/[PAMELA software]/DarthVader/CalorimeterLevel2/inc/CaloLevel2.h
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revision 1.1.1.1 by mocchiut, Fri May 19 13:15:49 2006 UTC revision 1.13 by mocchiut, Mon Jan 22 09:16:55 2007 UTC
# Line 7  Line 7 
7  //  //
8  #include <TObject.h>  #include <TObject.h>
9  #include <TClonesArray.h>  #include <TClonesArray.h>
10  #include <TArrayF.h>  #include <TArrayI.h>
11  //  //
12    #include <CaloStruct.h>
13    //
14    
15  /**  /**
16   * \brief Calorimeter track-related variables class   * \brief Calorimeter track-related variables class
17   *   *
# Line 22  private: Line 25  private:
25    
26  public:  public:
27      //      //
28      Int_t trkseqno; ///< tracker entry coming from tracker, -1 if selftrigger event, 100 if image track is used, -100 if the track is not consistent with calorimeter one      Int_t trkseqno; ///< this variable determine which track and which routine was used to obtain track related variables: if >= 0 standard routine/tracker track, -1 selftrigger event routine/calorimeter track, -2 high Z nuclei routine/calorimeter track, -3 standard routine/calorimeter track
29      //      //
30      // track related variables      // track related variables
31      //      //
32      Int_t ncore;     ///< SUM(j=1,2)SUM(i=1,PLmax) Nhit(i,j)*i , where Nhit(i,j) is the number of hits in a cylinder of radius 2 Rm (Moliere radius) around the track in the i-th plane (where the top plane is number 1 and the sum runs up to plane number PLmax, closest to the calculated electromagnetic shower maximum of the j-th view)      Int_t ncore;     ///< SUM(j=1,2)SUM(i=1,PLmax) Nhit(i,j)*i , where Nhit(i,j) is the number of hits in a cylinder of radius 2 Rm (Moliere radius) around the track in the i-th plane (where the top plane is number 1 and the sum runs up to plane number PLmax, closest to the calculated electromagnetic shower maximum of the j-th view)
33      Int_t noint;      ///< SUM(j=1,2)SUM(i=1,22) TH(i,j)*i , where TH(i,j) = 1 if the i-th plane of the j-th view has a cluster along (less than 4 mm away) the track with a deposited energy typical of a proton (order of one MIP), otherwise TH(i,j) = 0      Int_t noint;      ///< SUM(j=1,2)SUM(i=1,22) TH(i,j)*i , where TH(i,j) = 1 if the i-th plane of the j-th view has a cluster along (less than 4 mm away) the track with a deposited energy typical of a proton (order of one MIP), otherwise TH(i,j) = 0
34      Int_t ncyl;      ///< the number of strip hit in a cylinder of radius 8 strips around the shower axis      Int_t ncyl;      ///< the number of strip hit in a cylinder of radius 8 strips around the shower axis
35      Int_t nlast;     ///< the same as "ncyl" but only for the last four planes.      Int_t nlast;     ///< the same as "ncyl" but only for the last four planes and radius 4 strips.
36      Int_t npre;      ///< the same as "ncyl" but only for the first three planes      Int_t npre;      ///< the same as "ncyl" but only for the first three planes
37      Int_t npresh;    ///< the same as "ncyl" but with radius 2 strips and only in the first four planes      Int_t npresh;    ///< the same as "ncyl" but with radius 2 strips and only in the first four planes
38      Int_t ntr;       ///< the same as "ncyl" but with radius 4 strips      Int_t ntr;       ///< the same as "ncyl" but with radius 4 strips
39      Int_t planetot;  ///< number of planes used to calculate the energy truncated mean "qmean"      Int_t planetot;  ///< number of planes used to calculate the energy truncated mean "qmean"
40      Int_t nlow;      ///< the same as "nstrip" but below the calculated electromagnetic shower maximum      Int_t nlow;      ///< the same as "nstrip" but only after the calculated electromagnetic shower maximum
41      Int_t tibar[22][2];  ///< strip traversed by the trajectory as measured by the tracker      Int_t tibar[22][2];  ///< strip traversed by the trajectory as measured by the tracker or by the selftrigger when trkseqno = -1
42      Float_t tbar[22][2]; ///< position in cm as measured by the tracker      Float_t tbar[22][2]; ///< position in cm as measured by the tracker or by the selftrigger when trkseqno = -1
43      Float_t qcore;   ///< SUM(j=1,2)SUM(i=1,PLmax) Qhit(i,j)*i , where Qhit(i,j) is the energy released (MIP) in a cylinder of radius 2 Rm (Moliere radius) around the track in the i-th plane (where the top plane is number 1 and the sum runs up to plane number PLmax, closest to the calculated electromagnetic shower maximum of the j-th view).      Float_t qcore;   ///< SUM(j=1,2)SUM(i=1,PLmax) Qhit(i,j)*i , where Qhit(i,j) is the energy released (MIP) in a cylinder of radius 2 Rm (Moliere radius) around the track in the i-th plane (where the top plane is number 1 and the sum runs up to plane number PLmax, closest to the calculated electromagnetic shower maximum of the j-th view).
