[u/mrichter/AliRoot.git] / RICH / AliRICHParam.h

#ifndef AliRICHParam_h
#define AliRICHParam_h

#include <TObject.h>
#include <TMath.h>
#include <TVector3.h>
#include <TRandom.h>


static const int kNCH=7;           //number of RICH chambers 
static const int kNpadsX = 144;    //number of pads along X in single chamber
static const int kNpadsY = 160;    //number of pads along Y in single chamber
static const int kBad=-101;        //useful static const to mark initial (uninitalised) values


static const int kadc_satm  = 4096;  //dynamic range (10 bits)
static const int kCerenkov=50000050;  //??? go to something more general like TPDGCode
static const int kFeedback=50000051;  //??? go to something more general like TPDGCode


class AliRICHParam :public TObject  
{
public:
           AliRICHParam()                    {;}
  virtual ~AliRICHParam()                    {;}
  static const Int_t   NpadsX()              {return kNpadsX;}
  static const Int_t   NpadsY()              {return kNpadsY;}   
  static Int_t   NpadsXsec()                 {return NpadsX()/3;}   
  static Int_t   NpadsYsec()                 {return NpadsY()/2;}   
  static Double_t DeadZone()                 {return 2.6;}
  static Double_t PadSizeX()                 {return 0.84;}
  static Double_t PadSizeY()                 {return 0.8;}
  static Double_t SectorSizeX()              {return NpadsX()*PadSizeX()/3;}
  static Double_t SectorSizeY()              {return NpadsY()*PadSizeY()/2;}  
  static Double_t PcSizeX()                  {return NpadsX()*PadSizeX()+2*DeadZone();}
  static Double_t PcSizeY()                  {return NpadsY()*PadSizeY()+DeadZone();}
  static Double_t WirePitch()                {return PadSizeX()/2;}
  static Double_t SizeX()                    {return 132.6;}
  static Double_t SizeY()                    {return 26;}
  static Double_t SizeZ()                    {return 136.7;}   
  static Double_t Offset()                   {return 490+1.267;}  
  static Double_t AngleYZ()                  {return 19.5*TMath::DegToRad();} 
  static Double_t AngleXY()                  {return 20*TMath::DegToRad();} 
  static Double_t FreonThickness()           {return 1.5;}   
  static Double_t QuartzThickness()          {return 0.5;}   
  static Double_t GapThickness()             {return 8.0;}      
  static Double_t RadiatorToPads()           {return FreonThickness()+QuartzThickness()+GapThickness();}   
  static Double_t ProximityGapThickness()    {return 0.4;}    
  static Double_t AnodeCathodeGap()          {return 0.2;}
  static Double_t QuartzLength()             {return 133;}   
  static Double_t QuartzWidth()              {return 127.9;}
  static Double_t OuterFreonLength()         {return 133;}   
  static Double_t OuterFreonWidth()          {return 41.3;}   
  static Double_t InnerFreonLength()         {return 133;}   
  static Double_t InnerFreonWidth()          {return 41.3;}   
  static Double_t IonisationPotential()      {return 26.0e-9;}                            
  static Double_t MathiesonDeltaX()          {return 5*0.18;}    
  static Double_t MathiesonDeltaY()          {return 5*0.18;}    
  static Int_t    MaxQdc()                   {return 4095;}          
  static Double_t QdcSlope(Int_t sec)        {HV(sec);return 27;}
  static Double_t AlphaFeedback(Int_t sec)   {HV(sec);return 0.036;}
  
  static Bool_t  IsResolveClusters()         {return fgIsResolveClusters;}  
  static Bool_t   IsWireSag()                {return fgIsWireSag;}
  static Int_t    HV(Int_t)                  {return fgHV;}
  static Double_t AngleRot()                 {return fgAngleRot*TMath::DegToRad();} 
    static void  SetResolveClusters(Bool_t a){fgIsResolveClusters=a;}  
    static void  SetWireSag(Bool_t status)   {fgIsWireSag=status;}  
    static void  SetHV(Int_t hv)             {fgHV       =hv;}  
    static void  SetAngleRot(Double_t rot)   {fgAngleRot =rot;}

