DataTree/interface/BasicCluster.h

//--------------------------------------------------------------------------------------------------
// $Id: BasicCluster.h,v 1.13 2009/11/24 15:57:45 loizides Exp $
//
// BasicCluster
//
// This class holds information of basic reconstructed clusters.
//
// Authors: S.Xie
//--------------------------------------------------------------------------------------------------

#ifndef MITANA_DATATREE_BASICCLUSTER_H
#define MITANA_DATATREE_BASICCLUSTER_H
 
#include <TMath.h>
#include "MitCommon/DataFormats/interface/Vect3C.h"
#include "MitAna/DataTree/interface/DataObject.h"

namespace mithep 
{
  class BasicCluster : public DataObject
  {
    public:
      BasicCluster() : fEnergy(0) {}
      BasicCluster(Double_t e, const ThreeVector &p) : 
        fEnergy(e), fPoint(p) {}
     
      Double_t         Energy()                  const { return  fEnergy;       }       
      Double_t         Et()                      const;
      Double_t         Eta()                     const { return  fPoint.Eta();  }
      EObjType         ObjType()                 const { return  kBasicCluster; }       
      Double_t         Phi()                     const { return  fPoint.Phi();  }
      ThreeVectorC     Pos()                     const { return  fPoint.V();    }
      void             Print(Option_t *opt="")   const;
      Double_t         Rho()                     const { return  fPoint.Rho();  }
      Double_t         NHits()                   const { return  fNHits;        }
      Double_t         E1x3()                    const { return  fE1x3;         }
      Double_t         E3x1()                    const { return  fE3x1;         }
      Double_t         E1x5()                    const { return  fE1x5;         }
      Double_t         E2x2()                    const { return  fE2x2;         }
      Double_t         E3x2()                    const { return  fE3x2;         }
      Double_t         E3x3()                    const { return  fE3x3;         }
      Double_t         E4x4()                    const { return  fE4x4;         }
      Double_t         E5x5()                    const { return  fE5x5;         }
      Double_t         E2x5Right()               const { return  fE2x5Right;    }
      Double_t         E2x5Left()                const { return  fE2x5Left;     }
      Double_t         E2x5Top()                 const { return  fE2x5Top;      }
      Double_t         E2x5Bottom()              const { return  fE2x5Bottom;   }
      Double_t         E2x5Max()                 const { return  fE2x5Max;      }
      Double_t         ELeft()                   const { return  fELeft;        }
      Double_t         ERight()                  const { return  fERight;       }
      Double_t         ETop()                    const { return  fETop;         }
      Double_t         EBottom()                 const { return  fEBottom;      }
      Double_t         EMax()                    const { return  fEMax;         }
      Double_t         E2nd()                    const { return  fE2nd;         }
      Double_t         EtaLat()                  const { return  fEtaLat;       }
      Double_t         PhiLat()                  const { return  fPhiLat;       }
      Double_t         Lat()                     const { return  fLat;          }
      Double_t         CovEtaEta()               const { return  fCovEtaEta;    }
      Double_t         CovEtaPhi()               const { return  fCovEtaPhi;    }
      Double_t         CovPhiPhi()               const { return  fCovPhiPhi;    }
      Double_t         CoviEtaiEta()             const { return  fCoviEtaiEta;  }
      Double_t         CoviEtaiPhi()             const { return  fCoviEtaiPhi;  }
      Double_t         CoviPhiiPhi()             const { return  fCoviPhiiPhi;  }
      Double_t         Zernike20()               const { return  fZernike20;    }
      Double_t         Zernike42()               const { return  fZernike42;    }


