1 | """ |
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2 | This object is a small tool to allow user to quickly |
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3 | determine the variance in q from the |
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4 | instrumental parameters. |
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5 | """ |
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6 | from instrument import Sample |
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7 | from instrument import Detector |
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8 | from instrument import TOF as Neutron |
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9 | from instrument import Aperture |
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10 | # import math stuffs |
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11 | from math import pi |
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12 | from math import sqrt |
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13 | import math |
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14 | import numpy |
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15 | import sys |
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16 | import logging |
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17 | |
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18 | #Plank's constant in cgs unit |
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19 | _PLANK_H = 6.62606896E-27 |
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20 | #Gravitational acc. in cgs unit |
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21 | _GRAVITY = 981.0 |
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22 | |
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23 | |
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24 | class ResolutionCalculator(object): |
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25 | """ |
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26 | compute resolution in 2D |
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27 | """ |
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28 | def __init__(self): |
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29 | |
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30 | # wavelength |
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31 | self.wave = Neutron() |
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32 | # sample |
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33 | self.sample = Sample() |
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34 | # aperture |
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35 | self.aperture = Aperture() |
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36 | # detector |
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37 | self.detector = Detector() |
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38 | # 2d image of the resolution |
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39 | self.image = [] |
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40 | self.image_lam = [] |
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41 | # resolutions |
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42 | # lamda in r-direction |
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43 | self.sigma_lamd = 0 |
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44 | # x-dir (no lamda) |
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45 | self.sigma_1 = 0 |
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46 | #y-dir (no lamda) |
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47 | self.sigma_2 = 0 |
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48 | # 1D total |
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49 | self.sigma_1d = 0 |
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50 | self.gravity_phi = None |
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51 | # q min and max |
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52 | self.qx_min = -0.3 |
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53 | self.qx_max = 0.3 |
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54 | self.qy_min = -0.3 |
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55 | self.qy_max = 0.3 |
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56 | # q min and max of the detector |
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57 | self.detector_qx_min = -0.3 |
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58 | self.detector_qx_max = 0.3 |
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59 | self.detector_qy_min = -0.3 |
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60 | self.detector_qy_max = 0.3 |
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61 | # possible max qrange |
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62 | self.qxmin_limit = 0 |
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63 | self.qxmax_limit = 0 |
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64 | self.qymin_limit = 0 |
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65 | self.qymax_limit = 0 |
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66 | |
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67 | # plots |
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68 | self.plot = None |
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69 | # instrumental params defaults |
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70 | self.mass = 0 |
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71 | self.intensity = 0 |
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72 | self.wavelength = 0 |
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73 | self.wavelength_spread = 0 |
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74 | self.source_aperture_size = [] |
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75 | self.source2sample_distance = [] |
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76 | self.sample2sample_distance = [] |
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77 | self.sample_aperture_size = [] |
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78 | self.sample2detector_distance = [] |
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79 | self.detector_pix_size = [] |
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80 | self.detector_size = [] |
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81 | self.get_all_instrument_params() |
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82 | # max q range for all lambdas |
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83 | self.qxrange = [] |
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84 | self.qyrange = [] |
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85 | |
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86 | def compute_and_plot(self, qx_value, qy_value, qx_min, qx_max, |
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87 | qy_min, qy_max, coord='cartesian'): |
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88 | """ |
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89 | Compute the resolution |
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90 | : qx_value: x component of q |
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91 | : qy_value: y component of q |
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92 | """ |
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93 | # make sure to update all the variables need. |
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94 | # except lambda, dlambda, and intensity |
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95 | self.get_all_instrument_params() |
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96 | # wavelength etc. |
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97 | lamda_list, dlamb_list = self.get_wave_list() |
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98 | intens_list = [] |
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99 | sig1_list = [] |
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100 | sig2_list = [] |
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101 | sigr_list = [] |
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102 | sigma1d_list = [] |
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103 | num_lamda = len(lamda_list) |
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104 | for num in range(num_lamda): |
