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a9e2aefa | 1 | #ifndef ALIMUONRESPONSEV0_H |
2 | #define ALIMUONRESPONSEV0_H | |
3 | /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * | |
4 | * See cxx source for full Copyright notice */ | |
5 | ||
6 | /* $Id$ */ | |
7 | ||
8 | #include "AliMUONResponse.h" | |
9 | ||
10 | class AliMUONResponseV0 : | |
11 | public AliMUONResponse { | |
12 | public: | |
16d57990 | 13 | AliMUONResponseV0(){fChargeCorrel = 0;} // by default |
a9e2aefa | 14 | virtual ~AliMUONResponseV0(){} |
15 | // | |
16 | // Configuration methods | |
17 | // | |
18 | // Set number of sigmas over which cluster didintegration is performed | |
19 | virtual void SetSigmaIntegration(Float_t p1) {fSigmaIntegration=p1;} | |
20 | // Get number of sigmas over which cluster didintegration is performed | |
21 | virtual Float_t SigmaIntegration() {return fSigmaIntegration;} | |
22 | // Set single electron pulse height (ADCcounts/e) | |
23 | virtual void SetChargeSlope(Float_t p1) {fChargeSlope=p1;} | |
24 | // Get Set single electron pulse height (ADCcounts/e) | |
25 | virtual Float_t ChargeSlope() {return fChargeSlope;} | |
26 | // Set sigmas of the charge spread function | |
27 | virtual void SetChargeSpread(Float_t p1, Float_t p2) | |
28 | {fChargeSpreadX=p1; fChargeSpreadY=p2;} | |
29 | // Get sigma_X of the charge spread function | |
30 | virtual Float_t ChargeSpreadX() {return fChargeSpreadX;} | |
31 | // Get sigma_Y of the charge spread function | |
32 | virtual Float_t ChargeSpreadY() {return fChargeSpreadY;} | |
33 | // Set maximum Adc-count value | |
34 | virtual void SetMaxAdc(Int_t p1) {fMaxAdc=p1;} | |
35 | // Set zero suppression threshold | |
36 | virtual void SetZeroSuppression(Int_t p1) {fZeroSuppression=p1;} | |
37 | // Get maximum Adc-count value | |
38 | virtual Int_t MaxAdc() {return fMaxAdc;} | |
39 | // Get zero suppression threshold | |
40 | virtual Int_t ZeroSuppression() {return fZeroSuppression;} | |
41 | // Set anode cathode Pitch | |
42 | virtual Float_t Pitch() {return fPitch;} | |
43 | // Get anode cathode Pitch | |
44 | virtual void SetPitch(Float_t p1) {fPitch=p1;}; | |
16d57990 | 45 | // Set the charge correlation |
46 | virtual void SetChargeCorrel(Float_t correl){fChargeCorrel = correl;} | |
47 | // Get the charge correlation | |
48 | virtual Float_t ChargeCorrel(){return fChargeCorrel;} | |
a9e2aefa | 49 | // Set Mathieson parameters |
d5bfadcc | 50 | // Mathieson \sqrt{Kx3} and derived Kx2 and Kx4 |
51 | virtual void SetSqrtKx3AndDeriveKx2Kx4(Float_t SqrtKx3); | |
a9e2aefa | 52 | // Mathieson \sqrt{Kx3} |
53 | virtual void SetSqrtKx3(Float_t p1) {fSqrtKx3=p1;}; | |
54 | // Mathieson Kx2 | |
55 | virtual void SetKx2(Float_t p1) {fKx2=p1;}; | |
56 | // Mathieson Kx4 | |
57 | virtual void SetKx4(Float_t p1) {fKx4=p1;}; | |
d5bfadcc | 58 | // Mathieson \sqrt{Ky3} and derived Ky2 and Ky4 |
59 | virtual void SetSqrtKy3AndDeriveKy2Ky4(Float_t SqrtKy3); | |
a9e2aefa | 60 | // Mathieson \sqrt{Ky3} |
61 | virtual void SetSqrtKy3(Float_t p1) {fSqrtKy3=p1;}; | |
62 | // Mathieson Ky2 | |
63 | virtual void SetKy2(Float_t p1) {fKy2=p1;}; | |
64 | // Mathieson Ky4 | |
65 | virtual void SetKy4(Float_t p1) {fKy4=p1;}; | |
66 | // | |
67 | // Chamber response methods | |
68 | // Pulse height from scored quantity (eloss) | |
69 | virtual Float_t IntPH(Float_t eloss); | |
70 | // Charge disintegration | |
a30a000f | 71 | virtual Float_t IntXY(AliSegmentation * segmentation); |
a9e2aefa | 72 | // Noise, zero-suppression, adc saturation |
73 | virtual Int_t DigitResponse(Int_t digit); | |
74 | ||
75 | ClassDef(AliMUONResponseV0,1) // Implementation of Mathieson response | |
76 | protected: | |
77 | Float_t fChargeSlope; // Slope of the charge distribution | |
78 | Float_t fChargeSpreadX; // Width of the charge distribution in x | |
79 | Float_t fChargeSpreadY; // Width of the charge distribution in y | |
80 | Float_t fSigmaIntegration; // Number of sigma's used for charge distribution | |
81 | Int_t fMaxAdc; // Maximum ADC channel | |
82 | Int_t fZeroSuppression; // Zero suppression threshold | |
16d57990 | 83 | Float_t fChargeCorrel; // amplitude of charge correlation on 2 cathods |
84 | // is RMS of ln(q1/q2) | |
d5bfadcc | 85 | Float_t fSqrtKx3; // Mathieson Sqrt(Kx3) |
a9e2aefa | 86 | Float_t fKx2; // Mathieson Kx2 |
d5bfadcc | 87 | Float_t fKx4; // Mathieson Kx4 = Kx1/Kx2/Sqrt(Kx3) |
88 | Float_t fSqrtKy3; // Mathieson Sqrt(Ky3) | |
a9e2aefa | 89 | Float_t fKy2; // Mathieson Ky2 |
d5bfadcc | 90 | Float_t fKy4; // Mathieson Ky4 = Ky1/Ky2/Sqrt(Ky3) |
a9e2aefa | 91 | Float_t fPitch; // anode-cathode pitch |
92 | }; | |
93 | #endif | |
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