[ViewVC] Diff of: cvsroot/UserCode/MitAna/DataTree/interface/Muon.h

Comparing UserCode/MitAna/DataTree/interface/Muon.h (file contents):
Revision 1.18 by loizides, Thu Nov 27 16:15:06 2008 UTC vs.
Revision 1.45 by paus, Sun Oct 23 01:53:16 2011 UTC

#	Line 3 \| Line 3
3		//
4		// Muon
5		//
6	<	// Details to be worked out... TODO by Phil
6	>	// Classified into 3 Types
7	>	// Standalone : Muon fit from hits in the muon chambers
8	>	// Tracker : Tracker matched track to muon chambers with segments
9	>	// Global : Combined track and muon chambers fit
10	>	//
11	>	// In the muon class all three muon classes exist and can be determined by checking
12	>	// whether a fit track exists for such a Muon (eg HasTrackerTrk() == kTRUE). When
13	>	// BestTrk function is called the global fit is returned, if that does not
14	>	// exist the tracker fit is returned upon that failure the standalone muon
15	>	// is subsequently returned. To consult more see:
16	>	// http://cmsdoc.cern.ch/cms/Physics/muon/MPOG/Notes/MuonReco.pdf
17	>	//
18	>	// Quality Varaibles for Selection
19	>	// Isolation : decomposed to IsoRNNXXXXX
20	>	// NN = 03,05 to denote R =0.3,0.5 in Isolation Cone
21	>	// XXXXX = SumPt - Sum of Pt of Tracks in Cone (using all Pt Tracks)
22	>	// XXXXX = EmEt - Sum of Et of Em component of Calo Towers (Veto=0.08)
23	>	// XXXXX = HadEt - Sum of Et of Had component of Calo Towers (Veto=0.1)
24	>	// XXXXX = HoEt - Sum of Pt of Ho component of Calo Towers (Veto=0.1)
25	>	// XXXXX = NTrk - Number of Tracks within Cone (using all Pt Tracks)
26	>	// XXXXX = NJet - Sum of Jets inside Cone
27	>	//
28	>	// Muon Quality Variables
29	>	// Extracted from the Muon Tracking Associator
30	>	// For more se https://twiki.cern.ch/twiki/bin/view/CMS/TrackAssociator
31	>	// Energy Variables : Energy within (5x5 Ecal Crystal/Hcal/Ho) along Track
32	>	// using calo towers
33	>	// S9 Energy Variables : Energy using reconstructed hits calo towers default
34	>	// Segment Variables :
35	>	// Segment variables are stored in array of 8:
36	>	// 0-3: Correspond to segments in 4 DT chambers in->outward(3 has no Y res)
37	>	// 4-7: Correspond to segments in 4 CSC chambers in->out
38	>	// If value undetermined 999999 is returned.
39	>	// Variables:
40	>	// DX,DY,PullX,PullY: Uncertainties/Pulls of propagated track
41	>	// with respect to local muon segment
42	>	// TrackDist,TrackDistErr: Summed Dist/Err (in X,Y) of segment with respect
43	>	// to propagated track
44	>	// NSegments : Number of segments in muon using Segment+Track Arbitration
45	>	// NChambers : Number of muon chambers traversed in propagated track
46	>	// NMatches : Number of muon chambers with matches
47	>	// LastHit : Returns farest (from center) station with a recorded segment
48	>	// LastStation : Returns farest station using Segment+Track Arbitration
49	>	//
50	>	// Muon Id Methods: Please see Muon Id Note(as of now unpublished):
51	>	// https://www.cmsaf.mit.edu/twiki/pub/CmsHep/HepWAnalysis/MuonID-ingo.pdf
52	>	// TMOneStation : Returns bool whether muon passes "Tracker Muon One StationId"
53	>	// -Matching criteria for one of all segments matched to muon
54	>	// TMLastStation : Returns bool whether muon passes "LastStation Id" criteria
55	>	// -Matching criteria for last most segment
56		//
57		// Authors: J.Bendavid, C.Loizides, C.Paus, P.Harris
58		//--------------------------------------------------------------------------------------------------
#	Line 11 \| Line 60
60		#ifndef MITANA_DATATREE_MUON_H
61		#define MITANA_DATATREE_MUON_H
62
14	–	#include <TRef.h>
63		#include "MitAna/DataTree/interface/Track.h"
64		#include "MitAna/DataTree/interface/ChargedParticle.h"
