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Reference Guide
zdemo.py
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1## \file
2## \ingroup tutorial_pyroot
3## \notebook
4## This macro is an example of graphs in log scales with annotations.
5##
6## The presented results
7## are predictions of invariant cross-section of Direct Photons produced
8## at RHIC energies, based on the universality of scaling function H(z).
9##
10##
11## These Figures were published in JINR preprint E2-98-64, Dubna,
12## 1998 and submitted to CPC.
13##
14## \macro_image
15## \macro_code
16##
17## \authors Michael Tokarev, Elena Potrebenikova (JINR Dubna)
18
19import ROOT
20from array import array
21
22NMAX = 20
23Z = array( 'f', [0.]*NMAX )
24HZ = array( 'f', [0.]*NMAX )
25PT = array( 'f', [0.]*NMAX )
26INVSIG = array( 'f', [0.]*NMAX )
27
28NLOOP = 0
29saves = {}
30
31#_______________________________________________________________________________
32def hz_calc( ENERG, DENS, TGRAD, PTMIN, PTMAX, DELP ):
33 from math import sin, cos, sqrt
34 global NLOOP
35 global Z, HZ, PT, INVSIG
36
37 CSEFT= 1.
38 GM1 = 0.00001
39 GM2 = 0.00001
40 A1 = 1.
41 A2 = 1.
42 ALX = 2.
43 BETA = 1.
44 KF1 = 8.E-7
45 KF2 = 5.215
46
47 MN = 0.9383
48 DEGRAD=0.01745329
49
50 # print 'ENR= %f DENS= %f PTMIN= %f PTMAX= %f DELP= %f ' % (ENERG,DENS,PTMIN,PTMAX,DELP)
51
52 DNDETA= DENS
53 MB1 = MN*A1
54 MB2 = MN*A2
55 EB1 = ENERG/2.*A1
56 EB2 = ENERG/2.*A2
57 M1 = GM1
58 M2 = GM2
59 THET = TGRAD*DEGRAD
60 NLOOP = int((PTMAX-PTMIN)/DELP)
61
62 for I in range(NLOOP):
63 PT[I]=PTMIN+I*DELP
64 PTOT = PT[I]/sin(THET)
65
66 ETOT = sqrt(M1*M1 + PTOT*PTOT)
67 PB1 = sqrt(EB1*EB1 - MB1*MB1)
68 PB2 = sqrt(EB2*EB2 - MB2*MB2)
69 P2P3 = EB2*ETOT+PB2*PTOT*cos(THET)
70 P1P2 = EB2*EB1+PB2*PB1
71 P1P3 = EB1*ETOT-PB1*PTOT*cos(THET)
72
73 X1 = P2P3/P1P2
74 X2 = P1P3/P1P2
75 Y1 = X1+sqrt(X1*X2*(1.-X1)/(1.-X2))
76 Y2 = X2+sqrt(X1*X2*(1.-X2)/(1.-X1))
77
78 S = (MB1*MB1)+2.*P1P2+(MB2*MB2)
79 SMIN = 4.*((MB1*MB1)*(X1*X1) +2.*X1*X2*P1P2+(MB2*MB2)*(X2*X2))
80 SX1 = 4.*( 2*(MB1*MB1)*X1+2*X2*P1P2)
81 SX2 = 4.*( 2*(MB2*MB2)*X2+2*X1*P1P2)
82 SX1X2= 4.*(2*P1P2)
83 DELM = pow((1.-Y1)*(1.-Y2),ALX)
84
85 Z[I] = sqrt(SMIN)/DELM/pow(DNDETA,BETA)
86
87 Y1X1 = 1. +X2*(1-2.*X1)/(2.*(Y1-X1)*(1.-X2))
88 Y1X2 = X1*(1-X1)/(2.*(Y1-X1)*(1.-X2)*(1.-X2))
89 Y2X1 = X2*(1-X2)/(2.*(Y2-X2)*(1.-X1)*(1.-X1))
90 Y2X2 = 1. +X1*(1-2.*X2)/(2.*(Y2-X2)*(1.-X1))
91 Y2X1X2= Y2X1*( (1.-2.*X2)/(X2*(1-X2)) -( Y2X2-1.)/(Y2-X2))
92 Y1X1X2= Y1X2*( (1.-2.*X1)/(X1*(1-X1)) -( Y1X1-1.)/(Y1-X1))
93
94 KX1=-DELM*(Y1X1*ALX/(1.-Y1) + Y2X1*ALX/(1.-Y2))
95 KX2=-DELM*(Y2X2*ALX/(1.-Y2) + Y1X2*ALX/(1.-Y1))
96 ZX1=Z[I]*(SX1/(2.*SMIN)-KX1/DELM)
97 ZX2=Z[I]*(SX2/(2.*SMIN)-KX2/DELM)
98
99 H1=ZX1*ZX2
100
101 HZ[I]=KF1/pow(Z[I],KF2)
102 INVSIG[I]=(HZ[I]*H1*16.)/S
103
104
105#_______________________________________________________________________________
106def zdemo():
107 from array import array
108 global NLOOP
109 global Z, HZ, PT, INVSIG
110 global saves
111 global hz_calc
112
113 # Create a new canvas.