  inline static Double_t Mathieson(Double_t lx1,Double_t lx2,Double_t ly1,Double_t ly2);   
  inline static void    Loc2Area(TVector3 hitX3,Int_t &padxMin,Int_t &padyMin,Int_t &padxMax,Int_t &padyMax);
  inline static Int_t   PadNeighbours(Int_t iPadX,Int_t iPadY,Int_t aListX[4],Int_t aListY[4]);
  inline static Int_t   Loc2Pad(Double_t x,Double_t y,Int_t &padx,Int_t &pady); 
  inline static void    Pad2Loc(Int_t padx,Int_t pady,Double_t &x,Double_t &y);  
  inline static Double_t GainVariation(Double_t y,Int_t sector);       
  inline static Int_t   Loc2TotQdc(TVector3 locX3,Double_t eloss,Int_t iPid, Int_t &sector);
  inline static Double_t Loc2PadFrac(TVector3 locX3,Int_t padx,Int_t pady);
  
  inline static Int_t   Loc2Sec(Double_t &x,Double_t &y); 
  inline static Int_t   Pad2Sec(Int_t &padx,Int_t &pady); 
  static Int_t   Sector(Int_t padx,Int_t pady) {return Pad2Sec(padx,pady);}
  inline Bool_t IsOverTh(Int_t iChamber, Int_t x, Int_t y, Double_t q);
  static Int_t NsigmaTh() {return fgNsigmaTh;}
  static Float_t SigmaThMean() {return fgSigmaThMean;}
  static Float_t SigmaThSpread() {return fgSigmaThSpread;}
  void GenSigmaThMap();
protected:
  static Bool_t  fgIsWireSag;                           //is wire sagitta taken into account
  static Bool_t  fgIsResolveClusters;                   //performs declustering or not
  static Int_t   fgHV;                                  //HV applied to anod wires
  static Double_t fgAngleRot;                           //rotation of RICH from up postion (0,0,490)cm
  static Float_t fSigmaThMap[kNCH][kNpadsX][kNpadsY];   // sigma of the pedestal distributions for all pads
  static Int_t fgNsigmaTh;                              // n. of sigmas to cut for zero suppression
  static Float_t fgSigmaThMean;                         // sigma threshold value
  static Float_t fgSigmaThSpread;                       // spread of sigma
  ClassDef(AliRICHParam,4)    //RICH main parameters
};
//__________________________________________________________________________________________________
Int_t AliRICHParam::PadNeighbours(Int_t iPadX,Int_t iPadY,Int_t listX[4],Int_t listY[4])
{
  Int_t nPads=0;
  if(iPadY!=NpadsY()&&iPadY!=NpadsYsec())                      {listX[nPads]=iPadX;   listY[nPads]=iPadY+1; nPads++;}       
  if(iPadX!=NpadsXsec()&&iPadX!=2*NpadsXsec()&&iPadX!=NpadsX()){listX[nPads]=iPadX+1; listY[nPads]=iPadY;   nPads++;}       
  if(iPadY!=1&&iPadY!=NpadsYsec()+1)                           {listX[nPads]=iPadX;   listY[nPads]=iPadY-1; nPads++;}      
  if(iPadX!=1&&iPadX!=NpadsXsec()+1&&iPadX!=2*NpadsXsec()+1)   {listX[nPads]=iPadX-1; listY[nPads]=iPadY;   nPads++;}

  return nPads;
}//Pad2ClosePads()
//__________________________________________________________________________________________________
Int_t AliRICHParam::Loc2Sec(Double_t &x,Double_t &y)
{//Determines sector for a given hit (x,y) and trasform this point to the local system of that sector.
  Int_t sector=kBad;  
  Double_t x1=-PcSizeX()/2;      Double_t x2=-SectorSizeX()/2-DeadZone();  Double_t x3=-SectorSizeX()/2;
  Double_t x4= SectorSizeX()/2;  Double_t x5= SectorSizeX()/2+DeadZone();  Double_t x6= PcSizeX()/2;

  if     (x>=x1&&x<=x2)    {sector=1;x+=PcSizeX()/2;}
  else if(x>=x3&&x<=x4)    {sector=2;x+=SectorSizeX()/2;}
  else if(x>=x5&&x<=x6)    {sector=3;x-=SectorSizeX()/2+DeadZone();}
  else                     {return kBad;} //in dead zone