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105 | lam = lamda_list[num] |
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106 | # wavelength spread |
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107 | dlam = dlamb_list[num] |
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108 | intens = self.setup_tof(lam, dlam) |
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109 | intens_list.append(intens) |
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110 | # cehck if tof |
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111 | if num_lamda > 1: |
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112 | tof = True |
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113 | else: |
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114 | tof = False |
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115 | # compute 2d resolution |
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116 | _, _, sigma_1, sigma_2, sigma_r, sigma1d = \ |
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117 | self.compute(lam, dlam, qx_value, qy_value, coord, tof) |
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118 | # make image |
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119 | image = self.get_image(qx_value, qy_value, sigma_1, sigma_2, |
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120 | sigma_r, qx_min, qx_max, qy_min, qy_max, |
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121 | coord, False) |
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122 | if qx_min > self.qx_min: |
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123 | qx_min = self.qx_min |
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124 | if qx_max < self.qx_max: |
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125 | qx_max = self.qx_max |
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126 | if qy_min > self.qy_min: |
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127 | qy_min = self.qy_min |
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128 | if qy_max < self.qy_max: |
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129 | qy_max = self.qy_max |
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130 | |
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131 | # set max qranges |
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132 | self.qxrange = [qx_min, qx_max] |
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133 | self.qyrange = [qy_min, qy_max] |
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134 | sig1_list.append(sigma_1) |
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135 | sig2_list.append(sigma_2) |
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136 | sigr_list.append(sigma_r) |
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137 | sigma1d_list.append(sigma1d) |
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138 | # redraw image in global 2d q-space. |
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139 | self.image_lam = [] |
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140 | total_intensity = 0 |
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141 | sigma_1 = 0 |
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142 | sigma_r = 0 |
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143 | sigma_2 = 0 |
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144 | sigma1d = 0 |
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145 | for ind in range(num_lamda): |
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146 | lam = lamda_list[ind] |
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147 | dlam = dlamb_list[ind] |
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148 | intens = self.setup_tof(lam, dlam) |
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149 | out = self.get_image(qx_value, qy_value, sig1_list[ind], |
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150 | sig2_list[ind], sigr_list[ind], |
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151 | qx_min, qx_max, qy_min, qy_max, coord) |
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152 | # this is the case of q being outside the detector |
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153 | #if numpy.all(out==0.0): |
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154 | # continue |
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155 | image = out |
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156 | # set variance as sigmas |
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157 | sigma_1 += sig1_list[ind] * sig1_list[ind] * self.intensity |
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158 | sigma_r += sigr_list[ind] * sigr_list[ind] * self.intensity |
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159 | sigma_2 += sig2_list[ind] * sig2_list[ind] * self.intensity |
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160 | sigma1d += sigma1d_list[ind] * sigma1d_list[ind] * self.intensity |
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161 | total_intensity += self.intensity |
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162 | |
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163 | if total_intensity != 0: |
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164 | # average variance |
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165 | image_out = image / total_intensity |
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166 | sigma_1 = sigma_1 / total_intensity |
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167 | sigma_r = sigma_r / total_intensity |
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168 | sigma_2 = sigma_2 / total_intensity |
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169 | sigma1d = sigma1d / total_intensity |
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170 | # set sigmas |
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171 | self.sigma_1 = sqrt(sigma_1) |
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172 | self.sigma_lamd = sqrt(sigma_r) |
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173 | self.sigma_2 = sqrt(sigma_2) |
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174 | self.sigma_1d = sqrt(sigma1d) |
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175 | # rescale |
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176 | max_im_val = 1 |
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177 | if max_im_val > 0: |
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178 | image_out /= max_im_val |
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179 | else: |
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180 | image_out = image * 0.0 |
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181 | # Don't calculate sigmas nor set self.sigmas! |
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182 | sigma_1 = 0 |
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183 | sigma_r = 0 |
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184 | sigma_2 = 0 |
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185 | sigma1d = 0 |
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186 | if len(self.image) > 0: |
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187 | self.image += image_out |
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188 | else: |
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189 | self.image = image_out |
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190 | |
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191 | # plot image |
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192 | return self.plot_image(self.image) |
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193 | |
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194 | def setup_tof(self, wavelength, wavelength_spread): |
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195 | """ |
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196 | Setup all parameters in instrument |
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197 | |
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198 | : param ind: index of lambda, etc |
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199 | """ |
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200 | |
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201 | # set wave.wavelength |
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202 | self.set_wavelength(wavelength) |
