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58f66025 | 1 | #ifndef ALIPHOSRECOPARAM_H |
2 | #define ALIPHOSRECOPARAM_H | |
3 | /* Copyright(c) 2007, ALICE Experiment at CERN, All rights reserved. * | |
4 | * See cxx source for full Copyright notice */ | |
5 | ||
6 | /* $Id$ */ | |
7 | ||
8 | // Base class for the PHOS reconstruction parameters. | |
9 | // Do not use in the reconstruction; use derivative classes instead. | |
10 | ||
cf4e2a86 | 11 | #include "AliDetectorRecoParam.h" |
58f66025 | 12 | |
cf4e2a86 | 13 | class AliPHOSRecoParam : public AliDetectorRecoParam { |
58f66025 | 14 | |
15 | public: | |
16 | ||
17 | AliPHOSRecoParam(); | |
18 | AliPHOSRecoParam(const AliPHOSRecoParam& recoParam); | |
19 | AliPHOSRecoParam& operator = (const AliPHOSRecoParam& recoParam); | |
20 | virtual ~AliPHOSRecoParam() {} | |
21 | ||
7e88424f | 22 | Float_t GetEMCClusteringThreshold() const { return fEMCClusteringThreshold; } |
23 | Float_t GetEMCLocalMaxCut() const { return fEMCLocMaxCut; } | |
12dd7f10 | 24 | Float_t GetEMCRawDigitThreshold() const { return fEMCRawDigitThreshold; } |
7e88424f | 25 | Float_t GetEMCMinE() const { return fEMCMinE; } |
26 | Float_t GetEMCLogWeight() const { return fEMCW0; } | |
27 | Float_t GetEMCSampleQualityCut() const { return fEMCSampleQualityCut; } | |
28 | Float_t GetEMCEcoreRadius() const { return fEMCEcoreRadius; } | |
29 | Bool_t EMCEcore2ESD() const { return fEMCEcore2ESD; } | |
30 | Bool_t EMCSubtractPedestals() const { return fEMCSubtractPedestals; } | |
31 | Bool_t EMCToUnfold() const { return fEMCUnfold; } | |
379c5c09 | 32 | const char* EMCFitterVersion() const { return fEMCFitterVersion.Data(); } |
71994f35 | 33 | Bool_t GetEMCEnergyCorrectionOn() const { return fEMCEnergyCorrectionOn; } |
aa64ff7a | 34 | Int_t GetGlobalAltroOffset() const { return fGlobalAltroOffset ; } |
f78c9781 | 35 | Int_t GetGlobalAltroThreshold() const { return fGlobalAltroThreshold ; } |
7e88424f | 36 | |
37 | Float_t GetCPVClusteringThreshold() const { return fCPVClusteringThreshold; } | |
38 | Float_t GetCPVLocalMaxCut() const { return fCPVLocMaxCut; } | |
39 | Float_t GetCPVMinE() const { return fCPVMinE; } | |
40 | Float_t GetCPVLogWeight() const { return fCPVW0; } | |
41 | Bool_t CPVToUnfold() const { return fCPVUnfold; } | |
42 | ||
43 | void SetEMCClusteringThreshold(Float_t cluth) { fEMCClusteringThreshold=cluth; } | |
44 | void SetEMCLocalMaxCut(Float_t cut) { fEMCLocMaxCut =cut; } | |
12dd7f10 | 45 | void SetEMCRawDigitThreshold(Float_t rawDigTh) { fEMCRawDigitThreshold =rawDigTh;} |
7e88424f | 46 | void SetEMCMinE(Float_t minE) { fEMCMinE =minE; } |
47 | void SetEMCLogWeight(Float_t w) { fEMCW0 =w; } | |
48 | void SetEMCSampleQualityCut(Float_t qu) { fEMCSampleQualityCut =qu; } | |
49 | void SetEMCEcoreRadius(Float_t rCore) { fEMCEcoreRadius =rCore; } | |
50 | void SetEMCEcore2ESD(Bool_t ecore) { fEMCEcore2ESD =ecore; } | |
51 | void SetEMCSubtractPedestals(Bool_t subtract) { fEMCSubtractPedestals =subtract;} | |
