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8918e700 | 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 | ||
acd84897 | 16 | /* $Id$ */ |
8918e700 | 17 | |
116cbefd | 18 | //------------------------------------------------------------------------ |
116cbefd | 19 | // Generic Lego generator code |
5d8718b8 | 20 | // Uses geantino rays to check the material distributions and detector's |
21 | // geometry | |
22 | // Author: A.Morsch | |
116cbefd | 23 | //------------------------------------------------------------------------ |
24 | ||
8918e700 | 25 | #include "AliLegoGenerator.h" |
26 | #include "AliRun.h" | |
27 | ||
28 | ClassImp(AliLegoGenerator) | |
29 | ||
e2afb3b6 | 30 | //_______________________________________________________________________ |
31 | AliLegoGenerator::AliLegoGenerator(): | |
32 | fRadMin(0), | |
33 | fRadMax(0), | |
34 | fZMax(0), | |
35 | fNCoor1(0), | |
36 | fNCoor2(0), | |
37 | fCoor1Min(0), | |
38 | fCoor1Max(0), | |
39 | fCoor2Min(0), | |
40 | fCoor2Max(0), | |
41 | fCoor1Bin(-1), | |
42 | fCoor2Bin(-1), | |
43 | fCurCoor1(0), | |
44 | fCurCoor2(0) | |
34915916 | 45 | { |
46 | // | |
47 | // Default Constructor | |
48 | // | |
49 | SetName("Lego"); | |
34915916 | 50 | } |
51 | ||
e2afb3b6 | 52 | //_______________________________________________________________________ |
34915916 | 53 | AliLegoGenerator::AliLegoGenerator(Int_t nc1, Float_t c1min, |
e2afb3b6 | 54 | Float_t c1max, Int_t nc2, |
55 | Float_t c2min, Float_t c2max, | |
56 | Float_t rmin, Float_t rmax, Float_t zmax): | |
57 | AliGenerator(0), | |
58 | fRadMin(rmin), | |
59 | fRadMax(rmax), | |
60 | fZMax(zmax), | |
61 | fNCoor1(nc1), | |
62 | fNCoor2(nc2), | |
63 | fCoor1Min(0), | |
64 | fCoor1Max(0), | |
65 | fCoor2Min(0), | |
66 | fCoor2Max(0), | |
67 | fCoor1Bin(nc1), | |
68 | fCoor2Bin(-1), | |
69 | fCurCoor1(0), | |
70 | fCurCoor2(0) | |
8918e700 | 71 | { |
ef42d733 | 72 | // |
73 | // Standard generator for Lego rays | |
74 | // | |
e2afb3b6 | 75 | SetName("Lego"); |
34915916 | 76 | SetCoor1Range(nc1, c1min, c1max); |
77 | SetCoor2Range(nc2, c2min, c2max); | |
8918e700 | 78 | } |
79 | ||
e2afb3b6 | 80 | //_______________________________________________________________________ |
8918e700 | 81 | void AliLegoGenerator::Generate() |
82 | { | |
e2afb3b6 | 83 | // Create a geantino with kinematics corresponding to the current bins |
84 | // Here: Coor1 = theta | |
85 | // Coor2 = phi. | |
86 | ||
8918e700 | 87 | // |
88 | // Rootinos are 0 | |
89 | const Int_t kMpart = 0; | |
90 | Float_t orig[3], pmom[3]; | |
91 | Float_t t, cost, sint, cosp, sinp; | |
34915916 | 92 | if (fCoor1Bin==-1) fCoor1Bin=fNCoor1; |
8918e700 | 93 | // Prepare for next step |
34915916 | 94 | if(fCoor1Bin>=fNCoor1-1) |
95 | if(fCoor2Bin>=fNCoor2-1) { | |
8918e700 | 96 | Warning("Generate","End of Lego Generation"); |
97 | return; | |
98 | } else { | |
34915916 | 99 | fCoor2Bin++; |
100 | printf("Generating rays in phi bin:%d\n",fCoor2Bin); | |
101 | fCoor1Bin=0; | |
102 | } else fCoor1Bin++; | |
103 | ||