65	+	#include "MitAna/DataTree/interface/MuonQuality.h"
66
67		namespace mithep {
68		class Muon : public ChargedParticle {
69		public:
70	<	Muon() {}
22	<	~Muon() {}
70	>	Muon();
71
72		enum EClassType {
73		kNone, //no track assigned
74		kGlobal, //"Global"
75	<	kTrackerOnly, //"TrackerOnly"
75	>	kTracker, //"Tracker"
76		kSta, //"Standalone"
77		kAny //any "best" of the above
78		};
79
80	<	const Track *BestTrk() const;
81	<	const Track *GlobalTrk() const;
82	<	const Track *StandaloneTrk() const;
83	<	const Track *TrackerTrk() const;
84	<	const Track *Trk() const { return BestTrk(); }
85	<	Double_t IsoR03SumPt() const { return fIsoR03SumPt; }
86	<	Double_t IsoR03EmEt() const { return fIsoR03EmEt; }
87	<	Double_t IsoR03HadEt() const { return fIsoR03HadEt; }
88	<	Double_t IsoR03HoEt() const { return fIsoR03HoEt; }
89	<	Int_t IsoR03NTracks() const { return fIsoR03NTracks; }
90	<	Int_t IsoR03NJets() const { return fIsoR03NJets; }
91	<	Double_t IsoR05SumPt() const { return fIsoR05SumPt; }
92	<	Double_t IsoR05EmEt() const { return fIsoR05EmEt; }
93	<	Double_t IsoR05HadEt() const { return fIsoR05HadEt; }
94	<	Double_t IsoR05HoEt() const { return fIsoR05HoEt; }
95	<	Int_t IsoR05NTracks() const { return fIsoR05NTracks; }
96	<	Int_t IsoR05NJets() const { return fIsoR05NJets; }
97	<	Double_t EmEnergy() const { return fEmEnergy; }
98	<	Double_t HadEnergy() const { return fHadEnergy; }
99	<	Double_t HoEnergy() const { return fHoEnergy; }
100	<	Double_t EmS9Energy() const { return fEmS9Energy; }
101	<	Double_t HadS9Energy() const { return fHadS9Energy; }
102	<	Double_t HoS9Energy() const { return fHoS9Energy; }
103	<	Double_t Mass() const { return 105.658369e-3; }
104	<	Int_t NChambers() const { return fNTraversedChambers; }
105	<	Int_t NSegments() const { return fStationMask.NBitsSet(); }
106	<	Bool_t StationBit(Int_t bit) const { return fStationMask.TestBit(bit); }
107	<	Double_t GetDX(Int_t iStation) const;
108	<	Double_t GetDY(Int_t iStation) const;
109	<	Double_t GetPullX(Int_t iStation) const;
110	<	Double_t GetPullY(Int_t iStation) const;
111	<	Double_t GetTrackDist(Int_t iStation) const;
112	<	Double_t GetTrackDistErr(Int_t iStation) const;
113	<	Int_t GetNSegments(Int_t iStation) const;
114	<	Bool_t Has(EClassType type) const;
115	<	EClassType Is() const;
116	<	Int_t LastHit() const;
80	>	const Track *BestTrk() const;
81	>	const Track *GlobalTrk() const { return fGlobalTrkRef.Obj(); }
82	>	const Track *StandaloneTrk() const { return fStaTrkRef.Obj(); }
83	>	const Track *TrackerTrk() const { return fTrkTrkRef.Obj(); }
84	>	const Track *Trk() const { return BestTrk(); }
85	>	Double_t D0PV() const { return fD0PV; }
86	>	Double_t D0PVErr() const { return fD0PVErr; }
87	>	Double_t D0PVSignificance() const { return fD0PV/fD0PVErr; }
88	>	Double_t Ip3dPV() const { return fIp3dPV; }
89	>	Double_t Ip3dPVErr() const { return fIp3dPVErr; }
90	>	Double_t Ip3dPVSignificance() const { return fIp3dPV/fIp3dPVErr; }
91	>	Double_t D0PVBS() const { return fD0PVBS; }
92	>	Double_t D0PVBSErr() const { return fD0PVBSErr; }
93	>	Double_t D0PVBSSignificance() const { return fD0PVBS/fD0PVBSErr; }
94	>	Double_t Ip3dPVBS() const { return fIp3dPVBS; }
95	>	Double_t Ip3dPVBSErr() const { return fIp3dPVBSErr; }
96	>	Double_t Ip3dPVBSSignificance() const { return fIp3dPVBS/fIp3dPVBSErr; }
97	>	Double_t D0PVUB() const { return fD0PVUB; }
98	>	Double_t D0PVUBErr() const { return fD0PVUBErr; }
99	>	Double_t D0PVUBSignificance() const { return fD0PVUB/fD0PVUBErr; }
100	>	Double_t Ip3dPVUB() const { return fIp3dPVUB; }
101	>	Double_t Ip3dPVUBErr() const { return fIp3dPVUBErr; }