44      Float_t qcyl;    ///< the measured energy deposited in a cylinder of radius 8 strips around the shower axis      Float_t qcyl;    ///< the measured energy deposited in a cylinder of radius 8 strips around the shower axis
45      Float_t qlast;   ///< the same as "qcyl" but only for the last four planes.      Float_t qlast;   ///< the same as "qcyl" but only for the last four planes and radius 4 strips.
46      Float_t qpre;    ///< the same as "qcyl" but only for the first three planes      Float_t qpre;    ///< the same as "qcyl" but only for the first three planes
47      Float_t qpresh;  ///< the same as "qcyl" but with radius 2 strips and only in the first four planes      Float_t qpresh;  ///< the same as "qcyl" but with radius 2 strips and only in the first four planes
48      Float_t qtr;     ///< the same as "qcyl" but with radius 4 strips      Float_t qtr;     ///< the same as "qcyl" but with radius 4 strips
# Line 49  public: Line 52  public:
52      Float_t dxtrack; ///< measured energy outside the clusters along the track in the x-view      Float_t dxtrack; ///< measured energy outside the clusters along the track in the x-view
53      Float_t dytrack; ///< measured energy outside the clusters along the track in the y-view      Float_t dytrack; ///< measured energy outside the clusters along the track in the y-view
54      Float_t qmean;   ///< the energy truncated mean that is the average energy deposit for the five planes with the smaller energy deposit of the whole calorimeter      Float_t qmean;   ///< the energy truncated mean that is the average energy deposit for the five planes with the smaller energy deposit of the whole calorimeter
55      Float_t qlow;    ///< the same as "qstrip" but below the calculated electromagnetic shower maximum      Float_t qlow;    ///< the same as "qtot" but only after the calculated electromagnetic shower maximum
56      Float_t dX0l;    ///< traversed X0 lenght      Float_t dX0l;    ///< tranversed X0 lenght
57      //      //
58      CaloTrkVar(); ///< Constructor.      CaloTrkVar(); ///< Constructor.
59      /**      /**
# Line 58  public: Line 61  public:
61       */       */
62      CaloTrkVar(const CaloTrkVar &trkvar); ///< copy values from trkvar to this      CaloTrkVar(const CaloTrkVar &trkvar); ///< copy values from trkvar to this
63      //      //
64        void Clear(); ///< clear variables
65      CaloTrkVar* GetCaloTrkVar(){return this;}; ///< returns pointer to this object      CaloTrkVar* GetCaloTrkVar(){return this;}; ///< returns pointer to this object
66      //      //
67      ClassDef(CaloTrkVar,1);      ClassDef(CaloTrkVar,2);
68      //      //
69  };  };
70    
# Line 96  class CaloLevel2 : public TObject { Line 100  class CaloLevel2 : public TObject {
100      //      //
101      // Fit variables      // Fit variables
102      //      //
103      Int_t npcfit[2];     ///< number of point used to perform the fit for the two views      Int_t npcfit[4];     ///< number of point used to perform the fit for the two views (0,1 calo fit, 2,3 selftrigger fit if any)
104      Int_t cibar[22][2];  ///< strip traversed by the trajectory as measured by the calorimeter      Float_t varcfit[4];  ///< variance of the calorimeter fit for the two views (0,1 calo fit, 2,3 selftrigger fit if any)
105      Float_t cbar[22][2]; ///< position in cm as measured by the calorimeter      Float_t tanx[2];     ///< the tangent of the angle in the x direction as determined by the track fitted in the calorimeter (0 calo fit, 1 selftrigger fit)
106      Float_t impx;        ///< the x impact position on the first plane as determined by the track fitted in the calorimeter      Float_t tany[2];     ///< the tangent of the angle in the x direction as determined by the track fitted in the calorimeter (0 calo fit, 1 selftrigger fit)
