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28e0901a | 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 | // --- Standard libraries | |
17 | #include <stdlib.h> | |
28e0901a | 18 | |
19 | // --- ROOT system | |
20 | #include <TRandom.h> | |
21 | #include <TF1.h> | |
22 | ||
23 | // --- AliRoot classes | |
24 | #include "AliZDCFragment.h" | |
28e0901a | 25 | |
5a881c97 | 26 | ClassImp(AliZDCFragment) |
27 | ||
28 | int comp(const void *i,const void *j) {return *(int *)i - *(int *)j;} | |
29 | ||
30 | ||
28e0901a | 31 | //_____________________________________________________________________________ |
32 | AliZDCFragment::AliZDCFragment() | |
33 | { | |
34 | // | |
35 | // Default constructor | |
36 | // | |
37 | fB = 0; | |
38 | } | |
39 | ||
40 | //_____________________________________________________________________________ | |
41 | AliZDCFragment::AliZDCFragment(Float_t b) | |
42 | : TNamed(" "," ") | |
43 | { | |
44 | // | |
45 | // Standard constructor | |
46 | // | |
47 | fB = b; | |
48 | fZbAverage = 0; | |
49 | fNimf = 0; | |
50 | fZmax = 0; | |
51 | fTau = 0; | |
28e0901a | 52 | for(Int_t i=0; i<=99; i++){ |
53 | fZZ[i] = 0; | |
54 | fNN[i] = 0; | |
55 | } | |
5a881c97 | 56 | fNalpha = 0; |
57 | fZtot = 0; | |
58 | fNtot = 0; | |
28e0901a | 59 | |
60 | } | |
61 | ||
62 | //_____________________________________________________________________________ | |
63 | void AliZDCFragment::GenerateIMF(Int_t* fZZ, Int_t &fNalpha) | |
64 | { | |
65 | // Coefficients of polynomial for average number of IMF | |
5a881c97 | 66 | const Float_t ParamNimf[5]={0.011236,1.8364,56.572,-116.24,58.289}; |
28e0901a | 67 | // Coefficients of polynomial for fluctuations on average number of IMF |
5a881c97 | 68 | const Float_t ParamFluctNimf[4]={-0.13176,2.9392,-5.2147,2.3092}; |
28e0901a | 69 | // Coefficients of polynomial for average maximum Z of fragments |
5a881c97 | 70 | const Float_t ParamZmax[4]={0.16899,14.203,-2.8284,65.036}; |
28e0901a | 71 | // Coefficients of polynomial for fluctuations on maximum Z of fragments |
5a881c97 | 72 | const Float_t ParamFluctZmax[5]={0.013782,-0.17282,1.5065,1.0654,-2.4317}; |
28e0901a | 73 | // Coefficients of polynomial for exponent tau of fragments Z distribution |
5a881c97 | 74 | const Float_t ParamTau[3]={6.7233,-15.85,13.047}; |
28e0901a | 75 | //Coefficients of polynomial for average number of alphas |
5a881c97 | 76 | const Float_t ParamNalpha[4]={-0.68554,39.605,-68.311,30.165}; |
28e0901a | 77 | // Coefficients of polynomial for fluctuations on average number of alphas |
5a881c97 | 78 | const Float_t ParamFluctNalpha[5]={0.283,6.2141,-17.113,17.394,-6.6084}; |
28e0901a | 79 | // Coefficients of function for Pb nucleus skin |
5a881c97 | 80 | const Float_t ParamSkinPb[2]={0.93,11.05}; |
28e0901a | 81 | |
82 | // Thickness of nuclear surface | |
5a881c97 | 83 | const Float_t NuclearThick = 0.52; |
28e0901a | 84 | // Maximum impact parameter for U [r0*A**(1/3)] |
5a881c97 | 85 | const Float_t bMaxU = 14.87; |
28e0901a | 86 | // Maximum impact parameter for Pb [r0*A**(1/3)] |