  if     (y>=-PcSizeY()/2   &&y<=-DeadZone()/2)  {y+=PcSizeY()/2;  return sector;}
  else if(y> -DeadZone()/2  &&y<  DeadZone()/2)  {return kBad;} //in dead zone
  else if(y>= DeadZone()/2  &&y<= PcSizeY()/2)   {y-=DeadZone()/2; return sector+3;}
  else                                           {return kBad;}
}//Loc2Sec(Double_t x, Double_t y)
//__________________________________________________________________________________________________
Int_t AliRICHParam::Pad2Sec(Int_t &padx, Int_t &pady)
{//Determines sector for a given pad (padx,pady) and trasform this point to the local system of that sector.
  Int_t sector=kBad;      
  if     (padx>=1            &&padx<=NpadsXsec())      {sector=1;}
  else if(padx> NpadsXsec()  &&padx<=NpadsXsec()*2)    {sector=2;padx-=NpadsXsec();}
  else if(padx> NpadsXsec()*2&&padx<=NpadsX())         {sector=3;padx-=NpadsXsec()*2;}
  else                                                 {return kBad;}

  if     (pady>=1         &&pady<= NpadsYsec())     {return sector;}
  else if(pady>NpadsYsec()&&pady<= NpadsY())        {pady-=NpadsYsec();return sector+3;} 
  else                                              {return kBad;}
}//Pad2Sec()
//__________________________________________________________________________________________________
Int_t AliRICHParam::Loc2Pad(Double_t x, Double_t y, Int_t &padx, Int_t &pady)
{//returns pad numbers (iPadX,iPadY) for given point in local coordinates (x,y) 
 //count starts in lower left corner from 1,1 to 144,180
  
  padx=pady=kBad;
  Int_t sector=Loc2Sec(x,y);
  if(sector==kBad) return sector;
  
  padx=Int_t(x/PadSizeX())+1; 
  if(padx>NpadsXsec())            padx= NpadsXsec();
  if(sector==2||sector==5)       padx+=NpadsXsec();
  else if(sector==3||sector==6)  padx+=NpadsXsec()*2;
  
  pady=Int_t(y/PadSizeY())+1;
  if(pady>NpadsYsec())            padx= NpadsYsec();
  if(sector>0)                    pady+=NpadsYsec();    

  return sector;
}//Loc2Pad()
//__________________________________________________________________________________________________
void AliRICHParam::Pad2Loc(Int_t padx,Int_t pady,Double_t &x,Double_t &y)
{
  Int_t sector=Pad2Sec(padx,pady);  
  if(sector>3)
    y=0.5*DeadZone()+pady*PadSizeY()-0.5*PadSizeY();
  else{
    y=-0.5*PcSizeY()+pady*PadSizeY()-0.5*PadSizeY();
  }
  if(sector==1||sector==4)
    x=-0.5*PcSizeX()+padx*PadSizeX()-0.5*PadSizeX();
  else if(sector==2||sector==5)
    x=-0.5*SectorSizeX()+padx*PadSizeX()-0.5*PadSizeX();
  else
    x= 0.5*SectorSizeX()+DeadZone()+padx*PadSizeX()-0.5*PadSizeX();
  return;
}//Pad2Loc()
//__________________________________________________________________________________________________
Double_t AliRICHParam::GainVariation(Double_t y,Int_t sector)
{
//returns % of gain degradation due to wire sagita  
  if(IsWireSag()){
    if(y>0) y-=SectorSizeY()/2; else  y+=SectorSizeY()/2; 
    switch(HV(sector)){
      case 2150: return 9e-6*TMath::Power(y,4)+2e-7*TMath::Power(y,3)-0.0316*TMath::Power(y,2)-3e-4*y+25.367;//%
      case 2100: return 8e-6*TMath::Power(y,4)+2e-7*TMath::Power(y,3)-0.0283*TMath::Power(y,2)-2e-4*y+23.015;
      case 2050: return 7e-6*TMath::Power(y,4)+1e-7*TMath::Power(y,3)-0.0254*TMath::Power(y,2)-2e-4*y+20.888;
      case 2000: return 6e-6*TMath::Power(y,4)+8e-8*TMath::Power(y,3)-0.0227*TMath::Power(y,2)-1e-4*y+18.961;
      default:   return 0;
    }
  }else
    return 0;
}
//__________________________________________________________________________________________________
Int_t AliRICHParam::Loc2TotQdc(TVector3 x3,Double_t eloss,Int_t iPid,Int_t &sector)
{//calculates the total charge produced by the hit given in local refenrence system
  Double_t x=x3.X(),y=x3.Y();
  
  sector=Loc2Sec(x,y);
  
