CaloNuclei/inc/CaloNuclei.h



/**
 * \file CaloNuclei.h
 * \author Emiliano Mocchiutti
 */
#ifndef calonuclei_h
#define calonuclei_h

#include <PamLevel2.h>

#include <TTree.h>
#include <TFriendElement.h>
#include <TChain.h>
#include <TFile.h>
#include <TList.h>
#include <TKey.h>
#include <TSystemFile.h>
#include <TSystemDirectory.h>
#include <TSQLServer.h>

#include <iostream>

using namespace std;

/**
 *
 * Class to store and calculate variables useful for nuclei analysis
 */
class CaloNuclei : public TObject {

 private:
    //
    PamLevel2 *L2;
    Bool_t debug;
    Bool_t usetrack;
    //
    // needed to avoid reprocessing the same event over and over to obtain the variables
    //
    UInt_t OBT;
    UInt_t PKT;
    UInt_t atime;
    Int_t tr;
    Int_t sntr;
    //
    Bool_t usepl18x;
    //
    Int_t interplane; ///< Number of available dE/dx measurements before interaction or exit from the calo (interaction plane) 
    Int_t N; ///< Number of dE/dx measurements to be used to calculate qpremeanN, default N = 5
    Int_t R; ///< Number of strip to be used around the trajectory to calculate qpremeanN, default R = 3
    Int_t UN; ///< Number of dE/dx measurements really used to calculate qpremeanN
    Float_t preq; ///< Energy release (MIP) up to the interaction plane (included)
    Float_t postq; ///< Energy release (MIP) from the interaction plane (excluded) up to the last plane
    Float_t stdedx1; ///< Energy release (MIP) on the first Silicon detector (Y EVEN) around the strip with maximum energy release (no track information).
    Float_t dedx1; ///< Energy release (MIP) along the track on the first Silicon detector (Y EVEN).
    Float_t dedx3; ///< Energy release (MIP) along the track on the first three Silicon detectors (Y EVEN, X EVEN, Y ODD).
    Float_t qpremean; ///< Truncated mean (MIP) along the track up to the interaction plane preq using three points
    Float_t qpremeanN; ///< Truncated mean (MIP) along the track up to the interaction plane preq using N points
    Float_t qNmin1; ///< Truncated mean (MIP) along the track using N-1 measurements before of the interaction plane
    Float_t maxrel; ///<Energy maximum release on first Calorimeter plane (dedx of strip with maximum release)
    Float_t ethr; ///< Threshold (MIP) needed to find the interaction plane
    Bool_t multhit; ///< True if the interaction plane has been determined by multiple hit counting
    Bool_t gap; ///< True if determining the interaction plane a big (>5 planes) gap has been found between a point and another along the track
    Float_t charge_siegen1; 
    Float_t ZCalo_dedx_b;  //Z from Calo using dedx in first Calorimeter plane vs. beta
    Float_t ZCalo_maxrel_b; //Z from Calo using maximum release in first Calorimeter plane vs. beta 
    Float_t ZCalo_dedx_defl; //Z from Calo using dedx in first Calorimeter plane vs. rigidity
    Float_t ZCalo_Nmin1_defl;  //Z from Calo using truncated mean on N-1 Calorimeter planes (plane N+1 is the interaction plane) vs. rigidity
   //
    Float_t qNmin1_w;
    Int_t S2;
 public:
    //
    //
    //char* version();

    Int_t Get_interplane(){ Process(); return interplane;}; ///< Number of available dE/dx measurements before interaction or exit from the calo (interaction plane) 
    Int_t Get_N(){ return N;}; ///< Number of dE/dx measurements to be used to calculate qpremeanN, default N = 5
    Int_t Get_UsedN(){ return UN;}; ///< Number of dE/dx measurements really used to calculate qpremeanN
    Int_t Get_R(){ return R;}; ///< Number of strip to be used around the trajectory to calculate qpremeanN, default R = 3 
    Float_t Get_preq(){ Process(); return preq;}; ///< Energy release (MIP) up to the interaction plane (included)
    Float_t Get_postq(){ Process(); return postq;}; ///< Energy release (MIP) from the interaction plane (excluded) up to the last plane
    Float_t Get_StdEdx1(){ Process(); return stdedx1;}; ///< Energy release (MIP) on the first Silicon detector (Y EVEN) around the strip with maximum energy release (no track information, 3 strips in total).
    Float_t Get_dEdx1(){ Process(); return dedx1;}; ///< Energy release (MIP) along the track on the first Silicon detector (Y EVEN).
    Float_t Get_dEdx3(){ Process(); return dedx3;}; ///< Energy release (MIP) along the track on the first three Silicon detectors (Y EVEN, X EVEN, Y ODD).
    Float_t Get_qpremean(){ Process(); return qpremean;}; ///< Truncated mean (MIP) along the track up to the interaction plane preq using three points
    Float_t Get_qpremeanN(){ Process(); return qpremeanN;}; ///< Truncated mean (MIP) along the track up to the interaction plane preq using N points
    Float_t Get_qNmin1(){ Process(); return qNmin1;}; ///< Truncated mean (MIP) along the track using N-1 measurements before of the interaction plane
    Float_t Get_maxrel(){ Process(); return maxrel;}; ///<Energy maximum release on first Calorimeter plane (dedx of strip with maximum release)
    Float_t Get_ethr(){ Process(); return ethr;}; ///< Threshold (MIP) needed to find the interaction plane
    Bool_t IsMulthit(){ Process(); return multhit;}; ///< True if the interaction plane has been determined by multiple hit counting
    //
    Float_t Get_charge_siegen1(){ Process(); return charge_siegen1;}; ///< charge Siegen method stdedx1 vs. beta
    Float_t Get_ZCalo_dedx_b(){ Process(); return ZCalo_dedx_b;};  //Z from Calo using dedx (or StdEdx) in first Calorimeter plane vs. beta
    Float_t Get_ZCalo_maxrel_b(){ Process(); return ZCalo_maxrel_b;}; //Z from Calo using maximum release in first Calorimeter plane vs. beta 
    Float_t Get_ZCalo_dedx_defl(){ Process(); return ZCalo_dedx_defl;}; //Z from Calo using dedx in first Calorimeter plane vs. rigidity
    Float_t Get_ZCalo_Nmin1_defl(){ Process(); return ZCalo_Nmin1_defl;};  //Z from Calo using truncated mean on N-1 Calorimeter planes (plane N+1 is the interaction plane) vs. rigidity
    
