Enabled option for selecting tree name in trneding macro
[u/mrichter/AliRoot.git] / TOF / AliTOFGeometry.cxx
CommitLineData
0f4a7374 1/**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
3 * *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
6 * *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
15
16/*
17$Log$
731afc39 18Revision 1.20.1 2007/05/19 decaro
19 Added the following methods:
20 GetVolumeIndices(Int_t index, Int_t *det), to get
21 the volume indices (sector, plate, strip, padz, padx,
22 stored respectively in det[0], det[1], det[2], det[3], det[4])
23 from the calibration channel index;
24 NStrip(Int_t nPlate), to get the strips number
25 per each kind of TOF module.
26
24982ffc 27Revision 1.20 2007/10/08 17:52:55 decaro
28hole region in front of PHOS detector: update of sectors' numbers
29
3c5f55bc 30Revision 1.19 2007/10/04 14:05:09 zampolli
31AliTOFGeometryV5 becoming AliTOFGeometry
32
0ef21f59 33Revision 1.18 2007/02/19 18:55:26 decaro
34Added getter methods for volume path (for Event Display)
35
48e6af28 36Revision 1.17.1 2006/12/15
37 Added method DetToStripRF(...) to get
38 a pad corner coordinates in its strip reference frame
39 (A.De Caro, M.Di Stefano)
40Revision 1.17 2006/08/22 13:30:02 arcelli
41removal of effective c++ warnings (C.Zampolli)
42
655e379f 43Revision 1.16 2006/04/20 22:30:50 hristov
44Coding conventions (Annalisa)
45
0e46b9ae 46Revision 1.15 2006/04/16 22:29:05 hristov
47Coding conventions (Annalisa)
48
7aeeaf38 49Revision 1.14 2006/04/05 08:35:38 hristov
50Coding conventions (S.Arcelli, C.Zampolli)
51
340693af 52Revision 1.13 2006/03/12 14:37:54 arcelli
53 Changes for TOF Reconstruction using TGeo
54
c0545837 55Revision 1.12 2006/02/28 10:38:00 decaro
56AliTOFGeometry::fAngles, AliTOFGeometry::fHeights, AliTOFGeometry::fDistances arrays: dimension definition in the right location
57
4402e7cb 58Revision 1.11 2005/12/15 14:17:29 decaro
59Correction of some parameter values
60
6fbc8979 61Revision 1.10 2005/12/15 08:55:32 decaro
62New TOF geometry description (V5) -G. Cara Romeo and A. De Caro
63
d3c7bfac 64Revision 1.9.1 2005/07/19 A. De Caro
65 Created daughter-classes AliTOFGeometryV4 and AliTOFGeometryV5
66 => moved global methods IsInsideThePad, DistanceToPad,
67 GetPlate, GetSector, GetStrip, GetPadX, GetPadZ,
68 GetX, GetY, GetZ, GetPadDx, GetPadDy and GetPadDz
69 in daughter-classes
70
71Revision 1.9 2005/10/20 12:41:35 hristov
72Implementation of parallel tracking. It is not the default version, one can use it passing option MI from AliReconstruction to TOF (M.Ivanov)
73
d88fbf15 74Revision 1.8 2004/11/29 08:28:01 decaro
75Introduction of a new TOF constant (i.e. TDC bin width)
76
43f77f2d 77Revision 1.7 2004/11/05 07:20:08 decaro
78TOF library splitting and conversion of some printout messages in AliLog schema (T.Kuhr)
79
d076c8d5 80Revision 1.6 2004/06/15 15:27:59 decaro
81TOF raw data: preliminary implementation and style changes
82
7e6dce66 83Revision 1.5 2004/04/20 14:37:22 hristov
84Using TMath::Abs instead of fabs, arrays of variable size created/deleted correctly (HP,Sun)
85
9b49e4c9 86Revision 1.4 2004/04/13 09:42:51 decaro
87Track reconstruction code for TOF: updating
88
74ea065c 89Revision 1.3 2003/12/29 18:40:39 hristov
90Copy/paste error corrected
91
fb9747d4 92Revision 1.2 2003/12/29 17:26:01 hristov
93Using enum to initaialize static ints in the header file, the initialization of static floats moved to the implementation file
94
58eb5b61 95Revision 1.1 2003/12/29 15:18:03 decaro
96TOF geometry updating (addition of AliTOFGeometry)
97
7e6dce66 98Revision 0.05 2004/6/11 A.De Caro
99 Implement Global method NpadXStrip
100 Insert four float constants (originally in AliTOF class)
101Revision 0.04 2004/4/05 S.Arcelli
74ea065c 102 Implement Global methods IsInsideThePad
103 DistanceToPad
7e6dce66 104Revision 0.03 2003/12/14 S.Arcelli
105 Set Phi range [-180,180]->[0,360]
106Revision 0.02 2003/12/10 S.Arcelli:
107 Implement Global methods GetPos & GetDetID
108Revision 0.01 2003/12/04 S.Arcelli
0f4a7374 109*/
110
0f4a7374 111///////////////////////////////////////////////////////////////////////////////
112// //
113// TOF Geometry class //
114// //
115///////////////////////////////////////////////////////////////////////////////
116
0ef21f59 117#include "TGeoManager.h"
5c7c93fa 118//#include "TGeoMatrix.h"
119#include "TMath.h"
120
0ef21f59 121#include "AliConst.h"
ff826920 122#include "AliGeomManager.h"
123#include "AliLog.h"
0ef21f59 124
5c7c93fa 125#include "AliTOFGeometry.h"
126
0ef21f59 127extern TGeoManager *gGeoManager;
0f4a7374 128
129ClassImp(AliTOFGeometry)
130
0ef21f59 131const Float_t AliTOFGeometry::fgkZlenA = 370.6*2.; // length (cm) of the A module
132const Float_t AliTOFGeometry::fgkZlenB = 146.5; // length (cm) of the B module
133const Float_t AliTOFGeometry::fgkZlenC = 170.45; // length (cm) of the C module
134const Float_t AliTOFGeometry::fgkMaxhZtof = 370.6; // Max half z-size of TOF (cm)
135
8dacd1bb 136const Float_t AliTOFGeometry::fgkxTOF = 372.00;// Inner radius of the TOF for Reconstruction (cm)
137const Float_t AliTOFGeometry::fgkRmin = 371.00;// Inner radius of the TOF (cm)
138const Float_t AliTOFGeometry::fgkRmax = 400.05;// Outer radius of the TOF (cm)
58eb5b61 139
7e6dce66 140const Float_t AliTOFGeometry::fgkXPad = 2.5; // Pad size in the x direction (cm)
141const Float_t AliTOFGeometry::fgkZPad = 3.5; // Pad size in the z direction (cm)
58eb5b61 142
4402e7cb 143const Float_t AliTOFGeometry::fgkStripLength = 122.;// Strip Length (rho X phi direction) (cm)
144
d3c7bfac 145const Float_t AliTOFGeometry::fgkSigmaForTail1= 2.; //Sig1 for simulation of TDC tails
fb9747d4 146const Float_t AliTOFGeometry::fgkSigmaForTail2= 0.5;//Sig2 for simulation of TDC tails
58eb5b61 147
0ef21f59 148const Float_t AliTOFGeometry::fgkPhiSec= 20;//sector Phi width (deg)
149
6786addd 150Bool_t AliTOFGeometry::fgHoles = 1;//logical for geometry version (w/wo holes)
151
48e6af28 152const Float_t AliTOFGeometry::fgkTdcBin = 24.4; // time-of-flight bin width [ps]
5ab3605a 153const Float_t AliTOFGeometry::fgkToTBin = 48.8; // time-over-threshold bin width [ps]
2bf4d9d6 154const Float_t AliTOFGeometry::fgkBunchCrossingBin = fgkTdcBin * 1024; // bunch-crossing bin width [ps]
43f77f2d 155
104ba366 156const Float_t AliTOFGeometry::fgkSlewTOTMin = 10.; // min TOT for slewing correction [ns]
157const Float_t AliTOFGeometry::fgkSlewTOTMax = 16.; // max TOT for slewing correction [ns]
158
5ab3605a 159const Float_t AliTOFGeometry::fgkDeadTime = 25E+03; // Single channel dead time (ps)
160const Float_t AliTOFGeometry::fgkMatchingWindow = fgkTdcBin*TMath::Power(2,13); // Matching window (ps)
161
162const Float_t AliTOFGeometry::fgkAngles[kNPlates][kMaxNstrip] = {
0ef21f59 163 { 43.99, 43.20, 42.40, 41.59, 40.77, 39.94, 39.11, 38.25, 37.40, 36.53,
164 35.65, 34.76, 33.87, 32.96, 32.05, 31.13, 30.19, 29.24, 12.33, 0.00},
165
166 { 27.26, 26.28, 25.30, 24.31, 23.31, 22.31, 21.30, 20.29, 19.26, 18.24,
167 17.20, 16.16, 15.11, 14.05, 13.00, 11.93, 10.87, 9.80, 8.74, 0.00},
168
169 { 0.00, 6.30, 5.31, 4.25, 3.19, 2.12, 1.06, 0.00, -1.06, -2.12,
170 -3.19, -4.25, -5.31, -6.30, 0.00, 0.00, 0.00, 0.00, 0.00, 0.00},
171
172 { -8.74, -9.80, -10.87, -11.93, -13.00, -14.05, -15.11, -16.16, -17.20, -18.24,
173 -19.26, -20.29, -21.30, -22.31, -23.31, -24.31, -25.30, -26.28, -27.26, 0.00},
174
175 {-12.33, -29.24, -30.19, -31.13, -32.05, -32.96, -33.87, -34.76, -35.65, -36.53,
176 -37.40, -38.25, -39.11, -39.94, -40.77, -41.59, -42.40, -43.20, -43.99, 0.00}
177 };
639473af 178
179/*
5ab3605a 180const Float_t AliTOFGeometry::fgkHeights[kNPlates][kMaxNstrip] = {
0ef21f59 181 {-8.2, -7.5, -8.2, -7.7, -8.1, -7.6, -7.7, -7.7, -7.7, -7.7,
182 -7.5, -7.2, -7.3, -7.5, -7.6, -7.8, -8.3, -9.3, -3.1, 0.0},
183
184 {-7.9, -8.1, -8.5, -9.0, -10.1, -3.9, -5.9, -7.7, -10.1, -3.6,
185 -5.8, -8.0, -10.4, -4.4, -7.2, -10.2, -4.6, -7.4, -10.4, 0.0},
186
187 {-2.5, -10.4, -5.0, -9.9, -4.8, -9.9, -4.7, -10.2, -4.7, -9.9,
188 -4.8, -9.9, -5.0, -10.4, -2.5, 0.0, 0.0, 0.0, 0.0, 0.0},
189
190 {-10.4, -7.4, -4.6, -10.2, -7.2, -4.4, -10.4, -8.0, -5.8, -3.6,
639473af 191 -10.1, -7.7, -5.9, -3.9, -10.1, -9.0, -8.5, -8.1, -7.9, 0.0},
0ef21f59 192
639473af 193 { -3.1, -9.3, -8.3, -7.8, -7.6, -7.5, -7.3, -7.2, -7.5, -7.7,
194 -7.7, -7.7, -7.7, -7.6, -8.1, -7.7, -8.2, -7.5, -8.2, 0.0}
0ef21f59 195 };
639473af 196*/
197/*
198const Float_t AliTOFGeometry::fgkHeights[kNPlates][kMaxNstrip] = {
199 { -8.405, -10.885, -8.405, -7.765, -8.285, -7.745, -7.865, -7.905, -7.895, -7.885,
200 -7.705, -7.395, -7.525, -7.645, -11.285, -10.355, -8.365, -9.385, -3.255, 0.000 },
201 { -7.905, -8.235, -8.605, -9.045, -10.205, -3.975, -5.915, -7.765, -10.205, -3.635,
202 -5.885, -8.005, -10.505, -4.395, -7.325, -10.235, -4.655, -7.495, -10.515, 0.000 },
203 { -2.705, -10.645, -5.165, -10.095, -4.995, -10.815, -4.835, -10.385, -4.835, -10.815,
204 -4.995, -10.095, -5.165, -10.645, -2.705, 0.000, 0.000, 0.000, 0.000, 0.000 },
205 { -10.515, -7.495, -4.655, -10.235, -7.325, -4.395, -10.505, -8.005, -5.885, -3.635,
206 -10.205, -7.765, -5.915, -3.975, -10.205, -9.045, -8.605, -8.235, -7.905, 0.000 },
207 { -3.255, -9.385, -8.365, -10.355, -11.285, -7.645, -7.525, -7.395, -7.705, -7.885,
208 -7.895, -7.905, -7.865, -7.745, -8.285, -7.765, -8.405, -10.885, -8.405, 0.000 }
209};
210*/
211
212
213const Float_t AliTOFGeometry::fgkHeights[kNPlates][kMaxNstrip] = {
214 { -8.405, -7.725, -8.405, -7.765, -8.285, -7.745, -7.865, -7.905, -7.895, -7.885,
215 -7.705, -7.395, -7.525, -7.645, -7.835, -7.965, -8.365, -9.385, -3.255, 0.000 },
216 { -7.905, -8.235, -8.605, -9.045, -10.205, -3.975, -5.915, -7.765, -10.205, -3.635,
217 -5.885, -8.005, -10.505, -4.395, -7.325, -10.235, -4.655, -7.495, -10.515, 0.000 },
