Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
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G4AngularDistribution.cc
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26// hpw: done, but low quality at present.
27
28#include "globals.hh"
29#include "G4Log.hh"
30#include "G4SystemOfUnits.hh"
31#include "G4AngularDistribution.hh"
32#include "Randomize.hh"
33
34G4AngularDistribution::G4AngularDistribution(G4bool symmetrize)
35 : sym(symmetrize)
36{
37 // The following are parameters of the model - not to be confused with the PDG values!
38
39 mSigma = 0.55;
40 cmSigma = 1.20;
41 gSigma = 9.4;
42
43 mOmega = 0.783;
44 cmOmega = 0.808;
45 gOmega = 10.95;
46
47 mPion = 0.138;
48 cmPion = 0.51;
49 gPion = 7.27;
50
51 mNucleon = 0.938;
52
53 // Definition of constants for pion-Term (no s-dependence)
54
55 m42 = 4. * mNucleon * mNucleon;
56 mPion2 = mPion * mPion;
57 cmPion2 = cmPion * cmPion;
58 dPion1 = cmPion2-mPion2;
59 dPion2 = dPion1 * dPion1;
60 cm6gp = 1.5 * (cmPion2*cmPion2*cmPion2) * (gPion*gPion*gPion*gPion) * m42 * m42 / dPion2;
61
62 cPion_3 = -(cm6gp/3.);
63 cPion_2 = -(cm6gp * mPion2/dPion1);
64 cPion_1 = -(cm6gp * mPion2 * (2. * cmPion2 + mPion2) / dPion2);
65 cPion_m = -(cm6gp * cmPion2 * mPion2 / dPion2);
66 cPion_L = -(cm6gp * 2. * cmPion2 * mPion2 * (cmPion2 + mPion2) / dPion2 / dPion1);
67 cPion_0 = -(cPion_3 + cPion_2 + cPion_1 + cPion_m);
68
69 // Definition of constants for sigma-Term (no s-dependence)
70
71 G4double gSigmaSq = gSigma * gSigma;
72
73 mSigma2 = mSigma * mSigma;
74 cmSigma2 = cmSigma * cmSigma;
75 cmSigma4 = cmSigma2 * cmSigma2;
76 cmSigma6 = cmSigma2 * cmSigma4;
77 dSigma1 = m42 - cmSigma2;
78 dSigma2 = m42 - mSigma2;
79 dSigma3 = cmSigma2 - mSigma2;
80
81 G4double dSigma1Sq = dSigma1 * dSigma1;
82 G4double dSigma2Sq = dSigma2 * dSigma2;
83 G4double dSigma3Sq = dSigma3 * dSigma3;
84
85 cm2gs = 0.5 * cmSigma2 * gSigmaSq*gSigmaSq / dSigma3Sq;
86
87
88 cSigma_3 = -(cm2gs * dSigma1Sq / 3.);
89 cSigma_2 = -(cm2gs * cmSigma2 * dSigma1 * dSigma2 / dSigma3);
90 cSigma_1 = -(cm2gs * cmSigma4 * (2. * dSigma1 + dSigma2) * dSigma2 / dSigma3Sq);
91 cSigma_m = -(cm2gs * cmSigma6 * dSigma2Sq / mSigma2 / dSigma3Sq);
92 cSigma_L = -(cm2gs * cmSigma6 * dSigma2 * (dSigma1 + dSigma2) * 2. / (dSigma3 * dSigma3Sq));
93 cSigma_0 = -(cSigma_3 + cSigma_2 + cSigma_1 + cSigma_m);
94
95 // Definition of constants for omega-Term
96
97 G4double gOmegaSq = gOmega * gOmega;
98
99 mOmega2 = mOmega * mOmega;
100 cmOmega2 = cmOmega * cmOmega;
101 cmOmega4 = cmOmega2 * cmOmega2;
102 cmOmega6 = cmOmega2 * cmOmega4;
103 dOmega1 = m42 - cmOmega2;
104 dOmega2 = m42 - mOmega2;
105 dOmega3 = cmOmega2 - mOmega2;
106 sOmega1 = cmOmega2 + mOmega2;
107
108 G4double dOmega3Sq = dOmega3 * dOmega3;
109
110 cm2go = 0.5 * cmOmega2 * gOmegaSq * gOmegaSq / dOmega3Sq;
111
112 cOmega_3 = cm2go / 3.;
113 cOmega_2 = -(cm2go * cmOmega2 / dOmega3);
