34	virtual ~AliPHOSGeometry(void) ;
	35	static AliPHOSGeometry * GetInstance(const Text_t* name, const Text_t* title) ;
	36	static AliPHOSGeometry * GetInstance() ;
	37	virtual void GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos, TMatrix & gmat) ;
	38	virtual void GetGlobal(const AliRecPoint* RecPoint, TVector3 & gpos) ;
	39
	40	protected:
	41
	42	AliPHOSGeometry(const Text_t* name, const Text_t* title) : AliGeometry(name, title) { Init() ; }
	43	void Init(void) ; // steering method for PHOS and CPV
	44	void InitPHOS(void) ; // defines the various PHOS geometry parameters
	45	void InitPPSD(void) ; // defines the various PPSD geometry parameters
	46
	47	public:
	48
	49	// General
	50
	51	Bool_t AbsToRelNumbering(const Int_t AbsId, Int_t * RelId) ; // converts the absolute PHOS numbering to a relative
9f616d61	52	void EmcModuleCoverage(const Int_t m, Double_t & tm, Double_t & tM, Double_t & pm, Double_t & pM, Option_t * opt = kRadian);
	53	// calculates the angular coverage in theta and phi of a EMC module
	54	void EmcXtalCoverage(Double_t & theta, Double_t & phi, Option_t * opt = kRadian) ;
	55	// calculates the angular coverage in theta and phi of a
	56	// single crystal in a EMC module
	57	void ImpactOnEmc(const Double_t theta, const Double_t phi, Int_t & ModuleNumber, Double_t & x, Double_t & z) ;
	58	// calculates the impact coordinates of a neutral particle
	59	// emitted in direction theta and phi in ALICE
daa2ae2f	60	void RelPosInModule(const Int_t * RelId, Float_t & y, Float_t & z) ; // gets the position of element (pad or Xtal) relative to
	61	// center of PHOS module
	62	void RelPosInAlice(const Int_t AbsId, TVector3 & pos) ; // gets the position of element (pad or Xtal) relative to
	63	// Alice
	64	Bool_t RelToAbsNumbering(const Int_t * RelId, Int_t & AbsId) ; // converts the absolute PHOS numbering to a relative
	65	// inlines
	66
	67	///////////// PHOS related parameters
	68
	69	Bool_t IsInitialized(void) const { return fInit ; }
	70	Float_t GetAirFilledBoxSize(Int_t index) const { return fAirFilledBoxSize[index] ;}
	71	Float_t GetCrystalHolderThickness(void) const { return fCrystalHolderThickness ; }
	72	Float_t GetCrystalSize(Int_t index) const { return fXtlSize[index] ; }
	73	Float_t GetCrystalSupportHeight(void) const { return fCrystalSupportHeight ; }
	74	Float_t GetCrystalWrapThickness(void) const { return fCrystalWrapThickness;}
	75	Float_t GetGapBetweenCrystals(void) const { return fGapBetweenCrystals ; }
	76	Float_t GetIPtoCrystalSurface(void) const { return fIPtoCrystalSurface ; }
	77	Float_t GetIPtoOuterCoverDistance(void) const { return fIPtoOuterCoverDistance ; }
	78	Float_t GetIPtoTopLidDistance(void) const { return fIPtoTopLidDistance ; }
	79	Float_t GetLowerThermoPlateThickness(void) const { return fLowerThermoPlateThickness ; }
	80	Float_t GetLowerTextolitPlateThickness(void) const { return fLowerTextolitPlateThickness ; }
	81	Float_t GetModuleBoxThickness(void) const { return fModuleBoxThickness ; }
	82	Int_t GetNPhi(void) const { return fNPhi ; }
	83	Int_t GetNZ(void) const { return fNZ ; }
	84	Int_t GetNModules(void) const { return fNModules ; }
	85	Float_t GetOuterBoxSize(Int_t index) const { return fOuterBoxSize[index] ; }
	86	Float_t GetOuterBoxThickness(Int_t index) const { return fOuterBoxThickness[index] ; }
	87	Float_t GetPHOSAngle(Int_t index) const { return fPHOSAngle[index-1] ; }