218 { -2.705, -10.645, -5.165, -10.095, -4.995, -10.085, -4.835, -10.385, -4.835, -10.085,
219 -4.995, -10.095, -5.165, -10.645, -2.705, 0.000, 0.000, 0.000, 0.000, 0.000 },
220 {-10.515, -7.495, -4.655, -10.235, -7.325, -4.395, -10.505, -8.005, -5.885, -3.635,
221 -10.205, -7.765, -5.915, -3.975, -10.205, -9.045, -8.605, -8.235, -7.905, 0.000 },
222 { -3.255, -9.385, -8.365, -7.965, -7.835, -7.645, -7.525, -7.395, -7.705, -7.885,
223 -7.895, -7.905, -7.865, -7.745, -8.285, -7.765, -8.405, -7.725, -8.405, 0.000 }
224};
225
0ef21f59 226
227
5ab3605a 228const Float_t AliTOFGeometry::fgkDistances[kNPlates][kMaxNstrip] = {
639473af 229 { 364.14, 354.88, 344.49, 335.31, 325.44, 316.51, 307.11, 297.91, 288.84, 279.89,
230 271.20, 262.62, 253.84, 245.20, 236.56, 228.06, 219.46, 210.63, 206.09, 0.00 },
231 { 194.57, 186.38, 178.25, 170.13, 161.78, 156.62, 148.10, 139.72, 131.23, 125.87,
232 117.61, 109.44, 101.29, 95.46, 87.36, 79.37, 73.17, 65.33, 57.71, 0.00 },
233 { 49.28, 41.35, 35.37, 27.91, 21.20, 13.94, 7.06, 0.00, -7.06, -13.94,
234 -21.20, -27.91, -35.37, -41.35, -49.28, 0.00, 0.00, 0.00, 0.00, 0.00 },
235 { -57.71, -65.33, -73.17, -79.37, -87.36, -95.46, -101.29, -109.44, -117.61, -125.87,
236 -131.23, -139.72, -148.10, -156.62, -161.78, -170.13, -178.25, -186.38, -194.57, 0.00 },
237 {-206.09, -210.63, -219.46, -228.06, -236.56, -245.20, -253.84, -262.62, -271.20, -279.89,
238 -288.84, -297.91, -307.11, -316.51, -325.44, -335.31, -344.49, -354.88, -364.14, 0.00 }
239};
240
241/*
242const Float_t AliTOFGeometry::fgkDistances[kNPlates][kMaxNstrip] = {
0ef21f59 243 { 364.1, 354.9, 344.5, 335.4, 325.5, 316.6, 307.2, 298.0, 288.9, 280.0,
244 271.3, 262.7, 254.0, 244.8, 236.1, 227.7, 219.1, 210.3, 205.7, 0.0},
245
246 { 194.2, 186.1, 177.9, 169.8, 161.5, 156.3, 147.8, 139.4, 130.9, 125.6,
247 117.3, 109.2, 101.1, 95.3, 87.1, 79.2, 73.0, 65.1, 57.6, 0.0},
248
249 { 49.5, 41.3, 35.3, 27.8, 21.2, 13.9, 7.0, 0.0, -7.0, -13.9,
250 -21.2, -27.8, -35.3, -41.3, -49.5, 0.0, 0.0, 0.0, 0.0, 0.0},
251
252 { -57.6, -65.1, -73.0, -79.2, -87.1, -95.3, -101.1, -109.2, -117.3, -125.6,
253 -130.9, -139.4, -147.8, -156.3, -161.5, -169.8, -177.9, -186.1, -194.2, 0.0},
254
255 {-205.7, -210.3, -219.1, -227.7, -236.1, -244.8, -254.0, -262.7, -271.3, -280.0,
256 -288.9, -298.0, -307.2, -316.6, -325.5, -335.4, -344.5, -354.9, -364.1, 0.0}
257 };
639473af 258*/
0f4a7374 259//_____________________________________________________________________________
6786addd 260AliTOFGeometry::AliTOFGeometry()
0f4a7374 261{
262 //
263 // AliTOFGeometry default constructor
264 //
0f4a7374 265
266}
267
268//_____________________________________________________________________________
269AliTOFGeometry::~AliTOFGeometry()
270{
271 //
272 // AliTOFGeometry destructor
273 //
0f4a7374 274}
275//_____________________________________________________________________________
0ef21f59 276void AliTOFGeometry::ImportGeometry(){
277 TGeoManager::Import("geometry.root");
0f4a7374 278}
0f4a7374 279//_____________________________________________________________________________
6786addd 280void AliTOFGeometry::GetPosPar(Int_t *det, Float_t *pos)
0f4a7374 281{
282//
283// Returns space point coor (x,y,z) (cm) for Detector
284// Indices (iSect,iPlate,iStrip,iPadX,iPadZ)
285//
286
287 pos[0]=GetX(det);
288 pos[1]=GetY(det);
289 pos[2]=GetZ(det);
290
291}
292//_____________________________________________________________________________
6786addd 293void AliTOFGeometry::GetDetID( Float_t *pos, Int_t *det)
0f4a7374 294{
295 //
296 // Returns Detector Indices (iSect,iPlate,iStrip,iPadX,iPadZ)
297 // space point coor (x,y,z) (cm)
298
299
300 det[0]=GetSector(pos);
301 det[1]=GetPlate(pos);
302 det[2]=GetStrip(pos);
303 det[3]=GetPadZ(pos);
304 det[4]=GetPadX(pos);
305
306}
307//_____________________________________________________________________________
48e6af28 308
309void AliTOFGeometry::DetToStripRF(Int_t nPadX, Int_t nPadZ, Float_t &x, Float_t &z) const
310{
311 //
312 // Returns the local coordinates (x, z) in strip reference frame
313 // for the bottom corner of the pad number (nPadX, nPadZ)
314 //
315 /*
316 const Float_t xCenterStrip = kNpadX * fgkXPad / 2.;
317 const Float_t zCenterStrip = kNpadZ * fgkZPad / 2.;
318
319 const Float_t xCenterPad = nPadX*fgkXPad + fgkXPad / 2.;
320 const Float_t zCenterPad = nPadZ*fgkZPad + fgkZPad / 2.;
321
322 x = xCenterPad - xCenterStrip;
323 z = zCenterPad - zCenterStrip;
324 */
325
326
327 x = (nPadX - kNpadX*0.5) * fgkXPad;
328 z = (nPadZ - kNpadZ*0.5) * fgkZPad;
329
330
331}
332//_____________________________________________________________________________
d02e3c4b 333Float_t AliTOFGeometry::DistanceToPadPar(Int_t *det, const Float_t * pos, Float_t *dist3d)
0ef21f59 334{
335//
336// Returns distance of space point with coor pos (x,y,z) (cm) wrt
337// pad with Detector Indices idet (iSect,iPlate,iStrip,iPadX,iPadZ)
338//
339
340 //Transform pos into Sector Frame
341
342 Float_t x = pos[0];
343 Float_t y = pos[1];
344 Float_t z = pos[2];
345
346 Float_t radius = TMath::Sqrt(x*x+y*y);
347 //Float_t phi=TMath::ATan(y/x);
348 //if(phi<0) phi = k2PI+phi; //2.*TMath::Pi()+phi;
349 Float_t phi = TMath::Pi()+TMath::ATan2(-y,-x);
350 // Get the local angle in the sector philoc
351 Float_t angle = phi*kRaddeg-( Int_t (kRaddeg*phi/fgkPhiSec) + 0.5)*fgkPhiSec;
352 Float_t xs = radius*TMath::Cos(angle/kRaddeg);
353 Float_t ys = radius*TMath::Sin(angle/kRaddeg);
354 Float_t zs = z;
355
356 // Do the same for the selected pad
357
358 Float_t g[3];
359 GetPosPar(det,g);
360
361 Float_t padRadius = TMath::Sqrt(g[0]*g[0]+g[1]*g[1]);
362 //Float_t padPhi = TMath::ATan(g[1]/g[0]);
363 //if(padPhi<0) padPhi = k2Pi + padPhi;
364 Float_t padPhi = TMath::Pi()+TMath::ATan2(-g[1],-g[0]);
365
366 // Get the local angle in the sector philoc
367 Float_t padAngle = padPhi*kRaddeg-( Int_t (padPhi*kRaddeg/fgkPhiSec)+ 0.5) * fgkPhiSec;
368 Float_t padxs = padRadius*TMath::Cos(padAngle/kRaddeg);
369 Float_t padys = padRadius*TMath::Sin(padAngle/kRaddeg);
370 Float_t padzs = g[2];
371
372 //Now move to local pad coordinate frame. Translate:
373
374 Float_t xt = xs-padxs;
375 Float_t yt = ys-padys;
376 Float_t zt = zs-padzs;
377 //Now Rotate:
378
379 Float_t alpha = GetAngles(det[1],det[2]);
380 Float_t xr = xt*TMath::Cos(alpha/kRaddeg)+zt*TMath::Sin(alpha/kRaddeg);
381 Float_t yr = yt;
382 Float_t zr = -xt*TMath::Sin(alpha/kRaddeg)+zt*TMath::Cos(alpha/kRaddeg);
383
384 Float_t dist = TMath::Sqrt(xr*xr+yr*yr+zr*zr);
385
386 if (dist3d){
387 dist3d[0] = xr;
388 dist3d[1] = yr;
389 dist3d[2] = zr;
390 }
391
392 return dist;
393
394}
395//_____________________________________________________________________________
5533b7d3 396Bool_t AliTOFGeometry::IsInsideThePadPar(Int_t *det, const Float_t * pos)
0ef21f59 397{
398//
399// Returns true if space point with coor pos (x,y,z) (cm) falls
400// inside pad with Detector Indices idet (iSect,iPlate,iStrip,iPadX,iPadZ)
401//
402
403 Bool_t isInside=false;
404
405 /*
406 const Float_t khhony = 1.0 ; // heigth of HONY Layer
407 const Float_t khpcby = 0.08 ; // heigth of PCB Layer
408 const Float_t khrgly = 0.055 ; // heigth of RED GLASS Layer
409 const Float_t khglfy = 0.285 ; // heigth of GLASS+FISHLINE Layer
410 const Float_t khcpcby = 0.16 ; // heigth of PCB Central Layer
411 //const Float_t kwcpcbz = 12.4 ; // z dimension of PCB Central Layer
412 const Float_t khstripy = 2.*khhony+2.*khpcby+4.*khrgly+2.*khglfy+khcpcby;//3.11
413 //const Float_t kwstripz = kwcpcbz;
414 //const Float_t klstripx = fgkStripLength;
415 */
416
417 const Float_t kPadDepth = 0.5;//0.05;//0.11;//0.16;// // heigth of Sensitive Layer
418
419 //Transform pos into Sector Frame
420
421 Float_t x = pos[0];
422 Float_t y = pos[1];
423 Float_t z = pos[2];
424
425 Float_t radius = TMath::Sqrt(x*x+y*y);
426 Float_t phi = TMath::Pi()+TMath::ATan2(-y,-x);
427
428 // Get the local angle in the sector philoc
429 Float_t angle = phi*kRaddeg-( Int_t (kRaddeg*phi/fgkPhiSec) + 0.5) *fgkPhiSec;
430 Float_t xs = radius*TMath::Cos(angle/kRaddeg);
431 Float_t ys = radius*TMath::Sin(angle/kRaddeg);
432 Float_t zs = z;
433
434 // Do the same for the selected pad
435
436 Float_t g[3];
437 GetPosPar(det,g);
438
439 Float_t padRadius = TMath::Sqrt(g[0]*g[0]+g[1]*g[1]);
440 Float_t padPhi = TMath::Pi()+TMath::ATan2(-g[1],-g[0]);
441
442 // Get the local angle in the sector philoc
443 Float_t padAngle = padPhi*kRaddeg-( Int_t (padPhi*kRaddeg/fgkPhiSec)+ 0.5) * fgkPhiSec;
444 Float_t padxs = padRadius*TMath::Cos(padAngle/kRaddeg);
445 Float_t padys = padRadius*TMath::Sin(padAngle/kRaddeg);
446 Float_t padzs = g[2];
447
448 //Now move to local pad coordinate frame. Translate:
449
450 Float_t xt = xs-padxs;
451 Float_t yt = ys-padys;
452 Float_t zt = zs-padzs;
453
454 //Now Rotate:
455
456 Float_t alpha = GetAngles(det[1],det[2]);
457 Float_t xr = xt*TMath::Cos(alpha/kRaddeg)+zt*TMath::Sin(alpha/kRaddeg);
458 Float_t yr = yt;
459 Float_t zr = -xt*TMath::Sin(alpha/kRaddeg)+zt*TMath::Cos(alpha/kRaddeg);
460
461 if(TMath::Abs(xr)<=kPadDepth*0.5 && TMath::Abs(yr)<= (fgkXPad*0.5) && TMath::Abs(zr)<= (fgkZPad*0.5))
462 isInside=true;
463 return isInside;
464
465}
466//_____________________________________________________________________________
5533b7d3 467Bool_t AliTOFGeometry::IsInsideThePad(TGeoHMatrix *mat, const Float_t * pos, Float_t *dist3d)
0ef21f59 468{
6819758a 469 //
470 // Returns true if space point with coor pos (x,y,z) [cm] falls inside
471 // pad identified by the matrix mat. In case dist3d!=0, dist3d vector
472 // has been filled with the 3D distance between the impact point on
473 // the pad and the pad centre (in the reference frame of the TOF pad
474 // identified by the matrix mat).
