doc/examples/example1.C

//
//  Example to integrate all detector info by means of the PamLevel2 class
//
//  An object of this class has access to all the public members of all the detector classes.
//  Some local methods allows to sort tracks and solve the tracker y-view ambiguity (reject track images)
//
void example1(TString file){
    //
    // histos
    //
    TH1F* qtot    =  new TH1F("qtot","Total energy in the calorimeter",1000,0.,2000.);
    TH1F* npaddle =  new TH1F("npaddle","Total number of hit ToF paddles",16,-0.5,15.5);
    TH1F* ntrack  =  new TH1F("ntr","Number of fitted tracks",6,-0.5,5.5);
    //
    TH1F* rig   = new TH1F("rig","Particle rigidity",100,0.,100.);
    TH1F* resxs = new TH1F("resxs","Spatial residual (X) on the 1^ calo plane (sorted tracks)",100,-10.,10.);
    TH1F* resys = new TH1F("resys","Spatial residual (Y) on the 1^ calo plane (sorted tracks)",100,-10.,10.);
    TH1F* resxi = new TH1F("resxi","Spatial residual (X) on the 1^ calo plane (image tracks)",100,-10.,10.);
    TH1F* resyi = new TH1F("resyi","Spatial residual (Y) on the 1^ calo plane (image tracks)",100,-10.,10.); 
    //
    PamLevel2*  pam_event  = new PamLevel2();       // << create pamela event
    //
    TFile f(file);
    //
    TTree *T = pam_event->LoadPamTrees(&f);         // << load Pamela trees from file f
    Int_t nevent = T->GetEntries();
    //
    cout << endl<<" Start loop over events   ";
    for (Int_t i=0; i<nevent;i++){
        //
        T->GetEntry(i);
        //================================================================================
        // some general quantities
        //================================================================================
        // tracker
        ntrack->Fill( pam_event->GetNTracks()); 
        // calorimeter
        qtot->Fill(pam_event->qtot);
        // ToF
        Int_t npa=0;
        for(Int_t ipa=0; ipa<6; ipa++)npa = npa + pam_event->GetNHitPaddles(ipa);
        npaddle->Fill(npa);
        //================================================================================
        // track related variables
        //================================================================================
        for(Int_t it=0; it<pam_event->GetNTracks(); it++){     // << loop over the "physical" tracks (no track images)
            //
            // << get the it-th physical pamela track 
            // << PamTrack combines the tracker, calorimeter and ToF track-related variables
            // << (in case of image, choose the best track by means of calorimeter and ToF data)
            //
            PamTrack *track = pam_event->GetTrack(it);
            //
            // << if the track fit is good, fill some histos
            //
            if( track->chi2 > 0 && track->chi2 < 100){
                // 
                // << spatial residuals on the first calorimeter plane for the sorted track 
                //
                Float_t rxs = track->tbar[0][0] - pam_event->cbar[0][0];
                Float_t rys = track->tbar[0][1] - pam_event->cbar[0][1];
                resxs->Fill(rxs);
                resys->Fill(rys);
                //
                rig->Fill( track->GetRigidity() );
                //
                // << spatial residuals on the first calorimeter plane for the image track 
                //
                if(track->HasImage()){                                // << if the sorted track has an image...
                    //
                    PamTrack *image = pam_event->GetTrackImage(it);   // << ...get the image track
                    //
                    Float_t rxi = image->tbar[0][0] - pam_event->cbar[0][0];
                    Float_t ryi = image->tbar[0][1] - pam_event->cbar[0][1];
                    resxi->Fill(rxi);
                    resyi->Fill(ryi);
                };
            };
        };  // end loop over tracks
        //================================================================================

    };                                       // end loop over the events
    cout << endl << endl << " Done "<< endl<<endl;
    //
    // close file
    //
    f.Close();  
    