    //
    void Set_N(Int_t n){ N=n;};
    void Set_R(Int_t r){ R=r;};
    //
    CaloNuclei();
    CaloNuclei(PamLevel2 *L2);
    ~CaloNuclei(){ Delete(); };
    //
    void SetDebug(Bool_t d){ debug=d; };
    void UseTrack(Bool_t d){ usetrack=d; };


    void UsePlane18X(Bool_t use){usepl18x = use;};
    //
    //
    void Clear();
    void Clear(Option_t *option){Clear();};
    void Delete();
    void Delete(Option_t *option){Delete();};
    //
    void Process(); ///< Process data for track number 0
    void Process(Int_t ntr); ///< Process data for track number ntr
    void Print();
    void Print(Option_t *option){Print();};
    //
    ClassDef(CaloNuclei,2);
};

#endif

1
2
3	/**
4	* \file CaloNuclei.h
5	* \author Emiliano Mocchiutti
6	*/
7	#ifndef calonuclei_h
8	#define calonuclei_h
9
10	#include <PamLevel2.h>
11
12	#include <TTree.h>
13	#include <TFriendElement.h>
14	#include <TChain.h>
15	#include <TFile.h>
16	#include <TList.h>
17	#include <TKey.h>
18	#include <TSystemFile.h>
19	#include <TSystemDirectory.h>
20	#include <TSQLServer.h>
21
22	#include <iostream>
23
24	using namespace std;
25
26	/**
27	*
28	* Class to store and calculate variables useful for nuclei analysis
29	*/
30	class CaloNuclei : public TObject {
31
32	private:
33	//
34	PamLevel2 *L2;
35	Bool_t debug;
36	Bool_t usetrack;
37	//
38	// needed to avoid reprocessing the same event over and over to obtain the variables
39	//
40	UInt_t OBT;
41	UInt_t PKT;
42	UInt_t atime;
43	Int_t tr;
44	Int_t sntr;
45	//
46	Bool_t usepl18x;
47	//
48	Int_t interplane; ///< Number of available dE/dx measurements before interaction or exit from the calo (interaction plane)
49	Int_t N; ///< Number of dE/dx measurements to be used to calculate qpremeanN, default N = 5
50	Int_t R; ///< Number of strip to be used around the trajectory to calculate qpremeanN, default R = 3
51	Int_t UN; ///< Number of dE/dx measurements really used to calculate qpremeanN
52	Float_t preq; ///< Energy release (MIP) up to the interaction plane (included)
53	Float_t postq; ///< Energy release (MIP) from the interaction plane (excluded) up to the last plane
54	Float_t stdedx1; ///< Energy release (MIP) on the first Silicon detector (Y EVEN) around the strip with maximum energy release (no track information).
55	Float_t dedx1; ///< Energy release (MIP) along the track on the first Silicon detector (Y EVEN).
56	Float_t dedx3; ///< Energy release (MIP) along the track on the first three Silicon detectors (Y EVEN, X EVEN, Y ODD).
57	Float_t qpremean; ///< Truncated mean (MIP) along the track up to the interaction plane preq using three points
58	Float_t qpremeanN; ///< Truncated mean (MIP) along the track up to the interaction plane preq using N points
59	Float_t qNmin1; ///< Truncated mean (MIP) along the track using N-1 measurements before of the interaction plane
60	Float_t maxrel; ///<Energy maximum release on first Calorimeter plane (dedx of strip with maximum release)
61	Float_t ethr; ///< Threshold (MIP) needed to find the interaction plane
62	Bool_t multhit; ///< True if the interaction plane has been determined by multiple hit counting
63	Bool_t gap; ///< True if determining the interaction plane a big (>5 planes) gap has been found between a point and another along the track
64	Float_t charge_siegen1;
65	Float_t ZCalo_dedx_b; //Z from Calo using dedx in first Calorimeter plane vs. beta
66	Float_t ZCalo_maxrel_b; //Z from Calo using maximum release in first Calorimeter plane vs. beta
67	Float_t ZCalo_dedx_defl; //Z from Calo using dedx in first Calorimeter plane vs. rigidity
68	Float_t ZCalo_Nmin1_defl; //Z from Calo using truncated mean on N-1 Calorimeter planes (plane N+1 is the interaction plane) vs. rigidity