475 //
0ef21f59 476
477 const Float_t kPadDepth = 0.5; // heigth of Sensitive Layer
0ef21f59 478
6819758a 479 Double_t posg[3];
480 posg[0] = pos[0];
481 posg[1] = pos[1];
482 posg[2] = pos[2];
483
484 // from ALICE global reference system
485 // towards TOF pad reference system
486 Double_t posl[3] = {0., 0., 0.};
8104fec9 487 mat->MasterToLocal(posg,posl);
6819758a 488
489 Float_t xr = posl[0];
490 Float_t yr = posl[1];
491 Float_t zr = posl[2];
492
493 Bool_t isInside = false;
494 if (TMath::Abs(yr)<= kPadDepth*0.5 &&
495 TMath::Abs(xr)<= fgkXPad*0.5 &&
496 TMath::Abs(zr)<= fgkZPad*0.5)
497 isInside = true;
498
499 if (dist3d) {
500 //Double_t padl[3] = {0., 0., 0.};
501 dist3d[0] = posl[0]/* - padl[0]*/;
502 dist3d[1] = posl[1]/* - padl[1]*/;
503 dist3d[2] = posl[2]/* - padl[2]*/;
504
505 /*
506 Double_t padg[3] = {0., 0., 0.};
507 // from TOF pad local reference system
508 // towards ALICE global reference system
8104fec9 509 TGeoHMatrix inverse = mat->Inverse();
6819758a 510 inverse.MasterToLocal(padl,padg);
511
512 // returns the 3d distance
513 // between the impact point on the pad
514 // and the pad centre (in the ALICE global reference frame)
515 dist3d[0] = posg[0] - padg[0];
516 dist3d[1] = posg[1] - padg[1];
517 dist3d[2] = posg[2] - padg[2];
518 */
0ef21f59 519 }
520
0ef21f59 521 return isInside;
522
523}
524//_____________________________________________________________________________
a5043fb0 525void AliTOFGeometry::GetVolumePath(const Int_t * ind, Char_t *path ) {
0ef21f59 526 //--------------------------------------------------------------------
527 // This function returns the colume path of a given pad
528 //--------------------------------------------------------------------
529 Int_t sector = ind[0];
1d834a1e 530
531 const Int_t kSize = 100;
532
533 Char_t string1[kSize];
534 Char_t string2[kSize];
535 Char_t string3[kSize];
0ef21f59 536
537 Int_t icopy=-1;
538 icopy=sector;
539
1d834a1e 540 snprintf(string1,kSize,"/ALIC_1/B077_1/BSEGMO%i_1/BTOF%i_1",icopy,icopy);
0ef21f59 541
542 Int_t iplate=ind[1];
543 Int_t istrip=ind[2];
544 if( iplate==0) icopy=istrip;
545 if( iplate==1) icopy=istrip+NStripC();
546 if( iplate==2) icopy=istrip+NStripC()+NStripB();
547 if( iplate==3) icopy=istrip+NStripC()+NStripB()+NStripA();
548 if( iplate==4) icopy=istrip+NStripC()+2*NStripB()+NStripA();
549 icopy++;
1d834a1e 550 snprintf(string2,kSize,"FTOA_0/FLTA_0/FSTR_%i",icopy);
6786addd 551 if(fgHoles && (sector==13 || sector==14 || sector==15)){
1d834a1e 552 if(iplate<2) snprintf(string2,kSize,"FTOB_0/FLTB_0/FSTR_%i",icopy);
553 if(iplate>2) snprintf(string2,kSize,"FTOC_0/FLTC_0/FSTR_%i",icopy);
0ef21f59 554 }
555
556 Int_t padz = ind[3]+1;
557 Int_t padx = ind[4]+1;
1d834a1e 558 snprintf(string3,kSize,"FPCB_1/FSEN_1/FSEZ_%i/FPAD_%i",padz,padx);
559 snprintf(path,2*kSize,"%s/%s/%s",string1,string2,string3);
0ef21f59 560
561}
562//_____________________________________________________________________________
563void AliTOFGeometry::GetVolumePath(Int_t sector, Char_t *path ){
564 //--------------------------------------------------------------------
565 // This function returns the colume path of a given sector
566 //--------------------------------------------------------------------
567
de40f9c1 568 const Int_t kSize = 100;
1d834a1e 569
570 Char_t string[kSize];
0ef21f59 571
572 Int_t icopy = sector;
573
1d834a1e 574 snprintf(string,kSize,"/ALIC_1/B077_1/BSEGMO%i_1/BTOF%i_1",icopy,icopy);
de40f9c1 575 snprintf(path,2*kSize,"%s",string);
0ef21f59 576
577}
578//_____________________________________________________________________________
579void AliTOFGeometry::GetVolumePath(Int_t sector, Int_t plate, Int_t strip, Char_t *path ) {
580 //--------------------------------------------------------------------
581 // This function returns the colume path of a given strip
582 //--------------------------------------------------------------------
583
de40f9c1 584 const Int_t kSize = 100;
1d834a1e 585
586 Char_t string1[kSize];
587 Char_t string2[kSize];
588 Char_t string3[kSize];
0ef21f59 589
590 Int_t icopy = sector;
591
1d834a1e 592 snprintf(string1,kSize,"/ALIC_1/B077_1/BSEGMO%i_1/BTOF%i_1",icopy,icopy);
0ef21f59 593
594 if(plate==0) icopy=strip;
595 if(plate==1) icopy=strip+NStripC();
596 if(plate==2) icopy=strip+NStripC()+NStripB();
597 if(plate==3) icopy=strip+NStripC()+NStripB()+NStripA();
598 if(plate==4) icopy=strip+NStripC()+2*NStripB()+NStripA();
599 icopy++;
1d834a1e 600 snprintf(string2,kSize,"FTOA_0/FLTA_0/FSTR_%i",icopy);
6786addd 601 if(fgHoles && (sector==13 || sector==14 || sector==15)){
1d834a1e 602 if(plate<2) snprintf(string2,kSize,"FTOB_0/FLTB_0/FSTR_%i",icopy);
603 if(plate>2) snprintf(string2,kSize,"FTOC_0/FLTC_0/FSTR_%i",icopy);
0ef21f59 604 }
605
1d834a1e 606 snprintf(string3,kSize,"FPCB_1/FSEN_1");
607 snprintf(path,2*kSize,"%s/%s/%s",string1,string2,string3);
0ef21f59 608
609}
610//_____________________________________________________________________________
611void AliTOFGeometry::GetPos(Int_t *det, Float_t *pos)
612{
613//
614// Returns space point coor (x,y,z) (cm) for Detector
615// Indices (iSect,iPlate,iStrip,iPadX,iPadZ)
616//
de40f9c1 617 Char_t path[200];
618 GetVolumePath(det,path);
0ef21f59 619 if (!gGeoManager) {
620 printf("ERROR: no TGeo\n");
621 }
622 gGeoManager->cd(path);
623 TGeoHMatrix global;
624 global = *gGeoManager->GetCurrentMatrix();
625 const Double_t *tr = global.GetTranslation();
626
627 pos[0]=tr[0];
628 pos[1]=tr[1];
629 pos[2]=tr[2];
630}
631//_____________________________________________________________________________
a5043fb0 632Int_t AliTOFGeometry::GetPlate(const Float_t * pos)
0ef21f59 633{
634 //
635 // Returns the Plate index
636 //
637 const Float_t kInterCentrModBorder1 = 49.5;
638 const Float_t kInterCentrModBorder2 = 57.5;
639 const Float_t kExterInterModBorder1 = 196.0;
640 const Float_t kExterInterModBorder2 = 203.5;
641
642 const Float_t kLengthExInModBorder = 4.7;
643 const Float_t kLengthInCeModBorder = 7.0;
644
645 //const Float_t khAlWall = 0.1;
646 const Float_t kModuleWallThickness = 0.3;
647 //const Float_t kHoneycombLayerThickness = 1.5;
648
649 Int_t iPlate=-1;
650
651 Float_t posLocal[3];
652 for (Int_t ii=0; ii<3; ii++) posLocal[ii] = pos[ii];
653
654 Int_t isector = GetSector(posLocal);
655 if(isector == -1){
656 //AliError("Detector Index could not be determined");
657 return iPlate;
658 }
659
660 // ALICE reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
661 Double_t angles[6] =
662 {90., 90.+(isector+0.5)*fgkPhiSec,
663 0., 0.,
664 90., (isector+0.5)*fgkPhiSec
665 };
666 Rotation(posLocal,angles);
667
2942f542 668 Float_t step[3] = {0., 0., static_cast<Float_t>((fgkRmax+fgkRmin)*0.5)};
0ef21f59 669 Translation(posLocal,step);
670
671 // B071/B074/B075 = BTO1/2/3 reference frame -> FTOA = FLTA reference frame
672 angles[0] = 90.;
673 angles[1] = 0.;
674 angles[2] = 0.;
675 angles[3] = 0.;
676 angles[4] = 90.;
677 angles[5] =270.;
678
679 Rotation(posLocal,angles);
680
681 Float_t yLocal = posLocal[1];
682 Float_t zLocal = posLocal[2];
683
684 Float_t deltaRhoLoc = (fgkRmax-fgkRmin)*0.5 - kModuleWallThickness + yLocal;
685 Float_t deltaZetaLoc = TMath::Abs(zLocal);
686
687 Float_t deltaRHOmax = 0.;
688
689 if (TMath::Abs(zLocal)>=kExterInterModBorder1 && TMath::Abs(zLocal)<=kExterInterModBorder2)
690 {
691 deltaRhoLoc -= kLengthExInModBorder;
692 deltaZetaLoc = kExterInterModBorder2-deltaZetaLoc;
693 deltaRHOmax = (fgkRmax - fgkRmin)*0.5 - kModuleWallThickness - 2.*kLengthExInModBorder; // old 5.35, new 4.8
694
695 if (deltaRhoLoc > deltaZetaLoc*deltaRHOmax/(kInterCentrModBorder2-kInterCentrModBorder1)) {
696 if (zLocal<0) iPlate = 0;
697 else iPlate = 4;
698 }
699 else {
700 if (zLocal<0) iPlate = 1;
701 else iPlate = 3;
702 }
703 }
704 else if (TMath::Abs(zLocal)>=kInterCentrModBorder1 && TMath::Abs(zLocal)<=kInterCentrModBorder2)
705 {
706 deltaRhoLoc -= kLengthInCeModBorder;
707 deltaZetaLoc = deltaZetaLoc-kInterCentrModBorder1;
708 deltaRHOmax = (fgkRmax - fgkRmin)*0.5 - kModuleWallThickness - 2.*kLengthInCeModBorder; // old 0.39, new 0.2
709
710 if (deltaRhoLoc>deltaZetaLoc*deltaRHOmax/(kInterCentrModBorder2-kInterCentrModBorder1)) iPlate = 2;
711 else {
712 if (zLocal<0) iPlate = 1;
713 else iPlate = 3;
714 }
715 }
716
ff826920 717 if (zLocal>-fgkZlenA*0.5 && zLocal<-kExterInterModBorder2) iPlate = 0;
718 else if (zLocal>-kExterInterModBorder1 && zLocal<-kInterCentrModBorder2) iPlate = 1;
719 else if (zLocal>-kInterCentrModBorder1 && zLocal< kInterCentrModBorder1) iPlate = 2;
720 else if (zLocal> kInterCentrModBorder2 && zLocal< kExterInterModBorder1) iPlate = 3;
721 else if (zLocal> kExterInterModBorder2 && zLocal< fgkZlenA*0.5) iPlate = 4;
0ef21f59 722
723 return iPlate;
724
725}
726
727//_____________________________________________________________________________
a5043fb0 728Int_t AliTOFGeometry::GetSector(const Float_t * pos)
0ef21f59 729{
730 //
731 // Returns the Sector index
732 //
733
0ef21f59 734 Int_t iSect = -1;
735
736 Float_t x = pos[0];
737 Float_t y = pos[1];
738 Float_t z = pos[2];
739
740 Float_t rho = TMath::Sqrt(x*x + y*y);
741
0ef21f59 742 if (!((z>=-fgkZlenA*0.5 && z<=fgkZlenA*0.5) &&
743 (rho>=(fgkRmin) && rho<=(fgkRmax)))) {
0ef21f59 744 //AliError("Detector Index could not be determined");
745 return iSect;
746 }
747
748 Float_t phi = TMath::Pi() + TMath::ATan2(-y,-x);
749
750 iSect = (Int_t) (phi*kRaddeg/fgkPhiSec);
751
752 return iSect;
753
754}
755//_____________________________________________________________________________
a5043fb0 756Int_t AliTOFGeometry::GetStrip(const Float_t * pos)
0ef21f59 757{
758 //
759 // Returns the Strip index
760 //
761 const Float_t khhony = 1.0 ; // heigth of HONY Layer
762 const Float_t khpcby = 0.08 ; // heigth of PCB Layer
763 const Float_t khrgly = 0.055 ; // heigth of RED GLASS Layer
764 const Float_t khglfy = 0.285 ; // heigth of GLASS+FISHLINE Layer
765 const Float_t khcpcby = 0.16 ; // heigth of PCB Central Layer
766 const Float_t kwcpcbz = 12.4 ; // z dimension of PCB Central Layer