114 c1 = ROOT.TCanvas( 'zdemo', 'Monte Carlo Study of Z scaling', 10, 40, 800, 600 )
115 c1.Range( 0, 0, 25, 18 )
116 c1.SetFillColor( 40 )
117 saves[ 'c1' ] = c1 # prevent deteletion at end of zdemo
118
119 pl = ROOT.TPaveLabel( 1, 16.3, 24, 17.5,
120 'Z-scaling of Direct Photon Productions in pp Collisions at RHIC Energies', 'br' )
121 pl.SetFillColor(18)
122 pl.SetTextFont(32)
123 pl.SetTextColor(49)
124 pl.Draw()
125 saves[ 'pl' ] = pl
126
127 t = ROOT.TLatex()
128 t.SetTextFont(32)
129 t.SetTextColor(1)
130 t.SetTextSize(0.03)
131 t.SetTextAlign(12)
132 t.DrawLatex( 3.1, 15.5, 'M.Tokarev, E.Potrebenikova ')
133 t.DrawLatex( 14., 15.5, 'JINR preprint E2-98-64, Dubna, 1998 ')
134 saves[ 't' ] = t
135
136 pad1 = ROOT.TPad( 'pad1', 'This is pad1', 0.02, 0.02, 0.48, 0.83, 33 )
137 pad2 = ROOT.TPad( 'pad2', 'This is pad2', 0.52, 0.02, 0.98, 0.83, 33 )
138
139 pad1.Draw()
140 pad2.Draw()
141
142 saves[ 'pad1' ] = pad1; saves[ 'pad2' ] = pad2
143
144 #
145 # Cross-section of direct photon production in pp collisions at 500 GeV vs Pt
146 #
147 energ = 63
148 dens = 1.766
149 tgrad = 90.
150 ptmin = 4.
151 ptmax = 24.
152 delp = 2.
153 hz_calc( energ, dens, tgrad, ptmin, ptmax, delp )
154 pad1.cd()
155 pad1.Range( -0.255174, -19.25, 2.29657, -6.75 )
156 pad1.SetLogx()
157 pad1.SetLogy()
158
159 # create a 2-d histogram to define the range
160 pad1.DrawFrame( 1, 1e-18, 110, 1e-8 )
161 pad1.GetFrame().SetFillColor( 19 )
162 t = ROOT.TLatex()
163 t.SetNDC()
164 t.SetTextFont( 62 )
165 t.SetTextColor( 36 )
166 t.SetTextSize( 0.08 )
167 t.SetTextAlign( 12 )
168 t.DrawLatex( 0.6, 0.85, 'p - p' )
169
170 t.SetTextSize( 0.05 )
171 t.DrawLatex( 0.6, 0.79, 'Direct #gamma' )
172 t.DrawLatex( 0.6, 0.75, '#theta = 90^{o}' )
173
174 t.DrawLatex( 0.20, 0.45, 'Ed^{3}#sigma/dq^{3}' )
175 t.DrawLatex( 0.18, 0.40, '(barn/Gev^{2})' )
176
177 t.SetTextSize( 0.045 )
178 t.SetTextColor( ROOT.kBlue )
179 t.DrawLatex( 0.22, 0.260, '#sqrt{s} = 63(GeV)' )
180 t.SetTextColor( ROOT.kRed )
181 t.DrawLatex( 0.22, 0.205,'#sqrt{s} = 200(GeV)' )
182 t.SetTextColor( 6 )
183 t.DrawLatex( 0.22, 0.15, '#sqrt{s} = 500(GeV)' )
184
185 t.SetTextSize( 0.05 )
186 t.SetTextColor( 1 )
187 t.DrawLatex( 0.6, 0.06, 'q_{T} (Gev/c)' )
188 saves[ 't2' ] = t # note the label that is used!
189
190 gr1 = ROOT.TGraph( NLOOP, PT, INVSIG )
191
192 gr1.SetLineColor( 38 )
193 gr1.SetMarkerColor( ROOT.kBlue )
194 gr1.SetMarkerStyle( 21 )
195 gr1.SetMarkerSize( 1.1 )
196 gr1.Draw( 'LP' )
197 saves[ 'gr1' ] = gr1
198
199 #
200 # Cross-section of direct photon production in pp collisions at 200 GeV vs Pt
201 #
202
203 energ = 200
204 dens = 2.25
205 tgrad = 90.
206 ptmin = 4.
207 ptmax = 64.