102	>	Double_t Ip3dPVUBSignificance() const { return fIp3dPVUB/fIp3dPVUBErr; }
103	>	Double_t D0PVUBBS() const { return fD0PVUBBS; }
104	>	Double_t D0PVUBBSErr() const { return fD0PVUBBSErr; }
105	>	Double_t D0PVUBBSSignificance() const { return fD0PVUBBS/fD0PVUBBSErr; }
106	>	Double_t Ip3dPVUBBS() const { return fIp3dPVUBBS; }
107	>	Double_t Ip3dPVUBBSErr() const { return fIp3dPVUBBSErr; }
108	>	Double_t Ip3dPVUBBSSignificance() const { return fIp3dPVUBBS/fIp3dPVUBBSErr;}
109	>	Double_t PVCompatibility() const { return fPVCompatibility; }
110	>	Double_t PVBSCompatibility() const { return fPVBSCompatibility; }
111	>	Double_t TrkKink() const { return fTrkKink; }
112	>	Double_t GlbKink() const { return fGlbKink; }
113	>	Double_t EmEnergy() const { return fEmEnergy; }
114	>	Double_t EmS9Energy() const { return fEmS9Energy; }
115	>	Double_t GetDX(Int_t iStation) const;
116	>	Double_t GetDY(Int_t iStation) const;
117	>	Double_t GetPullX(Int_t iStation) const;
118	>	Double_t GetPullY(Int_t iStation) const;
119	>	Double_t GetTrackDist(Int_t iStation) const;
120	>	Double_t GetTrackDistErr(Int_t iStation) const;
121	>	Int_t GetNSegments(Int_t iStation) const;
122	>	Bool_t Has(EClassType type) const;
123	>	Bool_t HasTrk() const;
124	>	Bool_t HasGlobalTrk() const { return fGlobalTrkRef.IsValid(); }
125	>	Bool_t HasStandaloneTrk() const { return fStaTrkRef.IsValid(); }
126	>	Bool_t HasTrackerTrk() const { return fTrkTrkRef.IsValid(); }
127	>	Double_t HadEnergy() const { return fHadEnergy; }
128	>	Double_t HadS9Energy() const { return fHadS9Energy; }
129	>	Double_t HoEnergy() const { return fHoEnergy; }
130	>	Double_t HoS9Energy() const { return fHoS9Energy; }
131	>	EClassType Is() const;
132	>	Bool_t IsGlobalMuon() const { return fIsGlobalMuon; }
133	>	Bool_t IsTrackerMuon() const { return fIsTrackerMuon; }
134	>	Bool_t IsStandaloneMuon() const { return fIsStandaloneMuon; }
135	>	Bool_t IsCaloMuon() const { return fIsCaloMuon; }
136	>	Double_t IsoR03SumPt() const { return fIsoR03SumPt; }
137	>	Double_t IsoR03EmEt() const { return fIsoR03EmEt; }
138	>	Double_t IsoR03HadEt() const { return fIsoR03HadEt; }
139	>	Double_t IsoR03HoEt() const { return fIsoR03HoEt; }
140	>	UShort_t IsoR03NTracks() const { return fIsoR03NTracks; }
141	>	UShort_t IsoR03NJets() const { return fIsoR03NJets; }
142	>	Double_t IsoR05SumPt() const { return fIsoR05SumPt; }
143	>	Double_t IsoR05EmEt() const { return fIsoR05EmEt; }
144	>	Double_t IsoR05HadEt() const { return fIsoR05HadEt; }
145	>	Double_t IsoR05HoEt() const { return fIsoR05HoEt; }
146	>	UShort_t IsoR05NTracks() const { return fIsoR05NTracks; }
147	>	UShort_t IsoR05NJets() const { return fIsoR05NJets; }
148	>	UInt_t NValidHits() const { return fNValidHits; }
149	>	UInt_t NChambers() const { return fNTraversedChambers; }
150	>	UInt_t NSegments() const { return fStationMask.NBitsSet(); }
151	>	UInt_t NMatches() const { return fNMatches; }
152	>	Int_t LastHit() const;
153		Int_t LastStation(Double_t iMaxD, Double_t iMaxP) const;
154	<	Int_t LastStation(Int_t iMax=8) const;
155	<	Bool_t PromptTight(EClassType type) const;
156	<	Bool_t TMLastStation(Double_t iDYMin = 3., Double_t iPYMin = 3.,
157	<	Double_t iDXMin = 3., Double_t iPXMin = 3.,Int_t iN = 2) const;
158	<	Bool_t TMOneStation(Double_t iDYMin = 3., Double_t iPYMin = 3.,
159	<	Double_t iDXMin = 3., Double_t iPXMin = 3.,Int_t iN = 1) const;
160	<	void SetGlobalTrk(Track* t) { fGlobalTrackRef = t; }
161	<	void SetStandaloneTrk(Track* t) { fStandaloneTrackRef = t; }
162	<	void SetTrackerTrk(Track* t) { fTrackerTrackRef = t; }
163	<	void SetIsoR03SumPt(Double_t isoR03SumPt) { fIsoR03SumPt = isoR03SumPt; }
