1 | #!/usr/bin/env python |
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2 | """ |
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3 | Class to validate a given 2D model w/ 3 axes by averaging it |
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4 | and comparing to 1D prediction. |
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5 | |
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6 | The equation used for averaging is: |
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7 | |
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8 | (integral dphi from 0 to 2pi)(integral dtheta from 0 to pi) |
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9 | p(theta, phi) I(q) sin(theta) dtheta |
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10 | |
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11 | = (1/N_phi) (1/N_theta) (pi/2) (sum over N_phi) (sum over N_theta) |
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12 | p(theta_i, phi_i) I(q) sin(theta_i) |
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13 | |
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14 | where p(theta, phi) is the probability distribution normalized to 4pi. |
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15 | In the current case, we put p(theta, phi) = 1. |
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16 | |
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17 | The normalization factor results from: |
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18 | 2pi/N_phi for the phi sum |
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19 | x pi/N_theta for the theta sum |
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20 | x 1/(4pi) because p is normalized to 4pi |
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21 | -------------- |
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22 | = (1/N_phi) (1/N_theta) (pi/2) |
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23 | |
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24 | Note: |
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25 | Averaging the 3-axes 2D scattering intensity give a slightly |
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26 | different output than the 1D function |
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27 | at hight Q (Q>~0.2). This is due to the way the IGOR library |
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28 | averages(?), taking only 76 points in alpha, the angle between |
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29 | the axis of the ellipsoid and the q vector. |
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30 | |
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31 | Note: Core-shell and sphere models are symmetric around |
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32 | all axes and don't need to be tested in the following way. |
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33 | """ |
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34 | import sys, math |
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35 | from sans.models.EllipticalCylinderModel import EllipticalCylinderModel |
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36 | from sans.models.ParallelepipedModel import ParallelepipedModel |
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37 | from sans.models.TriaxialEllipsoidModel import TriaxialEllipsoidModel |
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38 | |
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39 | class Validate2D: |
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40 | """ |
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41 | Class to validate a given 2D model by averaging it |
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42 | and comparing to 1D prediction. |
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43 | """ |
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44 | |
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45 | def __init__(self): |
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46 | """ Initialization """ |
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47 | # Precision for the result comparison |
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48 | self.precision = 0.000001 |
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49 | # Flag for end result |
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50 | self.passed = True |
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51 | |
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52 | def __call__(self, model_class=EllipticalCylinderModel, points = 101): |
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53 | """ |
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54 | Perform test and produce output file |
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55 | @param model_class: python class of the model to test |
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56 | """ |
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57 | print "Averaging %s" % model_class.__name__ |
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58 | passed = True |
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59 | |
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60 | npts =points |
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61 | #The average values are very sensitive to npts of phi so npts_alpha should be large enough. |
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62 | npts_alpha =180 #npts of phi |
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63 | model = model_class() |
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64 | #model.setParam('scale', 1.0) |
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65 | #model.setParam('contrast', 1.0) |
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66 | |
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67 | theta_label = 'cyl_theta' |
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68 | if not model.params.has_key(theta_label): |
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69 | theta_label = 'parallel_theta' |
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70 | if not model.params.has_key(theta_label): |
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71 | theta_label = 'axis_theta' |
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72 | |
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73 | phi_label = 'cyl_phi' |
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74 | if not model.params.has_key(phi_label): |
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75 | phi_label = 'parallel_phi' |
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76 | if not model.params.has_key(phi_label): |
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77 | phi_label = 'axis_phi' |
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78 | |
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79 | psi_label = 'cyl_psi' |
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80 | if not model.params.has_key(psi_label): |
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81 | psi_label = 'parallel_psi' |
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82 | if not model.params.has_key(psi_label): |
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83 | psi_label = 'axis_psi' |
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84 | |
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85 | output_f = open("%s_avg.txt" % model.__class__.__name__,'w') |
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86 | output_f.write("<q_average> <2d_average> <1d_average>\n") |
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87 | |
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88 | for i_q in range(1, 23): |
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89 | q = 0.01*i_q |
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90 | sum = 0.0 |
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91 | weight = 0.0 |
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92 | for i_theta in range(npts): |
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93 | theta = 180.0/npts*(i_theta+1) |
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94 | |
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95 | model.setParam(theta_label, theta) |
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96 | |
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97 | for j in range(npts_alpha): |
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98 | model.setParam(phi_label, 180.0 * 2.0 / npts_alpha * j) |
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99 | for k in range(npts): |
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100 | model.setParam(psi_label, 180.0 * 2.0 / npts * k) |
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101 | if str(model.run([q, 0])).count("INF")>0: |
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102 | print "ERROR", q, theta, 180.0 * 2.0 / npts * k |
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103 | |
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104 | # sin() is due to having not uniform bin number density wrt the q plane. |
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105 | sum += model.run([q, 0])*math.sin(theta*math.pi/180.0) |
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106 | weight += math.sin(theta*math.pi/180.0) |
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107 | |
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108 | value = sum/weight #*math.pi/2.0 |
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109 | ana = model.run(q) |
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110 | if q<0.3 and (value-ana)/ana>0.05: |
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111 | passed = False |
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112 | output_f.write("%10g %10g %10g\n" % (q, value, ana)) |
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113 | print "Q=%g: %10g %10g %10g %10g" % (q, value, ana, value-ana, value/ana) |
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114 | |
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115 | output_f.close() |
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116 | return passed |
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117 | |
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118 | |
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119 | |
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120 | if __name__ == '__main__': |
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121 | validator = Validate2D() |
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122 | |
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123 | #Note: Test one model by one model, otherwise it could crash depending on the memory. |
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124 | |
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125 | te_passed =validator(TriaxialEllipsoidModel, points=76) |
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126 | #pp_passed = validator(ParallelepipedModel, points=76) |
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127 | #ell_passed = validator(EllipticalCylinderModel, points=76) |
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128 | |
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129 | print "" |
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130 | print "Model Passed" |
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131 | print "TriaxialEllipsoid %s" % te_passed |
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132 | #print "ParallelepipedModel %s" % pp_passed |
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133 | #print "EllipticalCylinder %s" % ell_passed |
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134 | |
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135 | |
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136 | |
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137 | |
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138 | |
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