767 const Float_t khstripy = 2.*khhony+2.*khpcby+4.*khrgly+2.*khglfy+khcpcby;//3.11
768 const Float_t kwstripz = kwcpcbz;
769 const Float_t klstripx = fgkStripLength;
770
771 Int_t iStrip=-1;
772
773 Float_t posLocal[3];
774 for (Int_t ii=0; ii<3; ii++) posLocal[ii] = pos[ii];
6786addd 775// AliDebug(1,Form(" posLocal[0] = %f, posLocal[1] = %f, posLocal[2] = %f ",
776// posLocal[0],posLocal[1],posLocal[2]));
6819758a 777
0ef21f59 778 Int_t isector = GetSector(posLocal);
779 if(isector == -1){
780 //AliError("Detector Index could not be determined");
781 return iStrip;}
782 Int_t iplate = GetPlate(posLocal);
783 if(iplate == -1){
784 //AliError("Detector Index could not be determined");
785 return iStrip;}
786
787 Int_t nstrips=0;
788 switch (iplate) {
789 case 0:
0ef21f59 790 case 4:
791 nstrips=kNStripC;
792 break;
793 case 1:
0ef21f59 794 case 3:
795 nstrips=kNStripB;
796 break;
797 case 2:
798 nstrips=kNStripA;
799 break;
800 }
801
802 // ALICE reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
803 Double_t angles[6] =
804 {90., 90.+(isector+0.5)*fgkPhiSec,
805 0., 0.,
806 90., (isector+0.5)*fgkPhiSec
807 };
808 Rotation(posLocal,angles);
6786addd 809 // AliDebug(1,Form(" posLocal[0] = %f, posLocal[1] = %f, posLocal[2] = %f ",
810 // posLocal[0],posLocal[1],posLocal[2]));
0ef21f59 811
2942f542 812 Float_t step[3] = {0., 0., static_cast<Float_t>((fgkRmax+fgkRmin)*0.5)};
0ef21f59 813 Translation(posLocal,step);
6786addd 814 // AliDebug(1,Form(" posLocal[0] = %f, posLocal[1] = %f, posLocal[2] = %f ",
815 // posLocal[0],posLocal[1],posLocal[2]));
0ef21f59 816
817 // B071/B074/B075 = BTO1/2/3 reference frame -> FTOA = FLTA reference frame
818 angles[0] = 90.;
819 angles[1] = 0.;
820 angles[2] = 0.;
821 angles[3] = 0.;
822 angles[4] = 90.;
823 angles[5] =270.;
824
825 Rotation(posLocal,angles);
6786addd 826 // AliDebug(1,Form(" posLocal[0] = %f, posLocal[1] = %f, posLocal[2] = %f ",
827 // posLocal[0],posLocal[1],posLocal[2]));
0ef21f59 828
829 // FTOA/B/C = FLTA/B/C reference frame -> FSTR reference frame
830 Int_t totStrip=0;
831 for (Int_t istrip=0; istrip<nstrips; istrip++){
832
833 Float_t posLoc2[3]={posLocal[0],posLocal[1],posLocal[2]};
834
835 step[0] = 0.;
836 step[1] = GetHeights(iplate,istrip);
837 step[2] = -GetDistances(iplate,istrip);
838 Translation(posLoc2,step);
839
840 if (GetAngles(iplate,istrip) >0.) {
841 angles[0] = 90.;
842 angles[1] = 0.;
843 angles[2] = 90.+GetAngles(iplate,istrip);
844 angles[3] = 90.;
845 angles[4] = GetAngles(iplate,istrip);
846 angles[5] = 90.;
847 }
848 else if (GetAngles(iplate,istrip)==0.) {
849 angles[0] = 90.;
850 angles[1] = 0.;
851 angles[2] = 90.;
852 angles[3] = 90.;
853 angles[4] = 0;
854 angles[5] = 0.;
855 }
856 else if (GetAngles(iplate,istrip) <0.) {
857 angles[0] = 90.;
858 angles[1] = 0.;
859 angles[2] = 90.+GetAngles(iplate,istrip);
860 angles[3] = 90.;
861 angles[4] =-GetAngles(iplate,istrip);
862 angles[5] = 270.;
863 }
864 Rotation(posLoc2,angles);
6786addd 865 // AliDebug(1,Form(" strip %2d: posLoc2[0] = %f, posLoc2[1] = %f, posLoc2[2] = %f ",
866 // istrip, posLoc2[0],posLoc2[1],posLoc2[2]));
0ef21f59 867
868 if ((TMath::Abs(posLoc2[0])<=klstripx*0.5) &&
869 (TMath::Abs(posLoc2[1])<=khstripy*0.5) &&
870 (TMath::Abs(posLoc2[2])<=kwstripz*0.5)) {
871 iStrip = istrip;
872 totStrip++;
873 for (Int_t jj=0; jj<3; jj++) posLocal[jj]=posLoc2[jj];
6786addd 874 // AliDebug(2,Form(" posLocal[0] = %f, posLocal[1] = %f, posLocal[2] = %f ",
875 // posLocal[0],posLocal[1],posLocal[2]));
0ef21f59 876
6786addd 877 // AliDebug(2,Form(" GetAngles(%1i,%2i) = %f, pos[0] = %f, pos[1] = %f, pos[2] = %f",
878 // iplate, istrip, GetAngles(iplate,istrip), pos[0], pos[1], pos[2]));
0ef21f59 879 break;
880 }
881
6786addd 882 // if (totStrip>1) AliInfo(Form("total strip number found %2i",totStrip));
0ef21f59 883
884 }
885
886 return iStrip;
887
888}
889//_____________________________________________________________________________
a5043fb0 890Int_t AliTOFGeometry::GetPadZ(const Float_t * pos)
0ef21f59 891{
892 //
893 // Returns the Pad index along Z
894 //
895 //const Float_t klsensmx = kNpadX*fgkXPad; // length of Sensitive Layer
896 //const Float_t khsensmy = 0.05;//0.11;//0.16;// heigth of Sensitive Layer
897 //const Float_t kwsensmz = kNpadZ*fgkZPad; // width of Sensitive Layer
898
899 Int_t iPadZ = -1;
900
901 Float_t posLocal[3];
902 for (Int_t ii=0; ii<3; ii++) posLocal[ii] = pos[ii];
903
904 Int_t isector = GetSector(posLocal);
905 if(isector == -1){
906 //AliError("Detector Index could not be determined");
907 return iPadZ;}
908 Int_t iplate = GetPlate(posLocal);
909 if(iplate == -1){
910 //AliError("Detector Index could not be determined");
911 return iPadZ;}
912 Int_t istrip = GetStrip(posLocal);
913 if(istrip == -1){
914 //AliError("Detector Index could not be determined");
915 return iPadZ;}
916
917 // ALICE reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
918 Double_t angles[6] =
919 {90., 90.+(isector+0.5)*fgkPhiSec,
920 0., 0.,
921 90., (isector+0.5)*fgkPhiSec
922 };
923 Rotation(posLocal,angles);
924
2942f542 925 Float_t step[3] = {0., 0., static_cast<Float_t>((fgkRmax+fgkRmin)*0.5)};
0ef21f59 926 Translation(posLocal,step);
927
928 // B071/B074/B075 = BTO1/2/3 reference frame -> FTOA = FLTA reference frame
929 angles[0] = 90.;
930 angles[1] = 0.;
931 angles[2] = 0.;
932 angles[3] = 0.;
933 angles[4] = 90.;
934 angles[5] =270.;
935
936 Rotation(posLocal,angles);
937
938 // FTOA/B/C = FLTA/B/C reference frame -> FSTR reference frame
939 step[0] = 0.;
940 step[1] = GetHeights(iplate,istrip);
941 step[2] = -GetDistances(iplate,istrip);
942 Translation(posLocal,step);
943
944 if (GetAngles(iplate,istrip) >0.) {
945 angles[0] = 90.;
946 angles[1] = 0.;
947 angles[2] = 90.+GetAngles(iplate,istrip);
948 angles[3] = 90.;
949 angles[4] = GetAngles(iplate,istrip);
950 angles[5] = 90.;
951 }
952 else if (GetAngles(iplate,istrip)==0.) {
953 angles[0] = 90.;
954 angles[1] = 0.;
955 angles[2] = 90.;
956 angles[3] = 90.;
957 angles[4] = 0;
958 angles[5] = 0.;
959 }
960 else if (GetAngles(iplate,istrip) <0.) {
961 angles[0] = 90.;
962 angles[1] = 0.;
963 angles[2] = 90.+GetAngles(iplate,istrip);
964 angles[3] = 90.;
965 angles[4] =-GetAngles(iplate,istrip);
966 angles[5] = 270.;
967 }
968 Rotation(posLocal,angles);
969
ff826920 970 step[0] =-0.5*kNpadX*fgkXPad;
971 step[1] = 0.;
972 step[2] =-0.5*kNpadZ*fgkZPad;
973 Translation(posLocal,step);
0ef21f59 974
ff826920 975 iPadZ = (Int_t)(posLocal[2]/fgkZPad);
976 if (iPadZ==kNpadZ) iPadZ--;
977 else if (iPadZ>kNpadZ) iPadZ=-1;
0ef21f59 978
979 return iPadZ;
980
981}
982//_____________________________________________________________________________
a5043fb0 983Int_t AliTOFGeometry::GetPadX(const Float_t * pos)
0ef21f59 984{
985 //
986 // Returns the Pad index along X
987 //
988 //const Float_t klsensmx = kNpadX*fgkXPad; // length of Sensitive Layer
989 //const Float_t khsensmy = 0.05;//0.11;//0.16;// heigth of Sensitive Layer
990 //const Float_t kwsensmz = kNpadZ*fgkZPad; // width of Sensitive Layer
991
992 Int_t iPadX = -1;
993
994 Float_t posLocal[3];
995 for (Int_t ii=0; ii<3; ii++) posLocal[ii] = pos[ii];
996
997 Int_t isector = GetSector(posLocal);
998 if(isector == -1){
999 //AliError("Detector Index could not be determined");
1000 return iPadX;}
1001 Int_t iplate = GetPlate(posLocal);
1002 if(iplate == -1){
1003 //AliError("Detector Index could not be determined");
1004 return iPadX;}
1005 Int_t istrip = GetStrip(posLocal);
1006 if(istrip == -1){
1007 //AliError("Detector Index could not be determined");
1008 return iPadX;}
1009
1010 // ALICE reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
1011 Double_t angles[6] =
1012 {90., 90.+(isector+0.5)*fgkPhiSec,
1013 0., 0.,
1014 90., (isector+0.5)*fgkPhiSec
1015 };
1016 Rotation(posLocal,angles);
1017
2942f542 1018 Float_t step[3] = {0., 0., static_cast<Float_t>((fgkRmax+fgkRmin)*0.5)};
0ef21f59 1019 Translation(posLocal,step);
1020
1021 // B071/B074/B075 = BTO1/2/3 reference frame -> FTOA/B/C = FLTA/B/C reference frame
1022 angles[0] = 90.;
1023 angles[1] = 0.;
1024 angles[2] = 0.;
1025 angles[3] = 0.;
1026 angles[4] = 90.;
1027 angles[5] =270.;
1028
1029 Rotation(posLocal,angles);
1030
1031 // FTOA/B/C = FLTA/B/C reference frame -> FSTR reference frame
1032 step[0] = 0.;
1033 step[1] = GetHeights(iplate,istrip);
1034 step[2] = -GetDistances(iplate,istrip);
1035 Translation(posLocal,step);
1036
1037 if (GetAngles(iplate,istrip) >0.) {
1038 angles[0] = 90.;
1039 angles[1] = 0.;
1040 angles[2] = 90.+GetAngles(iplate,istrip);
1041 angles[3] = 90.;
1042 angles[4] = GetAngles(iplate,istrip);
1043 angles[5] = 90.;
1044 }
1045 else if (GetAngles(iplate,istrip)==0.) {
1046 angles[0] = 90.;
1047 angles[1] = 0.;
1048 angles[2] = 90.;
1049 angles[3] = 90.;
1050 angles[4] = 0;
1051 angles[5] = 0.;
1052 }
1053 else if (GetAngles(iplate,istrip) <0.) {
1054 angles[0] = 90.;
1055 angles[1] = 0.;
1056 angles[2] = 90.+GetAngles(iplate,istrip);
1057 angles[3] = 90.;
1058 angles[4] =-GetAngles(iplate,istrip);
1059 angles[5] = 270.;
1060 }
1061 Rotation(posLocal,angles);
1062
ff826920 1063 step[0] =-0.5*kNpadX*fgkXPad;
1064 step[1] = 0.;
1065 step[2] =-0.5*kNpadZ*fgkZPad;
1066 Translation(posLocal,step);
0ef21f59 1067
ff826920 1068 iPadX = (Int_t)(posLocal[0]/fgkXPad);
1069 if (iPadX==kNpadX) iPadX--;
1070 else if (iPadX>kNpadX) iPadX=-1;
0ef21f59 1071
1072 return iPadX;
1073
1074}
1075//_____________________________________________________________________________
a5043fb0 1076Float_t AliTOFGeometry::GetX(const Int_t * det)
0ef21f59 1077{
1078 //
1079 // Returns X coordinate (cm)
1080 //
1081
1082 Int_t isector = det[0];
1083 Int_t iplate = det[1];
1084 Int_t istrip = det[2];
1085 Int_t ipadz = det[3];
1086 Int_t ipadx = det[4];
1087
1088 /*
1089 // Find out distance d on the plane wrt median phi:
1090 Float_t d = (ipadx+0.5-kNpadX*0.5)*fgkXPad;
1091
1092 // The radius r in xy plane:
1093 //Float_t r = (fgkRmin+fgkRmax)*0.5-0.01+GetHeights(iplate,istrip)+
1094 // (ipadz-0.5)*fgkZPad*TMath::Sin(GetAngles(iplate,istrip)/kRaddeg)-0.25; ???