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203 | self.set_wavelength_spread(wavelength_spread) |
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204 | self.intensity = self.wave.get_intensity() |
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205 | |
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206 | if wavelength == 0: |
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207 | msg = "Can't compute the resolution: the wavelength is zero..." |
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208 | raise RuntimeError, msg |
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209 | return self.intensity |
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210 | |
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211 | def compute(self, wavelength, wavelength_spread, qx_value, qy_value, |
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212 | coord='cartesian', tof=False): |
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213 | """ |
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214 | Compute the Q resoltuion in || and + direction of 2D |
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215 | : qx_value: x component of q |
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216 | : qy_value: y component of q |
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217 | """ |
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218 | coord = 'cartesian' |
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219 | lamb = wavelength |
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220 | lamb_spread = wavelength_spread |
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221 | # the shape of wavelength distribution |
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222 | |
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223 | if tof: |
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224 | # rectangular |
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225 | tof_factor = 2 |
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226 | else: |
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227 | # triangular |
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228 | tof_factor = 1 |
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229 | # Find polar values |
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230 | qr_value, phi = self._get_polar_value(qx_value, qy_value) |
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231 | # vacuum wave transfer |
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232 | knot = 2*pi/lamb |
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233 | # scattering angle theta; always true for plane detector |
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234 | # aligned vertically to the ko direction |
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235 | if qr_value > knot: |
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236 | theta = pi/2 |
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237 | else: |
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238 | theta = math.asin(qr_value/knot) |
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239 | # source aperture size |
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240 | rone = self.source_aperture_size |
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241 | # sample aperture size |
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242 | rtwo = self.sample_aperture_size |
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243 | # detector pixel size |
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244 | rthree = self.detector_pix_size |
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245 | # source to sample(aperture) distance |
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246 | l_ssa = self.source2sample_distance[0] |
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247 | # sample(aperture) to detector distance |
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248 | l_sad = self.sample2detector_distance[0] |
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249 | # sample (aperture) to sample distance |
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250 | l_sas = self.sample2sample_distance[0] |
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251 | # source to sample distance |
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252 | l_one = l_ssa + l_sas |
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253 | # sample to detector distance |
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254 | l_two = l_sad - l_sas |
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255 | |
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256 | # Sample offset correction for l_one and Lp on variance calculation |
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257 | l1_cor = (l_ssa * l_two) / (l_sas + l_two) |
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258 | lp_cor = (l_ssa * l_two) / (l_one + l_two) |
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259 | # the radial distance to the pixel from the center of the detector |
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260 | radius = math.tan(theta) * l_two |
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261 | #Lp = l_one*l_two/(l_one+l_two) |
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262 | # default polar coordinate |
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263 | comp1 = 'radial' |
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264 | comp2 = 'phi' |
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265 | # in the case of the cartesian coordinate |
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266 | if coord == 'cartesian': |
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267 | comp1 = 'x' |
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268 | comp2 = 'y' |
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269 | |
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270 | # sigma in the radial/x direction |
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271 | # for source aperture |
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272 | sigma_1 = self.get_variance(rone, l1_cor, phi, comp1) |
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273 | # for sample apperture |
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274 | sigma_1 += self.get_variance(rtwo, lp_cor, phi, comp1) |
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275 | # for detector pix |
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276 | sigma_1 += self.get_variance(rthree, l_two, phi, comp1) |
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277 | # for gravity term for 1d |
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278 | sigma_1grav1d = self.get_variance_gravity(l_ssa, l_sad, lamb, |
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279 | lamb_spread, phi, comp1, 'on') / tof_factor |
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280 | # for wavelength spread |
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281 | # reserve for 1d calculation |
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282 | A_value = self._cal_A_value(lamb, l_ssa, l_sad) |
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283 | sigma_wave_1, sigma_wave_1_1d = self.get_variance_wave(A_value, |
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284 | radius, l_two, lamb_spread, |
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285 | phi, 'radial', 'on') |
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286 | sigma_wave_1 /= tof_factor |
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287 | sigma_wave_1_1d /= tof_factor |
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288 | # for 1d |
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289 | variance_1d_1 = (sigma_1 + sigma_1grav1d) / 2 + sigma_wave_1_1d |
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290 | # normalize |
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291 | variance_1d_1 = knot * knot * variance_1d_1 / 12 |
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292 | |
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293 | # for 2d |
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294 | #sigma_1 += sigma_wave_1 |
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295 | # normalize |
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296 | sigma_1 = knot * sqrt(sigma_1 / 12) |