  Double_t gain=QdcSlope(sector)*(1+GainVariation(x3.Y(),sector)/100);

  
  if(iPid>50000){//it's photon => 1 electron
    return Int_t(gain*-TMath::Log(gRandom->Rndm()));
  }else{//it's MIP  
    Int_t iNelectrons=Int_t(eloss/IonisationPotential());
    if(iNelectrons==0) return 0;
    Double_t qdc=0;
    for(Int_t i=1;i<=iNelectrons;i++) qdc+=gain*-TMath::Log(gRandom->Rndm());
    return Int_t(qdc);
  }
}
//__________________________________________________________________________________________________
Double_t AliRICHParam::Loc2PadFrac(TVector3 hitX3,Int_t padx,Int_t pady)
{//
  Double_t padXcenter=0,padYcenter=0;  Pad2Loc(padx,pady,padXcenter,padYcenter);  

  //correction to the position of the nearest wire
  
  Double_t normXmin=(hitX3.X()-padXcenter-PadSizeX()/2)  /AnodeCathodeGap();
  Double_t normXmax=(hitX3.X()-padXcenter+PadSizeX()/2)  /AnodeCathodeGap();
  Double_t normYmin=(hitX3.Y()-padYcenter-PadSizeY()/2)  /AnodeCathodeGap();
  Double_t normYmax=(hitX3.Y()-padYcenter+PadSizeY()/2)  /AnodeCathodeGap();
  
  return Mathieson(normXmin,normYmin,normXmax,normYmax);
}//Loc2PadQdc()
//__________________________________________________________________________________________________
Double_t AliRICHParam::Mathieson(Double_t xMin,Double_t yMin,Double_t xMax,Double_t yMax)
{//see NIM A370(1988)602-603 
  const Double_t kSqrtKx3=0.77459667;const Double_t kX2=0.962;const Double_t kX4=0.379;
  const Double_t kSqrtKy3=0.77459667;const Double_t kY2=0.962;const Double_t kY4=0.379;