164	<	void SetIsoR03EmEt(Double_t isoR03EmEt) { fIsoR03EmEt = isoR03EmEt; }
165	<	void SetIsoR03HadEt(Double_t isoR03HadEt) { fIsoR03HadEt = isoR03HadEt; }
166	<	void SetIsoR03HoEt(Double_t isoR03HoEt) { fIsoR03HoEt = isoR03HoEt; }
167	<	void SetIsoR03NTracks(Int_t isoR03NTracks) { fIsoR03NTracks = isoR03NTracks; }
168	<	void SetIsoR03NJets(Int_t isoR03NJets) { fIsoR03NJets = isoR03NJets; }
169	<	void SetIsoR05SumPt(Double_t isoR05SumPt) { fIsoR05SumPt = isoR05SumPt; }
170	<	void SetIsoR05EmEt(Double_t isoR05EmEt) { fIsoR05EmEt = isoR05EmEt; }
171	<	void SetIsoR05HadEt(Double_t isoR05HadEt) { fIsoR05HadEt = isoR05HadEt; }
172	<	void SetIsoR05HoEt(Double_t isoR05HoEt) { fIsoR05HoEt = isoR05HoEt; }
89	<	void SetIsoR05NTracks(Int_t isoR05NTracks) { fIsoR05NTracks = isoR05NTracks; }
90	<	void SetIsoR05NJets(Int_t isoR05NJets) { fIsoR05NJets = isoR05NJets; }
91	<	void SetEmEnergy(Double_t EmEnergy) { fEmEnergy = EmEnergy; }
92	<	void SetHadEnergy(Double_t HadEnergy) { fHadEnergy = HadEnergy; }
93	<	void SetHoEnergy(Double_t HoEnergy) { fHoEnergy = HoEnergy; }
94	<	void SetEmS9Energy(Double_t EmS9Energy) { fEmS9Energy = EmS9Energy; }
95	<	void SetHadS9Energy(Double_t HadS9Energy) { fHadS9Energy = HadS9Energy; }
96	<	void SetHoS9Energy(Double_t HoS9Energy) { fHoS9Energy = HoS9Energy; }
97	<	void SetNChambers(Int_t iNTraCh) { fNTraversedChambers = iNTraCh; }
98	<	void SetStationMask(UInt_t iStMask) { fStationMask.SetBits(iStMask); }
154	>	Int_t LastStation(Int_t iMax=8) const;
155	>	Int_t ObjId() const { return ObjType()*1000+Is(); }
156	>	EObjType ObjType() const { return kMuon; }
157	>	void Print(Option_t *opt="") const;
158	>	Bool_t PromptTight(EClassType type) const;
159	>	const MuonQuality &Quality() const { return fQuality; }
160	>	MuonQuality &Quality() { return fQuality; }
161	>	Bool_t StationBit(Int_t bit) const { return fStationMask.TestBit(bit); }
162	>	Bool_t TMLastStation(Double_t iDYMin = 3, Double_t iPYMin = 3,
163	>	Double_t iDXMin = 3, Double_t iPXMin = 3,UInt_t iN = 2) const;
164	>	Bool_t TMOneStation(Double_t iDYMin = 3, Double_t iPYMin = 3,
165	>	Double_t iDXMin = 3, Double_t iPXMin = 3,UInt_t iN = 1) const;
166	>	void SetCharge(Char_t x) { fCharge = x; ClearCharge(); }
167	>	void SetGlobalTrk(const Track *t)
168	>	{ fGlobalTrkRef = t; ClearMom(); ClearCharge(); }
169	>	void SetStandaloneTrk(const Track *t)
170	>	{ fStaTrkRef = t; ClearMom(); ClearCharge(); }
171	>	void SetTrackerTrk(const Track *t)
172	>	{ fTrkTrkRef = t; ClearMom(); ClearCharge(); }
173		void SetDX(Int_t iStation, Double_t iDX);
174		void SetDY(Int_t iStation, Double_t iDY);
175	+	void SetD0PV(Double_t x) { fD0PV = x; }
176	+	void SetD0PVErr(Double_t x) { fD0PVErr = x; }
177	+	void SetIp3dPV(Double_t x) { fIp3dPV = x; }
178	+	void SetIp3dPVErr(Double_t x) { fIp3dPVErr = x; }
179	+	void SetD0PVBS(Double_t x) { fD0PVBS = x; }
180	+	void SetD0PVBSErr(Double_t x) { fD0PVBSErr = x; }
181	+	void SetIp3dPVBS(Double_t x) { fIp3dPVBS = x; }
182	+	void SetIp3dPVBSErr(Double_t x) { fIp3dPVBSErr = x; }
183	+	void SetD0PVUB(Double_t x) { fD0PVUB = x; }
184	+	void SetD0PVUBErr(Double_t x) { fD0PVUBErr = x; }
185	+	void SetIp3dPVUB(Double_t x) { fIp3dPVUB = x; }
186	+	void SetIp3dPVUBErr(Double_t x) { fIp3dPVUBErr = x; }
187	+	void SetD0PVUBBS(Double_t x) { fD0PVUBBS = x; }
188	+	void SetD0PVUBBSErr(Double_t x) { fD0PVUBBSErr = x; }
189	+	void SetIp3dPVUBBS(Double_t x) { fIp3dPVUBBS = x; }
190	+	void SetIp3dPVUBBSErr(Double_t x) { fIp3dPVUBBSErr = x; }
191	+	void SetPVCompatibility(Double_t x) { fPVCompatibility = x; }
192	+	void SetPVBSCompatibility(Double_t x) { fPVBSCompatibility = x; }
193	+	void SetTrkKink(Double_t x) { fTrkKink = x; }