114 cOmega_1 = cm2go * cmOmega4 / dOmega3Sq;
115 cOmega_m = cm2go * cmOmega6 / (dOmega3Sq * mOmega2);
116 cOmega_L = -(cm2go * cmOmega6 * 4. / (dOmega3 * dOmega3Sq));
117
118 // Definition of constants for mix-Term
119
120 G4double fac1Tmp = (gSigma * gOmega * cmSigma2 * cmOmega2);
121 fac1 = -(fac1Tmp * fac1Tmp * m42);
122 dMix1 = cmOmega2 - cmSigma2;
123 dMix2 = cmOmega2 - mSigma2;
124 dMix3 = cmSigma2 - mOmega2;
125
126 G4double dMix1Sq = dMix1 * dMix1;
127 G4double dMix2Sq = dMix2 * dMix2;
128 G4double dMix3Sq = dMix3 * dMix3;
129
130 cMix_o1 = fac1 / (cmOmega2 * dMix1Sq * dMix2 * dOmega3);
131 cMix_s1 = fac1 / (cmSigma2 * dMix1Sq * dMix3 * dSigma3);
132 cMix_Omega = fac1 / (dOmega3Sq * dMix3Sq * (mOmega2 - mSigma2));
133 cMix_sm = fac1 / (dSigma3Sq * dMix2Sq * (mSigma2 - mOmega2));
134 fac2 = (-fac1) / (dMix1*dMix1Sq * dOmega3Sq * dMix2Sq);
135 fac3 = (-fac1) / (dMix1*dMix1Sq * dSigma3Sq * dMix3Sq);
136
137 cMix_oLc = fac2 * (3. * cmOmega2*cmOmega4 - cmOmega4 * cmSigma2
138 - 2. * cmOmega4 * mOmega2 - 2. * cmOmega4 * mSigma2
139 + cmOmega2 * mOmega2 * mSigma2 + cmSigma2 * mOmega2 * mSigma2
140 - 4. * cmOmega4 * m42 + 2. * cmOmega2 * cmSigma2 * m42
141 + 3. * cmOmega2 * mOmega2 * m42 - cmSigma2 * mOmega2 * m42
142 + 3. * cmOmega2 * mSigma2 * m42 - cmSigma2 * mSigma2 * m42
143 - 2. * mOmega2 * mSigma2 * m42);
144
145 cMix_oLs = fac2 * (8. * cmOmega4 - 4. * cmOmega2 * cmSigma2
146 - 6. * cmOmega2 * mOmega2 + 2. * cmSigma2 * mOmega2
147 - 6. * cmOmega2 * mSigma2 + 2. * cmSigma2 * mSigma2
148 + 4. * mOmega2 * mSigma2);
149
150 cMix_sLc = fac3 * (cmOmega2 * cmSigma4 - 3. * cmSigma6
151 + 2. * cmSigma4 * mOmega2 + 2. * cmSigma4 * mSigma2
152 - cmOmega2 * mOmega2 * mSigma2 - cmSigma2 * mOmega2 * mSigma2
153 - 2. * cmOmega2 * cmSigma2 * m42 + 4. * cmSigma4 * m42
154 + cmOmega2 * mOmega2 * m42 - 3. * cmSigma2 * mOmega2 * m42
155 + cmOmega2 * mSigma2 * m42 - 3. * cmSigma2 * mSigma2 * m42
156 + 2. * mOmega2 * mSigma2 * m42);
157
158 cMix_sLs = fac3 * (4. * cmOmega2 * cmSigma2 - 8. * cmSigma4
159 - 2. * cmOmega2 * mOmega2 + 6. * cmSigma2 * mOmega2
160 - 2. * cmOmega2 * mSigma2 + 6. * cmSigma2 * mSigma2
161 - 4. * mOmega2 * mSigma2);
162}
163
164
165G4AngularDistribution::~
166G4AngularDistribution()
167{ }
168
169
170G4double G4AngularDistribution::CosTheta(G4double S, G4double m_1, G4double m_2) const
171{
172 G4double random = G4UniformRand();
173 G4double dCosTheta = 2.;
174 G4double cosTheta = -1.;
175
176 // For jmax=12 the accuracy is better than 0.1 degree
177 G4int jMax = 12;
178
179 for (G4int j = 1; j <= jMax; ++j)
180 {
181 // Accuracy is 2^-jmax
182 dCosTheta *= 0.5;
183 G4double cosTh = cosTheta + dCosTheta;
184 if(DifferentialCrossSection(S, m_1, m_2, cosTh) <= random) cosTheta = cosTh;
185 }
186
187 // Randomize in final interval in order to avoid discrete angles
188 cosTheta += G4UniformRand() * dCosTheta;
189
190
191 if (cosTheta > 1. || cosTheta < -1.)
