1 #ifndef ALITRDGEOMETRY_H
2 #define ALITRDGEOMETRY_H
3 /* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * See cxx source for full Copyright notice */
8 ///////////////////////////////////////////////////////////////////////////////
10 // TRD geometry class //
12 ///////////////////////////////////////////////////////////////////////////////
14 #include "AliGeometry.h"
15 #include "TObjArray.h"
19 class AliTRDgeometry : public AliGeometry {
23 enum { kNplan = 6, kNcham = 5, kNsect = 18, kNdet = 540, kNdets = 30 };
26 virtual ~AliTRDgeometry();
28 virtual void CreateGeometry(Int_t *idtmed);
29 virtual Int_t IsVersion() { return 1; };
31 virtual Bool_t Impact(const TParticle* ) const { return kTRUE; };
33 virtual Bool_t Local2Global(Int_t d, Double_t *local, Double_t *global) const;
34 virtual Bool_t Local2Global(Int_t p, Int_t c, Int_t s
35 , Double_t *local, Double_t *global) const;
36 virtual Bool_t Global2Local(Int_t mode, Double_t *local, Double_t *global
37 , Int_t* index) const;
38 virtual Bool_t Global2Detector(Double_t global[3], Int_t index[3]);
39 virtual Bool_t Rotate(Int_t d, Double_t *pos, Double_t *rot) const;
40 virtual Bool_t RotateBack(Int_t d, Double_t *rot, Double_t *pos) const;
42 void GroupChamber(Int_t iplan, Int_t icham, Int_t *idtmed);
43 void CreateFrame(Int_t *idtmed);
44 void CreateServices(Int_t *idtmed);
46 Bool_t ReadGeoMatrices();
47 TGeoHMatrix * GetGeoMatrix(Int_t det) { return (TGeoHMatrix *) fMatrixGeo->At(det); }
48 TGeoHMatrix * GetMatrix(Int_t det) { return (TGeoHMatrix *) fMatrixArray->At(det); }
49 TGeoHMatrix * GetCorrectionMatrix(Int_t det){ return (TGeoHMatrix *) fMatrixCorrectionArray->At(det); }
51 static Int_t Nsect() { return fgkNsect; };
52 static Int_t Nplan() { return fgkNplan; };
53 static Int_t Ncham() { return fgkNcham; };
54 static Int_t Ndet() { return fgkNdet; };
56 static Float_t Rmin() { return fgkRmin; };
57 static Float_t Rmax() { return fgkRmax; };
58 static Float_t Zmax1() { return fgkZmax1; };
59 static Float_t Zmax2() { return fgkZmax2; };
61 static Float_t Cwidcha() { return (fgkSwidth2 - fgkSwidth1)
62 / fgkSheight * (fgkCH + fgkVspace); };
63 static Float_t Cheight() { return fgkCH; };
64 static Float_t Cspace() { return fgkVspace; };
65 static Float_t CraHght() { return fgkCraH; };
66 static Float_t CdrHght() { return fgkCdrH; };
67 static Float_t CamHght() { return fgkCamH; };
68 static Float_t CroHght() { return fgkCroH; };
69 static Float_t CroWid() { return fgkCroW; };
70 static Float_t MyThick() { return fgkMyThick; };
71 static Float_t DrThick() { return fgkDrThick; };
72 static Float_t AmThick() { return fgkAmThick; };
73 static Float_t DrZpos() { return fgkDrZpos; };
74 static Float_t RpadW() { return fgkRpadW; };
75 static Float_t CpadW() { return fgkCpadW; };
77 //void SetSMstatus(Int_t sm, Char_t status) { sm += 5; if (sm > 17) sm -= 18;
78 // fSMstatus[sm] = status; };
79 void SetSMstatus(Int_t sm, Char_t status) { fSMstatus[sm] = status; };
81 virtual Bool_t IsHole(Int_t /*iplan*/, Int_t /*icham*/, Int_t /*isect*/) const { return kFALSE; };
82 static Int_t GetDetectorSec(Int_t p, Int_t c);
83 static Int_t GetDetector(Int_t p, Int_t c, Int_t s);
84 virtual Int_t GetPlane(Int_t d) const;
85 virtual Int_t GetChamber(Int_t d) const;
86 virtual Int_t GetSector(Int_t d) const;