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297 | sigma_r = knot * sqrt(sigma_wave_1 / (tof_factor *12)) |
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298 | # sigma in the phi/y direction |
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299 | # for source apperture |
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300 | sigma_2 = self.get_variance(rone, l1_cor, phi, comp2) |
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301 | |
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302 | # for sample apperture |
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303 | sigma_2 += self.get_variance(rtwo, lp_cor, phi, comp2) |
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304 | |
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305 | # for detector pix |
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306 | sigma_2 += self.get_variance(rthree, l_two, phi, comp2) |
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307 | |
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308 | # for gravity term for 1d |
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309 | sigma_2grav1d = self.get_variance_gravity(l_ssa, l_sad, lamb, |
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310 | lamb_spread, phi, comp2, 'on') / tof_factor |
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311 | |
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312 | # for wavelength spread |
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313 | # reserve for 1d calculation |
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314 | sigma_wave_2, sigma_wave_2_1d = self.get_variance_wave(A_value, |
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315 | radius, l_two, lamb_spread, |
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316 | phi, 'phi', 'on') |
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317 | sigma_wave_2 /= tof_factor |
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318 | sigma_wave_2_1d /= tof_factor |
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319 | # for 1d |
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320 | variance_1d_2 = (sigma_2 + sigma_2grav1d) / 2 + sigma_wave_2_1d |
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321 | # normalize |
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322 | variance_1d_2 = knot * knot * variance_1d_2 / 12 |
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323 | |
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324 | # for 2d |
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325 | #sigma_2 = knot*sqrt(sigma_2/12) |
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326 | #sigma_2 += sigma_wave_2 |
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327 | # normalize |
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328 | sigma_2 = knot * sqrt(sigma_2 / 12) |
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329 | sigma1d = sqrt(variance_1d_1 + variance_1d_2) |
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330 | # set sigmas |
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331 | self.sigma_1 = sigma_1 |
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332 | self.sigma_lamd = sigma_r |
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333 | self.sigma_2 = sigma_2 |
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334 | self.sigma_1d = sigma1d |
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335 | return qr_value, phi, sigma_1, sigma_2, sigma_r, sigma1d |
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336 | |
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337 | def _within_detector_range(self, qx_value, qy_value): |
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338 | """ |
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339 | check if qvalues are within detector range |
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340 | """ |
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341 | # detector range |
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342 | detector_qx_min = self.detector_qx_min |
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343 | detector_qx_max = self.detector_qx_max |
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344 | detector_qy_min = self.detector_qy_min |
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345 | detector_qy_max = self.detector_qy_max |
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346 | if self.qxmin_limit > detector_qx_min: |
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347 | self.qxmin_limit = detector_qx_min |
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348 | if self.qxmax_limit < detector_qx_max: |
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349 | self.qxmax_limit = detector_qx_max |
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350 | if self.qymin_limit > detector_qy_min: |
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351 | self.qymin_limit = detector_qy_min |
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352 | if self.qymax_limit < detector_qy_max: |
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353 | self.qymax_limit = detector_qy_max |
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354 | if qx_value < detector_qx_min or qx_value > detector_qx_max: |
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355 | return False |
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356 | if qy_value < detector_qy_min or qy_value > detector_qy_max: |
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357 | return False |
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358 | return True |
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359 | |
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360 | def get_image(self, qx_value, qy_value, sigma_1, sigma_2, sigma_r, |
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361 | qx_min, qx_max, qy_min, qy_max, |
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362 | coord='cartesian', full_cal=True): |
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363 | """ |
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364 | Get the resolution in polar coordinate ready to plot |
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365 | : qx_value: qx_value value |
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366 | : qy_value: qy_value value |
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367 | : sigma_1: variance in r direction |
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368 | : sigma_2: variance in phi direction |
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369 | : coord: coordinate system of image, 'polar' or 'cartesian' |
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370 | """ |
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371 | # Get qx_max and qy_max... |
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372 | self._get_detector_qxqy_pixels() |
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373 | |
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374 | qr_value, phi = self._get_polar_value(qx_value, qy_value) |
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375 | |
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376 | # Check whether the q value is within the detector range |
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377 | if qx_min < self.qx_min: |
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378 | self.qx_min = qx_min |
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379 | #raise ValueError, msg |
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380 | if qx_max > self.qx_max: |
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381 | self.qx_max = qx_max |
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382 | #raise ValueError, msg |
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383 | if qy_min < self.qy_min: |
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384 | self.qy_min = qy_min |
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385 | #raise ValueError, msg |
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386 | if qy_max > self.qy_max: |
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387 | self.qy_max = qy_max |
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388 | #raise ValueError, msg |
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389 | if not full_cal: |
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390 | return None |