208 delp = 6.
209 hz_calc( energ, dens, tgrad, ptmin, ptmax, delp )
210
211 gr2 = ROOT.TGraph( NLOOP, PT, INVSIG )
212 gr2.SetLineColor( 38 )
213 gr2.SetMarkerColor( ROOT.kRed )
214 gr2.SetMarkerStyle( 29 )
215 gr2.SetMarkerSize( 1.5 )
216 gr2.Draw( 'LP' )
217 saves[ 'gr2' ] = gr2
218
219 #
220 # Cross-section of direct photon production in pp collisions at 500 GeV vs Pt
221 #
222 energ = 500
223 dens = 2.73
224 tgrad = 90.
225 ptmin = 4.
226 ptmax = 104.
227 delp = 10.
228 hz_calc( energ, dens, tgrad, ptmin, ptmax, delp )
229
230 gr3 = ROOT.TGraph( NLOOP, PT, INVSIG )
231
232 gr3.SetLineColor( 38 )
233 gr3.SetMarkerColor( 6 )
234 gr3.SetMarkerStyle( 8 )
235 gr3.SetMarkerSize( 1.1 )
236 gr3.Draw( 'LP' )
237 saves[ 'gr3' ] = gr3
238
239 dum = array( 'f', [0.] )
240 graph = ROOT.TGraph( 1, dum, dum )
241 graph.SetMarkerColor( ROOT.kBlue )
242 graph.SetMarkerStyle( 21 )
243 graph.SetMarkerSize( 1.1 )
244 graph.SetPoint( 0, 1.7, 1.e-16 )
245 graph.Draw( 'LP' )
246 saves[ 'graph' ] = graph
247
248 graph = ROOT.TGraph( 1, dum, dum )
249 graph.SetMarkerColor( ROOT.kRed )
250 graph.SetMarkerStyle( 29 )
251 graph.SetMarkerSize( 1.5 )
252 graph.SetPoint( 0, 1.7, 2.e-17 )
253 graph.Draw( 'LP' )
254 saves[ 'graph2' ] = graph # note the label that is used!
255
256 graph = ROOT.TGraph( 1, dum, dum )
257 graph.SetMarkerColor( 6 )
258 graph.SetMarkerStyle( 8 )
259 graph.SetMarkerSize( 1.1 )
260 graph.SetPoint( 0, 1.7, 4.e-18)
261 graph.Draw( 'LP' )
262 saves[ 'graph3' ] = graph # note the label that is used!
263
264 pad2.cd()
265 pad2.Range( -0.43642, -23.75, 3.92778, -6.25 )
266 pad2.SetLogx()
267 pad2.SetLogy()
268
269 pad2.DrawFrame( 1, 1e-22, 3100, 1e-8 )
270 pad2.GetFrame().SetFillColor( 19 )
271
272 gr = ROOT.TGraph( NLOOP, Z, HZ )
273 gr.SetTitle( 'HZ vs Z' )
274 gr.SetFillColor( 19 )
275 gr.SetLineColor( 9 )
276 gr.SetMarkerColor( 50 )
277 gr.SetMarkerStyle( 29 )
278 gr.SetMarkerSize( 1.5 )
279 gr.Draw( 'LP' )
280 saves[ 'gr' ] = gr
281
282 t = ROOT.TLatex()
283 t.SetNDC()
284 t.SetTextFont( 62 )
285 t.SetTextColor( 36 )
286 t.SetTextSize( 0.08 )
287 t.SetTextAlign( 12 )
288 t.DrawLatex( 0.6, 0.85, 'p - p' )
289
290 t.SetTextSize( 0.05 )
291 t.DrawLatex( 0.6, 0.79, 'Direct #gamma' )
292 t.DrawLatex( 0.6, 0.75, '#theta = 90^{o}' )
293
294 t.DrawLatex( 0.70, 0.55, 'H(z)' )
295 t.DrawLatex( 0.68, 0.50, '(barn)' )
296
297 t.SetTextSize( 0.045 )
298 t.SetTextColor( 46 )
299 t.DrawLatex( 0.20, 0.30, '#sqrt{s}, GeV' )
300 t.DrawLatex( 0.22, 0.26, '63' )
301 t.DrawLatex( 0.22, 0.22, '200' )
302 t.DrawLatex( 0.22, 0.18, '500' )
303
304 t.SetTextSize( 0.05 )
305 t.SetTextColor( 1 )
306 t.DrawLatex( 0.88, 0.06, 'z' )
307 saves[ 't3' ] = t # note the label that is used!
308
309 c1.Modified()
310 c1.Update()
311
312
313if __name__ == '__main__': # run if loaded as script
314 zdemo()
double cos(double)
double pow(double, double)
double sqrt(double)
double sin(double)
h1 SetFillColor(kGreen)
Definition: zdemo.py:1