      void             SetEnergy(Double_t energy)                 {  fEnergy = energy;     }      
      void             SetXYZ(Double_t x, Double_t y, Double_t z) {  fPoint.SetXYZ(x,y,z); } 
      void             SetNHits(Int_t x)                          {  fNHits = x;            }
      void             SetE1x3(Double_t x)                        {  fE1x3 = x;            }
      void             SetE3x1(Double_t x)                        {  fE3x1 = x;            }
      void             SetE1x5(Double_t x)                        {  fE1x5 = x;            }
      void             SetE2x2(Double_t x)                        {  fE2x2 = x;            }
      void             SetE3x2(Double_t x)                        {  fE3x2 = x;            }
      void             SetE3x3(Double_t x)                        {  fE3x3 = x;            }
      void             SetE4x4(Double_t x)                        {  fE4x4 = x;            }
      void             SetE5x5(Double_t x)                        {  fE5x5 = x;            }
      void             SetE2x5Right(Double_t x)                   {  fE2x5Right = x;       }
      void             SetE2x5Left(Double_t x)                    {  fE2x5Left = x;        }
      void             SetE2x5Top(Double_t x)                     {  fE2x5Top = x;         }
      void             SetE2x5Bottom(Double_t x)                  {  fE2x5Bottom = x;      }
      void             SetE2x5Max(Double_t x)                     {  fE2x5Max = x;         }
      void             SetELeft(Double_t x)                       {  fELeft = x;           }
      void             SetERight(Double_t x)                      {  fERight = x;          }
      void             SetETop(Double_t x)                        {  fETop = x;            }
      void             SetEBottom(Double_t x)                     {  fEBottom = x;         }
      void             SetEMax(Double_t x)                        {  fEMax = x;            }
      void             SetE2nd(Double_t x)                        {  fE2nd = x;            }
      void             SetEtaLat(Double_t x)                      {  fEtaLat = x;          }
      void             SetPhiLat(Double_t x)                      {  fPhiLat = x;          }
      void             SetLat(Double_t x)                         {  fLat = x;             }
      void             SetCovEtaEta(Double_t x)                   {  fCovEtaEta = x;       }
      void             SetCovEtaPhi(Double_t x)                   {  fCovEtaPhi = x;       }
      void             SetCovPhiPhi(Double_t x)                   {  fCovPhiPhi = x;       }
      void             SetCoviEtaiEta(Double_t x)                 {  fCoviEtaiEta = x;     }
      void             SetCoviEtaiPhi(Double_t x)                 {  fCoviEtaiPhi = x;     }
      void             SetCoviPhiiPhi(Double_t x)                 {  fCoviPhiiPhi = x;     }
      void             SetZernike20(Double_t x)                   {  fZernike20 = x;       }
      void             SetZernike42(Double_t x)                   {  fZernike42 = x;       }


    protected:
        
      Double32_t       fEnergy;  //[0,0,14]assigned energy      
      Vect3C           fPoint;   //centroid Position
      

      Int_t      fNHits;
      Double32_t fE1x3;
      Double32_t fE3x1;
      Double32_t fE1x5;
      Double32_t fE2x2;
      Double32_t fE3x2;
      Double32_t fE3x3;
      Double32_t fE4x4;
      Double32_t fE5x5;
      Double32_t fE2x5Right;
      Double32_t fE2x5Left;
      Double32_t fE2x5Top;
      Double32_t fE2x5Bottom;
      Double32_t fE2x5Max;
      Double32_t fELeft;
      Double32_t fERight;
      Double32_t fETop;
      Double32_t fEBottom;
      Double32_t fEMax;
      Double32_t fE2nd;
      Double32_t fEtaLat;
      Double32_t fPhiLat;
      Double32_t fLat;
      Double32_t fCovEtaEta;
      Double32_t fCovEtaPhi;
      Double32_t fCovPhiPhi;
      Double32_t fCoviEtaiEta;
      Double32_t fCoviEtaiPhi;
      Double32_t fCoviPhiiPhi;
      Double32_t fZernike20;
      Double32_t fZernike42;


      ClassDef(BasicCluster, 1)  // Basic cluster class
  };
}

//--------------------------------------------------------------------------------------------------
inline Double_t mithep::BasicCluster::Et() const
{
  // Return transverse energy.