192 throw G4HadronicException(__FILE__, __LINE__, "G4AngularDistribution::CosTheta - std::cos(theta) outside allowed range");
193
194 return cosTheta;
195}
196
197
198G4double G4AngularDistribution::DifferentialCrossSection(G4double sIn, G4double m_1, G4double m_2,
199 G4double cosTheta) const
200{
201// local calculus is in GeV, ie. normalize input
202 sIn = sIn/sqr(GeV)+m42/2.;
203 m_1 = m_1/GeV;
204 m_2 = m_2/GeV;
205// G4cout << "Here we go"<<sIn << " "<<m1 << " " << m2 <<" " m42<< G4endl;
206// scaling from masses other than p,p.
207 G4double S = sIn - (m_1+m_2) * (m_1+m_2) + m42;
208 G4double tMax = S - m42;
209 G4double tp = 0.5 * (cosTheta + 1.) * tMax;
210 G4double twoS = 2. * S;
211
212 // Define s-dependent stuff for omega-Term
213 G4double brak1 = (twoS-m42) * (twoS-m42);
214 G4double bOmega_3 = cOmega_3 * (-2. * cmOmega4 - 2. * cmOmega2 * twoS - brak1);
215 G4double bOmega_2 = cOmega_2 * ( 2. * cmOmega2 * mOmega2 + sOmega1 * twoS + brak1);
216 G4double bOmega_1 = cOmega_1 * (-4. * cmOmega2 * mOmega2
217 - 2. * mOmega2*mOmega2
218 - 2. * (cmOmega2 + 2 * mOmega2) * twoS
219 - 3. * brak1);
220 G4double bOmega_m = cOmega_m * (-2. * mOmega2*mOmega2 - 2. * mOmega2 * twoS - brak1);
221 G4double bOmega_L = cOmega_L * (sOmega1 * mOmega2 + (cmOmega2 + 3. * mOmega2) * S + brak1);
222 G4double bOmega_0 = -(bOmega_3 + bOmega_2 + bOmega_1 + bOmega_m);
223
224 // Define s-dependent stuff for mix-Term
225 G4double bMix_o1 = cMix_o1 * (dOmega1 - twoS);
226 G4double bMix_s1 = cMix_s1 * (dSigma1 - twoS);
227 G4double bMix_Omega = cMix_Omega * (dOmega2 - twoS);
228 G4double bMix_sm = cMix_sm * (dSigma2 - twoS);
229 G4double bMix_oL = cMix_oLc + cMix_oLs * S;
230 G4double bMix_sL = cMix_sLc + cMix_sLs * S;
231
232 G4double t1_Pion = 1. / (1. + tMax / cmPion2);
233 G4double t2_Pion = 1. + tMax / mPion2;
234 G4double t1_Sigma = 1. / (1. + tMax / cmSigma2);
235 G4double t2_Sigma = 1. + tMax / mSigma2;
236 G4double t1_Omega = 1. / (1. + tMax / cmOmega2);
237 G4double t2_Omega = 1. + tMax / mOmega2;
238
239 G4double norm = Cross(t1_Pion, t1_Sigma, t1_Omega,
240 t2_Pion, t2_Sigma, t2_Omega,
241 bMix_o1, bMix_s1, bMix_Omega,
242 bMix_sm, bMix_oL, bMix_sL,
243 bOmega_0, bOmega_1, bOmega_2,
244 bOmega_3, bOmega_m, bOmega_L);
245
246 t1_Pion = 1. / (1. + tp / cmPion2);
247 t2_Pion = 1. + tp / mPion2;
248 t1_Sigma = 1. / (1. + tp / cmSigma2);
249 t2_Sigma = 1. + tp / mSigma2;
250 t1_Omega = 1. / (1. + tp / cmOmega2);
251 t2_Omega = 1. + tp / mOmega2;
252
253 G4double dSigma;
254 if (sym)
255 {
256 G4double to;
257 norm = 2. * norm;
258 to = tMax - tp;
259 G4double t3_Pion = 1. / (1. + to / cmPion2);
260 G4double t4_Pion = 1. + to / mPion2;
261 G4double t3_Sigma = 1. / (1. + to / cmSigma2);
262 G4double t4_Sigma = 1. + to / mSigma2;
263 G4double t3_Omega = 1. / (1. + to / cmOmega2);
264 G4double t4_Omega = 1. + to / mOmega2;
265
266 dSigma = ( Cross(t1_Pion, t1_Sigma, t1_Omega,
267 t2_Pion,t2_Sigma, t2_Omega,
268 bMix_o1, bMix_s1, bMix_Omega,
269 bMix_sm, bMix_oL, bMix_sL,
270 bOmega_0, bOmega_1, bOmega_2,
271 bOmega_3, bOmega_m, bOmega_L) -
272 Cross(t3_Pion,t3_Sigma, t3_Omega,
273 t4_Pion, t4_Sigma, t4_Omega,
274 bMix_o1, bMix_s1, bMix_Omega,