	88	Float_t GetPinDiodeSize(Int_t index) const { return fPinDiodeSize[index] ; }
	89	Float_t GetSecondUpperPlateThickness(void) const { return fSecondUpperPlateThickness ; }
	90	Float_t GetSupportPlateThickness(void) const { return fSupportPlateThickness ; }
	91	Float_t GetTextolitBoxSize(Int_t index) const { return fTextolitBoxSize[index] ; }
	92	Float_t GetTextolitBoxThickness(Int_t index) const { return fTextolitBoxThickness[index]; }
	93	Float_t GetUpperPlateThickness(void) const { return fUpperPlateThickness ; }
	94	Float_t GetUpperCoolingPlateThickness(void) const { return fUpperCoolingPlateThickness ; }
	95
	96	private:
	97
	98	void SetPHOSAngles() ; // calculates the PHOS modules PHI angle
	99
	100	public:
d15a28e7	101
daa2ae2f	102	///////////// PPSD (PHOS PRE SHOWER DETECTOR) related parameters
	103
	104
	105	Float_t GetAnodeThickness(void) const { return fAnodeThickness ; }
	106	Float_t GetAvalancheGap(void) const { return fAvalancheGap ; }
	107	Float_t GetCathodeThickness(void) const { return fCathodeThickness ; }
	108	Float_t GetCompositeThickness(void) const { return fCompositeThickness ; }
	109	Float_t GetConversionGap(void) const { return fConversionGap ; }
	110	Float_t GetLeadConverterThickness(void) const { return fLeadConverterThickness ; }
	111	Float_t GetLeadToMicro2Gap(void) const { return fLeadToMicro2Gap ; }
	112	Float_t GetLidThickness(void) const { return fLidThickness ; }
	113	Float_t GetMicromegas1Thickness(void) const { return fMicromegas1Thickness ; }
	114	Float_t GetMicromegas2Thickness(void) const { return fMicromegas2Thickness ; }
	115	Float_t GetMicromegasWallThickness(void) const { return fMicromegasWallThickness ; }
	116	Float_t GetMicro1ToLeadGap(void) const { return fMicro1ToLeadGap ; }
	117	Int_t GetNumberOfPadsPhi(void) const { return fNumberOfPadsPhi ; }
	118	Int_t GetNumberOfPadsZ(void) const { return fNumberOfPadsZ ; }
	119	Int_t GetNumberOfModulesPhi(void) const { return fNumberOfModulesPhi ; }
	120	Int_t GetNumberOfModulesZ(void) const { return fNumberOfModulesZ ; }
	121	Float_t GetPCThickness(void) const { return fPCThickness ; }
	122	Float_t GetPhiDisplacement(void) const { return fPhiDisplacement ; }
	123	Float_t GetPPSDBoxSize(Int_t index) const { return fPPSDBoxSize[index] ; }
	124	Float_t GetPPSDModuleSize(Int_t index) const { return fPPSDModuleSize[index] ; }
	125	Float_t GetZDisplacement(void) const { return fZDisplacement ; }
	126
	127	private:
	128
	129	///////////// PHOS related parameters
	130
	131	Float_t fAirFilledBoxSize[3] ; // Air filled box containing one module
	132	Float_t fAirThickness[3] ; // Space filled with air between the module box and the Textolit box
	133	Float_t fCrystalSupportHeight ; // Height of the support of the crystal
	134	Float_t fCrystalWrapThickness ; // Thickness of Tyvek wrapping the crystal
	135	Float_t fCrystalHolderThickness ; // Titanium holder of the crystal
	136	Float_t fGapBetweenCrystals ; // Total Gap between two adjacent crystals
	137	Bool_t fInit ; // Tells if geometry has been succesfully set up
	138	Float_t fIPtoOuterCoverDistance ; // Distances from interaction point to outer cover
	139	Float_t fIPtoCrystalSurface ; // Distances from interaction point to Xtal surface
	140	Float_t fModuleBoxThickness ; // Thickness of the thermo insulating box containing one crystals module
