1 | #!/usr/bin/env python |
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2 | """ |
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3 | Application to explore the difference between sasview 3.x orientation |
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4 | dispersity and possible replacement algorithms. |
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5 | """ |
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6 | from __future__ import division, print_function |
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7 | |
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8 | import sys, os |
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9 | sys.path.insert(0, os.path.dirname(os.path.dirname(os.path.realpath(__file__)))) |
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10 | |
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11 | import argparse |
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12 | |
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13 | import mpl_toolkits.mplot3d # Adds projection='3d' option to subplot |
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14 | import matplotlib.pyplot as plt |
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15 | from matplotlib.widgets import Slider, CheckButtons |
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16 | from matplotlib import cm |
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17 | import numpy as np |
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18 | from numpy import pi, cos, sin, sqrt, exp, degrees, radians |
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19 | |
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20 | def draw_beam(ax, view=(0, 0)): |
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21 | """ |
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22 | Draw the beam going from source at (0, 0, 1) to detector at (0, 0, -1) |
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23 | """ |
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24 | #ax.plot([0,0],[0,0],[1,-1]) |
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25 | #ax.scatter([0]*100,[0]*100,np.linspace(1, -1, 100), alpha=0.8) |
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26 | |
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27 | steps = 25 |
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28 | u = np.linspace(0, 2 * np.pi, steps) |
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29 | v = np.linspace(-1, 1, steps) |
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30 | |
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31 | r = 0.02 |
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32 | x = r*np.outer(np.cos(u), np.ones_like(v)) |
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33 | y = r*np.outer(np.sin(u), np.ones_like(v)) |
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34 | z = 1.3*np.outer(np.ones_like(u), v) |
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35 | |
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36 | theta, phi = view |
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37 | shape = x.shape |
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38 | points = np.matrix([x.flatten(), y.flatten(), z.flatten()]) |
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39 | points = Rz(phi)*Ry(theta)*points |
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40 | x, y, z = [v.reshape(shape) for v in points] |
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41 | |
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42 | ax.plot_surface(x, y, z, rstride=4, cstride=4, color='y', alpha=0.5) |
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43 | |
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44 | def draw_jitter(ax, view, jitter, dist='gaussian', size=(0.1, 0.4, 1.0)): |
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45 | """ |
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46 | Represent jitter as a set of shapes at different orientations. |
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47 | """ |
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48 | # set max diagonal to 0.95 |
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49 | scale = 0.95/sqrt(sum(v**2 for v in size)) |
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50 | size = tuple(scale*v for v in size) |
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51 | draw_shape = draw_parallelepiped |
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52 | #draw_shape = draw_ellipsoid |
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53 | |
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54 | #np.random.seed(10) |
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55 | #cloud = np.random.randn(10,3) |
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56 | cloud = [ |
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57 | [-1, -1, -1], |
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58 | [-1, -1, 0], |
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59 | [-1, -1, 1], |
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60 | [-1, 0, -1], |
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61 | [-1, 0, 0], |
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62 | [-1, 0, 1], |
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63 | [-1, 1, -1], |
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64 | [-1, 1, 0], |
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65 | [-1, 1, 1], |
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66 | [ 0, -1, -1], |
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67 | [ 0, -1, 0], |
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68 | [ 0, -1, 1], |
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69 | [ 0, 0, -1], |
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70 | [ 0, 0, 0], |
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71 | [ 0, 0, 1], |
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72 | [ 0, 1, -1], |
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73 | [ 0, 1, 0], |
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74 | [ 0, 1, 1], |
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75 | [ 1, -1, -1], |
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76 | [ 1, -1, 0], |
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77 | [ 1, -1, 1], |
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78 | [ 1, 0, -1], |
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79 | [ 1, 0, 0], |
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80 | [ 1, 0, 1], |
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81 | [ 1, 1, -1], |
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82 | [ 1, 1, 0], |
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83 | [ 1, 1, 1], |
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84 | ] |
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85 | dtheta, dphi, dpsi = jitter |
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86 | if dtheta == 0: |
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87 | cloud = [v for v in cloud if v[0] == 0] |
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88 | if dphi == 0: |
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89 | cloud = [v for v in cloud if v[1] == 0] |
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90 | if dpsi == 0: |
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91 | cloud = [v for v in cloud if v[2] == 0] |
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92 | draw_shape(ax, size, view, [0, 0, 0], steps=100, alpha=0.8) |
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93 | scale = {'gaussian':1, 'rectangle':1/sqrt(3), 'uniform':1/3}[dist] |
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94 | for point in cloud: |
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95 | delta = [scale*dtheta*point[0], scale*dphi*point[1], scale*dpsi*point[2]] |
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96 | draw_shape(ax, size, view, delta, alpha=0.8) |
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97 | for v in 'xyz': |
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98 | a, b, c = size |
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99 | lim = np.sqrt(a**2+b**2+c**2) |
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100 | getattr(ax, 'set_'+v+'lim')([-lim, lim]) |
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101 | getattr(ax, v+'axis').label.set_text(v) |
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102 | |
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103 | def draw_ellipsoid(ax, size, view, jitter, steps=25, alpha=1): |
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104 | """Draw an ellipsoid.""" |