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391 | |
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392 | # Make an empty graph in the detector scale |
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393 | dx_size = (self.qx_max - self.qx_min) / (1000 - 1) |
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394 | dy_size = (self.qy_max - self.qy_min) / (1000 - 1) |
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395 | x_val = numpy.arange(self.qx_min, self.qx_max, dx_size) |
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396 | y_val = numpy.arange(self.qy_max, self.qy_min, -dy_size) |
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397 | q_1, q_2 = numpy.meshgrid(x_val, y_val) |
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398 | #q_phi = numpy.arctan(q_1,q_2) |
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399 | # check whether polar or cartesian |
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400 | if coord == 'polar': |
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401 | # Find polar values |
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402 | qr_value, phi = self._get_polar_value(qx_value, qy_value) |
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403 | q_1, q_2 = self._rotate_z(q_1, q_2, phi) |
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404 | qc_1 = qr_value |
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405 | qc_2 = 0.0 |
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406 | # Calculate the 2D Gaussian distribution image |
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407 | image = self._gaussian2d_polar(q_1, q_2, qc_1, qc_2, |
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408 | sigma_1, sigma_2, sigma_r) |
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409 | else: |
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410 | # catesian coordinate |
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411 | # qx_center |
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412 | qc_1 = qx_value |
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413 | # qy_center |
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414 | qc_2 = qy_value |
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415 | |
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416 | # Calculate the 2D Gaussian distribution image |
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417 | image = self._gaussian2d(q_1, q_2, qc_1, qc_2, |
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418 | sigma_1, sigma_2, sigma_r) |
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419 | # out side of detector |
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420 | if not self._within_detector_range(qx_value, qy_value): |
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421 | image *= 0.0 |
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422 | self.intensity = 0.0 |
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423 | #return self.image |
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424 | |
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425 | # Add it if there are more than one inputs. |
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426 | if len(self.image_lam) > 0: |
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427 | self.image_lam += image * self.intensity |
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428 | else: |
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429 | self.image_lam = image * self.intensity |
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430 | |
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431 | return self.image_lam |
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432 | |
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433 | def plot_image(self, image): |
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434 | """ |
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435 | Plot image using pyplot |
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436 | : image: 2d resolution image |
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437 | |
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438 | : return plt: pylab object |
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439 | """ |
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440 | import matplotlib.pyplot as plt |
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441 | |
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442 | self.plot = plt |
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443 | plt.xlabel('$\\rm{Q}_{x} [A^{-1}]$') |
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444 | plt.ylabel('$\\rm{Q}_{y} [A^{-1}]$') |
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445 | # Max value of the image |
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446 | # max = numpy.max(image) |
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447 | qx_min, qx_max, qy_min, qy_max = self.get_detector_qrange() |
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448 | |
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449 | # Image |
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450 | im = plt.imshow(image, |
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451 | extent=[qx_min, qx_max, qy_min, qy_max]) |
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452 | |
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453 | # bilinear interpolation to make it smoother |
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454 | im.set_interpolation('bilinear') |
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455 | |
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456 | return plt |
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457 | |
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458 | def reset_image(self): |
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459 | """ |
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460 | Reset image to default (=[]) |
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461 | """ |
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462 | self.image = [] |
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463 | |
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464 | def get_variance(self, size=[], distance=0, phi=0, comp='radial'): |
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465 | """ |
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466 | Get the variance when the slit/pinhole size is given |
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467 | : size: list that can be one(diameter for circular) or two components(lengths for rectangular) |
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468 | : distance: [z, x] where z along the incident beam, x // qx_value |
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469 | : comp: direction of the sigma; can be 'phi', 'y', 'x', and 'radial' |
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470 | |
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471 | : return variance: sigma^2 |
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472 | """ |
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473 | # check the length of size (list) |
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474 | len_size = len(size) |
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475 | |
---|
476 | # define sigma component direction |
---|
477 | if comp == 'radial': |
---|
478 | phi_x = math.cos(phi) |
---|
479 | phi_y = math.sin(phi) |
---|
480 | elif comp == 'phi': |
---|
481 | phi_x = math.sin(phi) |
---|
482 | phi_y = math.cos(phi) |
---|
483 | elif comp == 'x': |
---|
484 | phi_x = 1 |
---|
485 | phi_y = 0 |
---|
486 | elif comp == 'y': |
---|
487 | phi_x = 0 |
---|
488 | phi_y = 1 |
---|
489 | else: |
---|
490 | phi_x = 0 |
---|
491 | phi_y = 0 |
---|
492 | # calculate each component |
---|
493 | # for pinhole w/ radius = size[0]/2 |
---|
494 | if len_size == 1: |
---|
495 | x_comp = (0.5 * size[0]) * sqrt(3) |
---|
496 | y_comp = 0 |
---|
497 | # for rectangular slit |
---|
498 | elif len_size == 2: |
---|
499 | x_comp = size[0] * phi_x |
---|
500 | y_comp = size[1] * phi_y |
---|
501 | # otherwise |
---|
502 | else: |
---|
503 | raise ValueError, " Improper input..." |
---|
504 | # get them squared |
---|
505 | sigma = x_comp * x_comp |
---|
506 | sigma += y_comp * y_comp |
---|
507 | # normalize by distance |
---|
508 | sigma /= (distance * distance) |