194	+	void SetGlbKink(Double_t x) { fGlbKink = x; }
195	+	void SetEmEnergy(Double_t emEnergy) { fEmEnergy = emEnergy; }
196	+	void SetEmS9Energy(Double_t emS9Energy) { fEmS9Energy = emS9Energy; }
197	+	void SetHadEnergy(Double_t hadEnergy) { fHadEnergy = hadEnergy; }
198	+	void SetHadS9Energy(Double_t hadS9Energy) { fHadS9Energy = hadS9Energy; }
199	+	void SetHoEnergy(Double_t hoEnergy) { fHoEnergy = hoEnergy; }
200	+	void SetHoS9Energy(Double_t hoS9Energy) { fHoS9Energy = hoS9Energy; }
201	+	void SetIsGlobalMuon(Bool_t b) { fIsGlobalMuon = b; }
202	+	void SetIsTrackerMuon(Bool_t b) { fIsTrackerMuon = b; }
203	+	void SetIsStandaloneMuon(Bool_t b) { fIsStandaloneMuon = b; }
204	+	void SetIsCaloMuon(Bool_t b) { fIsCaloMuon = b; }
205	+	void SetIsoR03SumPt(Double_t isoR03SumPt) { fIsoR03SumPt = isoR03SumPt; }
206	+	void SetIsoR03EmEt(Double_t isoR03EmEt) { fIsoR03EmEt = isoR03EmEt; }
207	+	void SetIsoR03HadEt(Double_t isoR03HadEt) { fIsoR03HadEt = isoR03HadEt; }
208	+	void SetIsoR03HoEt(Double_t isoR03HoEt) { fIsoR03HoEt = isoR03HoEt; }
209	+	void SetIsoR03NTracks(UShort_t isoR03NTrk) { fIsoR03NTracks = isoR03NTrk; }
210	+	void SetIsoR03NJets(UShort_t isoR03NJets) { fIsoR03NJets = isoR03NJets; }
211	+	void SetIsoR05SumPt(Double_t isoR05SumPt) { fIsoR05SumPt = isoR05SumPt; }
212	+	void SetIsoR05EmEt(Double_t isoR05EmEt) { fIsoR05EmEt = isoR05EmEt; }
213	+	void SetIsoR05HadEt(Double_t isoR05HadEt) { fIsoR05HadEt = isoR05HadEt; }
214	+	void SetIsoR05HoEt(Double_t isoR05HoEt) { fIsoR05HoEt = isoR05HoEt; }
215	+	void SetIsoR05NTracks(UShort_t isoR05NTrk) { fIsoR05NTracks = isoR05NTrk; }
216	+	void SetIsoR05NJets(UShort_t isoR05NJets) { fIsoR05NJets = isoR05NJets; }
217	+	void SetNValidHits(UShort_t iNValidHits) { fNValidHits = iNValidHits; }
218	+	void SetNChambers(UShort_t iNTraCh) { fNTraversedChambers = iNTraCh; }
219	+	void SetNSegments(Int_t iStation, Int_t nSegments);
220	+	void SetNMatches(UShort_t iNMatCh) { fNMatches = iNMatCh; }
221	+	void SetPtEtaPhi(Double_t pt, Double_t eta, Double_t phi);
222		void SetPullX(Int_t iStation, Double_t iPullX);
223		void SetPullY(Int_t iStation, Double_t iPullY);
224	+	void SetStationMask(UInt_t iStMask) { fStationMask.SetBits(iStMask); }
225		void SetTrackDist(Int_t iStation, Double_t iDist);
226		void SetTrackDistErr(Int_t iStation, Double_t iDistErr);
105	–	void SetNSegments(Int_t iStation, Int_t NSegments);
227
228		protected:
229	<	TRef fGlobalTrackRef; //global combined track reference
230	<	TRef fStandaloneTrackRef; //standalone muon track reference
231	<	TRef fTrackerTrackRef; //tracker track reference
232	<	Double32_t fIsoR03SumPt; //isolation size R=0.3 sum pt
233	<	Double32_t fIsoR03EmEt; //isolation size R=0.3 em trans energy
234	<	Double32_t fIsoR03HadEt; //isolation size R=0.3 had trans energy
235	<	Double32_t fIsoR03HoEt; //isolation size R=0.3 ho trans energy
236	<	Int_t fIsoR03NTracks; //isolation size R=0.3 number of tracks
237	<	Int_t fIsoR03NJets; //isolation size R=0.3 number of jets
238	<	Double32_t fIsoR05SumPt; //isolation size R=0.5 sum pt
239	<	Double32_t fIsoR05EmEt; //isolation size R=0.5 em trans energy
240	<	Double32_t fIsoR05HadEt; //isolation size R=0.5 had trans energy
241	<	Double32_t fIsoR05HoEt; //isolation size R=0.5 ho trans energy
242	<	Int_t fIsoR05NTracks; //isolation size R=0.5 number of tracks
243	<	Int_t fIsoR05NJets; //isolation size R=0.5 number of jets
244	<	Double32_t fEmEnergy; //energy deposit in ecal
245	<	Double32_t fHadEnergy; //energy deposit in hcal
246	<	Double32_t fHoEnergy; //energy deposit in outer hcal
247	<	Double32_t fEmS9Energy; //?
248	<	Double32_t fHadS9Energy; //?
249	<	Double32_t fHoS9Energy; //?