107      Float_t impy;        ///< the y impact position on the first plane as determined by the track fitted in the calorimeter      Int_t fitmode[2];    ///< for x and y is 0 if the fit was performed with the "electron" algorithm, is 1 if the fit was performed with the "nuclei" algorithm
108      Float_t tanx;        ///< the tangent of the angle in the x direction as determined by the track fitted in the calorimeter      Int_t cibar[22][2];  ///< strip traversed by the trajectory as measured by the calorimeter (calo fit)
109      Float_t tany;        ///< the tangent of the angle in the x direction as determined by the track fitted in the calorimeter      Float_t cbar[22][2]; ///< position in cm as measured by the calorimeter (calo fit)
     Float_t varcfit[2];  ///< variance of the calorimeter fit for the two views  
110      //      //
111      // Energy variables      // Energy variables
112      //      //
# Line 112  class CaloLevel2 : public TObject { Line 115  class CaloLevel2 : public TObject {
115      //      //
116      // track related variables: inline methods      // track related variables: inline methods
117      //      //
118      Int_t ntrk()                                       {return CaloTrk->GetEntries();};  ///< number of saved blocks of track-related variables      Int_t ntrk(){return CaloTrk->GetEntries();};  ///< number of saved blocks of track-related variables
     Int_t trkseqno(Int_t entry)                        {return (((CaloTrkVar *)CaloTrk->At(entry))->trkseqno);}; ///< extract trkseqno  
     Int_t ncore(Int_t entry)                           {return (((CaloTrkVar *)CaloTrk->At(entry))->ncore);}; ///< extract ncore  
     Int_t noint(Int_t entry)                           {return (((CaloTrkVar *)CaloTrk->At(entry))->noint);}; ///< extract noint  
     Int_t ncyl(Int_t entry)                            {return (((CaloTrkVar *)CaloTrk->At(entry))->ncyl);}; ///< extract ncyl  
     Int_t nlast(Int_t entry)                           {return (((CaloTrkVar *)CaloTrk->At(entry))->nlast);}; ///< extract nlast  
     Int_t npre(Int_t entry)                            {return (((CaloTrkVar *)CaloTrk->At(entry))->npre);}; ///< extract npre  
     Int_t npresh(Int_t entry)                          {return (((CaloTrkVar *)CaloTrk->At(entry))->npresh);}; ///< extract npresh  
     Int_t ntr(Int_t entry)                             {return (((CaloTrkVar *)CaloTrk->At(entry))->ntr);}; ///< extract ntr  
     Int_t nlow(Int_t entry)                            {return (((CaloTrkVar *)CaloTrk->At(entry))->nlow);}; ///< extract nlow  
     Int_t planetot(Int_t entry)                        {return (((CaloTrkVar *)CaloTrk->At(entry))->planetot);}; ///< extract planetot  
     Int_t tibar(Int_t entry, Int_t plane, Int_t view)  {return (((CaloTrkVar *)CaloTrk->At(entry))->tibar[plane][view]);}; ///< extract tibar  
     Float_t tbar(Int_t entry, Int_t plane, Int_t view) {return (((CaloTrkVar *)CaloTrk->At(entry))->tbar[plane][view]);}; ///< extract tbar  
     Float_t qcore(Int_t entry)                         {return (((CaloTrkVar *)CaloTrk->At(entry))->qcore);}; ///< extract qcore  
     Float_t qcyl(Int_t entry)                          {return (((CaloTrkVar *)CaloTrk->At(entry))->qcyl);}; ///< extract qcyl  
     Float_t qlast(Int_t entry)                         {return (((CaloTrkVar *)CaloTrk->At(entry))->qlast);}; ///< extract qlast  
     Float_t qpre(Int_t entry)                          {return (((CaloTrkVar *)CaloTrk->At(entry))->qpre);}; ///< extract qpre  
     Float_t qpresh(Int_t entry)                        {return (((CaloTrkVar *)CaloTrk->At(entry))->qpresh);}; ///< extract qpresh  