  Double_t ux1=kSqrtKx3*TMath::TanH(kX2*xMin);
  Double_t ux2=kSqrtKx3*TMath::TanH(kX2*xMax);    
  Double_t uy1=kSqrtKy3*TMath::TanH(kY2*yMin);
  Double_t uy2=kSqrtKy3*TMath::TanH(kY2*yMax);
  return 4*kX4*(TMath::ATan(ux2)-TMath::ATan(ux1))*kY4*(TMath::ATan(uy2)-TMath::ATan(uy1));
}  
//__________________________________________________________________________________________________
void AliRICHParam::Loc2Area(TVector3 hitX3,Int_t &iPadXmin,Int_t &iPadYmin,Int_t &iPadXmax,Int_t &iPadYmax)
{//calculates the area of disintegration for a given hit. Area is a rectangulare set pf pads
 //defined by its left-down and right-up coners
  //  hitX3.SetX(Shift2NearestWire(hitX3.X());
  Loc2Pad(hitX3.X()-MathiesonDeltaX(),hitX3.Y()-MathiesonDeltaY(),iPadXmin,iPadYmin);   
  Loc2Pad(hitX3.X()+MathiesonDeltaX(),hitX3.Y()+MathiesonDeltaY(),iPadXmax,iPadYmax);     
}//
//__________________________________________________________________________________________________
Bool_t AliRICHParam::IsOverTh(Int_t iChamber, Int_t x, Int_t y, Double_t q)
{// Calculate the new charge subtracting pedestal and if the current digit is over threshold
  if(q>NsigmaTh()*fSigmaThMap[iChamber-1][x-1][y-1]) return kTRUE; else return kFALSE;
}//
#endif //AliRICHParam_h
Commit	Line	Data
d48cca74	1	#ifndef AliRICHParam_h
	2	#define AliRICHParam_h
	3
c712cb2f	4	#include <TObject.h>
	5	#include <TMath.h>
	6	#include <TVector3.h>
	7	#include <TRandom.h>
9e23b054	8
ed3ceb24	9
	10	static const int kNCH=7; //number of RICH chambers
	11	static const int kNpadsX = 144; //number of pads along X in single chamber
	12	static const int kNpadsY = 160; //number of pads along Y in single chamber
	13	static const int kBad=-101; //useful static const to mark initial (uninitalised) values
	14
	15
	16	static const int kadc_satm = 4096; //dynamic range (10 bits)
	17	static const int kCerenkov=50000050; //??? go to something more general like TPDGCode
	18	static const int kFeedback=50000051; //??? go to something more general like TPDGCode
	19
	20
d48cca74	21	class AliRICHParam :public TObject
	22	{
	23	public:
c712cb2f	24	AliRICHParam() {;}
08479a10	25	virtual ~AliRICHParam() {;}
ed3ceb24	26	static const Int_t NpadsX() {return kNpadsX;}
	27	static const Int_t NpadsY() {return kNpadsY;}
	28	static Int_t NpadsXsec() {return NpadsX()/3;}
	29	static Int_t NpadsYsec() {return NpadsY()/2;}
c712cb2f	30	static Double_t DeadZone() {return 2.6;}
	31	static Double_t PadSizeX() {return 0.84;}
	32	static Double_t PadSizeY() {return 0.8;}
	33	static Double_t SectorSizeX() {return NpadsX()*PadSizeX()/3;}
	34	static Double_t SectorSizeY() {return NpadsY()*PadSizeY()/2;}
	35	static Double_t PcSizeX() {return NpadsX()PadSizeX()+2DeadZone();}
	36	static Double_t PcSizeY() {return NpadsY()*PadSizeY()+DeadZone();}
	37	static Double_t WirePitch() {return PadSizeX()/2;}
	38	static Double_t SizeX() {return 132.6;}
	39	static Double_t SizeY() {return 26;}
	40	static Double_t SizeZ() {return 136.7;}
	41	static Double_t Offset() {return 490+1.267;}
	42	static Double_t AngleYZ() {return 19.5*TMath::DegToRad();}
	43	static Double_t AngleXY() {return 20*TMath::DegToRad();}
	44	static Double_t FreonThickness() {return 1.5;}
	45	static Double_t QuartzThickness() {return 0.5;}
	46	static Double_t GapThickness() {return 8.0;}
	47	static Double_t RadiatorToPads() {return FreonThickness()+QuartzThickness()+GapThickness();}
	48	static Double_t ProximityGapThickness() {return 0.4;}
	49	static Double_t AnodeCathodeGap() {return 0.2;}
	50	static Double_t QuartzLength() {return 133;}
	51	static Double_t QuartzWidth() {return 127.9;}
	52	static Double_t OuterFreonLength() {return 133;}
	53	static Double_t OuterFreonWidth() {return 41.3;}
	54	static Double_t InnerFreonLength() {return 133;}