275 bMix_sm, bMix_oL, bMix_sL,
276 bOmega_0, bOmega_1, bOmega_2,
277 bOmega_3, bOmega_m, bOmega_L) )
278 / norm + 0.5;
279 }
280 else
281 {
282 dSigma = Cross(t1_Pion, t1_Sigma, t1_Omega,
283 t2_Pion, t2_Sigma, t2_Omega,
284 bMix_o1, bMix_s1, bMix_Omega,
285 bMix_sm, bMix_oL, bMix_sL,
286 bOmega_0, bOmega_1, bOmega_2,
287 bOmega_3, bOmega_m, bOmega_L)
288 / norm;
289 }
290
291 return dSigma;
292}
293
294
295G4double G4AngularDistribution::Cross(G4double tpPion,
296 G4double tpSigma,
297 G4double tpOmega,
298 G4double tmPion,
299 G4double tmSigma,
300 G4double tmOmega,
301 G4double bMix_o1,
302 G4double bMix_s1,
303 G4double bMix_Omega,
304 G4double bMix_sm,
305 G4double bMix_oL,
306 G4double bMix_sL,
307 G4double bOmega_0,
308 G4double bOmega_1,
309 G4double bOmega_2,
310 G4double bOmega_3,
311 G4double bOmega_m,
312 G4double bOmega_L) const
313{
314 G4double cross = 0;
315 // Pion
316 cross += ((cPion_3 * tpPion + cPion_2) * tpPion + cPion_1) * tpPion + cPion_m/tmPion + cPion_0 + cPion_L * G4Log(tpPion*tmPion);
317// G4cout << "cross1 "<< cross<<G4endl;
318 // Sigma
319 cross += ((cSigma_3 * tpSigma + cSigma_2) * tpSigma + cSigma_1) * tpSigma + cSigma_m/tmSigma + cSigma_0 + cSigma_L * G4Log(tpSigma*tmSigma);
320// G4cout << "cross2 "<< cross<<G4endl;
321 // Omega
322 cross += ((bOmega_3 * tpOmega + bOmega_2) * tpOmega + bOmega_1) * tpOmega + bOmega_m/tmOmega + bOmega_0 + bOmega_L * G4Log(tpOmega*tmOmega)
323 // Mix
324 + bMix_o1 * (tpOmega - 1.)
325 + bMix_s1 * (tpSigma - 1.)
326 + bMix_Omega * G4Log(tmOmega)
327 + bMix_sm * G4Log(tmSigma)
328 + bMix_oL * G4Log(tpOmega)
329 + bMix_sL * G4Log(tpSigma);
330/* G4cout << "cross3 "<< cross<<" "
331 <<bMix_o1<<" "
332 <<bMix_s1<<" "
333 <<bMix_Omega<<" "
334 <<bMix_sm<<" "
335 <<bMix_oL<<" "
336 <<bMix_sL<<" "
337 <<tpOmega<<" "
338 <<tpSigma<<" "
339 <<tmOmega<<" "
340 <<tmSigma<<" "
341 <<tpOmega<<" "
342 <<tpSigma
343 <<G4endl;
344*/
345 return cross;
346
347}
S
G4double S(G4double temp)
Definition: G4DNAElectronHoleRecombination.cc:76
G4Log
G4double G4Log(G4double x)
Definition: G4Log.hh:227
G4double
double G4double
Definition: G4Types.hh:83
G4bool
bool G4bool
Definition: G4Types.hh:86
G4int
int G4int
Definition: G4Types.hh:85
G4UniformRand
#define G4UniformRand()
Definition: Randomize.hh:52
G4AngularDistribution::G4AngularDistribution
G4AngularDistribution(G4bool symmetrize)
Definition: G4AngularDistribution.cc:34
G4AngularDistribution::CosTheta
virtual G4double CosTheta(G4double s, G4double m1, G4double m2) const
Definition: G4AngularDistribution.cc:170
G4AngularDistribution::Cross
G4double Cross(G4double tpPion, G4double tpSigma, G4double tpOmega, G4double tmPion, G4double tmSigma, G4double tmOmega, G4double bMix_o1, G4double bMix_s1, G4double bMix_Omega, G4double bMix_sm, G4double bMix_oL, G4double bMix_sL, G4double bOmega_0, G4double bOmega_1, G4double bOmega_2, G4double bOmega_3, G4double bOmega_m, G4double bOmega_L) const
Definition: G4AngularDistribution.cc:295
G4AngularDistribution::DifferentialCrossSection
G4double DifferentialCrossSection(G4double sIn, G4double m1, G4double m2, G4double cosTheta) const
Definition: G4AngularDistribution.cc:198
sqr
T sqr(const T &x)
Definition: templates.hh:128