5a881c97 | 87 | const Float_t bMaxPb = 14.22; |
28e0901a | 88 | // Z of the projectile |
5a881c97 | 89 | const Float_t ZProj = 82.; |
28e0901a | 90 | |
91 | // From b(Pb) to b(U) | |
92 | Float_t bU = fB*bMaxU/bMaxPb; | |
93 | ||
94 | // From b(U) to Zbound(U) | |
95 | // --- A.Schuttauf et al, Nuc.Phys. A607 (1996) 457 --------------- | |
96 | // From geometrical consideration and from dsigma/dZbound for U+U, | |
97 | // which is approx. constant, the constant value is found | |
98 | // integrating the nucleus cross surface from 0 to bmax=R1+R2 where | |
99 | // R = 1.2*A**(1/3). This value has been measured in Aladin (U+U). | |
100 | Float_t ZbU = bU*bU*TMath::Pi()/7.48; | |
101 | ||
102 | // Rescale Zbound for Pb | |
103 | fZbAverage = ZProj/92.*ZbU; | |
104 | ||
105 | // Zbound is proportional to b**2 up to b < bMaxPb-2*NuclearThick | |
106 | // and then it is an increasing exponential, imposing that at | |
107 | // b=bMaxPb-2NuclearThick the two functions have the same derivative | |
108 | Float_t bCore = bMaxPb-2*NuclearThick; | |
109 | if(fB>bCore){ | |
110 | fZbAverage=ZProj*(1.-TMath::Exp(-ParamSkinPb[0]*(fB-ParamSkinPb[1]))); | |
111 | } | |
112 | if(fZbAverage>ZProj) fZbAverage = ZProj; | |
113 | Float_t ZbNorm = fZbAverage/ZProj; | |
114 | Float_t bNorm = fB/bMaxPb; | |
115 | ||
116 | // From Zbound to <Nimf>,<Zmax>,tau | |
117 | // Polinomial fits to Aladin distribution | |
118 | // --- A.Schuttauf et al, Nuc.Phys. A607 (1996) 457. | |
119 | Float_t AverageNimf = ParamNimf[0]+ParamNimf[1]*ZbNorm+ParamNimf[2]* | |
120 | TMath::Power(ZbNorm,2)+ParamNimf[3]*TMath::Power(ZbNorm,3)+ | |
121 | ParamNimf[4]*TMath::Power(ZbNorm,4); | |
122 | ||
123 | // Add fluctuation: from Singh et al. | |
124 | Float_t FluctNimf = ParamFluctNimf[0]+ParamFluctNimf[1]*ZbNorm+ | |
125 | ParamFluctNimf[2]*TMath::Power(ZbNorm,2)+ParamFluctNimf[3] | |
126 | *TMath::Power(ZbNorm,3); | |
127 | Float_t xx = gRandom->Gaus(0.0,1.0); | |
128 | FluctNimf = FluctNimf*xx; | |
129 | fNimf = Int_t(AverageNimf+FluctNimf); | |
130 | Float_t y = gRandom->Rndm(); | |
131 | if(y < ((AverageNimf+FluctNimf)-fNimf)) fNimf += 1; | |
132 | if(fNimf ==0 && ZbNorm>0.75) fNimf = 1; | |
28e0901a | 133 | |
134 | Float_t AverageZmax = ParamZmax[0]+ParamZmax[1]*ZbNorm+ParamZmax[2]* | |
135 | TMath::Power(ZbNorm,2)+ParamZmax[3]*TMath::Power(ZbNorm,3); | |
136 | fTau = ParamTau[0]+ParamTau[1]*ZbNorm+ParamTau[2]*TMath::Power(ZbNorm,2); | |
137 | ||
138 | // Add fluctuation to mean value of Zmax (see Hubele) | |
139 | Float_t FluctZmax = ParamFluctZmax[0]+ParamFluctZmax[1]*ZbNorm+ | |
140 | ParamFluctZmax[2]*TMath::Power(ZbNorm,2)+ParamFluctZmax[3]* | |
141 | TMath::Power(ZbNorm,3)+ParamFluctZmax[4]*TMath::Power(ZbNorm,4); | |
142 | FluctZmax = FluctZmax*ZProj/6.; | |
143 | Float_t xg = gRandom->Gaus(0.0,1.0); | |
144 | FluctZmax = FluctZmax*xg; | |
145 | fZmax = AverageZmax+FluctZmax; | |
146 | if(fZmax>ZProj) fZmax = ZProj; | |
5a881c97 | 147 | |
148 | // printf("\n\n ------------------------------------------------------------"); | |
149 | // printf("\n Generation of nuclear fragments\n"); | |