104 | fCurCoor1 = (fCoor1Min+(fCoor1Bin+0.5)*(fCoor1Max-fCoor1Min)/fNCoor1); | |
105 | fCurCoor2 = (fCoor2Min+(fCoor2Bin+0.5)*(fCoor2Max-fCoor2Min)/fNCoor2); | |
106 | cost = TMath::Cos(fCurCoor1 * TMath::Pi()/180.); | |
107 | sint = TMath::Sin(fCurCoor1 * TMath::Pi()/180.); | |
108 | cosp = TMath::Cos(fCurCoor2 * TMath::Pi()/180.); | |
109 | sinp = TMath::Sin(fCurCoor2 * TMath::Pi()/180.); | |
8918e700 | 110 | |
111 | pmom[0] = cosp*sint; | |
112 | pmom[1] = sinp*sint; | |
113 | pmom[2] = cost; | |
114 | ||
115 | // --- Where to start | |
116 | orig[0] = orig[1] = orig[2] = 0; | |
117 | Float_t dalicz = 3000; | |
118 | if (fRadMin > 0) { | |
34915916 | 119 | t = PropagateCylinder(orig,pmom,fRadMin,dalicz); |
120 | orig[0] = pmom[0]*t; | |
121 | orig[1] = pmom[1]*t; | |
122 | orig[2] = pmom[2]*t; | |
123 | if (TMath::Abs(orig[2]) > fZMax) return; | |
8918e700 | 124 | } |
125 | ||
126 | Float_t polar[3]={0.,0.,0.}; | |
127 | Int_t ntr; | |
642f15cf | 128 | gAlice->PushTrack(1, -1, kMpart, pmom, orig, polar, 0, kPPrimary, ntr); |
34915916 | 129 | |
8918e700 | 130 | } |
131 | ||
e2afb3b6 | 132 | //_______________________________________________________________________ |
133 | Float_t AliLegoGenerator::PropagateCylinder(Float_t *x, Float_t *v, Float_t r, | |
134 | Float_t z) | |
8918e700 | 135 | { |
e2afb3b6 | 136 | // |
137 | // Propagate to cylinder from inside | |
138 | // | |
8918e700 | 139 | Double_t hnorm, sz, t, t1, t2, t3, sr; |
140 | Double_t d[3]; | |
141 | const Float_t kSmall = 1e-8; | |
142 | const Float_t kSmall2 = kSmall*kSmall; | |
143 | ||
144 | // ---> Find intesection with Z planes | |
145 | d[0] = v[0]; | |
146 | d[1] = v[1]; | |
147 | d[2] = v[2]; | |
148 | hnorm = TMath::Sqrt(1/(d[0]*d[0]+d[1]*d[1]+d[2]*d[2])); | |
149 | d[0] *= hnorm; | |
150 | d[1] *= hnorm; | |
151 | d[2] *= hnorm; | |
152 | if (d[2] > kSmall) sz = (z-x[2])/d[2]; | |
153 | else if (d[2] < -kSmall) sz = -(z+x[2])/d[2]; | |
154 | else sz = 1.e10; // ---> Direction parallel to X-Y, no intersection | |
155 | ||
156 | // ---> Intersection with cylinders | |
157 | // Intersection point (x,y,z) | |
158 | // (x,y,z) is on track : x=X(1)+t*D(1) | |
159 | // y=X(2)+t*D(2) | |
160 | // z=X(3)+t*D(3) | |
161 | // (x,y,z) is on cylinder : x**2 + y**2 = R**2 | |
162 | // | |
163 | // (D(1)**2+D(2)**2)*t**2 | |
164 | // +2.*(X(1)*D(1)+X(2)*D(2))*t | |
165 | // +X(1)**2+X(2)**2-R**2=0 | |
166 | // ---> Solve second degree equation | |
167 | t1 = d[0]*d[0] + d[1]*d[1]; | |
168 | if (t1 <= kSmall2) { | |
169 | t = sz; // ---> Track parallel to the z-axis, take distance to planes | |
170 | } else { | |
171 | t2 = x[0]*d[0] + x[1]*d[1]; | |
172 | t3 = x[0]*x[0] + x[1]*x[1]; | |
173 | // ---> It should be positive, but there may be numerical problems | |
34915916 | 174 | sr = (-t2 +TMath::Sqrt(TMath::Max(t2*t2-(t3-r*r)*t1,0.)))/t1; |
8918e700 | 175 | // ---> Find minimum distance between planes and cylinder |
176 | t = TMath::Min(sz,sr); | |
177 | } | |
178 | return t; | |
179 | } | |
180 | ||
34915916 | 181 |