1095 Float_t r = (fgkRmin+fgkRmax)*0.5-0.01+GetHeights(iplate,istrip)+
1096 (ipadz-0.5)*fgkZPad*TMath::Sin(GetAngles(iplate,istrip)/kRaddeg);
1097
1098 // local azimuthal angle in the sector philoc
1099 Float_t philoc = TMath::ATan(d/r);
1100 //if(philoc<0.) philoc = k2PI + philoc;
1101
1102 // azimuthal angle in the global frame phi
1103 Float_t phi = philoc*kRaddeg+(isector+0.5)*fgkPhiSec;
1104
1105 Float_t xCoor = r/TMath::Cos(philoc)*TMath::Cos(phi/kRaddeg);
1106 */
1107
1108 // Pad reference frame -> FSTR reference frame
0ef21f59 1109 Float_t posLocal[3] = {0., 0., 0.};
2942f542 1110 Float_t step[3] = {static_cast<Float_t>(-(ipadx+0.5)*fgkXPad), 0., static_cast<Float_t>(-(ipadz+0.5)*fgkZPad)};
0ef21f59 1111 Translation(posLocal,step);
1112
1113 step[0] = kNpadX*0.5*fgkXPad;
1114 step[1] = 0.;
1115 step[2] = kNpadZ*0.5*fgkZPad;
0ef21f59 1116 /*
1117 Float_t posLocal[3] = {(ipadx+0.5)*fgkXPad, 0., (ipadz+0.5)*fgkZPad};
1118 Float_t step[3]= {kNpadX*0.5*fgkXPad, 0., kNpadZ*0.5*fgkZPad};
1119 */
1120 Translation(posLocal,step);
1121
1122 // FSTR reference frame -> FTOA/B/C = FLTA/B/C reference frame
1d834a1e 1123 Double_t angles[6] = {0.,0.,0.,0.,0.,0.};
0ef21f59 1124 if (GetAngles(iplate,istrip) >0.) {
1125 angles[0] = 90.;
1126 angles[1] = 0.;
1127 angles[2] = 90.+GetAngles(iplate,istrip);
1128 angles[3] = 90.;
1129 angles[4] = GetAngles(iplate,istrip);
1130 angles[5] = 90.;
1131 }
1132 else if (GetAngles(iplate,istrip)==0.) {
1133 angles[0] = 90.;
1134 angles[1] = 0.;
1135 angles[2] = 90.;
1136 angles[3] = 90.;
1137 angles[4] = 0;
1138 angles[5] = 0.;
1139 }
1140 else if (GetAngles(iplate,istrip) <0.) {
1141 angles[0] = 90.;
1142 angles[1] = 0.;
1143 angles[2] = 90.+GetAngles(iplate,istrip);
1144 angles[3] = 90.;
1145 angles[4] =-GetAngles(iplate,istrip);
1146 angles[5] = 270.;
1147 }
1148
1149 InverseRotation(posLocal,angles);
1150
1151 step[0] = 0.;
1152 step[1] = -GetHeights(iplate,istrip);
1153 step[2] = GetDistances(iplate,istrip);
1154 Translation(posLocal,step);
1155
1156 // FTOA = FLTA reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
1157 angles[0] = 90.;
1158 angles[1] = 0.;
1159 angles[2] = 0.;
1160 angles[3] = 0.;
1161 angles[4] = 90.;
1162 angles[5] =270.;
1163
1164 InverseRotation(posLocal,angles);
1165
1166 // B071/B074/B075 = BTO1/2/3 reference frame -> ALICE reference frame
1167 step[0] = 0.;
1168 step[1] = 0.;
1169 step[2] = -((fgkRmax+fgkRmin)*0.5);
1170 Translation(posLocal,step);
1171
1172 angles[0] = 90.;
1173 angles[1] = 90.+(isector+0.5)*fgkPhiSec;
1174 angles[2] = 0.;
1175 angles[3] = 0.;
1176 angles[4] = 90.;
1177 angles[5] = (isector+0.5)*fgkPhiSec;
1178
1179 InverseRotation(posLocal,angles);
1180
1181 Float_t xCoor = posLocal[0];
1182
1183 return xCoor;
1184
1185}
1186//_____________________________________________________________________________
a5043fb0 1187Float_t AliTOFGeometry::GetY(const Int_t * det)
0ef21f59 1188{
1189 //
1190 // Returns Y coordinate (cm)
1191 //
1192
1193 Int_t isector = det[0];
1194 Int_t iplate = det[1];
1195 Int_t istrip = det[2];
1196 Int_t ipadz = det[3];
1197 Int_t ipadx = det[4];
1198
1199 /*
1200 // Find out distance d on the plane wrt median phi:
1201 Float_t d = (ipadx+0.5-kNpadX*0.5)*fgkXPad;
1202
1203 // The radius r in xy plane:
1204 //Float_t r = (fgkRmin+fgkRmax)*0.5-0.01+GetHeights(iplate,istrip)+
1205 // (ipadz-0.5)*fgkZPad*TMath::Sin(GetAngles(iplate,istrip)/kRaddeg)-0.25; ???
1206 Float_t r = (fgkRmin+fgkRmax)*0.5-0.01+GetHeights(iplate,istrip)+
1207 (ipadz-0.5)*fgkZPad*TMath::Sin(GetAngles(iplate,istrip)/kRaddeg);
1208
1209 // local azimuthal angle in the sector philoc
1210 Float_t philoc = TMath::ATan(d/r);
1211 //if(philoc<0.) philoc = k2PI + philoc;
1212
1213 // azimuthal angle in the global frame phi
1214 Float_t phi = philoc*kRaddeg+(isector+0.5)*fgkPhiSec;
1215
1216 Float_t yCoor = r/TMath::Cos(philoc)*TMath::Sin(phi/kRaddeg);
1217 */
1218
1219 // Pad reference frame -> FSTR reference frame
0ef21f59 1220 Float_t posLocal[3] = {0., 0., 0.};
2942f542 1221 Float_t step[3] = {static_cast<Float_t>(-(ipadx+0.5)*fgkXPad), 0., static_cast<Float_t>(-(ipadz+0.5)*fgkZPad)};
0ef21f59 1222 Translation(posLocal,step);
1223
1224 step[0] = kNpadX*0.5*fgkXPad;
1225 step[1] = 0.;
1226 step[2] = kNpadZ*0.5*fgkZPad;
0ef21f59 1227 /*
1228 Float_t posLocal[3] = {(ipadx+0.5)*fgkXPad, 0., (ipadz+0.5)*fgkZPad};
1229 Float_t step[3]= {kNpadX*0.5*fgkXPad, 0., kNpadZ*0.5*fgkZPad};
1230 */
1231 Translation(posLocal,step);
1232
1233 // FSTR reference frame -> FTOA/B/C = FLTA/B/C reference frame
1234
1d834a1e 1235 Double_t angles[6] = {0.,0.,0.,0.,0.,0.};
0ef21f59 1236 if (GetAngles(iplate,istrip) >0.) {
1237 angles[0] = 90.;
1238 angles[1] = 0.;
1239 angles[2] = 90.+GetAngles(iplate,istrip);
1240 angles[3] = 90.;
1241 angles[4] = GetAngles(iplate,istrip);
1242 angles[5] = 90.;
1243 }
1244 else if (GetAngles(iplate,istrip)==0.) {
1245 angles[0] = 90.;
1246 angles[1] = 0.;
1247 angles[2] = 90.;
1248 angles[3] = 90.;
1249 angles[4] = 0;
1250 angles[5] = 0.;
1251 }
1252 else if (GetAngles(iplate,istrip) <0.) {
1253 angles[0] = 90.;
1254 angles[1] = 0.;
1255 angles[2] = 90.+GetAngles(iplate,istrip);
1256 angles[3] = 90.;
1257 angles[4] =-GetAngles(iplate,istrip);
1258 angles[5] = 270.;
1259 }
1260
1261 InverseRotation(posLocal,angles);
1262
1263 step[0] = 0.;
1264 step[1] = -GetHeights(iplate,istrip);
1265 step[2] = GetDistances(iplate,istrip);
1266 Translation(posLocal,step);
1267
1268 // FTOA = FLTA reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
1269 angles[0] = 90.;
1270 angles[1] = 0.;
1271 angles[2] = 0.;
1272 angles[3] = 0.;
1273 angles[4] = 90.;
1274 angles[5] =270.;
1275
1276 InverseRotation(posLocal,angles);
1277
1278 // B071/B074/B075 = BTO1/2/3 reference frame -> ALICE reference frame
1279 step[0] = 0.;
1280 step[1] = 0.;
1281 step[2] = -((fgkRmax+fgkRmin)*0.5);
1282 Translation(posLocal,step);
1283
1284 angles[0] = 90.;
1285 angles[1] = 90.+(isector+0.5)*fgkPhiSec;
1286 angles[2] = 0.;
1287 angles[3] = 0.;
1288 angles[4] = 90.;
1289 angles[5] = (isector+0.5)*fgkPhiSec;
1290
1291 InverseRotation(posLocal,angles);
1292
1293 Float_t yCoor = posLocal[1];
1294
1295 return yCoor;
1296
1297}
1298
1299//_____________________________________________________________________________
a5043fb0 1300Float_t AliTOFGeometry::GetZ(const Int_t * det)
0ef21f59 1301{
1302 //
1303 // Returns Z coordinate (cm)
1304 //
1305
1306 Int_t isector = det[0];
1307 Int_t iplate = det[1];
1308 Int_t istrip = det[2];
1309 Int_t ipadz = det[3];
1310 Int_t ipadx = det[4];
1311
1312 /*
1313 Float_t zCoor = GetDistances(iplate,istrip) +
1314 (0.5-ipadz) * fgkZPad * TMath::Cos(GetAngles(iplate,istrip)*kDegrad);
1315 */
1316
1317 // Pad reference frame -> FSTR reference frame
0ef21f59 1318 Float_t posLocal[3] = {0., 0., 0.};
2942f542 1319 Float_t step[3] = {static_cast<Float_t>(-(ipadx+0.5)*fgkXPad), 0., static_cast<Float_t>(-(ipadz+0.5)*fgkZPad)};
0ef21f59 1320 Translation(posLocal,step);
1321
1322 step[0] = kNpadX*0.5*fgkXPad;
1323 step[1] = 0.;
1324 step[2] = kNpadZ*0.5*fgkZPad;
0ef21f59 1325 /*
1326 Float_t posLocal[3] = {(ipadx+0.5)*fgkXPad, 0., (ipadz+0.5)*fgkZPad};
1327 Float_t step[3]= {kNpadX*0.5*fgkXPad, 0., kNpadZ*0.5*fgkZPad};
1328 */
1329 Translation(posLocal,step);
1330
1331 // FSTR reference frame -> FTOA/B/C = FLTA/B/C reference frame
1d834a1e 1332 Double_t angles[6] = {0.,0.,0.,0.,0.,0.};
0ef21f59 1333 if (GetAngles(iplate,istrip) >0.) {
1334 angles[0] = 90.;
1335 angles[1] = 0.;
1336 angles[2] = 90.+GetAngles(iplate,istrip);
1337 angles[3] = 90.;
1338 angles[4] = GetAngles(iplate,istrip);
1339 angles[5] = 90.;
1340 }
1341 else if (GetAngles(iplate,istrip)==0.) {
1342 angles[0] = 90.;
1343 angles[1] = 0.;
1344 angles[2] = 90.;
1345 angles[3] = 90.;
1346 angles[4] = 0;
1347 angles[5] = 0.;
1348 }
1349 else if (GetAngles(iplate,istrip) <0.) {
1350 angles[0] = 90.;
1351 angles[1] = 0.;
1352 angles[2] = 90.+GetAngles(iplate,istrip);
1353 angles[3] = 90.;
1354 angles[4] =-GetAngles(iplate,istrip);
1355 angles[5] = 270.;
1356 }
1357
1358 InverseRotation(posLocal,angles);
1359
1360 step[0] = 0.;
1361 step[1] = -GetHeights(iplate,istrip);
1362 step[2] = GetDistances(iplate,istrip);
1363 Translation(posLocal,step);
1364
1365 // FTOA = FLTA reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
1366 angles[0] = 90.;
1367 angles[1] = 0.;
1368 angles[2] = 0.;
1369 angles[3] = 0.;
1370 angles[4] = 90.;
1371 angles[5] =270.;
1372
1373 InverseRotation(posLocal,angles);
1374
1375 // B071/B074/B075 = BTO1/2/3 reference frame -> ALICE reference frame