150 | // printf("\n fNimf = %d\n", fNimf); | |
151 | // printf("\n fZmax = %f\n", fZmax); | |
28e0901a | 152 | |
153 | // Find the number of alpha particles | |
154 | // from Singh et al. : Pb+emulsion | |
155 | Float_t AverageAlpha = ParamNalpha[0]+ParamNalpha[1]*ZbNorm+ | |
156 | ParamNalpha[2]*TMath::Power(ZbNorm,2)+ParamNalpha[3]* | |
157 | TMath::Power(ZbNorm,3); | |
158 | Float_t FluctAlpha = ParamFluctNalpha[0]+ParamFluctNalpha[1]* | |
159 | ZbNorm+ParamFluctNalpha[2]*TMath::Power(ZbNorm,2)+ | |
160 | ParamFluctNalpha[3]*TMath::Power(ZbNorm,3)+ | |
161 | ParamFluctNalpha[4]*TMath::Power(ZbNorm,4); | |
162 | Float_t xxx = gRandom->Gaus(0.0,1.0); | |
163 | FluctAlpha = FluctAlpha*xxx; | |
164 | fNalpha = Int_t(AverageAlpha+FluctAlpha); | |
165 | Float_t yy = gRandom->Rndm(); | |
166 | if(yy < ((AverageAlpha+FluctAlpha)-fNalpha)) fNalpha += 1; | |
167 | ||
28e0901a | 168 | // 2 possibilities: |
169 | // 1) for bNorm < 0.9 ==> first remove alphas, then fragments | |
170 | // 2) for bNorm > 0.9 ==> first remove fragments, then alphas | |
171 | ||
5a881c97 | 172 | Int_t Choice = 0; |
173 | Float_t ZbFrag = 0, SumZ = 0.; | |
174 | ||
28e0901a | 175 | if(bNorm<=0.9) { |
176 | // remove alpha from zbound to find zbound for fragments (Z>=3) | |
177 | ZbFrag = fZbAverage-fNalpha*2; | |
178 | Choice = 1; | |
179 | } | |
180 | else { | |
181 | ZbFrag = fZbAverage; | |
182 | Choice = 0; | |
183 | } | |
184 | // printf("\n Choice = %d, fZbAverage = %f, ZbFrag = %f \n", Choice, fZbAverage, ZbFrag); | |
185 | ||
186 | ||
187 | // Check if ZbFrag < fZmax | |
188 | if(ZbFrag<=fZmax) { | |
189 | if(fNimf>0 && ZbFrag>=2){ | |
190 | fNimf = 1; | |
191 | fZZ[0] = Int_t(ZbFrag); | |
192 | SumZ = ZbFrag; | |
193 | } | |
194 | else { | |
195 | fNimf = 0; | |
196 | } | |
197 | return; | |
198 | } | |
199 | ||
200 | // Prepare the exponential charge distribution dN/dZ | |
201 | if(fZmax <= 0.01) { | |
202 | fNimf = 0; | |
203 | return; | |
204 | } | |
205 | if(fNimf == 0) { | |
206 | fNimf = 0; | |
207 | return; | |
208 | } | |
209 | ||
210 | TF1 *funTau = new TF1("funTau","1./(x**[0])",0.01,fZmax); | |
211 | funTau->SetParameter(0,fTau); | |
212 | ||
213 | // Extract randomly the charge of the fragments from the distribution | |
214 | ||
215 | Float_t zz[fNimf]; | |
216 | for(Int_t j=0; j<fNimf; j++){ | |
217 | zz[j] =0; | |
218 | } | |
219 | for(Int_t i=0; i<fNimf; i++){ | |
220 | zz[i] = Float_t(funTau->GetRandom()); | |
221 | // printf("\n zz[%d] = %f \n",i,zz[i]); | |
222 | } | |
223 | delete funTau; | |
224 | ||
5a881c97 | 225 | // Sorting vector in ascending order with C function QSORT |
28e0901a | 226 | qsort((void*)zz,fNimf,sizeof(float),comp); |
227 | ||
5a881c97 | 228 | |
229 | // for(Int_t i=0; i<fNimf; i++){ | |
28e0901a | 230 | // printf("\n After sorting -> zz[%d] = %f \n",i,zz[i]); |
5a881c97 | 231 | // } |
28e0901a | 232 | |
233 | // Rescale the maximum charge to fZmax | |
234 | for(Int_t j=0; j<fNimf; j++){ | |
235 | fZZ[j] = Int_t (zz[j]*fZmax/zz[fNimf-1]); | |
236 | if(fZZ[j]<3) fZZ[j] = 3; | |