250	<	Int_t fNTraversedChambers; //number of tranversed chambers
229	>	Double_t GetCharge() const;
230	>	Double_t GetMass() const { return 105.658369e-3; }
231	>	void GetMom() const;
232	>
233	>	Vect3C fMom; //stored three-momentum
234	>	Char_t fCharge; //stored charge - filled with -99 when reading old files
235	>	Ref<Track> fGlobalTrkRef; //global combined track reference
236	>	Ref<Track> fStaTrkRef; //standalone muon track reference
237	>	Ref<Track> fTrkTrkRef; //tracker track reference
238	>	Double32_t fIsoR03SumPt; //[0,0,14]isolation size R=0.3 sum pt
239	>	Double32_t fIsoR03EmEt; //[0,0,14]isolation size R=0.3 em trans energy
240	>	Double32_t fIsoR03HadEt; //[0,0,14]isolation size R=0.3 had trans energy
241	>	Double32_t fIsoR03HoEt; //[0,0,14]isolation size R=0.3 ho trans energy
242	>	UShort_t fIsoR03NTracks; //isolation size R=0.3 number of tracks
243	>	UShort_t fIsoR03NJets; //isolation size R=0.3 number of jets
244	>	Double32_t fIsoR05SumPt; //[0,0,14]isolation size R=0.5 sum pt
245	>	Double32_t fIsoR05EmEt; //[0,0,14]isolation size R=0.5 em trans energy
246	>	Double32_t fIsoR05HadEt; //[0,0,14]isolation size R=0.5 had trans energy
247	>	Double32_t fIsoR05HoEt; //[0,0,14]isolation size R=0.5 ho trans energy
248	>	UShort_t fIsoR05NTracks; //isolation size R=0.5 number of tracks
249	>	UShort_t fIsoR05NJets; //isolation size R=0.5 number of jets
250	>	Double32_t fEmEnergy; //[0,0,14]energy deposit in ecal
251	>	Double32_t fHadEnergy; //[0,0,14]energy deposit in hcal
252	>	Double32_t fHoEnergy; //[0,0,14]energy deposit in outer hcal
253	>	Double32_t fEmS9Energy; //[0,0,14]energy deposit in 3x3 ecal
254	>	Double32_t fHadS9Energy; //[0,0,14]energy deposit in 3x3 hcal
255	>	Double32_t fHoS9Energy; //[0,0,14]energy deposit in 3x3 outer hcal
256	>	Double32_t fD0PV; //[0,0,14]transverse impact parameter to signal PV
257	>	Double32_t fD0PVErr; //[0,0,14]transverse impact parameter uncertainty to signal PV
258	>	Double32_t fIp3dPV; //[0,0,14]3d impact parameter to signal PV
259	>	Double32_t fIp3dPVErr; //[0,0,14]3d impact parameter uncertainty to signal PV
260	>	Double32_t fD0PVBS; //[0,0,14]transverse impact parameter to signal PV w/ bs constraint
261	>	Double32_t fD0PVBSErr; //[0,0,14]transverse impact parameter uncertainty to signal PV w/ bs constraint
262	>	Double32_t fIp3dPVBS; //[0,0,14]3d impact parameter to signal PV w/ bs constraint
263	>	Double32_t fIp3dPVBSErr; //[0,0,14]3d impact parameter uncertainty to signal PV w/ bs constraint
264	>	Double32_t fPVCompatibility; //[0,0,14]chi^2 compatibility with signal PV (ndof=2)
265	>	Double32_t fPVBSCompatibility; //[0,0,14]chi^2 compatibility with signal PV w/ bs constraint (ndof=2)
266	>	Double32_t fD0PVUB; //[0,0,14]transverse impact parameter to signal PVUB (unbiased primary vertex - refit removing lepton track)
267	>	Double32_t fD0PVUBErr; //[0,0,14]transverse impact parameter uncertainty to signal PVUB
268	>	Double32_t fIp3dPVUB; //[0,0,14]3d impact parameter to signal PVUB
269	>	Double32_t fIp3dPVUBErr; //[0,0,14]3d impact parameter uncertainty to signal PVUB
270	>	Double32_t fD0PVUBBS; //[0,0,14]transverse impact parameter to signal PVUB w/ bs constraint
271	>	Double32_t fD0PVUBBSErr; //[0,0,14]transverse impact parameter uncertainty to signal PVUB w/ bs constraint
272	>	Double32_t fIp3dPVUBBS; //[0,0,14]3d impact parameter to signal PVUB w/ bs constraint
273	>	Double32_t fIp3dPVUBBSErr; //[0,0,14]3d impact parameter uncertainty to signal PVUB w/ bs constraint
274	>	Double32_t fTrkKink; //[0,0,14]kink algorithm output (tracker track)
275	>	Double32_t fGlbKink; //[0,0,14]kink algorithm output (global track)
276	>	UShort_t fNValidHits; //number of Valid hits in global fit
277	>	UShort_t fNTraversedChambers; //number of traversed chambers
278	>	UShort_t fNMatches; //number of muon chambers with matches
279	>	MuonQuality fQuality; //muon quality
280		BitMask8 fStationMask; //bitmap of station with tracks, 0-3 DT, 4-7 CSCs
281	<	Double32_t fDX[8]; //uncertainty in x in given muon chamber
282	<	Double32_t fDY[8]; //uncertainty in y in given muon chamber
283	<	Double32_t fPullX[8]; //pull in x in given muon chamber
284	<	Double32_t fPullY[8]; //pull in y in given muon chamber
285	<	Double32_t fTrackDist[8]; //dist. to track in trans. plane in given muon chamber