---|
509 | |
---|
510 | return sigma |
---|
511 | |
---|
512 | def get_variance_wave(self, A_value, radius, distance, spread, phi, |
---|
513 | comp='radial', switch='on'): |
---|
514 | """ |
---|
515 | Get the variance when the wavelength spread is given |
---|
516 | |
---|
517 | : radius: the radial distance from the beam center to the pix of q |
---|
518 | : distance: sample to detector distance |
---|
519 | : spread: wavelength spread (ratio) |
---|
520 | : comp: direction of the sigma; can be 'phi', 'y', 'x', and 'radial' |
---|
521 | |
---|
522 | : return variance: sigma^2 for 2d, sigma^2 for 1d [tuple] |
---|
523 | """ |
---|
524 | if switch.lower() == 'off': |
---|
525 | return 0, 0 |
---|
526 | # check the singular point |
---|
527 | if distance == 0 or comp == 'phi': |
---|
528 | return 0, 0 |
---|
529 | else: |
---|
530 | # calculate sigma^2 for 1d |
---|
531 | sigma1d = 2 * math.pow(radius/distance*spread, 2) |
---|
532 | if comp == 'x': |
---|
533 | sigma1d *= (math.cos(phi)*math.cos(phi)) |
---|
534 | elif comp == 'y': |
---|
535 | sigma1d *= (math.sin(phi)*math.sin(phi)) |
---|
536 | else: |
---|
537 | sigma1d *= 1 |
---|
538 | # sigma^2 for 2d |
---|
539 | # shift the coordinate due to the gravitational shift |
---|
540 | rad_x = radius * math.cos(phi) |
---|
541 | rad_y = A_value - radius * math.sin(phi) |
---|
542 | radius = math.sqrt(rad_x * rad_x + rad_y * rad_y) |
---|
543 | # new phi |
---|
544 | phi = math.atan2(-rad_y, rad_x) |
---|
545 | self.gravity_phi = phi |
---|
546 | # calculate sigma^2 |
---|
547 | sigma = 2 * math.pow(radius/distance*spread, 2) |
---|
548 | if comp == 'x': |
---|
549 | sigma *= (math.cos(phi)*math.cos(phi)) |
---|
550 | elif comp == 'y': |
---|
551 | sigma *= (math.sin(phi)*math.sin(phi)) |
---|
552 | else: |
---|
553 | sigma *= 1 |
---|
554 | |
---|
555 | return sigma, sigma1d |
---|
556 | |
---|
557 | def get_variance_gravity(self, s_distance, d_distance, wavelength, spread, |
---|
558 | phi, comp='radial', switch='on'): |
---|
559 | """ |
---|
560 | Get the variance from gravity when the wavelength spread is given |
---|
561 | |
---|
562 | : s_distance: source to sample distance |
---|
563 | : d_distance: sample to detector distance |
---|
564 | : wavelength: wavelength |
---|
565 | : spread: wavelength spread (ratio) |
---|
566 | : comp: direction of the sigma; can be 'phi', 'y', 'x', and 'radial' |
---|
567 | |
---|
568 | : return variance: sigma^2 |
---|
569 | """ |
---|
570 | if switch.lower() == 'off': |
---|
571 | return 0 |
---|
572 | if self.mass == 0.0: |
---|
573 | return 0 |
---|
574 | # check the singular point |
---|
575 | if d_distance == 0 or comp == 'x': |
---|
576 | return 0 |
---|
577 | else: |
---|
578 | a_value = self._cal_A_value(None, s_distance, d_distance) |
---|
579 | # calculate sigma^2 |
---|
580 | sigma = math.pow(a_value / d_distance, 2) |
---|
581 | sigma *= math.pow(wavelength, 4) |
---|
582 | sigma *= math.pow(spread, 2) |
---|
583 | sigma *= 8 |
---|
584 | return sigma |
---|
585 | |
---|
586 | def _cal_A_value(self, lamda, s_distance, d_distance): |
---|
587 | """ |
---|
588 | Calculate A value for gravity |
---|
589 | |
---|
590 | : s_distance: source to sample distance |
---|
591 | : d_distance: sample to detector distance |
---|
592 | """ |
---|
593 | # neutron mass in cgs unit |
---|
594 | self.mass = self.get_neutron_mass() |
---|
595 | # plank constant in cgs unit |
---|
596 | h_constant = _PLANK_H |
---|
597 | # gravity in cgs unit |
---|
598 | gravy = _GRAVITY |
---|
599 | # m/h |
---|
600 | m_over_h = self.mass / h_constant |
---|
601 | # A value |
---|
602 | a_value = d_distance * (s_distance + d_distance) |
---|
603 | a_value *= math.pow(m_over_h / 2, 2) |
---|
604 | a_value *= gravy |
---|
605 | # unit correction (1/cm to 1/A) for A and d_distance below |
---|
606 | a_value *= 1.0E-16 |
---|
607 | # if lamda is give (broad meanning of A) return 2* lamda^2 * A |
---|
608 | if lamda != None: |
---|
609 | a_value *= (4 * lamda * lamda) |
---|
610 | return a_value |
---|
611 | |
---|
612 | def get_intensity(self): |
---|
613 | """ |
---|
614 | Get intensity |
---|
615 | """ |
---|
616 | return self.wave.intensity |
---|
617 | |
---|
618 | def get_wavelength(self): |
---|
619 | """ |
---|
620 | Get wavelength |
---|
621 | """ |
---|
622 | return self.wave.wavelength |
---|
623 | |
---|
624 | def get_default_spectrum(self): |
---|
625 | """ |
---|
626 | Get default_spectrum |
---|
627 | """ |
---|
628 | return self.wave.get_default_spectrum() |
---|
629 | |
---|
630 | def get_spectrum(self): |
---|
631 | """ |
---|
632 | Get _spectrum |
---|
633 | """ |
---|
634 | return self.wave.get_spectrum() |
---|
635 | |
---|
636 | def get_wavelength_spread(self): |
---|
637 | """ |
---|
638 | Get wavelength spread |
---|
639 | """ |
---|
640 | return self.wave.wavelength_spread |
---|
641 | |
---|
642 | def get_neutron_mass(self): |
---|
643 | """ |
---|
644 | Get Neutron mass |
---|
645 | """ |
---|
646 | return self.wave.mass |
---|
647 | |
---|
648 | def get_source_aperture_size(self): |
---|
649 | """ |
---|
650 | Get source aperture size |
---|
651 | """ |
---|
652 | return self.aperture.source_size |
---|
653 | |
---|
654 | def get_sample_aperture_size(self): |
---|
655 | """ |
---|
656 | Get sample aperture size |
---|
657 | """ |
---|
658 | return self.aperture.sample_size |
---|
659 | |
---|
660 | def get_detector_pix_size(self): |
---|
661 | """ |
---|
662 | Get detector pixel size |
---|
663 | """ |
---|
664 | return self.detector.pix_size |
---|
665 | |
---|
666 | def get_detector_size(self): |
---|
667 | """ |
---|
668 | Get detector size |
---|
669 | """ |
---|
670 | return self.detector.size |
---|
671 | |
---|
672 | def get_source2sample_distance(self): |
---|
673 | """ |
---|
674 | Get detector source2sample_distance |
---|
675 | """ |
---|
676 | return self.aperture.sample_distance |
---|
677 | |
---|
678 | def get_sample2sample_distance(self): |
---|
679 | """ |
---|
680 | Get detector sampleslitsample_distance |
---|
681 | """ |
---|
682 | return self.sample.distance |
---|
683 | |
---|
684 | def get_sample2detector_distance(self): |
---|
685 | """ |
---|
686 | Get detector sample2detector_distance |
---|
687 | """ |
---|
688 | return self.detector.distance |
---|
689 | |
---|
690 | def set_intensity(self, intensity): |
---|
691 | """ |
---|
692 | Set intensity |
---|
693 | """ |
---|
694 | self.wave.set_intensity(intensity) |
---|
695 | |
---|
696 | def set_wave(self, wavelength): |
---|
697 | """ |
---|
698 | Set wavelength list or wavelength |
---|
699 | """ |
---|
700 | if wavelength.__class__.__name__ == 'list': |
---|
701 | self.wave.set_wave_list(wavelength) |
---|
702 | elif wavelength.__class__.__name__ == 'float': |
---|
703 | self.wave.set_wave_list([wavelength]) |
---|
704 | #self.set_wavelength(wavelength) |
---|
705 | else: |
---|
706 | raise |
---|
707 | |
---|
708 | def set_wave_spread(self, wavelength_spread): |
---|
709 | """ |
---|
710 | Set wavelength spread or wavelength spread |
---|
711 | """ |
---|
712 | if wavelength_spread.__class__.__name__ == 'list': |
---|
713 | self.wave.set_wave_spread_list(wavelength_spread) |
---|
714 | elif wavelength_spread.__class__.__name__ == 'float': |
---|
715 | self.wave.set_wave_spread_list([wavelength_spread]) |
---|
716 | else: |
---|
717 | raise |
---|
718 | |
---|
719 | def set_wavelength(self, wavelength): |
---|
720 | """ |
---|
721 | Set wavelength |
---|
722 | """ |
---|
723 | self.wavelength = wavelength |
---|
724 | self.wave.set_wavelength(wavelength) |
---|
725 | |
---|
726 | def set_spectrum(self, spectrum): |
---|
727 | """ |
---|
728 | Set spectrum |
---|
729 | """ |
---|
730 | self.spectrum = spectrum |
---|
731 | self.wave.set_spectrum(spectrum) |
---|
732 | |
---|
733 | def set_wavelength_spread(self, wavelength_spread): |
---|
734 | """ |
---|
735 | Set wavelength spread |
---|
736 | """ |
---|
737 | self.wavelength_spread = wavelength_spread |
---|
738 | self.wave.set_wavelength_spread(wavelength_spread) |
---|
739 | |
---|
740 | def set_wave_list(self, wavelength_list, wavelengthspread_list): |
---|
741 | """ |
---|
742 | Set wavelength and its spread list |
---|
743 | """ |
---|
744 | self.wave.set_wave_list(wavelength_list) |
---|
745 | self.wave.set_wave_spread_list(wavelengthspread_list) |
---|
746 | |
---|
747 | def get_wave_list(self): |
---|
748 | """ |
---|
749 | Set wavelength spread |
---|
