[u/mrichter/AliRoot.git] / MUON / AliMUONSegRes.h

#ifndef MUONSegRes_H
#define MUONSegRes_H
#include "TObject.h"
#include "TClonesArray.h"
#include "TF1.h"
class AliMUONchamber;

//----------------------------------------------
//
// Chamber segmentation virtual base class
//
class AliMUONsegmentation :
public TObject {
 public:
    // Set Chamber Segmentation Parameters
    //
    // Pad size Dx*Dy 
    virtual void    SetPADSIZ(Float_t p1, Float_t p2)  =0;
    // Anod Pitch
    virtual void    SetDAnod(Float_t D)                =0;
    // Transform from pad (wire) to real coordinates and vice versa
    //
    // Anod wire coordinate closest to xhit
    virtual Float_t GetAnod(Float_t xhit)              =0;
    // Transform from pad to real coordinates
    virtual void    GetPadIxy(Float_t x ,Float_t y ,Int_t   &ix,Int_t   &iy)=0;
    // Transform from real to pad coordinates
    virtual void    GetPadCxy(Int_t   ix,Int_t   iy,Float_t &x ,Float_t &y )=0;
    //
    // Initialisation
    virtual void Init(AliMUONchamber*)                 =0;
    //
    // Get member data
    //
    // Pad size in x
    virtual Float_t Dpx()                              =0;
    // Pad size in y 
    virtual Float_t Dpy()                              =0;
    // Pad size in x by Sector 
    virtual Float_t Dpx(Int_t)                         =0;
    // Pad size in y by Sector 
    virtual Float_t Dpy(Int_t)                         =0;
    // Max number of Pads in x
    virtual Int_t    Npx()                             =0;
    // max number of Pads in y
    virtual Int_t    Npy()                             =0;
    // set pad position
    virtual void     SetPad(Int_t, Int_t)              =0;
    // set hit position
    virtual void     SetHit(Float_t, Float_t)          =0;
    
    //
    // Iterate over pads
    // Initialiser
    virtual void  FirstPad(Float_t xhit, Float_t yhit, Float_t dx, Float_t dy) =0;
    // Stepper
    virtual void  NextPad()                            =0;
    // Condition
    virtual Int_t MorePads()                           =0;
    //
    // Distance between 1 pad and a position
    virtual Float_t Distance2AndOffset(Int_t iX, Int_t iY, Float_t X, Float_t Y, Int_t *dummy) =0;
    // Number of pads read in parallel and offset to add to x 
    // (specific to LYON, but mandatory for display)
    virtual void GetNParallelAndOffset(Int_t iX, Int_t iY,
				       Int_t *Nparallel, Int_t *Offset) =0;
    // Get next neighbours 
    virtual void Neighbours
	(Int_t iX, Int_t iY, Int_t* Nlist, Int_t Xlist[10], Int_t Ylist[10])     =0;
    // Current pad cursor during disintegration
    // x-coordinate
    virtual Int_t  Ix()                                =0;
    // y-coordinate
    virtual Int_t  Iy()                                =0;
    // current sector
    virtual Int_t  ISector()                           =0;
    // calculate sector from pad coordinates
    virtual Int_t  Sector(Int_t ix, Int_t iy)          =0;
    //
    // Signal Generation Condition during Stepping
    virtual Int_t SigGenCond(Float_t x, Float_t y, Float_t z) = 0;
    // Initialise signal gneration at coord (x,y,z)
    virtual void  SigGenInit(Float_t x, Float_t y, Float_t z) = 0;
    // Current integration limits 
    virtual void  IntegrationLimits
	(Float_t& x1, Float_t& x2, Float_t& y1, Float_t& y2)  = 0;
    // Test points for auto calibration
    virtual void GiveTestPoints(Int_t &n, Float_t *x, Float_t *y) = 0;
    // Debug utilities
    virtual void Draw(Option_t *)                             = 0;
    // Function for systematic corrections
    virtual void SetCorrFunc(Int_t, TF1*)                         = 0;
    virtual TF1* CorrFunc(Int_t)                                  = 0;
	    
    ClassDef(AliMUONsegmentation,1) //Segmentation class for homogeneous segmentation
};
//----------------------------------------------
//
// Chamber response virtual base class
//
class AliMUONresponse :
public TObject {
 public:
    //
    // Configuration methods
    //
    // Number of sigmas over which cluster didintegration is performed
    virtual void    SetSigmaIntegration(Float_t p1)           =0;
    virtual Float_t SigmaIntegration()                        =0;
    // charge slope in ADC/e
    virtual void    SetChargeSlope(Float_t p1)                =0;
    virtual Float_t ChargeSlope()                             =0;
    // sigma of the charge spread function
    virtual void    SetChargeSpread(Float_t p1, Float_t p2)   =0;
    virtual Float_t ChargeSpreadX()                           =0;
    virtual Float_t ChargeSpreadY()                           =0;
    // Adc-count saturation value
    virtual void    SetMaxAdc(Float_t p1)                     =0;
    virtual Float_t MaxAdc()                                  =0;
    // anode cathode Pitch
    virtual void    SetPitch(Float_t)                         =0;
    virtual Float_t Pitch()                                   =0;
    //  
    // Chamber response methods
    // Pulse height from scored quantity (eloss)
    virtual Float_t IntPH(Float_t eloss)                      =0;
    // Charge disintegration 
    virtual Float_t IntXY(AliMUONsegmentation *)              =0;

