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