88 //Char_t GetSMstatus(Int_t sm) const { sm += 5; if (sm > 17) sm -= 18;
89 // return fSMstatus[sm]; };
90 Char_t GetSMstatus(Int_t sm) const { return fSMstatus[sm]; };
91 Float_t GetChamberWidth(Int_t p) const { return fCwidth[p]; };
92 Float_t GetChamberLength(Int_t p, Int_t c) const { return fClength[p][c]; };
94 virtual void GetGlobal(const AliRecPoint* , TVector3& , TMatrixF& ) const { };
95 virtual void GetGlobal(const AliRecPoint* , TVector3& ) const { };
97 static Double_t GetAlpha() { return 2 * 3.14159265358979323846 / fgkNsect; };
99 static AliTRDgeometry* GetGeometry(AliRunLoader* runLoader = NULL);
101 static Float_t GetTime0(Int_t p) { return fgkTime0[p]; };
105 static const Int_t fgkNsect; // Number of sectors in the full detector (18)
106 static const Int_t fgkNplan; // Number of planes of the TRD (6)
107 static const Int_t fgkNcham; // Number of chambers in z-direction (5)
108 static const Int_t fgkNdet; // Total number of detectors (18 * 6 * 5 = 540)
110 static const Float_t fgkRmin; // Minimal radius of the TRD
111 static const Float_t fgkRmax; // Maximal radius of the TRD
113 static const Float_t fgkZmax1; // Half-length of the TRD at outer radius
114 static const Float_t fgkZmax2; // Half-length of the TRD at inner radius
116 static const Float_t fgkSheight; // Height of the TRD-volume in spaceframe (BTR1-3)
117 static const Float_t fgkSwidth1; // Lower width of the TRD-volume in spaceframe (BTR1-3)
118 static const Float_t fgkSwidth2; // Upper width of the TRD-volume in spaceframe (BTR1-3)
119 static const Float_t fgkSlenTR1; // Length of the TRD-volume in spaceframe (BTR1)
120 static const Float_t fgkSlenTR2; // Length of the TRD-volume in spaceframe (BTR2)
121 static const Float_t fgkSlenTR3; // Length of the TRD-volume in spaceframe (BTR3)
123 static const Float_t fgkSMpltT; // Thickness of the super module side plates
124 //static const Float_t fgkSMgapT; // Thickness of the gap between side plates and space frame
126 static const Float_t fgkCraH; // Height of the radiator part of the chambers
127 static const Float_t fgkCdrH; // Height of the drift region of the chambers
128 static const Float_t fgkCamH; // Height of the amplification region of the chambers
129 static const Float_t fgkCroH; // Height of the readout of the chambers
130 static const Float_t fgkCH; // Total height of the chambers
132 static const Float_t fgkVspace; // Vertical spacing of the chambers
133 static const Float_t fgkHspace; // Horizontal spacing of the chambers
134 static const Float_t fgkVrocsm; // Radial distance of the first ROC to the outer plates of the SM
135 static const Float_t fgkCalT; // Thickness of the lower aluminum frame
136 static const Float_t fgkCclsT; // Thickness of the lower G10 frame sides
137 static const Float_t fgkCclfT; // Thickness of the lower G10 frame front
138 static const Float_t fgkCcuT; // Thickness of the upper G10 frame
139 static const Float_t fgkCauT; // Thickness of the upper aluminum frame
141 static const Float_t fgkCroW; // Additional width of the readout chamber frames
143 static const Float_t fgkCpadW; // Difference of outer chamber width and pad plane width
144 static const Float_t fgkRpadW; // Difference of outer chamber width and pad plane width