	55	static Double_t InnerFreonWidth() {return 41.3;}
	56	static Double_t IonisationPotential() {return 26.0e-9;}
9d6f9427	57	static Double_t MathiesonDeltaX() {return 5*0.18;}
9d6f9427	58	static Double_t MathiesonDeltaY() {return 5*0.18;}
c712cb2f	59	static Int_t MaxQdc() {return 4095;}
	60	static Double_t QdcSlope(Int_t sec) {HV(sec);return 27;}
	61	static Double_t AlphaFeedback(Int_t sec) {HV(sec);return 0.036;}
853634d3	62
e33758d8	63	static Bool_t IsResolveClusters() {return fgIsResolveClusters;}
c712cb2f	64	static Bool_t IsWireSag() {return fgIsWireSag;}
c712cb2f	65	static Int_t HV(Int_t) {return fgHV;}
e33758d8	66	static Double_t AngleRot() {return fgAngleRot*TMath::DegToRad();}
	67	static void SetResolveClusters(Bool_t a){fgIsResolveClusters=a;}
	68	static void SetWireSag(Bool_t status) {fgIsWireSag=status;}
	69	static void SetHV(Int_t hv) {fgHV =hv;}
08479a10	70	static void SetAngleRot(Double_t rot) {fgAngleRot =rot;}
c712cb2f	71
9d6f9427	72	inline static Double_t Mathieson(Double_t lx1,Double_t lx2,Double_t ly1,Double_t ly2);
c712cb2f	73	inline static void Loc2Area(TVector3 hitX3,Int_t &padxMin,Int_t &padyMin,Int_t &padxMax,Int_t &padyMax);
	74	inline static Int_t PadNeighbours(Int_t iPadX,Int_t iPadY,Int_t aListX[4],Int_t aListY[4]);
	75	inline static Int_t Loc2Pad(Double_t x,Double_t y,Int_t &padx,Int_t &pady);
	76	inline static void Pad2Loc(Int_t padx,Int_t pady,Double_t &x,Double_t &y);
	77	inline static Double_t GainVariation(Double_t y,Int_t sector);
	78	inline static Int_t Loc2TotQdc(TVector3 locX3,Double_t eloss,Int_t iPid, Int_t &sector);
	79	inline static Double_t Loc2PadFrac(TVector3 locX3,Int_t padx,Int_t pady);
543d5224	80
c712cb2f	81	inline static Int_t Loc2Sec(Double_t &x,Double_t &y);
c712cb2f	82	inline static Int_t Pad2Sec(Int_t &padx,Int_t &pady);
ed3ceb24	83	static Int_t Sector(Int_t padx,Int_t pady) {return Pad2Sec(padx,pady);}
08479a10	84	inline Bool_t IsOverTh(Int_t iChamber, Int_t x, Int_t y, Double_t q);
	85	static Int_t NsigmaTh() {return fgNsigmaTh;}
	86	static Float_t SigmaThMean() {return fgSigmaThMean;}
	87	static Float_t SigmaThSpread() {return fgSigmaThSpread;}
	88	void GenSigmaThMap();
d48cca74	89	protected:
08479a10	90	static Bool_t fgIsWireSag; //is wire sagitta taken into account
	91	static Bool_t fgIsResolveClusters; //performs declustering or not
	92	static Int_t fgHV; //HV applied to anod wires
	93	static Double_t fgAngleRot; //rotation of RICH from up postion (0,0,490)cm
ed3ceb24	94	static Float_t fSigmaThMap[kNCH][kNpadsX][kNpadsY]; // sigma of the pedestal distributions for all pads
08479a10	95	static Int_t fgNsigmaTh; // n. of sigmas to cut for zero suppression
	96	static Float_t fgSigmaThMean; // sigma threshold value
	97	static Float_t fgSigmaThSpread; // spread of sigma
c712cb2f	98	ClassDef(AliRICHParam,4) //RICH main parameters
d48cca74	99	};
c2c6679b	100	//__________________________________________________________________________________________________
c712cb2f	101	Int_t AliRICHParam::PadNeighbours(Int_t iPadX,Int_t iPadY,Int_t listX[4],Int_t listY[4])
	102	{
	103	Int_t nPads=0;
ed3ceb24	104	if(iPadY!=NpadsY()&&iPadY!=NpadsYsec()) {listX[nPads]=iPadX; listY[nPads]=iPadY+1; nPads++;}
	105	if(iPadX!=NpadsXsec()&&iPadX!=2*NpadsXsec()&&iPadX!=NpadsX()){listX[nPads]=iPadX+1; listY[nPads]=iPadY; nPads++;}
	106	if(iPadY!=1&&iPadY!=NpadsYsec()+1) {listX[nPads]=iPadX; listY[nPads]=iPadY-1; nPads++;}
	107	if(iPadX!=1&&iPadX!=NpadsXsec()+1&&iPadX!=2*NpadsXsec()+1) {listX[nPads]=iPadX-1; listY[nPads]=iPadY; nPads++;}
	108
c712cb2f	109	return nPads;
	110	}//Pad2ClosePads()
	111	//__________________________________________________________________________________________________
	112	Int_t AliRICHParam::Loc2Sec(Double_t &x,Double_t &y)