69	//
70	Float_t qNmin1_w;
71	Int_t S2;
72	public:
73	//
74	//
75	//char* version();
76
77	Int_t Get_interplane(){ Process(); return interplane;}; ///< Number of available dE/dx measurements before interaction or exit from the calo (interaction plane)
78	Int_t Get_N(){ return N;}; ///< Number of dE/dx measurements to be used to calculate qpremeanN, default N = 5
79	Int_t Get_UsedN(){ return UN;}; ///< Number of dE/dx measurements really used to calculate qpremeanN
80	Int_t Get_R(){ return R;}; ///< Number of strip to be used around the trajectory to calculate qpremeanN, default R = 3
81	Float_t Get_preq(){ Process(); return preq;}; ///< Energy release (MIP) up to the interaction plane (included)
82	Float_t Get_postq(){ Process(); return postq;}; ///< Energy release (MIP) from the interaction plane (excluded) up to the last plane
83	Float_t Get_StdEdx1(){ Process(); return stdedx1;}; ///< Energy release (MIP) on the first Silicon detector (Y EVEN) around the strip with maximum energy release (no track information, 3 strips in total).
84	Float_t Get_dEdx1(){ Process(); return dedx1;}; ///< Energy release (MIP) along the track on the first Silicon detector (Y EVEN).
85	Float_t Get_dEdx3(){ Process(); return dedx3;}; ///< Energy release (MIP) along the track on the first three Silicon detectors (Y EVEN, X EVEN, Y ODD).
86	Float_t Get_qpremean(){ Process(); return qpremean;}; ///< Truncated mean (MIP) along the track up to the interaction plane preq using three points
87	Float_t Get_qpremeanN(){ Process(); return qpremeanN;}; ///< Truncated mean (MIP) along the track up to the interaction plane preq using N points
88	Float_t Get_qNmin1(){ Process(); return qNmin1;}; ///< Truncated mean (MIP) along the track using N-1 measurements before of the interaction plane
89	Float_t Get_maxrel(){ Process(); return maxrel;}; ///<Energy maximum release on first Calorimeter plane (dedx of strip with maximum release)
90	Float_t Get_ethr(){ Process(); return ethr;}; ///< Threshold (MIP) needed to find the interaction plane
91	Bool_t IsMulthit(){ Process(); return multhit;}; ///< True if the interaction plane has been determined by multiple hit counting
92	//
93	Float_t Get_charge_siegen1(){ Process(); return charge_siegen1;}; ///< charge Siegen method stdedx1 vs. beta
94	Float_t Get_ZCalo_dedx_b(){ Process(); return ZCalo_dedx_b;}; //Z from Calo using dedx (or StdEdx) in first Calorimeter plane vs. beta
95	Float_t Get_ZCalo_maxrel_b(){ Process(); return ZCalo_maxrel_b;}; //Z from Calo using maximum release in first Calorimeter plane vs. beta
96	Float_t Get_ZCalo_dedx_defl(){ Process(); return ZCalo_dedx_defl;}; //Z from Calo using dedx in first Calorimeter plane vs. rigidity
97	Float_t Get_ZCalo_Nmin1_defl(){ Process(); return ZCalo_Nmin1_defl;}; //Z from Calo using truncated mean on N-1 Calorimeter planes (plane N+1 is the interaction plane) vs. rigidity
98
99	//
100	void Set_N(Int_t n){ N=n;};
101	void Set_R(Int_t r){ R=r;};
102	//
103	CaloNuclei();
104	CaloNuclei(PamLevel2 *L2);
105	~CaloNuclei(){ Delete(); };
106	//
107	void SetDebug(Bool_t d){ debug=d; };
108	void UseTrack(Bool_t d){ usetrack=d; };
109
110
111	void UsePlane18X(Bool_t use){usepl18x = use;};
112	//
113	//
114	void Clear();
115	void Clear(Option_t *option){Clear();};
116	void Delete();
117	void Delete(Option_t *option){Delete();};
118	//
119	void Process(); ///< Process data for track number 0
120	void Process(Int_t ntr); ///< Process data for track number ntr
121	void Print();
122	void Print(Option_t *option){Print();};
123	//
124	ClassDef(CaloNuclei,2);
125	};
126
127	#endif
128