  return fEnergy*fPoint.Rho()/fPoint.V().R();
}
#endif
Revision:	1.14
Committed:	Wed Mar 24 15:35:20 2010 UTC (15 years, 1 month ago) by sixie
Content type:	text/plain
Branch:	MAIN
CVS Tags:	Mit_013
Changes since 1.13:	+110 -11 lines
Log Message:	Add EM shower shape variables
#	User	Rev	Content
1	sixie	1.1	//--------------------------------------------------------------------------------------------------
2	sixie	1.14	// $Id: BasicCluster.h,v 1.13 2009/11/24 15:57:45 loizides Exp $
3	sixie	1.1	//
4	loizides	1.7	// BasicCluster
5	sixie	1.1	//
6	loizides	1.5	// This class holds information of basic reconstructed clusters.
7	sixie	1.1	//
8			// Authors: S.Xie
9			//--------------------------------------------------------------------------------------------------
10
11	loizides	1.2	#ifndef MITANA_DATATREE_BASICCLUSTER_H
12			#define MITANA_DATATREE_BASICCLUSTER_H
13	sixie	1.1
14			#include <TMath.h>
15	loizides	1.9	#include "MitCommon/DataFormats/interface/Vect3C.h"
16	sixie	1.1	#include "MitAna/DataTree/interface/DataObject.h"
17
18			namespace mithep
19			{
20			class BasicCluster : public DataObject
21			{
22			public:
23	bendavid	1.8	BasicCluster() : fEnergy(0) {}
24	loizides	1.7	BasicCluster(Double_t e, const ThreeVector &p) :
25	bendavid	1.8	fEnergy(e), fPoint(p) {}
26	sixie	1.1
27	sixie	1.14	Double_t Energy() const { return fEnergy; }
28			Double_t Et() const;
29			Double_t Eta() const { return fPoint.Eta(); }
30			EObjType ObjType() const { return kBasicCluster; }
31			Double_t Phi() const { return fPoint.Phi(); }
32			ThreeVectorC Pos() const { return fPoint.V(); }
33			void Print(Option_t *opt="") const;
34			Double_t Rho() const { return fPoint.Rho(); }
35			Double_t NHits() const { return fNHits; }
36			Double_t E1x3() const { return fE1x3; }
37			Double_t E3x1() const { return fE3x1; }
38			Double_t E1x5() const { return fE1x5; }
39			Double_t E2x2() const { return fE2x2; }
40			Double_t E3x2() const { return fE3x2; }
41			Double_t E3x3() const { return fE3x3; }
42			Double_t E4x4() const { return fE4x4; }
43			Double_t E5x5() const { return fE5x5; }
44			Double_t E2x5Right() const { return fE2x5Right; }
45			Double_t E2x5Left() const { return fE2x5Left; }
46			Double_t E2x5Top() const { return fE2x5Top; }
47			Double_t E2x5Bottom() const { return fE2x5Bottom; }
48			Double_t E2x5Max() const { return fE2x5Max; }
49			Double_t ELeft() const { return fELeft; }
50			Double_t ERight() const { return fERight; }
51			Double_t ETop() const { return fETop; }
52			Double_t EBottom() const { return fEBottom; }
53			Double_t EMax() const { return fEMax; }
54			Double_t E2nd() const { return fE2nd; }
55			Double_t EtaLat() const { return fEtaLat; }
56			Double_t PhiLat() const { return fPhiLat; }
57			Double_t Lat() const { return fLat; }
58			Double_t CovEtaEta() const { return fCovEtaEta; }
59			Double_t CovEtaPhi() const { return fCovEtaPhi; }
60			Double_t CovPhiPhi() const { return fCovPhiPhi; }
61			Double_t CoviEtaiEta() const { return fCoviEtaiEta; }
62			Double_t CoviEtaiPhi() const { return fCoviEtaiPhi; }
63			Double_t CoviPhiiPhi() const { return fCoviPhiiPhi; }
64			Double_t Zernike20() const { return fZernike20; }