1376 step[0] = 0.;
1377 step[1] = 0.;
1378 step[2] = -((fgkRmax+fgkRmin)*0.5);
1379 Translation(posLocal,step);
1380
1381 angles[0] = 90.;
1382 angles[1] = 90.+(isector+0.5)*fgkPhiSec;
1383 angles[2] = 0.;
1384 angles[3] = 0.;
1385 angles[4] = 90.;
1386 angles[5] = (isector+0.5)*fgkPhiSec;
1387
1388 InverseRotation(posLocal,angles);
1389
1390 Float_t zCoor = posLocal[2];
1391
1392 return zCoor;
1393
1394}
1395//_____________________________________________________________________________
1396
125dbd7c 1397void AliTOFGeometry::DetToSectorRF(Int_t vol[5], Double_t coord[4][3])
0ef21f59 1398{
1399 //
1400 // Returns the local coordinates (x, y, z) in sector reference frame
1401 // for the 4 corners of each sector pad (vol[1], vol[2], vol[3], vol[4])
1402 //
1403
1404 if (!gGeoManager) printf("ERROR: no TGeo\n");
1405
1406 // ALICE -> TOF Sector
de40f9c1 1407 Char_t path1[200];
0ef21f59 1408 GetVolumePath(vol[0],path1);
1409 gGeoManager->cd(path1);
1410 TGeoHMatrix aliceToSector;
1411 aliceToSector = *gGeoManager->GetCurrentMatrix();
1412
1413 // TOF Sector -> ALICE
1414 //TGeoHMatrix sectorToALICE = aliceToSector.Inverse();
1415
1416 // ALICE -> TOF Pad
de40f9c1 1417 Char_t path2[200];
0ef21f59 1418 GetVolumePath(vol,path2);
1419 gGeoManager->cd(path2);
1420 TGeoHMatrix aliceToPad;
1421 aliceToPad = *gGeoManager->GetCurrentMatrix();
1422
1423 // TOF Pad -> ALICE
1424 TGeoHMatrix padToALICE = aliceToPad.Inverse();
1425
1426 // TOF Pad -> TOF Sector
1427 TGeoHMatrix padToSector = padToALICE*aliceToSector;
1428
1429 // TOF Sector -> TOF Pad
1430 //TGeoHMatrix sectorToPad = sectorToALICE*aliceToPad;
1431
1432 // coordinates of the pad bottom corner
1433 Double_t **cornerPad = new Double_t*[4];
1434 for (Int_t ii=0; ii<4; ii++) cornerPad[ii] = new Double_t[3];
1435
1436 cornerPad[0][0] = -fgkXPad/2.;
1437 cornerPad[0][1] = 0.;
1438 cornerPad[0][2] = -fgkZPad/2.;
1439
1440 cornerPad[1][0] = fgkXPad/2.;
1441 cornerPad[1][1] = 0.;
1442 cornerPad[1][2] = -fgkZPad/2.;
1443
1444 cornerPad[2][0] = fgkXPad/2.;
1445 cornerPad[2][1] = 0.;
1446 cornerPad[2][2] = fgkZPad/2.;
1447
1448 cornerPad[3][0] = -fgkXPad/2.;
1449 cornerPad[3][1] = 0.;
1450 cornerPad[3][2] = fgkZPad/2.;
1451
1452 for(Int_t aa=0; aa<4; aa++) for(Int_t bb=0; bb<3; bb++) coord[aa][bb]=0.;
1453
1454 for (Int_t jj=0; jj<4; jj++) padToSector.MasterToLocal(&cornerPad[jj][0], &coord[jj][0]);
1455
4ce766eb 1456 delete [] cornerPad;
0ef21f59 1457
1458 //sectorToPad.LocalToMaster(cornerPad, coord);
1459
1460}
1461//_____________________________________________________________________________
a5043fb0 1462Float_t AliTOFGeometry::GetPadDx(const Float_t * pos)
0ef21f59 1463{
1464 //
1465 // Returns the x coordinate in the Pad reference frame
1466 //
1467
1468 Float_t xpad = -2.;
1469
1470 Float_t posLocal[3];
1471 for (Int_t ii=0; ii<3; ii++) posLocal[ii] = pos[ii];
1472
1473 Int_t isector = GetSector(posLocal);
1474 if(isector == -1){
1475 //AliError("Detector Index could not be determined");
1476 return xpad;}
1477 Int_t iplate = GetPlate(posLocal);
1478 if(iplate == -1){
1479 //AliError("Detector Index could not be determined");
1480 return xpad;}
1481 Int_t istrip = GetStrip(posLocal);
1482 if(istrip == -1){
1483 //AliError("Detector Index could not be determined");
1484 return xpad;}
1485 Int_t ipadz = GetPadZ(posLocal);
1486 if(ipadz == -1){
1487 //AliError("Detector Index could not be determined");
1488 return xpad;}
1489 Int_t ipadx = GetPadX(posLocal);
1490 if(ipadx == -1){
1491 //AliError("Detector Index could not be determined");
1492 return xpad;}
1493
1494 // ALICE reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
1495 Double_t angles[6] =
1496 {90., 90.+(isector+0.5)*fgkPhiSec,
1497 0., 0.,
1498 90., (isector+0.5)*fgkPhiSec
1499 };
1500 Rotation(posLocal,angles);
1501
2942f542 1502 Float_t step[3] = {0., 0., static_cast<Float_t>((fgkRmax+fgkRmin)*0.5)};
0ef21f59 1503 Translation(posLocal,step);
1504
1505 // B071/B074/B075 = BTO1/2/3 reference frame -> FTOA/B/C = FLTA/B/C reference frame
1506 angles[0] = 90.;
1507 angles[1] = 0.;
1508 angles[2] = 0.;
1509 angles[3] = 0.;
1510 angles[4] = 90.;
1511 angles[5] =270.;
1512
1513 Rotation(posLocal,angles);
1514
1515 // FTOA/B/C = FLTA/B/C reference frame -> FSTR reference frame
1516 step[0] = 0.;
1517 step[1] = GetHeights(iplate,istrip);
1518 step[2] = -GetDistances(iplate,istrip);
1519 Translation(posLocal,step);
1520
1521 if (GetAngles(iplate,istrip) >0.) {
1522 angles[0] = 90.;
1523 angles[1] = 0.;
1524 angles[2] = 90.+GetAngles(iplate,istrip);
1525 angles[3] = 90.;
1526 angles[4] = GetAngles(iplate,istrip);
1527 angles[5] = 90.;
1528 }
1529 else if (GetAngles(iplate,istrip)==0.) {
1530 angles[0] = 90.;
1531 angles[1] = 0.;
1532 angles[2] = 90.;
1533 angles[3] = 90.;
1534 angles[4] = 0;
1535 angles[5] = 0.;
1536 }
1537 else if (GetAngles(iplate,istrip) <0.) {
1538 angles[0] = 90.;
1539 angles[1] = 0.;
1540 angles[2] = 90.+GetAngles(iplate,istrip);
1541 angles[3] = 90.;
1542 angles[4] =-GetAngles(iplate,istrip);
1543 angles[5] = 270.;
1544 }
1545 Rotation(posLocal,angles);
1546
1547 step[0] =-0.5*kNpadX*fgkXPad;
1548 step[1] = 0.;
1549 step[2] =-0.5*kNpadZ*fgkZPad;
1550 Translation(posLocal,step);
1551
1552 step[0] = (ipadx+0.5)*fgkXPad;
1553 step[1] = 0.;
1554 step[2] = (ipadz+0.5)*fgkZPad;
1555 Translation(posLocal,step);
1556
1557 xpad=posLocal[0];
1558
1559 return xpad;
1560
1561}
1562//_____________________________________________________________________________
a5043fb0 1563Float_t AliTOFGeometry::GetPadDy(const Float_t * pos)
0ef21f59 1564{
1565 //
1566 // Returns the y coordinate in the Pad reference frame
1567 //
1568
1569 Float_t ypad = -2.;
1570
1571 Float_t posLocal[3];
1572 for (Int_t ii=0; ii<3; ii++) posLocal[ii] = pos[ii];
1573
1574 Int_t isector = GetSector(posLocal);
1575 if(isector == -1){
1576 //AliError("Detector Index could not be determined");
1577 return ypad;}
1578 Int_t iplate = GetPlate(posLocal);
1579 if(iplate == -1){
1580 //AliError("Detector Index could not be determined");
1581 return ypad;}
1582 Int_t istrip = GetStrip(posLocal);
1583 if(istrip == -1){
1584 //AliError("Detector Index could not be determined");
1585 return ypad;}
1586 Int_t ipadz = GetPadZ(posLocal);
1587 if(ipadz == -1){
1588 //AliError("Detector Index could not be determined");
1589 return ypad;}
1590 Int_t ipadx = GetPadX(posLocal);
1591 if(ipadx == -1){
1592 //AliError("Detector Index could not be determined");
1593 return ypad;}
1594
1595 // ALICE reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
1596 Double_t angles[6] =
1597 {90., 90.+(isector+0.5)*fgkPhiSec,
1598 0., 0.,
1599 90., (isector+0.5)*fgkPhiSec
1600 };
1601 Rotation(posLocal,angles);
1602
2942f542 1603 Float_t step[3] = {0., 0., static_cast<Float_t>((fgkRmax+fgkRmin)*0.5)};
0ef21f59 1604 Translation(posLocal,step);
1605
1606 // B071/B074/B075 = BTO1/2/3 reference frame -> FTOA/B/C = FLTA/B/C reference frame
1607 angles[0] = 90.;
1608 angles[1] = 0.;
1609 angles[2] = 0.;
1610 angles[3] = 0.;
1611 angles[4] = 90.;
1612 angles[5] =270.;
1613
1614 Rotation(posLocal,angles);
1615
1616 // FTOA/B/C = FLTA/B/C reference frame -> FSTR reference frame
1617 step[0] = 0.;
1618 step[1] = GetHeights(iplate,istrip);
1619 step[2] = -GetDistances(iplate,istrip);
1620 Translation(posLocal,step);
1621
1622 if (GetAngles(iplate,istrip) >0.) {
1623 angles[0] = 90.;
1624 angles[1] = 0.;
1625 angles[2] = 90.+GetAngles(iplate,istrip);
1626 angles[3] = 90.;
1627 angles[4] = GetAngles(iplate,istrip);
1628 angles[5] = 90.;
1629 }
1630 else if (GetAngles(iplate,istrip)==0.) {
1631 angles[0] = 90.;
1632 angles[1] = 0.;
1633 angles[2] = 90.;
1634 angles[3] = 90.;
1635 angles[4] = 0;
1636 angles[5] = 0.;
1637 }
1638 else if (GetAngles(iplate,istrip) <0.) {
1639 angles[0] = 90.;
1640 angles[1] = 0.;
1641 angles[2] = 90.+GetAngles(iplate,istrip);
1642 angles[3] = 90.;
1643 angles[4] =-GetAngles(iplate,istrip);
1644 angles[5] = 270.;
1645 }
1646 Rotation(posLocal,angles);
1647
1648 step[0] =-0.5*kNpadX*fgkXPad;
1649 step[1] = 0.;
1650 step[2] =-0.5*kNpadZ*fgkZPad;
1651 Translation(posLocal,step);
1652
1653 step[0] = (ipadx+0.5)*fgkXPad;
1654 step[1] = 0.;
1655 step[2] = (ipadz+0.5)*fgkZPad;
1656 Translation(posLocal,step);
1657
1658 ypad=posLocal[1];
1659
1660 return ypad;
1661
1662}
1663//_____________________________________________________________________________
a5043fb0 1664Float_t AliTOFGeometry::GetPadDz(const Float_t * pos)
0ef21f59 1665{
1666 //
1667 // Returns the z coordinate in the Pad reference frame
1668 //
1669
1670 Float_t zpad = -2.;
1671