146 static const Float_t fgkRaThick; // Thickness of the radiator
147 static const Float_t fgkMyThick; // Thickness of the mylar-layer
148 static const Float_t fgkXeThick; // Thickness of the gas volume
149 static const Float_t fgkDrThick; // Thickness of the drift region
150 static const Float_t fgkAmThick; // Thickness of the amplification region
151 static const Float_t fgkCuThick; // Thickness of the pad plane
152 static const Float_t fgkSuThick; // Thickness of the HEXCEL+G10 support structure
153 static const Float_t fgkFeThick; // Thickness of the FEE + signal lines
154 static const Float_t fgkCoThick; // Thickness of the PE of the cooling device
155 static const Float_t fgkWaThick; // Thickness of the cooling water
156 static const Float_t fgkRpThick; // Thickness of the PCB readout boards
157 static const Float_t fgkRcThick; // Thickness of the PCB copper layers
159 static const Float_t fgkRaZpos; // Position of the radiator
160 static const Float_t fgkMyZpos; // Position of the mylar-layer
161 static const Float_t fgkDrZpos; // Position of the drift region
162 static const Float_t fgkAmZpos; // Position of the amplification region
163 static const Float_t fgkCuZpos; // Position of the pad plane
164 static const Float_t fgkSuZpos; // Position of the HEXCEL+G10 support structure
165 static const Float_t fgkFeZpos; // Position of the FEE + signal lines
166 static const Float_t fgkCoZpos; // Position of the PE of the cooling device
167 static const Float_t fgkWaZpos; // Position of the cooling water
168 static const Float_t fgkRpZpos; // Position of the PCB readout boards
169 static const Float_t fgkRcZpos; // Position of the PCB copper layers
171 Char_t fSMstatus[kNsect]; // Super module status byte
173 Float_t fCwidth[kNplan]; // Outer widths of the chambers
174 Float_t fClength[kNplan][kNcham]; // Outer lengths of the chambers
176 Float_t fRotA11[kNsect]; // Matrix elements for the rotation
177 Float_t fRotA12[kNsect]; // Matrix elements for the rotation
178 Float_t fRotA21[kNsect]; // Matrix elements for the rotation
179 Float_t fRotA22[kNsect]; // Matrix elements for the rotation
181 Float_t fRotB11[kNsect]; // Matrix elements for the backward rotation
182 Float_t fRotB12[kNsect]; // Matrix elements for the backward rotation
183 Float_t fRotB21[kNsect]; // Matrix elements for the backward rotation
184 Float_t fRotB22[kNsect]; // Matrix elements for the backward rotation
186 static const Double_t fgkTime0Base; // Base value for calculation of Time-position of pad 0
187 static const Float_t fgkTime0[kNplan]; // Time-position of pad 0
189 Float_t fChamberUAorig[3*kNdets][3]; // Volumes origin in
190 Float_t fChamberUDorig[3*kNdets][3]; // the chamber
191 Float_t fChamberUForig[3*kNdets][3]; // [3] = x, y, z
192 Float_t fChamberUUorig[3*kNdets][3]; //
194 Float_t fChamberUAboxd[3*kNdets][3]; // Volumes box
195 Float_t fChamberUDboxd[3*kNdets][3]; // dimensions (half)
196 Float_t fChamberUFboxd[3*kNdets][3]; // [3] = x, y, z
197 Float_t fChamberUUboxd[3*kNdets][3]; //
199 TObjArray * fMatrixArray; //! array of matrix - Transformation Global to Local
200 TObjArray * fMatrixCorrectionArray; //! array of Matrix - Transformation Cluster to Tracking systerm
201 TObjArray * fMatrixGeo; //! geo matrices
203 ClassDef(AliTRDgeometry,10) // TRD geometry class