	113	{//Determines sector for a given hit (x,y) and trasform this point to the local system of that sector.
	114	Int_t sector=kBad;
6a005d35	115	Double_t x1=-PcSizeX()/2; Double_t x2=-SectorSizeX()/2-DeadZone(); Double_t x3=-SectorSizeX()/2;
6a005d35	116	Double_t x4= SectorSizeX()/2; Double_t x5= SectorSizeX()/2+DeadZone(); Double_t x6= PcSizeX()/2;
c712cb2f	117
6a005d35	118	if (x>=x1&&x<=x2) {sector=1;x+=PcSizeX()/2;}
	119	else if(x>=x3&&x<=x4) {sector=2;x+=SectorSizeX()/2;}
	120	else if(x>=x5&&x<=x6) {sector=3;x-=SectorSizeX()/2+DeadZone();}
	121	else {return kBad;} //in dead zone
c712cb2f	122
c1863e3c	123	if (y>=-PcSizeY()/2 &&y<=-DeadZone()/2) {y+=PcSizeY()/2; return sector;}
6a005d35	124	else if(y> -DeadZone()/2 &&y< DeadZone()/2) {return kBad;} //in dead zone
c1863e3c	125	else if(y>= DeadZone()/2 &&y<= PcSizeY()/2) {y-=DeadZone()/2; return sector+3;}
6a005d35	126	else {return kBad;}
c712cb2f	127	}//Loc2Sec(Double_t x, Double_t y)
c2c6679b	128	//__________________________________________________________________________________________________
c712cb2f	129	Int_t AliRICHParam::Pad2Sec(Int_t &padx, Int_t &pady)
	130	{//Determines sector for a given pad (padx,pady) and trasform this point to the local system of that sector.
	131	Int_t sector=kBad;
	132	if (padx>=1 &&padx<=NpadsXsec()) {sector=1;}
	133	else if(padx> NpadsXsec() &&padx<=NpadsXsec()*2) {sector=2;padx-=NpadsXsec();}
	134	else if(padx> NpadsXsec()2&&padx<=NpadsX()) {sector=3;padx-=NpadsXsec()2;}
	135	else {return kBad;}
	136
c1863e3c	137	if (pady>=1 &&pady<= NpadsYsec()) {return sector;}
c1863e3c	138	else if(pady>NpadsYsec()&&pady<= NpadsY()) {pady-=NpadsYsec();return sector+3;}
c712cb2f	139	else {return kBad;}
	140	}//Pad2Sec()
	141	//__________________________________________________________________________________________________
	142	Int_t AliRICHParam::Loc2Pad(Double_t x, Double_t y, Int_t &padx, Int_t &pady)
	143	{//returns pad numbers (iPadX,iPadY) for given point in local coordinates (x,y)
	144	//count starts in lower left corner from 1,1 to 144,180
	145
	146	padx=pady=kBad;
	147	Int_t sector=Loc2Sec(x,y);
	148	if(sector==kBad) return sector;
	149
	150	padx=Int_t(x/PadSizeX())+1;
	151	if(padx>NpadsXsec()) padx= NpadsXsec();
c1863e3c	152	if(sector==2\|\|sector==5) padx+=NpadsXsec();
c1863e3c	153	else if(sector==3\|\|sector==6) padx+=NpadsXsec()*2;
c712cb2f	154
	155	pady=Int_t(y/PadSizeY())+1;
	156	if(pady>NpadsYsec()) padx= NpadsYsec();
	157	if(sector>0) pady+=NpadsYsec();
	158
	159	return sector;
	160	}//Loc2Pad()
	161	//__________________________________________________________________________________________________
	162	void AliRICHParam::Pad2Loc(Int_t padx,Int_t pady,Double_t &x,Double_t &y)
	163	{
	164	Int_t sector=Pad2Sec(padx,pady);
c1863e3c	165	if(sector>3)
c712cb2f	166	y=0.5DeadZone()+padyPadSizeY()-0.5*PadSizeY();
c712cb2f	167	else{
c712cb2f	168	y=-0.5PcSizeY()+padyPadSizeY()-0.5*PadSizeY();
c712cb2f	169	}
c1863e3c	170	if(sector==1\|\|sector==4)
c712cb2f	171	x=-0.5PcSizeX()+padxPadSizeX()-0.5*PadSizeX();
c1863e3c	172	else if(sector==2\|\|sector==5)
c712cb2f	173	x=-0.5SectorSizeX()+padxPadSizeX()-0.5*PadSizeX();
c2c6679b	174	else
c712cb2f	175	x= 0.5SectorSizeX()+DeadZone()+padxPadSizeX()-0.5*PadSizeX();
	176	return;
	177	}//Pad2Loc()
c60862bf	178	//__________________________________________________________________________________________________
c712cb2f	179	Double_t AliRICHParam::GainVariation(Double_t y,Int_t sector)
c60862bf	180	{
ed3ceb24	181	//returns % of gain degradation due to wire sagita
c712cb2f	182	if(IsWireSag()){
	183	if(y>0) y-=SectorSizeY()/2; else y+=SectorSizeY()/2;
	184	switch(HV(sector)){
ed3ceb24	185	case 2150: return 9e-6TMath::Power(y,4)+2e-7TMath::Power(y,3)-0.0316TMath::Power(y,2)-3e-4y+25.367;//%