};
1	//
2	// Example to integrate all detector info by means of the PamLevel2 class
3	//
4	// An object of this class has access to all the public members of all the detector classes.
5	// Some local methods allows to sort tracks and solve the tracker y-view ambiguity (reject track images)
6	//
7	void example1(TString file){
8	//
9	// histos
10	//
11	TH1F* qtot = new TH1F("qtot","Total energy in the calorimeter",1000,0.,2000.);
12	TH1F* npaddle = new TH1F("npaddle","Total number of hit ToF paddles",16,-0.5,15.5);
13	TH1F* ntrack = new TH1F("ntr","Number of fitted tracks",6,-0.5,5.5);
14	//
15	TH1F* rig = new TH1F("rig","Particle rigidity",100,0.,100.);
16	TH1F* resxs = new TH1F("resxs","Spatial residual (X) on the 1^ calo plane (sorted tracks)",100,-10.,10.);
17	TH1F* resys = new TH1F("resys","Spatial residual (Y) on the 1^ calo plane (sorted tracks)",100,-10.,10.);
18	TH1F* resxi = new TH1F("resxi","Spatial residual (X) on the 1^ calo plane (image tracks)",100,-10.,10.);
19	TH1F* resyi = new TH1F("resyi","Spatial residual (Y) on the 1^ calo plane (image tracks)",100,-10.,10.);
20	//
21	PamLevel2* pam_event = new PamLevel2(); // << create pamela event
22	//
23	TFile f(file);
24	//
25	TTree *T = pam_event->LoadPamTrees(&f); // << load Pamela trees from file f
26	Int_t nevent = T->GetEntries();
27	//
28	cout << endl<<" Start loop over events ";
29	for (Int_t i=0; i<nevent;i++){
30	//
31	T->GetEntry(i);
32	//================================================================================
33	// some general quantities
34	//================================================================================
35	// tracker
36	ntrack->Fill( pam_event->GetNTracks());
37	// calorimeter
38	qtot->Fill(pam_event->qtot);
39	// ToF
40	Int_t npa=0;
41	for(Int_t ipa=0; ipa<6; ipa++)npa = npa + pam_event->GetNHitPaddles(ipa);
42	npaddle->Fill(npa);
43	//================================================================================
44	// track related variables
45	//================================================================================
46	for(Int_t it=0; it<pam_event->GetNTracks(); it++){ // << loop over the "physical" tracks (no track images)
47	//
48	// << get the it-th physical pamela track
49	// << PamTrack combines the tracker, calorimeter and ToF track-related variables
50	// << (in case of image, choose the best track by means of calorimeter and ToF data)
51	//
52	PamTrack *track = pam_event->GetTrack(it);
53	//
54	// << if the track fit is good, fill some histos
55	//
56	if( track->chi2 > 0 && track->chi2 < 100){
57	//
58	// << spatial residuals on the first calorimeter plane for the sorted track
59	//
60	Float_t rxs = track->tbar[0][0] - pam_event->cbar[0][0];
61	Float_t rys = track->tbar[0][1] - pam_event->cbar[0][1];
62	resxs->Fill(rxs);
63	resys->Fill(rys);
64	//
65	rig->Fill( track->GetRigidity() );
66	//
67	// << spatial residuals on the first calorimeter plane for the image track
68	//
69	if(track->HasImage()){ // << if the sorted track has an image...
70	//
71	PamTrack *image = pam_event->GetTrackImage(it); // << ...get the image track
72	//
73	Float_t rxi = image->tbar[0][0] - pam_event->cbar[0][0];
74	Float_t ryi = image->tbar[0][1] - pam_event->cbar[0][1];
75	resxi->Fill(rxi);
76	resyi->Fill(ryi);
77	};
78	};
79	}; // end loop over tracks
80	//================================================================================
81
82	}; // end loop over the events
83	cout << endl << endl << " Done "<< endl<<endl;
84	//
85	// close file
86	//
87	f.Close();
88
89	};