286	<	Double32_t fTrackDistErr[8]; //error of dist. to track in trans. plane in chamber
281	>	Double32_t fDX[8]; //[0,0,14]uncertainty in x in given muon chamber
282	>	Double32_t fDY[8]; //[0,0,14]uncertainty in y in given muon chamber
283	>	Double32_t fPullX[8]; //[0,0,14]pull in x in given muon chamber
284	>	Double32_t fPullY[8]; //[0,0,14]pull in y in given muon chamber
285	>	Double32_t fTrackDist[8]; //[0,0,14]dist. to track in trans. plane in muon chamber
286	>	Double32_t fTrackDistErr[8]; //[0,0,14]error of dist. to track in trans. plane
287		Int_t fNSegments[8]; //number of segments in given muon chamber
288	+	Bool_t fIsGlobalMuon; //GlobalMuon algo flag
289	+	Bool_t fIsTrackerMuon; //TrackerMuon algo flag
290	+	Bool_t fIsStandaloneMuon; //StandaloneMuon algo flag
291	+	Bool_t fIsCaloMuon; //CaloMuon algo flag
292
293	<	ClassDef(Muon, 1) // Muon class
293	>	ClassDef(Muon, 8) // Muon class
294		};
295		}
296
#	Line 145 \| Line 299 \| *inline const mithep::Track mithep::Muon**
299		{
300		// Return "best" track.
301
302	<	if (GlobalTrk())
149	<	return GlobalTrk();
150	<	else if (TrackerTrk())
302	>	if (HasTrackerTrk())
303		return TrackerTrk();
304	<	else if (StandaloneTrk())
304	>	else if (HasGlobalTrk())
305	>	return GlobalTrk();
306	>	else if (HasStandaloneTrk())
307		return StandaloneTrk();
308
309	+	Error("BestTrk", "No track reference found, returning NULL pointer.");
310		return 0;
311		}
312
313		//--------------------------------------------------------------------------------------------------
314	<	inline const mithep::Track *mithep::Muon::GlobalTrk() const
315	<	{
316	<	// Return global combined track.
317	<
163	<	return static_cast<const Track*>(fGlobalTrackRef.GetObject());
164	<	}
314	>	inline Double_t mithep::Muon::GetCharge() const
315	>	{
316	>	// Return stored charge, unless it is set to invalid (-99),
317	>	// in that case get charge from track as before
318
319	<	//--------------------------------------------------------------------------------------------------
320	<	inline const mithep::Track *mithep::Muon::StandaloneTrk() const
321	<	{
322	<	// Return standalone track.
319	>	if (fCharge==-99)
320	>	return mithep::ChargedParticle::GetCharge();
321	>	else
322	>	return fCharge;
323
171	–	return static_cast<const Track*>(fStandaloneTrackRef.GetObject());
324		}
325
326		//--------------------------------------------------------------------------------------------------
327	<	inline const mithep::Track *mithep::Muon::TrackerTrk() const
328	<	{
329	<	// Return tracker track.
330	<
331	<	return static_cast<const Track*>(fTrackerTrackRef.GetObject());
327	>	inline void mithep::Muon::GetMom() const
328	>	{
329	>	// Get momentum of the muon. We use an explicitly stored three vector, with the pdg mass,
330	>	// since the momentum vector may be computed non-trivially in cmssw (since the tracker
331	>	// information has better resolution apparently in some cases than the global fit.)
332	>	// If momentum is unfilled, fall back to old method of getting momentum from best track
333	>	// (for backwards compatibility.)
334	>
335	>	if (fMom.Rho()>0.0) {
336	>	fCachedMom.SetCoordinates(fMom.Rho(),fMom.Eta(),fMom.Phi(),GetMass());
337	>	}
338	>	else {
339	>	mithep::ChargedParticle::GetMom();
340	>	}
341	>
342		}
343
344		//--------------------------------------------------------------------------------------------------
#	Line 249 \| Line 411 \| inline Bool_t mithep::Muon::Has(EClassTy
411
412		switch (type) {
413		case kAny:
414	<	if (BestTrk())
414	>	if (HasTrk())
415		return kTRUE;
416		break;
417		case kGlobal:
418	<	if (GlobalTrk())
418	>	if (HasGlobalTrk())
419		return kTRUE;
420		break;
421	<	case kTrackerOnly:
422	<	if (TrackerTrk())
421	>	case kTracker:
422	>	if (HasTrackerTrk())
423		return kTRUE;
424		break;
425		case kSta:
426	<	if (StandaloneTrk())
426	>	if (HasStandaloneTrk())
427		return kTRUE;
428		break;
429		case kNone:
430	<	if (!BestTrk())
430	>	if (!HasTrk())
431		return kTRUE;
432		break;
433		default:
#	Line 276 \| Line 438 \| inline Bool_t mithep::Muon::Has(EClassTy
438		}
439
440		//--------------------------------------------------------------------------------------------------
441	+	inline Bool_t mithep::Muon::HasTrk() const
442	+	{
443	+	// Return true if the muon has assigned any kind of track.