     Float_t qtr(Int_t entry)                           {return (((CaloTrkVar *)CaloTrk->At(entry))->qtr);}; ///< extract qtr  
     Float_t qtrack(Int_t entry)                        {return (((CaloTrkVar *)CaloTrk->At(entry))->qtrack);}; ///< extract qtrack  
     Float_t qtrackx(Int_t entry)                       {return (((CaloTrkVar *)CaloTrk->At(entry))->qtrackx);}; ///< extract qtrackx  
     Float_t qtracky(Int_t entry)                       {return (((CaloTrkVar *)CaloTrk->At(entry))->qtracky);}; ///< extract qtracky  
     Float_t dxtrack(Int_t entry)                       {return (((CaloTrkVar *)CaloTrk->At(entry))->dxtrack);}; ///< extract dxtrack  
     Float_t dytrack(Int_t entry)                       {return (((CaloTrkVar *)CaloTrk->At(entry))->dytrack);}; ///< extract dytrack  
     Float_t qmean(Int_t entry)                         {return (((CaloTrkVar *)CaloTrk->At(entry))->qmean);}; ///< extract qmean  
     Float_t qlow(Int_t entry)                          {return (((CaloTrkVar *)CaloTrk->At(entry))->qlow);}; ///< extract qlow  
     Float_t dX0l(Int_t entry)                          {return (((CaloTrkVar *)CaloTrk->At(entry))->dX0l);}; ///< extract dX0l  
     //  
     // Number of strip with energy > emip and their value coded with view plane and strip number:  
     // view x(y) plane PP strip SS with energy mmmm.iip = +(-) ( PP*10^6 + SS*10^4 + mmmm.iip )  
     //  
     TArrayF estrip; ///< MIP values for each strip with energy > emin  
119      //      //
120      // METHODS      // METHODS
121      //      //
122        Float_t impx(Int_t tr);        ///< the x impact position on the first plane as determined by the track fitted in the calorimeter ( tr = 0 calo fit, tr = 1 selftrigger fit)
123        Float_t impy(Int_t tr);        ///< the y impact position on the first plane as determined by the track fitted in the calorimeter ( tr = 0 calo fit, tr = 1 selftrigger fit)
124    
125        //
126      void GetElectronEnergy(Float_t &energy, Float_t &sigma); ///< returns energy and sigma using qtot and assuming the particle being an electron      void GetElectronEnergy(Float_t &energy, Float_t &sigma); ///< returns energy and sigma using qtot and assuming the particle being an electron
     Float_t GetEstrip(Int_t view, Int_t plane, Int_t strip); ///< returns saved MIP value for the indicated strip  
     Float_t DecodeEstrip(Int_t entry, Int_t &view, Int_t &plane, Int_t &strip); ///< returns saved MIP value for the entry number "entry" of the TArrayF.  
     CaloTrkVar *GetCaloTrkVar(Int_t notrack);  ///< returns a pointer to the CaloTrkVar class containing track related variables  
127      //      //
128        CaloTrkVar *GetCaloTrkVar(Int_t notrack);  ///< returns a pointer to the CaloTrkVar class containing track related variables for track number notrack
129        //
130        TClonesArray *GetTrackArray(){return CaloTrk;}; ///< returns a pointer to the track related variables array
131      CaloLevel2* GetCaloLevel2(){return this;}; ///< returns pointer to this object      CaloLevel2* GetCaloLevel2(){return this;}; ///< returns pointer to this object
132      //      //
133        void GetLevel2Struct(cCaloLevel2 *l2) const;
134        //
135        void Clear();
136        void Delete(); //ELENA
137        void Set(); //ELENA
138        //
139      // constructor      // constructor
140      //      //
141      CaloLevel2();      CaloLevel2(); ///< Constructor.
142        ~CaloLevel2(){Delete();}; //ELENA
143      //      //
144      friend class CaloProcessing;      friend class CaloProcessing;
145      //      //
146      ClassDef(CaloLevel2,1);      ClassDef(CaloLevel2,4);
147  };  };
148    
149  #endif  #endif

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