1672 Float_t posLocal[3];
1673 for (Int_t ii=0; ii<3; ii++) posLocal[ii] = pos[ii];
1674
1675 Int_t isector = GetSector(posLocal);
1676 if(isector == -1){
1677 //AliError("Detector Index could not be determined");
1678 return zpad;}
1679 Int_t iplate = GetPlate(posLocal);
1680 if(iplate == -1){
1681 //AliError("Detector Index could not be determined");
1682 return zpad;}
1683 Int_t istrip = GetStrip(posLocal);
1684 if(istrip == -1){
1685 //AliError("Detector Index could not be determined");
1686 return zpad;}
1687 Int_t ipadz = GetPadZ(posLocal);
1688 if(ipadz == -1){
1689 //AliError("Detector Index could not be determined");
1690 return zpad;}
1691 Int_t ipadx = GetPadX(posLocal);
1692 if(ipadx == -1){
1693 //AliError("Detector Index could not be determined");
1694 return zpad;}
1695
1696 // ALICE reference frame -> B071/B074/B075 = BTO1/2/3 reference frame
1697 Double_t angles[6] =
1698 {90., 90.+(isector+0.5)*fgkPhiSec,
1699 0., 0.,
1700 90., (isector+0.5)*fgkPhiSec
1701 };
1702 Rotation(posLocal,angles);
1703
2942f542 1704 Float_t step[3] = {0., 0., static_cast<Float_t>((fgkRmax+fgkRmin)*0.5)};
0ef21f59 1705 Translation(posLocal,step);
1706
1707 // B071/B074/B075 = BTO1/2/3 reference frame -> FTOA/B/C = FLTA/B/C reference frame
1708 angles[0] = 90.;
1709 angles[1] = 0.;
1710 angles[2] = 0.;
1711 angles[3] = 0.;
1712 angles[4] = 90.;
1713 angles[5] =270.;
1714
1715 Rotation(posLocal,angles);
1716
1717 // FTOA/B/C = FLTA/B/C reference frame -> FSTR reference frame
1718 step[0] = 0.;
1719 step[1] = GetHeights(iplate,istrip);
1720 step[2] = -GetDistances(iplate,istrip);
1721 Translation(posLocal,step);
1722
1723 if (GetAngles(iplate,istrip) >0.) {
1724 angles[0] = 90.;
1725 angles[1] = 0.;
1726 angles[2] = 90.+GetAngles(iplate,istrip);
1727 angles[3] = 90.;
1728 angles[4] = GetAngles(iplate,istrip);
1729 angles[5] = 90.;
1730 }
1731 else if (GetAngles(iplate,istrip)==0.) {
1732 angles[0] = 90.;
1733 angles[1] = 0.;
1734 angles[2] = 90.;
1735 angles[3] = 90.;
1736 angles[4] = 0;
1737 angles[5] = 0.;
1738 }
1739 else if (GetAngles(iplate,istrip) <0.) {
1740 angles[0] = 90.;
1741 angles[1] = 0.;
1742 angles[2] = 90.+GetAngles(iplate,istrip);
1743 angles[3] = 90.;
1744 angles[4] =-GetAngles(iplate,istrip);
1745 angles[5] = 270.;
1746 }
1747 Rotation(posLocal,angles);
1748
1749 step[0] =-0.5*kNpadX*fgkXPad;
1750 step[1] = 0.;
1751 step[2] =-0.5*kNpadZ*fgkZPad;
1752 Translation(posLocal,step);
1753
1754 step[0] = (ipadx+0.5)*fgkXPad;
1755 step[1] = 0.;
1756 step[2] = (ipadz+0.5)*fgkZPad;
1757 Translation(posLocal,step);
1758
1759 zpad=posLocal[2];
1760
1761 return zpad;
1762
1763}
1764//_____________________________________________________________________________
1765
6786addd 1766void AliTOFGeometry::Translation(Float_t *xyz, Float_t translationVector[3])
0ef21f59 1767{
1768 //
1769 // Return the vector xyz translated by translationVector vector
1770 //
1771
1772 Int_t ii=0;
1773
1774 for (ii=0; ii<3; ii++)
1775 xyz[ii] -= translationVector[ii];
1776
1777 return;
1778
1779}
1780//_____________________________________________________________________________
1781
6786addd 1782void AliTOFGeometry::Rotation(Float_t *xyz, Double_t rotationAngles[6])
0ef21f59 1783{
1784 //
1785 // Return the vector xyz rotated according to the rotationAngles angles
1786 //
1787
1788 Int_t ii=0;
1789 /*
1790 TRotMatrix *matrix = new TRotMatrix("matrix","matrix", angles[0], angles[1],
1791 angles[2], angles[3],
1792 angles[4], angles[5]);
1793 */
1794
1795 for (ii=0; ii<6; ii++) rotationAngles[ii]*=kDegrad;
1796
1797 Float_t xyzDummy[3] = {0., 0., 0.};
1798
1799 for (ii=0; ii<3; ii++) {
1800 xyzDummy[ii] =
1801 xyz[0]*TMath::Sin(rotationAngles[2*ii])*TMath::Cos(rotationAngles[2*ii+1]) +
1802 xyz[1]*TMath::Sin(rotationAngles[2*ii])*TMath::Sin(rotationAngles[2*ii+1]) +
1803 xyz[2]*TMath::Cos(rotationAngles[2*ii]);
1804 }
1805
1806 for (ii=0; ii<3; ii++) xyz[ii]=xyzDummy[ii];
1807
1808 return;
1809
1810}
1811//_____________________________________________________________________________
6786addd 1812void AliTOFGeometry::InverseRotation(Float_t *xyz, Double_t rotationAngles[6])
0ef21f59 1813{
1814 //
baf89633 1815 // Rotates the vector xyz acordint to the rotationAngles
0ef21f59 1816 //
1817
1818 Int_t ii=0;
1819
1820 for (ii=0; ii<6; ii++) rotationAngles[ii]*=kDegrad;
1821
1822 Float_t xyzDummy[3] = {0., 0., 0.};
1823
1824 xyzDummy[0] =
1825 xyz[0]*TMath::Sin(rotationAngles[0])*TMath::Cos(rotationAngles[1]) +
1826 xyz[1]*TMath::Sin(rotationAngles[2])*TMath::Cos(rotationAngles[3]) +
1827 xyz[2]*TMath::Sin(rotationAngles[4])*TMath::Cos(rotationAngles[5]);
1828
1829 xyzDummy[1] =
1830 xyz[0]*TMath::Sin(rotationAngles[0])*TMath::Sin(rotationAngles[1]) +
1831 xyz[1]*TMath::Sin(rotationAngles[2])*TMath::Sin(rotationAngles[3]) +
1832 xyz[2]*TMath::Sin(rotationAngles[4])*TMath::Sin(rotationAngles[5]);
1833
1834 xyzDummy[2] =
1835 xyz[0]*TMath::Cos(rotationAngles[0]) +
1836 xyz[1]*TMath::Cos(rotationAngles[2]) +
1837 xyz[2]*TMath::Cos(rotationAngles[4]);
1838
1839 for (ii=0; ii<3; ii++) xyz[ii]=xyzDummy[ii];
1840
1841 return;
1842
1843}
1844//_____________________________________________________________________________
1845
a5043fb0 1846Int_t AliTOFGeometry::GetIndex(const Int_t * detId)
0ef21f59 1847{
1848 //Retrieve calibration channel index
1849 Int_t isector = detId[0];
1850 if (isector >= kNSectors){
5ab3605a 1851 printf("Wrong sector number in TOF (%d) !\n",isector);
0ef21f59 1852 return -1;
1853 }
1854 Int_t iplate = detId[1];
1855 if (iplate >= kNPlates){
5ab3605a 1856 printf("Wrong plate number in TOF (%d) !\n",iplate);
0ef21f59 1857 return -1;
1858 }
1859 Int_t istrip = detId[2];
ff826920 1860 Int_t stripOffset = GetStripNumberPerSM(iplate,istrip);
1861 if (stripOffset==-1) {
1862 printf("Wrong strip number per SM in TOF (%d) !\n",stripOffset);
1863 return -1;
1864 }
1865
0ef21f59 1866 Int_t ipadz = detId[3];
1867 Int_t ipadx = detId[4];
0ef21f59 1868
ff826920 1869 Int_t idet = ((2*(kNStripC+kNStripB)+kNStripA)*kNpadZ*kNpadX)*isector +
0ef21f59 1870 (stripOffset*kNpadZ*kNpadX)+
0ef21f59 1871 (kNpadX)*ipadz+
1872 ipadx;
1873 return idet;
1874}
731afc39 1875//_____________________________________________________________________________
1876
1877void AliTOFGeometry::GetVolumeIndices(Int_t index, Int_t *detId)
1878{
1879 //
1880 // Retrieve volume indices from the calibration channel index
1881 //
1882
1883 detId[0] = index/NpadXStrip()/NStripXSector();
1884
1885 Int_t dummyStripPerModule =
1886 ( index - ( NStripXSector()*NpadXStrip()*detId[0]) ) / NpadXStrip();
1887 if (dummyStripPerModule<kNStripC) {
1888 detId[1] = 0;
1889 detId[2] = dummyStripPerModule;
1890 }
1891 else if (dummyStripPerModule>=kNStripC && dummyStripPerModule<kNStripC+kNStripB) {
1892 detId[1] = 1;
1893 detId[2] = dummyStripPerModule-kNStripC;
1894 }
1895 else if (dummyStripPerModule>=kNStripC+kNStripB && dummyStripPerModule<kNStripC+kNStripB+kNStripA) {
1896 detId[1] = 2;
1897 detId[2] = dummyStripPerModule-kNStripC-kNStripB;
1898 }
1899 else if (dummyStripPerModule>=kNStripC+kNStripB+kNStripA && dummyStripPerModule<kNStripC+kNStripB+kNStripA+kNStripB) {
1900 detId[1] = 3;
1901 detId[2] = dummyStripPerModule-kNStripC-kNStripB-kNStripA;
1902 }
1903 else if (dummyStripPerModule>=kNStripC+kNStripB+kNStripA+kNStripB && dummyStripPerModule<NStripXSector()) {
1904 detId[1] = 4;
1905 detId[2] = dummyStripPerModule-kNStripC-kNStripB-kNStripA-kNStripB;
1906 }
1907
1908 Int_t padPerStrip = ( index - ( NStripXSector()*NpadXStrip()*detId[0]) ) - dummyStripPerModule*NpadXStrip();
1909
ff826920 1910 detId[3] = padPerStrip / kNpadX; // padZ
1911 detId[4] = padPerStrip - detId[3]*kNpadX; // padX
731afc39 1912
1913}
1914//_____________________________________________________________________________
0ef21f59 1915
731afc39 1916Int_t AliTOFGeometry::NStrip(Int_t nPlate)
1917{
1918 //
1919 // Returns the strips number for the plate number 'nPlate'
1920 //
0ef21f59 1921
731afc39 1922 Int_t nStrips = kNStripC;
0ef21f59 1923
731afc39 1924 switch(nPlate) {
1925 case 2:
1926 nStrips = kNStripA;
1927 break;
1928 case 1:
1929 case 3:
1930 nStrips = kNStripB;
1931 break;
1932 case 0:
1933 case 4:
1934 default:
1935 nStrips = kNStripC;
1936 break;
1937 }
1938
1939 return nStrips;
1940
1941}
ff826920 1942//-------------------------------------------------------------------------
1943
6786addd 1944UShort_t AliTOFGeometry::GetAliSensVolIndex(Int_t isector, Int_t iplate, Int_t istrip)
ff826920 1945{
1946 //
1947 // Get the index of the TOF alignable volume in the AliGeomManager order.