    ClassDef(AliMUONresponse,1) // Implementation of Mathieson CPC response 
};
#endif
Commit	Line	Data
	1	#ifndef MUONSegRes_H
	2	#define MUONSegRes_H
	3	#include "TObject.h"
	4	#include "TClonesArray.h"
	5	#include "TF1.h"
	6	class AliMUONchamber;
	7
	8	//----------------------------------------------
	9	//
	10	// Chamber segmentation virtual base class
	11	//
	12	class AliMUONsegmentation :
	13	public TObject {
	14	public:
	15	// Set Chamber Segmentation Parameters
	16	//
	17	// Pad size Dx*Dy
	18	virtual void SetPADSIZ(Float_t p1, Float_t p2) =0;
	19	// Anod Pitch
	20	virtual void SetDAnod(Float_t D) =0;
	21	// Transform from pad (wire) to real coordinates and vice versa
	22	//
	23	// Anod wire coordinate closest to xhit
	24	virtual Float_t GetAnod(Float_t xhit) =0;
	25	// Transform from pad to real coordinates
	26	virtual void GetPadIxy(Float_t x ,Float_t y ,Int_t &ix,Int_t &iy)=0;
	27	// Transform from real to pad coordinates
	28	virtual void GetPadCxy(Int_t ix,Int_t iy,Float_t &x ,Float_t &y )=0;
	29	//
	30	// Initialisation
	31	virtual void Init(AliMUONchamber*) =0;
	32	//
	33	// Get member data
	34	//
	35	// Pad size in x
	36	virtual Float_t Dpx() =0;
	37	// Pad size in y
	38	virtual Float_t Dpy() =0;
	39	// Pad size in x by Sector
	40	virtual Float_t Dpx(Int_t) =0;
	41	// Pad size in y by Sector
	42	virtual Float_t Dpy(Int_t) =0;
	43	// Max number of Pads in x
	44	virtual Int_t Npx() =0;
	45	// max number of Pads in y
	46	virtual Int_t Npy() =0;
	47	// set pad position
	48	virtual void SetPad(Int_t, Int_t) =0;
	49	// set hit position
	50	virtual void SetHit(Float_t, Float_t) =0;
	51
	52	//
	53	// Iterate over pads
	54	// Initialiser
	55	virtual void FirstPad(Float_t xhit, Float_t yhit, Float_t dx, Float_t dy) =0;
	56	// Stepper
	57	virtual void NextPad() =0;
	58	// Condition
	59	virtual Int_t MorePads() =0;
	60	//
	61	// Distance between 1 pad and a position
	62	virtual Float_t Distance2AndOffset(Int_t iX, Int_t iY, Float_t X, Float_t Y, Int_t *dummy) =0;
	63	// Number of pads read in parallel and offset to add to x
	64	// (specific to LYON, but mandatory for display)
	65	virtual void GetNParallelAndOffset(Int_t iX, Int_t iY,
	66	Int_t Nparallel, Int_t Offset) =0;
	67	// Get next neighbours
	68	virtual void Neighbours
	69	(Int_t iX, Int_t iY, Int_t* Nlist, Int_t Xlist[10], Int_t Ylist[10]) =0;
	70	// Current pad cursor during disintegration
	71	// x-coordinate
	72	virtual Int_t Ix() =0;
	73	// y-coordinate
	74	virtual Int_t Iy() =0;
	75	// current sector
	76	virtual Int_t ISector() =0;
	77	// calculate sector from pad coordinates
	78	virtual Int_t Sector(Int_t ix, Int_t iy) =0;
	79	//
	80	// Signal Generation Condition during Stepping
	81	virtual Int_t SigGenCond(Float_t x, Float_t y, Float_t z) = 0;
	82	// Initialise signal gneration at coord (x,y,z)
	83	virtual void SigGenInit(Float_t x, Float_t y, Float_t z) = 0;
	84	// Current integration limits
	85	virtual void IntegrationLimits
	86	(Float_t& x1, Float_t& x2, Float_t& y1, Float_t& y2) = 0;
	87	// Test points for auto calibration
	88	virtual void GiveTestPoints(Int_t &n, Float_t x, Float_t y) = 0;
	89	// Debug utilities
	90	virtual void Draw(Option_t *) = 0;
	91	// Function for systematic corrections
	92	virtual void SetCorrFunc(Int_t, TF1*) = 0;
	93	virtual TF1* CorrFunc(Int_t) = 0;
	94
	95	ClassDef(AliMUONsegmentation,1) //Segmentation class for homogeneous segmentation
	96	};
	97	//----------------------------------------------
	98	//
	99	// Chamber response virtual base class
	100	//
	101	class AliMUONresponse :
	102	public TObject {
	103	public:
	104	//
	105	// Configuration methods
	106	//
	107	// Number of sigmas over which cluster didintegration is performed
	108	virtual void SetSigmaIntegration(Float_t p1) =0;
	109	virtual Float_t SigmaIntegration() =0;
	110	// charge slope in ADC/e
	111	virtual void SetChargeSlope(Float_t p1) =0;
	112	virtual Float_t ChargeSlope() =0;
	113	// sigma of the charge spread function
	114	virtual void SetChargeSpread(Float_t p1, Float_t p2) =0;
	115	virtual Float_t ChargeSpreadX() =0;
	116	virtual Float_t ChargeSpreadY() =0;
	117	// Adc-count saturation value
	118	virtual void SetMaxAdc(Float_t p1) =0;
	119	virtual Float_t MaxAdc() =0;
	120	// anode cathode Pitch
	121	virtual void SetPitch(Float_t) =0;
	122	virtual Float_t Pitch() =0;
	123	//
	124	// Chamber response methods
	125	// Pulse height from scored quantity (eloss)
	126	virtual Float_t IntPH(Float_t eloss) =0;
	127	// Charge disintegration
	128	virtual Float_t IntXY(AliMUONsegmentation *) =0;
	129
	130	ClassDef(AliMUONresponse,1) // Implementation of Mathieson CPC response
	131	};
	132	#endif
	133
	134
	135