5a881c97 | 237 | // printf("\n fZZ[%d] = %d \n",j,fZZ[j]); |
28e0901a | 238 | } |
239 | ||
5a881c97 | 240 | // Check that the sum of the bound charges is not > than Zbound-Zalfa |
28e0901a | 241 | |
242 | for(Int_t ii=0; ii<fNimf; ii++){ | |
243 | SumZ += fZZ[ii]; | |
244 | } | |
245 | ||
246 | Int_t k = 0; | |
247 | if(SumZ>ZbFrag){ | |
248 | for(Int_t i=0; i< fNimf; i++){ | |
249 | k += 1; | |
250 | SumZ -= fZZ[i]; | |
251 | if(SumZ<=ZbFrag){ | |
252 | fNimf -= (i+1); | |
253 | break; | |
254 | } | |
255 | } | |
256 | } | |
257 | else { | |
258 | if(Choice == 1) return; | |
259 | Int_t iDiff = Int_t((ZbFrag-SumZ)/2); | |
260 | if(iDiff<fNalpha){ | |
261 | fNalpha=iDiff; | |
262 | return; | |
263 | } | |
264 | else{ | |
265 | return; | |
266 | } | |
267 | } | |
268 | ||
269 | fNimf += k; | |
270 | for(Int_t i=0; i<fNimf; i++){ | |
271 | fZZ[i] = fZZ[i+k]; | |
272 | } | |
273 | fNimf -= k; | |
274 | ||
275 | SumZ=0; | |
276 | for(Int_t i=0; i<fNimf; i++){ | |
277 | SumZ += fZZ[i]; | |
278 | } | |
28e0901a | 279 | |
280 | } | |
281 | ||
28e0901a | 282 | //_____________________________________________________________________________ |
283 | void AliZDCFragment::AttachNeutrons(Int_t *fZZ, Int_t *fNN, Int_t &fZtot,Int_t &fNtot) | |
284 | { | |
5a881c97 | 285 | const Float_t AIon[68]={1.87612,2.80943,3.7284,5.60305,6.53536, |
28e0901a | 286 | 6.53622,8.39479,9.32699,10.2551,11.17793, |
287 | 13.04378,14.89917,17.6969,18.62284,21.41483, | |
288 | 22.34193,25.13314,26.06034,28.85188,29.7818, | |
289 | 32.57328,33.50356,36.29447,37.22492,41.87617, | |
290 | 44.66324,47.45401,48.38228,51.17447,52.10307, | |
291 | 54.89593,53.96644,58.61856,59.54963,68.85715, | |
292 | 74.44178,78.16309,81.88358,83.74571,91.19832, | |
293 | 98.64997,106.10997,111.68821,122.86796, | |
294 | 128.45793, | |
295 | 130.32111,141.51236, | |
296 | 141.55,146.477,148.033,152.699,153.631, | |
297 | 155.802,157.357,162.022,162.984,166.2624, | |
298 | 168.554,171.349,173.4536,177.198,179.0518, | |
299 | 180.675,183.473,188.1345,190.77,193.729, | |
300 | 221.74295}; | |
5a881c97 | 301 | const Int_t ZIon[68]={1,1,2,3,3, |
28e0901a | 302 | 4,4,5,5,6, |
303 | 7,8,9,10,11, | |
304 | 12,13,14,15,16, | |
305 | 17,18,19,20,21, | |
306 | 22,23,24,25,26, | |
307 | 27,28,29,30,32, | |
308 | 34,36,38,40,42, | |
309 | 46,48,50,54,56, | |
310 | 58,62, | |
311 | 63,64,65,66,67, | |
312 | 68,69,70,71,72, | |
313 | 73,74,75,76,77, | |
314 | 78,79,80,81,82, | |
315 | 92}; | |
316 | ||
317 | Int_t iZ, iA; | |
5a881c97 | 318 | // printf("\n fNimf=%d\n",fNimf); |
319 | ||
28e0901a | 320 | for(Int_t i=0; i<fNimf; i++) { |
321 | for(Int_t j=0; j<68; j++) { | |
322 | iZ = ZIon[j]; | |
323 | if((fZZ[i]-iZ) == 0){ | |
324 | iA = Int_t(AIon[j]/0.93149432+0.5); | |
325 | fNN[i] = iA - iZ; | |
28e0901a | 326 | break; |
327 | } | |
328 | else if((fZZ[i]-iZ) < 0){ | |
329 | fZZ[i] = ZIon[j-1]; | |
330 | iA = Int_t (AIon[j-1]/0.93149432+0.5); | |
331 | fNN[i] = iA - ZIon[j-1]; | |
28e0901a | 332 | break; |
333 | } | |
334 | } | |
335 | fZtot += fZZ[i]; | |
336 | fNtot += fNN[i]; | |
337 | } | |
338 | ||
339 | ||
340 | } |