750 | """ |
---|
751 | return self.wave.get_wave_list() |
---|
752 | |
---|
753 | def get_intensity_list(self): |
---|
754 | """ |
---|
755 | Set wavelength spread |
---|
756 | """ |
---|
757 | return self.wave.get_intensity_list() |
---|
758 | |
---|
759 | def set_source_aperture_size(self, size): |
---|
760 | """ |
---|
761 | Set source aperture size |
---|
762 | |
---|
763 | : param size: [dia_value] or [x_value, y_value] |
---|
764 | """ |
---|
765 | if len(size) < 1 or len(size) > 2: |
---|
766 | raise RuntimeError, "The length of the size must be one or two." |
---|
767 | self.aperture.set_source_size(size) |
---|
768 | |
---|
769 | def set_neutron_mass(self, mass): |
---|
770 | """ |
---|
771 | Set Neutron mass |
---|
772 | """ |
---|
773 | self.wave.set_mass(mass) |
---|
774 | self.mass = mass |
---|
775 | |
---|
776 | def set_sample_aperture_size(self, size): |
---|
777 | """ |
---|
778 | Set sample aperture size |
---|
779 | |
---|
780 | : param size: [dia_value] or [xheight_value, yheight_value] |
---|
781 | """ |
---|
782 | if len(size) < 1 or len(size) > 2: |
---|
783 | raise RuntimeError, "The length of the size must be one or two." |
---|
784 | self.aperture.set_sample_size(size) |
---|
785 | |
---|
786 | def set_detector_pix_size(self, size): |
---|
787 | """ |
---|
788 | Set detector pixel size |
---|
789 | """ |
---|
790 | self.detector.set_pix_size(size) |
---|
791 | |
---|
792 | def set_detector_size(self, size): |
---|
793 | """ |
---|
794 | Set detector size in number of pixels |
---|
795 | : param size: [pixel_nums] or [x_pix_num, yx_pix_num] |
---|
796 | """ |
---|
797 | self.detector.set_size(size) |
---|
798 | |
---|
799 | def set_source2sample_distance(self, distance): |
---|
800 | """ |
---|
801 | Set detector source2sample_distance |
---|
802 | |
---|
803 | : param distance: [distance, x_offset] |
---|
804 | """ |
---|
805 | if len(distance) < 1 or len(distance) > 2: |
---|
806 | raise RuntimeError, "The length of the size must be one or two." |
---|
807 | self.aperture.set_sample_distance(distance) |
---|
808 | |
---|
809 | def set_sample2sample_distance(self, distance): |
---|
810 | """ |
---|
811 | Set detector sample_slit2sample_distance |
---|
812 | |
---|
813 | : param distance: [distance, x_offset] |
---|
814 | """ |
---|
815 | if len(distance) < 1 or len(distance) > 2: |
---|
816 | raise RuntimeError, "The length of the size must be one or two." |
---|
817 | self.sample.set_distance(distance) |
---|
818 | |
---|
819 | def set_sample2detector_distance(self, distance): |
---|
820 | """ |
---|
821 | Set detector sample2detector_distance |
---|
822 | |
---|
823 | : param distance: [distance, x_offset] |
---|
824 | """ |
---|
825 | if len(distance) < 1 or len(distance) > 2: |
---|
826 | raise RuntimeError, "The length of the size must be one or two." |
---|
827 | self.detector.set_distance(distance) |
---|
828 | |
---|
829 | def get_all_instrument_params(self): |
---|
830 | """ |
---|
831 | Get all instrumental parameters |
---|
832 | """ |
---|
833 | self.mass = self.get_neutron_mass() |
---|
834 | self.spectrum = self.get_spectrum() |
---|
835 | self.source_aperture_size = self.get_source_aperture_size() |
---|
836 | self.sample_aperture_size = self.get_sample_aperture_size() |
---|
837 | self.detector_pix_size = self.get_detector_pix_size() |
---|
838 | self.detector_size = self.get_detector_size() |
---|
839 | self.source2sample_distance = self.get_source2sample_distance() |
---|
840 | self.sample2sample_distance = self.get_sample2sample_distance() |
---|
841 | self.sample2detector_distance = self.get_sample2detector_distance() |
---|
842 | |
---|
843 | def get_detector_qrange(self): |
---|
844 | """ |
---|
845 | get max detector q ranges |
---|
846 | |
---|
847 | : return: qx_min, qx_max, qy_min, qy_max tuple |
---|
848 | """ |
---|
849 | if len(self.qxrange) != 2 or len(self.qyrange) != 2: |
---|
850 | return None |
---|
851 | qx_min = self.qxrange[0] |
---|
852 | qx_max = self.qxrange[1] |
---|
853 | qy_min = self.qyrange[0] |
---|
854 | qy_max = self.qyrange[1] |
---|
855 | |
---|
856 | return qx_min, qx_max, qy_min, qy_max |
---|
857 | |
---|
858 | def _rotate_z(self, x_value, y_value, theta=0.0): |
---|
859 | """ |
---|
860 | Rotate x-y cordinate around z-axis by theta |
---|
861 | : x_value: numpy array of x values |
---|
862 | : y_value: numpy array of y values |
---|
863 | : theta: angle to rotate by in rad |
---|
864 | |
---|
865 | :return: x_prime, y-prime |
---|
866 | """ |
---|
867 | # rotate by theta |
---|
868 | x_prime = x_value * math.cos(theta) + y_value * math.sin(theta) |
---|
869 | y_prime = -x_value * math.sin(theta) + y_value * math.cos(theta) |
---|
870 | |
---|
871 | return x_prime, y_prime |
---|
872 | |
---|
873 | def _gaussian2d(self, x_val, y_val, x0_val, y0_val, |
---|
874 | sigma_x, sigma_y, sigma_r): |
---|
875 | """ |
---|
876 | Calculate 2D Gaussian distribution |
---|
877 | : x_val: x value |
---|
878 | : y_val: y value |
---|
879 | : x0_val: mean value in x-axis |
---|
880 | : y0_val: mean value in y-axis |
---|
881 | : sigma_x: variance in x-direction |
---|
882 | : sigma_y: variance in y-direction |
---|
883 | |
---|
884 | : return: gaussian (value) |
---|
885 | """ |
---|
886 | # phi values at each points (not at the center) |
---|
887 | x_value = x_val - x0_val |
---|
888 | y_value = y_val - y0_val |
---|
889 | phi_i = numpy.arctan2(y_val, x_val) |
---|
890 | |
---|
891 | # phi correction due to the gravity shift (in phi) |
---|
892 | phi_0 = math.atan2(y0_val, x0_val) |
---|
893 | phi_i = phi_i - phi_0 + self.gravity_phi |
---|
894 | |
---|
895 | sin_phi = numpy.sin(self.gravity_phi) |
---|
896 | cos_phi = numpy.cos(self.gravity_phi) |
---|
897 | |
---|
898 | x_p = x_value * cos_phi + y_value * sin_phi |
---|
899 | y_p = -x_value * sin_phi + y_value * cos_phi |
---|
900 | |
---|
901 | new_sig_x = sqrt(sigma_r * sigma_r / (sigma_x * sigma_x) + 1) |
---|
902 | new_sig_y = sqrt(sigma_r * sigma_r / (sigma_y * sigma_y) + 1) |
---|
903 | new_x = x_p * cos_phi / new_sig_x - y_p * sin_phi |
---|
904 | new_x /= sigma_x |
---|
905 | new_y = x_p * sin_phi / new_sig_y + y_p * cos_phi |
---|
906 | new_y /= sigma_y |
---|
907 | |
---|
908 | nu_value = -0.5 * (new_x * new_x + new_y * new_y) |
---|
909 | |
---|
910 | gaussian = numpy.exp(nu_value) |
---|
911 | # normalizing factor correction |
---|
912 | gaussian /= gaussian.sum() |
---|
913 | |
---|
914 | return gaussian |
---|
915 | |
---|
916 | def _gaussian2d_polar(self, x_val, y_val, x0_val, y0_val, |
---|
917 | sigma_x, sigma_y, sigma_r): |
---|
918 | """ |
---|
919 | Calculate 2D Gaussian distribution for polar coodinate |
---|
920 | : x_val: x value |
---|
921 | : y_val: y value |
---|
922 | : x0_val: mean value in x-axis |
---|
923 | : y0_val: mean value in y-axis |
---|
924 | : sigma_x: variance in r-direction |
---|
925 | : sigma_y: variance in phi-direction |
---|
926 | : sigma_r: wavelength variance in r-direction |
---|
927 | |
---|
928 | : return: gaussian (value) |
---|
929 | """ |
---|
930 | sigma_x = sqrt(sigma_x * sigma_x + sigma_r * sigma_r) |
---|
931 | # call gaussian1d |
---|
932 | gaussian = self._gaussian1d(x_val, x0_val, sigma_x) |
---|
933 | gaussian *= self._gaussian1d(y_val, y0_val, sigma_y) |
---|
934 | |
---|
935 | # normalizing factor correction |
---|
936 | if sigma_x != 0 and sigma_y != 0: |
---|
937 | gaussian *= sqrt(2 * pi) |
---|
938 | return gaussian |
---|
939 | |
---|
940 | def _gaussian1d(self, value, mean, sigma): |
---|
941 | """ |
---|
942 | Calculate 1D Gaussian distribution |
---|
943 | : value: value |
---|
944 | : mean: mean value |
---|
945 | : sigma: variance |
---|
946 | |
---|
947 | : return: gaussian (value) |
---|
948 | """ |
---|
949 | # default |
---|
950 | gaussian = 1.0 |
---|
951 | if sigma != 0: |
---|
952 | # get exponent |
---|
953 | nu_value = (value - mean) / sigma |
---|
954 | nu_value *= nu_value |
---|
955 | nu_value *= -0.5 |
---|
956 | gaussian *= numpy.exp(nu_value) |
---|
957 | gaussian /= sigma |
---|
958 | # normalize |
---|
959 | gaussian /= sqrt(2 * pi) |
---|
960 | |
---|
961 | return gaussian |
---|
962 | |
---|
963 | def _atan_phi(self, qy_value, qx_value): |
---|
964 | """ |
---|
965 | Find the angle phi of q on the detector plane for qx_value, qy_value given |
---|
966 | : qx_value: x component of q |
---|
967 | : qy_value: y component of q |
---|
968 | |
---|
969 | : return phi: the azimuthal angle of q on x-y plane |