	141	Float_t fLowerTextolitPlateThickness ; // Thickness of lower textolit plate
	142	Float_t fLowerThermoPlateThickness ; // Thickness of lower thermo insulating plate
	143	Int_t fNModules ; // Number of modules constituing PHOS
	144	Int_t fNPhi ; // Number of crystal units in X (phi) direction
	145	Int_t fNZ ; // Number of crystal units in Z direction
	146	Float_t fOuterBoxSize[3] ; // Size of the outer thermo insulating foam box
	147	Float_t fOuterBoxThickness[3] ; // Thickness of the outer thermo insulating foam box
	148	Float_t fPHOSAngle[4] ; // Position angles of modules
	149	Float_t fPinDiodeSize[3] ; // Size of the PIN Diode
	150	TObjArray * fRotMatrixArray ; // Liste of rotation matrices (one per phos module)
	151	Float_t fSecondUpperPlateThickness ; // Thickness of upper polystyrene foam plate
	152	Float_t fSupportPlateThickness ; // Thickness of the Aluminium support plate
	153	Float_t fUpperCoolingPlateThickness ; // Thickness of the upper cooling plate
	154	Float_t fUpperPlateThickness ; // Thickness of the uper thermo insulating foam plate
	155	Float_t fTextolitBoxSize[3] ; // Size of the Textolit box inside the insulating foam box
	156	Float_t fTextolitBoxThickness[3] ; // Thicknesses of th Textolit box
	157	Float_t fXtlSize[3] ; // PWO4 crystal dimensions
	158
	159
	160	///////////// PPSD (PHOS PRE SHOWER DETECTOR) related parameters
	161
	162	Float_t fAnodeThickness ; // Thickness of the copper layer which makes the anode
	163	Float_t fAvalancheGap ; // Thickness of the gas in the avalanche stage
	164	Float_t fCathodeThickness ; // Thickeness of composite material ensuring rigidity of cathode
	165	Float_t fCompositeThickness ; // Thickeness of composite material ensuring rigidity of anode
166	Float_t fConversionGap ; // Thickness of the gas in the conversion stage
167	Float_t fIPtoTopLidDistance ; // Distance from interaction point to top lid of PPSD
168	Float_t fLeadConverterThickness ; // Thickness of the Lead converter
169	Float_t fLeadToMicro2Gap ; // Thickness of the air gap between the Lead and Micromegas 2
170	Float_t fLidThickness ; // Thickness of top lid
171	Float_t fMicromegas1Thickness ; // Thickness of the first downstream Micromegas
172	Float_t fMicromegas2Thickness ; // Thickness of the second downstream Micromegas
173	Float_t fMicromegasWallThickness ; // Thickness of the Micromegas leak tight box
174	Float_t fMicro1ToLeadGap ; // Thickness of the air gap between Micromegas 1 and the Lead
175	Int_t fNumberOfPadsPhi ; // Number of pads on a micromegas module ;
176	Int_t fNumberOfPadsZ ; // Number of pads on a micromegas module ;
177	Int_t fNumberOfModulesPhi ; // Number of micromegas modules in phi
178	Int_t fNumberOfModulesZ ; // Number of micromegas modules in z
179	Float_t fPCThickness ; // Thickness of the printed circuit board of the anode
180	Float_t fPhiDisplacement ; // Phi displacement of micromegas1 with respect to micromegas2
181	Float_t fPPSDBoxSize[3] ; // Size of large box which contains PPSD; matches PHOS module size
182	Float_t fPPSDModuleSize[3] ; // Size of an individual micromegas module
183	Float_t fZDisplacement ; // Z displacement of micromegas1 with respect to micromegas2
184
185	static AliPHOSGeometry * fGeom ; // pointer to the unique instance of the singleton
186
187	ClassDef(AliPHOSGeometry,1) // PHOS geometry class , version subatech
188
189	} ;
190
191	#endif // AliPHOSGEOMETRY_H