source: fact/tools/pyscripts/pyfact/image_extractors.py@ 13389

Last change on this file since 13389 was 13299, checked in by neise, 13 years ago
removed debug print out
  • Property svn:executable set to *
File size: 5.6 KB
Line 
1#!/usr/bin/python -tt
2#
3# Dominik Neise
4# TU Dortmund
5#
6from coor import Coordinator
7import numpy as np
8from euclid import Vector2
9import sys
10
11class SimpleArea(object):
12 """ Calculate Hillas Area in simple way.
13 Sum up the number of pixels, which survived the cleaning.
14 The unit is [Number of Pixel]
15 """
16 def __init__(self):
17 # I don't know, if classes, which need no initialization
18 # do still need an empty __init__ func....
19 pass
20
21 def __call__(self, survivors):
22 return len(survivors)
23
24class SimpleSize(object):
25 """ Calculate Hillas Size in a very simple way
26 Sum up the 'amplitude'-like value, for each survivor
27 """
28 def __init__(self):
29 # I don't know, if classes, which need no initialization
30 # do still need an empty __init__ func....
31 pass
32
33 def __call__(self, survivors, amplitude):
34 size = 0
35 for pixel in survivors:
36 size += amplitude[pixel]
37 return size
38
39class HillasParameter(object):
40 """ Calculate Hillas Parameters
41 http://magic.mppmu.mpg.de/publications/theses/TBretz.pdf p.42
42
43 """
44 def __init__(self, source_pos = (0,0)):
45 self.coordinator = Coordinator()
46 self._chid2coor = self.coordinator.chid2coor_np
47 self.source_pos = source_pos
48
49 def __call__(self, survivors, amplitude):
50 self.survivors = survivors
51 self.amplitude = amplitude
52
53 self._CalculateSize()
54 self._CalculateCOG()
55 self._CalculateHillas()
56
57 return self.__dict__
58
59 def _CalculateSize(self):
60 # shortcuts
61 survivors = self.survivors
62 amplitude = self.amplitude
63 size = 0
64 for pixel in survivors:
65 size += amplitude[pixel]
66
67 self.size = size
68 return size
69
70 def _CalculateCOG(self):
71 # shortcuts
72 survivors = self.survivors
73 amplitude = self.amplitude
74 chid2coor = self._chid2coor
75 center = self.coordinator.center
76 ex = np.array(self.coordinator.ex)
77 ey = np.array(self.coordinator.ey)
78
79 cog = np.zeros(2)
80 for chid in survivors:
81 cog += chid2coor[chid] * amplitude[chid]
82 cog /= self.size
83 self.cog = cog
84 #print 'debug-COG=',cog, 'in hex coordinates'
85 cog_euc = cog[0] * ex + cog[1] * ey + center
86 self.cog_euc = cog_euc
87 #print 'debug-COG=', cog_euc, 'in euclidic coordinates'
88 return cog, cog_euc
89
90
91 def _CalculateHillas(self):
92 """ calculates Hillas parameters as explained in TBs dissertation on page: 42
93 """
94 # define a few shortcuts
95 survivors = self.survivors
96 amplitude = self.amplitude
97 chid2coor = self._chid2coor
98 cog_euc = self.cog_euc
99 S = self.size
100 center = self.coordinator.center
101 ex = np.array(self.coordinator.ex)
102 ey = np.array(self.coordinator.ey)
103 source_pos = self.source_pos
104
105 # calculate matrix elements
106
107 Mxx = 0.
108 Myy = 0.
109 Mxy = 0.
110 for pixel in survivors:
111 # hex coordinates
112 coor = chid2coor[pixel]
113 # make euclidic coordinates
114 coor = coor[0] * ex + coor[1] * ey + center
115 rel_coor = coor - cog_euc
116
117
118 mxx = rel_coor[0] * rel_coor[0] * amplitude[pixel]
119 mxy = rel_coor[0] * rel_coor[1] * amplitude[pixel]
120 myy = rel_coor[1] * rel_coor[1] * amplitude[pixel]
121
122 Mxx += mxx
123 Myy += myy
124 Mxy += mxy
125 self.Mxx = Mxx
126 self.Mxy = Mxy
127 self.Myy = Myy
128
129
130 # use the covariance matrix to calulate the number TB also cals in his thesis
131 radicand = (Myy-Mxx)**2 + 4*Mxy**2
132 k = np.sqrt(radicand) + (Myy - Mxx)
133 self.k = k
134 tan_delta = k / (2*Mxy )
135 if tan_delta > 0:
136 delta_in_rad = np.arctan ( tan_delta )
137 else:
138 delta_in_rad = np.arctan ( tan_delta ) + np.pi
139 delta_in_deg = delta_in_rad / np.pi * 180
140 #print 'delta_in_rad' , delta_in_rad
141 #print 'delta_in_deg' , delta_in_deg
142 self.delta = delta_in_rad
143
144 # width
145 numerator = Mxx*tan_delta**2 - k + Myy
146 denominiator = (tan_delta**2 + 1) * S
147 width = np.sqrt(numerator / denominiator)
148 self.width = width
149
150 #length
151 numerator = Myy*tan_delta**2 + k + Mxx
152 denominiator = (tan_delta**2 + 1) * S
153 length = np.sqrt(numerator / denominiator)
154 self.length = length
155
156 # make strange rotation matrix .. called capital R in TBs diss
157 # shortcut
158 d = delta_in_rad
159 R = np.array( ((np.cos(d), np.sin(d)),(-np.sin(d), np.cos(d))) )
160 self.R = R
161 # calculate vector v between COG of shower and source position
162 # currently I don't know the cource position, so I use the center of the camera
163
164 v = cog_euc - source_pos
165 # and calculate some strange vertor r = R v
166 r = (R*v).sum(axis=1)
167 #print 'r',r
168 self.v = v
169 self.r = r
170 #dist
171 dist = np.sqrt( v[0]**2 + v[1]**2 )
172 self.dist = dist
173 #print 'dist', dist
174
175 #alpha
176 alpha = np.arcsin( r[1] / dist)
177 alpha_in_deg = alpha / np.pi * 180
178 self.alpha = alpha
179 #print 'alpha', alpha
180 #print 'alpha_in_deg ', alpha_in_deg
181
182 area = np.pi * width * length
183 self.area = area
184
185if __name__ == '__main__':
186 """ no tests yet """
187 print 'no test implemented yet'
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