#ifndef AliRICHParam_h #define AliRICHParam_h #include #include "AliRICHConst.h" class AliRICHParam :public TObject { public: AliRICHParam(); void Recalc();//Recalculate dependent parameters after changes void Segmentation(Int_t Nx, Int_t Ny) {fNx=Nx;fNy=Ny;Recalc();} Int_t Nx() const{return fNx;} Int_t Ny() const{return fNy;} void DeadZone(Float_t a) { fDeadZone=a;Recalc();} Float_t DeadZone() const{return fDeadZone;} void PadSize(Float_t x,Float_t y) { fPadX=x;fPadY=y;Recalc();} Float_t PadX() const{return fPadX;} Float_t PadY() const{return fPadY;} Float_t PadPlaneWidth() const{return fPadPlaneWidth;} Float_t PadPlaneLength() const{return fPadPlaneLength;} void Size(Float_t x,Float_t y,Float_t z){fSizeX=x;fSizeY=y;fSizeZ=z;} void GeantSize(Float_t *pParam) const{pParam[0]=fSizeX/2;pParam[1]=fSizeY/2;pParam[2]=fSizeZ/2;} Float_t SizeX() const{return fSizeX;} Float_t SizeY() const{return fSizeY;} Float_t SizeZ() const{return fSizeZ;} void Offset(Float_t offset) { fOffset=offset;} Float_t Offset() const{return fOffset;} void AnglesDeg(Float_t xy,Float_t yz) { fAngleXY=xy;fAngleYZ=yz;} Float_t AngleYZ() const{return fAngleYZ*d2r;} Float_t AngleXY() const{return fAngleXY*d2r;} void AngleRot(Float_t angle) { fAngleRot=angle;} Float_t AngleRot() const{return fAngleRot*d2r;} void GapThickness(Float_t a) { fGapThickness=a;} Float_t GapThickness() const{return fGapThickness;} void ProximityGapThickness(Float_t a) { fProximityGapThickness=a;} Float_t ProximityGapThickness() const{return fProximityGapThickness;} void QuartzLength(Float_t a) { fQuartzLength=a;} Float_t QuartzLength() const{return fQuartzLength;} void QuartzWidth(Float_t a) { fQuartzWidth=a;} Float_t QuartzWidth() const{return fQuartzWidth;} void QuartzThickness(Float_t a) { fQuartzThickness=a;} Float_t QuartzThickness() const{return fQuartzThickness;} void OuterFreonLength(Float_t a) { fOuterFreonLength=a;} Float_t OuterFreonLength() const{return fOuterFreonLength;} void OuterFreonWidth(Float_t a) { fOuterFreonWidth=a;} Float_t OuterFreonWidth() const{return fOuterFreonWidth;} void InnerFreonLength(Float_t a) { fInnerFreonLength=a;} Float_t InnerFreonLength() const{return fInnerFreonLength;} void InnerFreonWidth(Float_t a) { fInnerFreonWidth=a;} Float_t InnerFreonWidth() const{return fInnerFreonWidth;} void FreonThickness(Float_t a) { fFreonThickness=a;} Float_t FreonThickness() const{return fFreonThickness;} void RadiatorToPads(Float_t a) { fRadiatorToPads=a;} Float_t RadiatorToPads() const{return fRadiatorToPads;} void SigmaIntegration(Float_t a) { fSigmaIntegration=a;} Float_t SigmaIntegration() const{return fSigmaIntegration;} void ChargeSpreadX(Float_t a) { fChargeSpreadX=a;} Float_t ChargeSpreadX() const{return fChargeSpreadX;} void ChargeSpreadY(Float_t a) { fChargeSpreadY=a;} Float_t ChargeSpreadY() const{return fChargeSpreadY;} void ChargeSlope(Float_t a) { fChargeSlope=a;} Float_t ChargeSlope() {return fChargeSlope;} void MaxAdc(Float_t a) { fMaxAdc=a;} Float_t MaxAdc() const{return fMaxAdc;} void Pitch(Float_t a) { fPitch=a;}; Float_t Pitch() const{return fPitch;} void AlphaFeedback(Float_t a) { fAlphaFeedback=a;} Float_t AlphaFeedback() const{return fAlphaFeedback;} void EIonisation(Float_t a) { fEIonisation=a;} Float_t EIonisation() const{return fEIonisation;} void SqrtKx3(Float_t a) { fSqrtKx3=a;}; void Kx2(Float_t a) { fKx2=a;}; void Kx4(Float_t a) { fKx4=a;}; void SqrtKy3(Float_t a) { fSqrtKy3=a;}; void Ky2(Float_t a) { fKy2=a;}; void Ky4(Float_t a) { fKy4=a;}; void WireSag(Int_t a) { fWireSag=a;}; void Voltage(Int_t a) { fVoltage=a;}; protected: Int_t fNx; //number of pads along X Int_t fNy; //number of pads along Y Float_t fDeadZone; //spacer between PC planes, cm Float_t fPadX; //pad width, cm Float_t fPadY; //pad lenght, cm Float_t fPadPlaneWidth; //pad plane width, cm Float_t fPadPlaneLength; //pad plane length, cm Float_t fSizeX; //chamber length, cm Float_t fSizeY; //chamber thickness, cm Float_t fSizeZ; //chamber width, cm Float_t fAngleRot; //azimuthal rotation angle in X-Y plane, grad Float_t fAngleYZ; //angle between RICH chambers in YZ plane, grad Float_t fAngleXY; //angle between RICH chambers in XY plane, grad Float_t fOffset; //chambers offset from IP, cm Float_t fGapThickness; //gap thickness, cm Float_t fProximityGapThickness; //proximity gap thickness, cm Float_t fQuartzLength; //quartz length Float_t fQuartzWidth; //quartz width Float_t fQuartzThickness; //quartz thickness Float_t fOuterFreonLength; //outer freon length Float_t fOuterFreonWidth; //outer freon width Float_t fInnerFreonLength; //inner freon length Float_t fInnerFreonWidth; //inner freon width Float_t fFreonThickness; //freon thickness Float_t fRadiatorToPads; //distance from radiator to pads Float_t fChargeSlope; //Slope of the charge distribution Float_t fChargeSpreadX; //Width of the charge distribution in x Float_t fChargeSpreadY; //Width of the charge distribution in y Float_t fSigmaIntegration; //Number of sigma's used for charge distribution Float_t fAlphaFeedback; //Feedback photons coefficient Float_t fEIonisation; //Mean ionisation energy Float_t fMaxAdc; //Maximum ADC channel Float_t fSqrtKx3; //Mathieson parameters for x Float_t fKx2; //Mathieson parameters for x Float_t fKx4; //Mathieson parameters for x Float_t fSqrtKy3; //Mathieson parameters for y Float_t fKy2; //Mathieson parameters for y Float_t fKy4; //Mathieson parameters for y Float_t fPitch; //Anode-cathode pitch Int_t fWireSag; //Flag to turn on/off (0/1) wire sag Int_t fVoltage; //Working voltage (2000, 2050, 2100, 2150) ClassDef(AliRICHParam,1) //RICH main parameters }; #endif //AliRICHParam_h