379c5c09 | 52 | void SetEMCFitterVersion(const char* version="v1") { fEMCFitterVersion =version ; } |
71994f35 | 53 | void SetEMCUnfolding(Bool_t toUnfold=kFALSE) { fEMCUnfold =toUnfold;} |
54 | void SetEMCEnergyCorrectionOn(Bool_t on=kTRUE) { fEMCEnergyCorrectionOn =on; } | |
55 | void SetGlobalAltroOffset(Int_t offset=5) { fGlobalAltroOffset =offset ; } | |
f78c9781 | 56 | void SetGlobalAltroThreshold(Int_t ZSth=5) { fGlobalAltroThreshold =ZSth; } |
7e88424f | 57 | |
58 | void SetCPVClusteringThreshold(Float_t cluth) { fCPVClusteringThreshold=cluth; } | |
59 | void SetCPVLocalMaxCut(Float_t cut) { fCPVLocMaxCut =cut; } | |
60 | void SetCPVMinE(Float_t minE) { fCPVMinE =minE; } | |
61 | void SetCPVLogWeight(Float_t w) { fCPVW0 =w; } | |
62 | void SetCPVUnfolding(Bool_t toUnfold=kFALSE) { fCPVUnfold =toUnfold;} | |
63 | ||
12dd7f10 | 64 | virtual void Print(const Option_t *option="RecoParam") const; |
0428f331 | 65 | |
7e88424f | 66 | static AliPHOSRecoParam* GetDefaultParameters(); |
67 | static const TObjArray* GetMappings(); | |
58f66025 | 68 | |
69 | protected: | |
70 | ||
7e88424f | 71 | Float_t fEMCClusteringThreshold; // EMC: Min.digit energy to start a new cluster, in GeV |
72 | Float_t fEMCLocMaxCut; // EMC: Min.energy difference between two local maxima, in GeV | |
12dd7f10 | 73 | Float_t fEMCRawDigitThreshold; // EMC: Min.amplitude of a digit produced from raw data in ADC |
74 | Float_t fEMCMinE; // EMC: Min.E in the digits list associated with rec.point, in GeV | |
7e88424f | 75 | Float_t fEMCW0; // EMC: Log.weight to evaluate a local coordinate of rec.point |
76 | Float_t fEMCSampleQualityCut; // EMC: Cut on pulse shape fit quality | |
77 | Float_t fEMCEcoreRadius; // EMC: Radius within which the core energy is calculated, in cm | |
78 | Bool_t fEMCEcore2ESD; // EMC: true if Ecore is stored in ESD instead of Etot | |
79 | Bool_t fEMCSubtractPedestals; // EMC: true if pedestal should be subtracted (in non-ZS) | |
80 | Bool_t fEMCUnfold; // EMC: true if overlapped clusters should be unfolded | |
71994f35 | 81 | Bool_t fEMCEnergyCorrectionOn; // EMC: if true do non-linear correction of cluster energy |
379c5c09 | 82 | TString fEMCFitterVersion ; // EMC: AliPHOSRawFitter version |
aa64ff7a | 83 | Int_t fGlobalAltroOffset ; // Offset used in ALTRO chips in SZ runs |
f78c9781 | 84 | Int_t fGlobalAltroThreshold ; // Threshold used in ALTRO chips in SZ runs |
7e88424f | 85 | |
86 | Float_t fCPVClusteringThreshold; // CPV: Min.digit energy to start a new cluster, in GeV | |
87 | Float_t fCPVLocMaxCut; // CPV: Min.energy difference between two local maxima, in GeV | |
88 | Float_t fCPVMinE; // CPV: Min.E in the digits list associated with rec.point, in GeV | |
89 | Float_t fCPVW0; // CPV: Log.weight to evaluate a local coordinate of rec.point | |
90 | Bool_t fCPVUnfold; // CPV: true if overlapped clusters should be unfolded | |
91 | ||
92 | static TObjArray* fgkMaps; // ALTRO mappings for RCU0..RCU3 | |
93 | ||
f78c9781 | 94 | ClassDef(AliPHOSRecoParam,10) |
58f66025 | 95 | }; |
96 | ||
97 | #endif |