444	+
445	+	return (HasGlobalTrk() \|\| HasTrackerTrk() \|\| HasStandaloneTrk());
446	+	}
447	+
448	+	//--------------------------------------------------------------------------------------------------
449		inline mithep::Muon::EClassType mithep::Muon::Is() const
450		{
451		// Return the "best" classification of the muon according to the assigned tracks.
452
453	<	if (GlobalTrk())
453	>	if (HasGlobalTrk())
454		return kGlobal;
455	<	else if (TrackerTrk())
456	<	return kTrackerOnly;
457	<	else if (StandaloneTrk())
455	>	else if (HasTrackerTrk())
456	>	return kTracker;
457	>	else if (HasStandaloneTrk())
458		return kSta;
459
460		return kNone;
#	Line 347 \| Line 517 \| inline Bool_t mithep::Muon::PromptTight(
517		case kGlobal:
518		lTrack = GlobalTrk();
519		break;
520	<	case kTrackerOnly:
520	>	case kTracker:
521		lTrack = TrackerTrk();
522		break;
523		case kSta:
#	Line 372 \| Line 542 \| inline Bool_t mithep::Muon::PromptTight(
542
543		//--------------------------------------------------------------------------------------------------
544		inline Bool_t mithep::Muon::TMOneStation(Double_t iDYMin, Double_t iPYMin,
545	<	Double_t iDXMin, Double_t iPXMin, Int_t iN) const
545	>	Double_t iDXMin, Double_t iPXMin, UInt_t iN) const
546		{
547		// Check if the muon is matched to at least one station (chamber).
548
#	Line 380 \| Line 550 \| inline Bool_t mithep::Muon::TMOneStation
550		return kFALSE; //second last one
551
552		Bool_t pGoodX = kFALSE;
553	+	Bool_t pBadY = kFALSE;
554		for (Int_t i0 = 0; i0 < 8; ++i0) {
555		if ((TMath::Abs(GetDX(i0)) < iDXMin \|\|
556		TMath::Abs(GetPullX(i0)) < iPXMin))
#	Line 388 \| Line 559 \| inline Bool_t mithep::Muon::TMOneStation
559		(TMath::Abs(GetDY(i0)) < iDYMin \|\|
560		TMath::Abs(GetPullY(i0)) < iPYMin))
561		return kTRUE;
391	–	Bool_t pBadY = kFALSE;
562		if (TMath::Abs(GetDY(i0)) < 999999)
563		pBadY = kTRUE;
564		if (i0 == 3 && pGoodX && !pBadY)
#	Line 399 \| Line 569 \| inline Bool_t mithep::Muon::TMOneStation
569
570		//--------------------------------------------------------------------------------------------------
571		inline Bool_t mithep::Muon::TMLastStation(Double_t iDYMin, Double_t iPYMin,
572	<	Double_t iDXMin, Double_t iPXMin, Int_t iN) const
572	>	Double_t iDXMin, Double_t iPXMin, UInt_t iN) const
573		{
574		// Check if the muon is matched to its last station (chamber).
575
#	Line 465 \| Line 635 \| inline void mithep::Muon::SetPullY(Int_t
635
636		//--------------------------------------------------------------------------------------------------
637		inline void mithep::Muon::SetTrackDist(Int_t iStation, Double_t iDist)
638	+
639		{
640		// Set track distance in given chamber.
641
#	Line 482 \| Line 653 \| inline void mithep::Muon::SetTrackDistEr
653		}
654
655		//--------------------------------------------------------------------------------------------------
656	<	inline void mithep::Muon::SetNSegments(Int_t iStation, Int_t NSegments)
656	>	inline void mithep::Muon::SetNSegments(Int_t iStation, Int_t nSegments)
657		{
658		// Set number of segments in chamber.
659
660		assert(iStation >= 0 && iStation < 8);
661	<	fNSegments[iStation] = NSegments;
661	>	fNSegments[iStation] = nSegments;
662	>	}
663	>
664	>	//-------------------------------------------------------------------------------------------------
665	>	inline void mithep::Muon::SetPtEtaPhi(Double_t pt, Double_t eta, Double_t phi)
666	>	{
667	>	// Set three-vector
668	>
669	>	fMom.Set(pt,eta,phi);
670	>	ClearMom();
671		}
672		#endif
673

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Comparing UserCode/MitAna/DataTree/interface/Muon.h (file contents): Revision 1.18 by loizides, Thu Nov 27 16:15:06 2008 UTC vs. Revision 1.45 by paus, Sun Oct 23 01:53:16 2011 UTC

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Comparing UserCode/MitAna/DataTree/interface/Muon.h (file contents):
Revision 1.18 by loizides, Thu Nov 27 16:15:06 2008 UTC vs.
Revision 1.45 by paus, Sun Oct 23 01:53:16 2011 UTC