1948 //
1949
1950 Int_t index = GetStripNumber(isector, iplate, istrip);
1951
1952 UShort_t volIndex = AliGeomManager::LayerToVolUID(AliGeomManager::kTOF,index);
1953
1954 return volIndex;
1955
1956}
1957//-------------------------------------------------------------------------
1958
1959Int_t AliTOFGeometry::GetStripNumber(Int_t isector, Int_t iplate, Int_t istrip)
1960{
1961 //
1962 // Get the serial number of the TOF strip number istrip [0,14/18],
1963 // in the module number iplate [0,4],
1964 // in the TOF SM number isector [0,17].
1965 // This number will range in [0,1637].
1966 //
1967
1968 Bool_t check = (isector >= kNSectors);
1969
1970 if (check)
1971 printf("E-AliTOFGeometry::GetStripNumber: Wrong sector number in TOF (%d)!\n",isector);
1972
1973 Int_t index = -1;
1974 Int_t stripInSM = GetStripNumberPerSM(iplate, istrip);
1975 if (!check && stripInSM!=-1)
1976 index = (2*(kNStripC+kNStripB)+kNStripA)*isector + stripInSM;
1977
1978 return index;
1979
1980}
1981//-------------------------------------------------------------------------
1982
ea932f75 1983void AliTOFGeometry::GetStripAndModule(Int_t iStripPerSM, Int_t &iplate, Int_t &istrip)
1984{
1985 //
1986 // Convert the serial number of the TOF strip number iStripPerSM [0,90]
1987 // in module number iplate [0,4] and strip number istrip [0,14/18].
1988 //
1989
1990 if (iStripPerSM<0 || iStripPerSM>=kNStripC+kNStripB+kNStripA+kNStripB+kNStripC) {
1991 iplate = -1;
1992 istrip = -1;
1993 }
1994 else if (iStripPerSM<kNStripC) {
1995 iplate = 0;
1996 istrip = iStripPerSM;
1997 }
1998 else if (iStripPerSM>=kNStripC && iStripPerSM<kNStripC+kNStripB) {
1999 iplate = 1;
2000 istrip = iStripPerSM-kNStripC;
2001 }
2002 else if (iStripPerSM>=kNStripC+kNStripB && iStripPerSM<kNStripC+kNStripB+kNStripA) {
2003 iplate = 2;
2004 istrip = iStripPerSM-kNStripC-kNStripB;
2005 }
2006 else if (iStripPerSM>=kNStripC+kNStripB+kNStripA && iStripPerSM<kNStripC+kNStripB+kNStripA+kNStripB) {
2007 iplate = 3;
2008 istrip = iStripPerSM-kNStripC-kNStripB-kNStripA;
2009 }
2010 else if (iStripPerSM>=kNStripC+kNStripB+kNStripA+kNStripB && iStripPerSM<kNStripC+kNStripB+kNStripA+kNStripB+kNStripC) {
2011 iplate = 4;
2012 istrip = iStripPerSM-kNStripC-kNStripB-kNStripA-kNStripB;
2013 }
2014
2015
2016}
2017//-------------------------------------------------------------------------
2018
ff826920 2019Int_t AliTOFGeometry::GetStripNumberPerSM(Int_t iplate, Int_t istrip)
2020{
2021 //
2022 // Get the serial number of the TOF strip number istrip [0,14/18],
2023 // in the module number iplate [0,4].
2024 // This number will range in [0,90].
2025 //
2026
2027 Int_t index = -1;
2028
2029 Bool_t check = (
2030 (iplate<0 || iplate>=kNPlates)
2031 ||
2032 (
2033 (iplate==2 && (istrip<0 || istrip>=kNStripA))
2034 ||
2035 (iplate!=2 && (istrip<0 || istrip>=kNStripC))
2036 )
2037 );
2038
2039 if (iplate<0 || iplate>=kNPlates)
2040 printf("E-AliTOFGeometry::GetStripNumberPerSM: Wrong plate number in TOF (%1d)!\n",iplate);
2041
2042 if (
2043 (iplate==2 && (istrip<0 || istrip>=kNStripA))
2044 ||
2045 (iplate!=2 && (istrip<0 || istrip>=kNStripC))
2046 )
6819758a 2047 printf("E-AliTOFGeometry::GetStripNumberPerSM: Wrong strip number in TOF "
2048 "(strip=%2d in the plate=%1d)!\n",istrip,iplate);
ff826920 2049
2050 Int_t stripOffset = 0;
2051 switch (iplate) {
2052 case 0:
2053 stripOffset = 0;
2054 break;
2055 case 1:
2056 stripOffset = kNStripC;
2057 break;
2058 case 2:
2059 stripOffset = kNStripC+kNStripB;
2060 break;
2061 case 3:
2062 stripOffset = kNStripC+kNStripB+kNStripA;
2063 break;
2064 case 4:
2065 stripOffset = kNStripC+kNStripB+kNStripA+kNStripB;
2066 break;
2067 };
2068
2069 if (!check) index = stripOffset + istrip;
2070
2071 return index;
2072
2073}
6819758a 2074//-------------------------------------------------------------------------
2075
2076void AliTOFGeometry::PadRF2TrackingRF(Float_t *ctrackPos, Float_t *differenceT)
2077{
2078 //
2079 // To convert the 3D distance ctrackPos, referred to the ALICE RF,
2080 // into the 3D distance differenceT, referred to the tracking RF
2081 // in case ctrakPos belongs to a TOF sensitive volume.
2082 //
2083
2084 for (Int_t ii=0; ii<3; ii++) differenceT[ii] = 999.;
2085
2086 AliDebug(1,Form(" track position in ALICE global Ref. frame -> %f, %f, %f",
2087 ctrackPos[0],ctrackPos[1],ctrackPos[2]));
2088
2089 Int_t detId[5] = {-1,-1,-1,-1,-1};
2090
2091 detId[0] = GetSector(ctrackPos);
2092 if (detId[0]==-1) {
2093 AliWarning(Form("This point does not belong to any TOF sector"));
2094 return;
2095 }
2096
2097 detId[1] = GetPlate(ctrackPos);
2098 if (detId[1]==-1) {
2099 AliWarning(Form("This point does not belong to any TOF module"));
2100 return;
2101 }
2102
2103 detId[2] = GetStrip(ctrackPos);
2104 if (detId[2]==-1) {
2105 AliWarning(Form("This point does not belong to any TOF strip"));
2106 return;
2107 }
2108
2109 detId[3] = GetPadZ(ctrackPos);
2110 if (detId[3]==-1) {
2111 AliWarning(Form("This point does not belong to any TOF pad-row"));
2112 return;
2113 }
2114
2115 detId[4] = GetPadX(ctrackPos);
2116 if (detId[4]==-1) {
2117 AliWarning(Form("This point does not belong to any TOF pad"));
2118 return;
2119 }
2120
2121
2122 UShort_t alignableStripIndex =
2123 GetAliSensVolIndex(detId[0],detId[1],detId[2]);
2124 AliDebug(1,Form(" sector = %2d, plate = %1d, strip = %2d (padZ = %1d, padX = %2d) "
2125 "---> stripIndex = %4d",
2126 detId[0], detId[1], detId[2], detId[3], detId[4], alignableStripIndex));
2127
2128 // pad centre coordinates in the strip ref. frame
2129 Double_t padCentreL[3] = {(detId[4]-AliTOFGeometry::NpadX()/2)*AliTOFGeometry::XPad()
2130 +AliTOFGeometry::XPad()/2.,
2131 0.,
2132 (detId[3]-AliTOFGeometry::NpadZ()/2)*AliTOFGeometry::XPad()
2133 +AliTOFGeometry::XPad()/2.};
2134 // pad centre coordinates in the strip tracking frame
2135 Double_t padCentreT[3] = {0., 0., 0.};
2136 TGeoHMatrix l2t = *AliGeomManager::GetTracking2LocalMatrix(alignableStripIndex);
2137 l2t.MasterToLocal(padCentreL,padCentreT);
2138
2139
de40f9c1 2140 Char_t path[200];
6819758a 2141 // pad centre coordinates in its ref. frame
2142 Double_t padCentreL2[3] = {0., 0., 0.};
2143 // pad centre coordinates in the ALICE global ref. frame
2144 Double_t padCentreG[3] = {0., 0., 0.};
2145 GetVolumePath(detId,path);
2146 gGeoManager->cd(path);
2147 TGeoHMatrix g2l = *gGeoManager->GetCurrentMatrix();
2148 TGeoHMatrix l2g = g2l.Inverse();
2149 l2g.MasterToLocal(padCentreL2,padCentreG);
2150
2151
de40f9c1 2152 Char_t path2[200];
6819758a 2153 // strip centre coordinates in its ref. frame
2154 Double_t stripCentreL[3] = {0., 0., 0.};
2155 // strip centre coordinates in the ALICE global ref. frame
2156 Double_t stripCentreG[3] = {0., 0., 0.};
2157 GetVolumePath(detId[0],detId[1],detId[2],path2);
2158 gGeoManager->cd(path2);
2159 TGeoHMatrix g2lb = *gGeoManager->GetCurrentMatrix();
2160 TGeoHMatrix l2gb = g2lb.Inverse();
2161 l2gb.MasterToLocal(stripCentreL,stripCentreG);
2162
2163 TGeoHMatrix g2t = 0;
2164 AliGeomManager::GetTrackingMatrix(alignableStripIndex, g2t);
2165
2166 // track position in the ALICE global ref. frame
2167 Double_t posG[3];
2168 for (Int_t ii=0; ii<3; ii++) posG[ii] = (Double_t)ctrackPos[ii];
2169
2170 // strip centre coordinates in the tracking ref. frame
2171 Double_t stripCentreT[3] = {0., 0., 0.};
2172 // track position in the tracking ref. frame
2173 Double_t posT[3] = {0., 0., 0.};
2174 g2t.MasterToLocal(posG,posT);
2175 g2t.MasterToLocal(stripCentreG,stripCentreT);
2176
2177 for (Int_t ii=0; ii<3; ii++)
2178 AliDebug(1,Form(" track position in ALICE global and tracking RFs -> posG[%d] = %f --- posT[%d] = %f",
2179 ii, posG[ii], ii, posT[ii]));
2180 for (Int_t ii=0; ii<3; ii++)
2181 AliDebug(1,Form(" pad centre coordinates in its, the ALICE global and tracking RFs -> "
2182 "padCentreL[%d] = %f --- padCentreG[%d] = %f --- padCentreT[%d] = %f",
2183 ii, padCentreL[ii],
2184 ii, padCentreG[ii],
2185 ii, padCentreT[ii]));
2186 for (Int_t ii=0; ii<3; ii++)
2187 AliDebug(1,Form(" strip centre coordinates in its, the ALICE global and tracking RFs -> "
2188 "stripCentreL[%d] = %f --- stripCentreG[%d] = %f --- stripCentreT[%d] = %f",
2189 ii, stripCentreL[ii],
2190 ii, stripCentreG[ii],
2191 ii, stripCentreT[ii]));
2192 for (Int_t ii=0; ii<3; ii++)
2193 AliDebug(1,Form(" difference between the track position and the pad centre in the tracking RF "
2194 "-> posT[%d]-padCentreT[%d] = %f",
2195 ii,ii,
2196 posT[ii]-padCentreT[ii]));
2197
2198 for (Int_t ii=0; ii<3; ii++) differenceT[ii] = (Float_t)(posT[ii]-padCentreT[ii]);
2199
2200}
0262f8e8 2201//-------------------------------------------------------------------------
2202
a5043fb0 2203Int_t AliTOFGeometry::GetTOFsupermodule(Int_t index)
0262f8e8 2204{
2205 // Return the TOF supermodule where TOF channel index is located
2206
2207 if (index<0 || index>=NPadXSector()*NSectors()) return -1;
2208 else return index/NpadXStrip()/NStripXSector();
2209
2210}