65			Double_t Zernike42() const { return fZernike42; }
66
67
68			void SetEnergy(Double_t energy) { fEnergy = energy; }
69			void SetXYZ(Double_t x, Double_t y, Double_t z) { fPoint.SetXYZ(x,y,z); }
70			void SetNHits(Int_t x) { fNHits = x; }
71			void SetE1x3(Double_t x) { fE1x3 = x; }
72			void SetE3x1(Double_t x) { fE3x1 = x; }
73			void SetE1x5(Double_t x) { fE1x5 = x; }
74			void SetE2x2(Double_t x) { fE2x2 = x; }
75			void SetE3x2(Double_t x) { fE3x2 = x; }
76			void SetE3x3(Double_t x) { fE3x3 = x; }
77			void SetE4x4(Double_t x) { fE4x4 = x; }
78			void SetE5x5(Double_t x) { fE5x5 = x; }
79			void SetE2x5Right(Double_t x) { fE2x5Right = x; }
80			void SetE2x5Left(Double_t x) { fE2x5Left = x; }
81			void SetE2x5Top(Double_t x) { fE2x5Top = x; }
82			void SetE2x5Bottom(Double_t x) { fE2x5Bottom = x; }
83			void SetE2x5Max(Double_t x) { fE2x5Max = x; }
84			void SetELeft(Double_t x) { fELeft = x; }
85			void SetERight(Double_t x) { fERight = x; }
86			void SetETop(Double_t x) { fETop = x; }
87			void SetEBottom(Double_t x) { fEBottom = x; }
88			void SetEMax(Double_t x) { fEMax = x; }
89			void SetE2nd(Double_t x) { fE2nd = x; }
90			void SetEtaLat(Double_t x) { fEtaLat = x; }
91			void SetPhiLat(Double_t x) { fPhiLat = x; }
92			void SetLat(Double_t x) { fLat = x; }
93			void SetCovEtaEta(Double_t x) { fCovEtaEta = x; }
94			void SetCovEtaPhi(Double_t x) { fCovEtaPhi = x; }
95			void SetCovPhiPhi(Double_t x) { fCovPhiPhi = x; }
96			void SetCoviEtaiEta(Double_t x) { fCoviEtaiEta = x; }
97			void SetCoviEtaiPhi(Double_t x) { fCoviEtaiPhi = x; }
98			void SetCoviPhiiPhi(Double_t x) { fCoviPhiiPhi = x; }
99			void SetZernike20(Double_t x) { fZernike20 = x; }
100			void SetZernike42(Double_t x) { fZernike42 = x; }
101
102	sixie	1.1
103			protected:
104	bendavid	1.8
105	loizides	1.9	Double32_t fEnergy; //[0,0,14]assigned energy
106			Vect3C fPoint; //centroid Position
107	sixie	1.1
108	sixie	1.14
109			Int_t fNHits;
110			Double32_t fE1x3;
111			Double32_t fE3x1;
112			Double32_t fE1x5;
113			Double32_t fE2x2;
114			Double32_t fE3x2;
115			Double32_t fE3x3;
116			Double32_t fE4x4;
117			Double32_t fE5x5;
118			Double32_t fE2x5Right;
119			Double32_t fE2x5Left;
120			Double32_t fE2x5Top;
121			Double32_t fE2x5Bottom;
122			Double32_t fE2x5Max;
123			Double32_t fELeft;
124			Double32_t fERight;
125			Double32_t fETop;
126			Double32_t fEBottom;
127			Double32_t fEMax;
128			Double32_t fE2nd;
129			Double32_t fEtaLat;
130			Double32_t fPhiLat;
131			Double32_t fLat;
132			Double32_t fCovEtaEta;
133			Double32_t fCovEtaPhi;
134			Double32_t fCovPhiPhi;
135			Double32_t fCoviEtaiEta;
136			Double32_t fCoviEtaiPhi;
137			Double32_t fCoviPhiiPhi;
138			Double32_t fZernike20;
139			Double32_t fZernike42;
140
141
142	loizides	1.5	ClassDef(BasicCluster, 1) // Basic cluster class
143	sixie	1.1	};
144			}
145	loizides	1.13
146			//--------------------------------------------------------------------------------------------------
147			inline Double_t mithep::BasicCluster::Et() const
148			{
149			// Return transverse energy.
150
151			return fEnergy*fPoint.Rho()/fPoint.V().R();
152			}
153	sixie	1.1	#endif