---|
970 | """ |
---|
971 | phi = math.atan2(qy_value, qx_value) |
---|
972 | return phi |
---|
973 | |
---|
974 | def _get_detector_qxqy_pixels(self): |
---|
975 | """ |
---|
976 | Get the pixel positions of the detector in the qx_value-qy_value space |
---|
977 | """ |
---|
978 | |
---|
979 | # update all param values |
---|
980 | self.get_all_instrument_params() |
---|
981 | |
---|
982 | # wavelength |
---|
983 | wavelength = self.wave.wavelength |
---|
984 | # Gavity correction |
---|
985 | delta_y = self._get_beamcenter_drop() # in cm |
---|
986 | |
---|
987 | # detector_pix size |
---|
988 | detector_pix_size = self.detector_pix_size |
---|
989 | # Square or circular pixel |
---|
990 | if len(detector_pix_size) == 1: |
---|
991 | pix_x_size = detector_pix_size[0] |
---|
992 | pix_y_size = detector_pix_size[0] |
---|
993 | # rectangular pixel pixel |
---|
994 | elif len(detector_pix_size) == 2: |
---|
995 | pix_x_size = detector_pix_size[0] |
---|
996 | pix_y_size = detector_pix_size[1] |
---|
997 | else: |
---|
998 | raise ValueError, " Input value format error..." |
---|
999 | # Sample to detector distance = sample slit to detector |
---|
1000 | # minus sample offset |
---|
1001 | sample2detector_distance = self.sample2detector_distance[0] - \ |
---|
1002 | self.sample2sample_distance[0] |
---|
1003 | # detector offset in x-direction |
---|
1004 | detector_offset = 0 |
---|
1005 | try: |
---|
1006 | detector_offset = self.sample2detector_distance[1] |
---|
1007 | except: |
---|
1008 | logging.error(sys.exc_value) |
---|
1009 | |
---|
1010 | # detector size in [no of pix_x,no of pix_y] |
---|
1011 | detector_pix_nums_x = self.detector_size[0] |
---|
1012 | |
---|
1013 | # get pix_y if it exists, otherwse take it from [0] |
---|
1014 | try: |
---|
1015 | detector_pix_nums_y = self.detector_size[1] |
---|
1016 | except: |
---|
1017 | detector_pix_nums_y = self.detector_size[0] |
---|
1018 | |
---|
1019 | # detector offset in pix number |
---|
1020 | offset_x = detector_offset / pix_x_size |
---|
1021 | offset_y = delta_y / pix_y_size |
---|
1022 | |
---|
1023 | # beam center position in pix number (start from 0) |
---|
1024 | center_x, center_y = self._get_beamcenter_position(detector_pix_nums_x, |
---|
1025 | detector_pix_nums_y, |
---|
1026 | offset_x, offset_y) |
---|
1027 | # distance [cm] from the beam center on detector plane |
---|
1028 | detector_ind_x = numpy.arange(detector_pix_nums_x) |
---|
1029 | detector_ind_y = numpy.arange(detector_pix_nums_y) |
---|
1030 | |
---|
1031 | # shif 0.5 pixel so that pix position is at the center of the pixel |
---|
1032 | detector_ind_x = detector_ind_x + 0.5 |
---|
1033 | detector_ind_y = detector_ind_y + 0.5 |
---|
1034 | |
---|
1035 | # the relative postion from the beam center |
---|
1036 | detector_ind_x = detector_ind_x - center_x |
---|
1037 | detector_ind_y = detector_ind_y - center_y |
---|
1038 | |
---|
1039 | # unit correction in cm |
---|
1040 | detector_ind_x = detector_ind_x * pix_x_size |
---|
1041 | detector_ind_y = detector_ind_y * pix_y_size |
---|
1042 | |
---|
1043 | qx_value = numpy.zeros(len(detector_ind_x)) |
---|
1044 | qy_value = numpy.zeros(len(detector_ind_y)) |
---|
1045 | i = 0 |
---|
1046 | |
---|
1047 | for indx in detector_ind_x: |
---|
1048 | qx_value[i] = self._get_qx(indx, sample2detector_distance, wavelength) |
---|
1049 | i += 1 |
---|
1050 | i = 0 |
---|
1051 | for indy in detector_ind_y: |
---|
1052 | qy_value[i] = self._get_qx(indy, sample2detector_distance, wavelength) |
---|
1053 | i += 1 |
---|
1054 | |
---|
1055 | # qx_value and qy_value values in array |
---|
1056 | qx_value = qx_value.repeat(detector_pix_nums_y) |
---|
1057 | qx_value = qx_value.reshape(detector_pix_nums_x, detector_pix_nums_y) |
---|
1058 | qy_value = qy_value.repeat(detector_pix_nums_x) |
---|
1059 | qy_value = qy_value.reshape(detector_pix_nums_y, detector_pix_nums_x) |
---|
1060 | qy_value = qy_value.transpose() |
---|
1061 | |
---|
1062 | # p min and max values among the center of pixels |
---|
1063 | self.qx_min = numpy.min(qx_value) |
---|
1064 | self.qx_max = numpy.max(qx_value) |
---|
1065 | self.qy_min = numpy.min(qy_value) |
---|
1066 | self.qy_max = numpy.max(qy_value) |
---|
1067 | |
---|
1068 | # Appr. min and max values of the detector display limits |
---|
1069 | # i.e., edges of the last pixels. |
---|
1070 | self.qy_min += self._get_qx(-0.5 * pix_y_size, |
---|
1071 | sample2detector_distance, wavelength) |
---|
1072 | self.qy_max += self._get_qx(0.5 * pix_y_size, |
---|
1073 | sample2detector_distance, wavelength) |
---|
1074 | #if self.qx_min == self.qx_max: |
---|
1075 | self.qx_min += self._get_qx(-0.5 * pix_x_size, |
---|
1076 | sample2detector_distance, wavelength) |
---|
1077 | self.qx_max += self._get_qx(0.5 * pix_x_size, |
---|
1078 | sample2detector_distance, wavelength) |
---|
1079 | |
---|
1080 | # min and max values of detecter |
---|
1081 | self.detector_qx_min = self.qx_min |
---|
1082 | self.detector_qx_max = self.qx_max |
---|
1083 | self.detector_qy_min = self.qy_min |
---|
1084 | self.detector_qy_max = self.qy_max |
---|
1085 | |
---|
1086 | # try to set it as a Data2D otherwise pass (not required for now) |
---|
1087 | try: |
---|
1088 | from sas.sascalc.dataloader.data_info import Data2D |
---|
1089 | output = Data2D() |
---|
1090 | inten = numpy.zeros_like(qx_value) |
---|
1091 | output.data = inten |
---|
1092 | output.qx_data = qx_value |
---|
1093 | output.qy_data = qy_value |
---|
1094 | except: |
---|
1095 | logging.error(sys.exc_value) |
---|
1096 | |
---|
1097 | return output |
---|
1098 | |
---|
1099 | def _get_qx(self, dx_size, det_dist, wavelength): |
---|
1100 | """ |
---|
1101 | :param dx_size: x-distance from beam center [cm] |
---|
1102 | :param det_dist: sample to detector distance [cm] |
---|
1103 | |
---|
1104 | :return: q-value at the given position |
---|
1105 | """ |
---|
1106 | # Distance from beam center in the plane of detector |
---|
1107 | plane_dist = dx_size |
---|
1108 | # full scattering angle on the x-axis |
---|
1109 | theta = numpy.arctan(plane_dist / det_dist) |
---|
1110 | qx_value = (2.0 * pi / wavelength) * numpy.sin(theta) |
---|
1111 | return qx_value |
---|
1112 | |
---|
1113 | def _get_polar_value(self, qx_value, qy_value): |
---|
1114 | """ |
---|
1115 | Find qr_value and phi from qx_value and qy_value values |
---|
1116 | |
---|
1117 | : return qr_value, phi |
---|
1118 | """ |
---|
1119 | # find |q| on detector plane |
---|
1120 | qr_value = sqrt(qx_value*qx_value + qy_value*qy_value) |
---|
1121 | # find angle phi |
---|
1122 | phi = self._atan_phi(qy_value, qx_value) |
---|
1123 | |
---|
1124 | return qr_value, phi |
---|
1125 | |
---|
1126 | def _get_beamcenter_position(self, num_x, num_y, offset_x, offset_y): |
---|
1127 | """ |
---|
1128 | :param num_x: number of pixel in x-direction |
---|
1129 | :param num_y: number of pixel in y-direction |
---|
1130 | :param offset: detector offset in x-direction in pix number |
---|
1131 | |
---|
1132 | :return: pix number; pos_x, pos_y in pix index |
---|
1133 | """ |
---|
1134 | # beam center position |
---|
1135 | pos_x = num_x / 2 |
---|
1136 | pos_y = num_y / 2 |
---|
1137 | |
---|
1138 | # correction for offset |
---|
1139 | pos_x += offset_x |
---|
1140 | # correction for gravity that is always negative |
---|
1141 | pos_y -= offset_y |
---|
1142 | |
---|
1143 | return pos_x, pos_y |
---|
1144 | |
---|
1145 | def _get_beamcenter_drop(self): |
---|
1146 | """ |
---|
1147 | Get the beam center drop (delta y) in y diection due to gravity |
---|
1148 | |
---|
1149 | :return delta y: the beam center drop in cm |
---|
1150 | """ |
---|
1151 | # Check if mass == 0 (X-ray). |
---|
1152 | if self.mass == 0: |
---|
1153 | return 0 |
---|
1154 | # Covert unit from A to cm |
---|
1155 | unit_cm = 1e-08 |
---|
1156 | # Velocity of neutron in horizontal direction (~ actual velocity) |
---|
1157 | velocity = _PLANK_H / (self.mass * self.wave.wavelength * unit_cm) |
---|
1158 | # Compute delta y |
---|
1159 | delta_y = 0.5 |
---|
1160 | delta_y *= _GRAVITY |
---|
1161 | sampletodetector = self.sample2detector_distance[0] - \ |
---|
1162 | self.sample2sample_distance[0] |
---|
1163 | delta_y *= sampletodetector |
---|
1164 | delta_y *= (self.source2sample_distance[0] + self.sample2detector_distance[0]) |
---|
1165 | delta_y /= (velocity * velocity) |
---|
1166 | |
---|
1167 | return delta_y |
---|