	186	case 2100: return 8e-6TMath::Power(y,4)+2e-7TMath::Power(y,3)-0.0283TMath::Power(y,2)-2e-4y+23.015;
	187	case 2050: return 7e-6TMath::Power(y,4)+1e-7TMath::Power(y,3)-0.0254TMath::Power(y,2)-2e-4y+20.888;
	188	case 2000: return 6e-6TMath::Power(y,4)+8e-8TMath::Power(y,3)-0.0227TMath::Power(y,2)-1e-4y+18.961;
	189	default: return 0;
c712cb2f	190	}
	191	}else
	192	return 0;
	193	}
	194	//__________________________________________________________________________________________________
	195	Int_t AliRICHParam::Loc2TotQdc(TVector3 x3,Double_t eloss,Int_t iPid,Int_t &sector)
	196	{//calculates the total charge produced by the hit given in local refenrence system
	197	Double_t x=x3.X(),y=x3.Y();
	198
	199	sector=Loc2Sec(x,y);
	200
	201	Double_t gain=QdcSlope(sector)*(1+GainVariation(x3.Y(),sector)/100);
	202
	203
	204	if(iPid>50000){//it's photon => 1 electron
	205	return Int_t(gain*-TMath::Log(gRandom->Rndm()));
	206	}else{//it's MIP
	207	Int_t iNelectrons=Int_t(eloss/IonisationPotential());
	208	if(iNelectrons==0) return 0;
	209	Double_t qdc=0;
	210	for(Int_t i=1;i<=iNelectrons;i++) qdc+=gain*-TMath::Log(gRandom->Rndm());
	211	return Int_t(qdc);
	212	}
543d5224	213	}
c2c6679b	214	//__________________________________________________________________________________________________
c712cb2f	215	Double_t AliRICHParam::Loc2PadFrac(TVector3 hitX3,Int_t padx,Int_t pady)
	216	{//
	217	Double_t padXcenter=0,padYcenter=0; Pad2Loc(padx,pady,padXcenter,padYcenter);
	218
	219	//correction to the position of the nearest wire
	220
	221	Double_t normXmin=(hitX3.X()-padXcenter-PadSizeX()/2) /AnodeCathodeGap();
	222	Double_t normXmax=(hitX3.X()-padXcenter+PadSizeX()/2) /AnodeCathodeGap();
	223	Double_t normYmin=(hitX3.Y()-padYcenter-PadSizeY()/2) /AnodeCathodeGap();
	224	Double_t normYmax=(hitX3.Y()-padYcenter+PadSizeY()/2) /AnodeCathodeGap();
	225
9d6f9427	226	return Mathieson(normXmin,normYmin,normXmax,normYmax);
c712cb2f	227	}//Loc2PadQdc()
c712cb2f	228	//__________________________________________________________________________________________________
9d6f9427	229	Double_t AliRICHParam::Mathieson(Double_t xMin,Double_t yMin,Double_t xMax,Double_t yMax)
c712cb2f	230	{//see NIM A370(1988)602-603
53fd478b	231	const Double_t kSqrtKx3=0.77459667;const Double_t kX2=0.962;const Double_t kX4=0.379;
53fd478b	232	const Double_t kSqrtKy3=0.77459667;const Double_t kY2=0.962;const Double_t kY4=0.379;
c712cb2f	233
53fd478b	234	Double_t ux1=kSqrtKx3TMath::TanH(kX2xMin);
	235	Double_t ux2=kSqrtKx3TMath::TanH(kX2xMax);
	236	Double_t uy1=kSqrtKy3TMath::TanH(kY2yMin);
	237	Double_t uy2=kSqrtKy3TMath::TanH(kY2yMax);
	238	return 4kX4(TMath::ATan(ux2)-TMath::ATan(ux1))kY4(TMath::ATan(uy2)-TMath::ATan(uy1));
c712cb2f	239	}
	240	//__________________________________________________________________________________________________
	241	void AliRICHParam::Loc2Area(TVector3 hitX3,Int_t &iPadXmin,Int_t &iPadYmin,Int_t &iPadXmax,Int_t &iPadYmax)
	242	{//calculates the area of disintegration for a given hit. Area is a rectangulare set pf pads
	243	//defined by its left-down and right-up coners
	244	// hitX3.SetX(Shift2NearestWire(hitX3.X());
9d6f9427	245	Loc2Pad(hitX3.X()-MathiesonDeltaX(),hitX3.Y()-MathiesonDeltaY(),iPadXmin,iPadYmin);
9d6f9427	246	Loc2Pad(hitX3.X()+MathiesonDeltaX(),hitX3.Y()+MathiesonDeltaY(),iPadXmax,iPadYmax);
c712cb2f	247	}//
08479a10	248	//__________________________________________________________________________________________________
	249	Bool_t AliRICHParam::IsOverTh(Int_t iChamber, Int_t x, Int_t y, Double_t q)
	250	{// Calculate the new charge subtracting pedestal and if the current digit is over threshold
	251	if(q>NsigmaTh()*fSigmaThMap[iChamber-1][x-1][y-1]) return kTRUE; else return kFALSE;
	252	}//
d48cca74	253	#endif //AliRICHParam_h