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105 | a,b,c = size |
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106 | u = np.linspace(0, 2 * np.pi, steps) |
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107 | v = np.linspace(0, np.pi, steps) |
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108 | x = a*np.outer(np.cos(u), np.sin(v)) |
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109 | y = b*np.outer(np.sin(u), np.sin(v)) |
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110 | z = c*np.outer(np.ones_like(u), np.cos(v)) |
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111 | x, y, z = transform_xyz(view, jitter, x, y, z) |
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112 | |
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113 | ax.plot_surface(x, y, z, rstride=4, cstride=4, color='w', alpha=alpha) |
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114 | |
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115 | draw_labels(ax, view, jitter, [ |
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116 | ('c+', [ 0, 0, c], [ 1, 0, 0]), |
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117 | ('c-', [ 0, 0,-c], [ 0, 0,-1]), |
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118 | ('a+', [ a, 0, 0], [ 0, 0, 1]), |
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119 | ('a-', [-a, 0, 0], [ 0, 0,-1]), |
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120 | ('b+', [ 0, b, 0], [-1, 0, 0]), |
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121 | ('b-', [ 0,-b, 0], [-1, 0, 0]), |
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122 | ]) |
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123 | |
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124 | def draw_parallelepiped(ax, size, view, jitter, steps=None, alpha=1): |
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125 | """Draw a parallelepiped.""" |
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126 | a,b,c = size |
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127 | x = a*np.array([ 1,-1, 1,-1, 1,-1, 1,-1]) |
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128 | y = b*np.array([ 1, 1,-1,-1, 1, 1,-1,-1]) |
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129 | z = c*np.array([ 1, 1, 1, 1,-1,-1,-1,-1]) |
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130 | tri = np.array([ |
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131 | # counter clockwise triangles |
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132 | # z: up/down, x: right/left, y: front/back |
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133 | [0,1,2], [3,2,1], # top face |
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134 | [6,5,4], [5,6,7], # bottom face |
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135 | [0,2,6], [6,4,0], # right face |
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136 | [1,5,7], [7,3,1], # left face |
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137 | [2,3,6], [7,6,3], # front face |
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138 | [4,1,0], [5,1,4], # back face |
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139 | ]) |
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140 | |
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141 | x, y, z = transform_xyz(view, jitter, x, y, z) |
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142 | ax.plot_trisurf(x, y, triangles=tri, Z=z, color='w', alpha=alpha) |
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143 | |
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144 | draw_labels(ax, view, jitter, [ |
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145 | ('c+', [ 0, 0, c], [ 1, 0, 0]), |
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146 | ('c-', [ 0, 0,-c], [ 0, 0,-1]), |
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147 | ('a+', [ a, 0, 0], [ 0, 0, 1]), |
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148 | ('a-', [-a, 0, 0], [ 0, 0,-1]), |
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149 | ('b+', [ 0, b, 0], [-1, 0, 0]), |
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150 | ('b-', [ 0,-b, 0], [-1, 0, 0]), |
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151 | ]) |
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152 | |
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153 | def draw_sphere(ax, radius=10., steps=100): |
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154 | """Draw a sphere""" |
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155 | u = np.linspace(0, 2 * np.pi, steps) |
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156 | v = np.linspace(0, np.pi, steps) |
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157 | |
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158 | x = radius * np.outer(np.cos(u), np.sin(v)) |
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159 | y = radius * np.outer(np.sin(u), np.sin(v)) |
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160 | z = radius * np.outer(np.ones(np.size(u)), np.cos(v)) |
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161 | ax.plot_surface(x, y, z, rstride=4, cstride=4, color='w') |
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162 | |
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163 | PROJECTIONS = [ |
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164 | # in order of PROJECTION number; do not change without updating the |
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165 | # constants in kernel_iq.c |
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166 | 'equirectangular', 'sinusoidal', 'guyou', 'azimuthal_equidistance', |
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167 | 'azimuthal_equal_area', |
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168 | ] |
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169 | def draw_mesh(ax, view, jitter, radius=1.2, n=11, dist='gaussian', |
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170 | projection='equirectangular'): |
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171 | """ |
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172 | Draw the dispersion mesh showing the theta-phi orientations at which |
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173 | the model will be evaluated. |
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174 | |
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175 | jitter projections |
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176 | <https://en.wikipedia.org/wiki/List_of_map_projections> |
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177 | |
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178 | equirectangular (standard latitude-longitude mesh) |
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179 | <https://en.wikipedia.org/wiki/Equirectangular_projection> |
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180 | Allows free movement in phi (around the equator), but theta is |
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181 | limited to +/- 90, and points are cos-weighted. Jitter in phi is |
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182 | uniform in weight along a line of latitude. With small theta and |
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183 | phi ranging over +/- 180 this forms a wobbling disk. With small |
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184 | phi and theta ranging over +/- 90 this forms a wedge like a slice |
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185 | of an orange. |
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186 | azimuthal_equidistance (Postel) |
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187 | <https://en.wikipedia.org/wiki/Azimuthal_equidistant_projection> |
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188 | Preserves distance from center, and so is an excellent map for |
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189 | representing a bivariate gaussian on the surface. Theta and phi |
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190 | operate identically, cutting wegdes from the antipode of the viewing |
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191 | angle. This unfortunately does not allow free movement in either |
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192 | theta or phi since the orthogonal wobble decreases to 0 as the body |
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193 | rotates through 180 degrees. |
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194 | sinusoidal (Sanson-Flamsteed, Mercator equal-area) |
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195 | <https://en.wikipedia.org/wiki/Sinusoidal_projection> |
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196 | Preserves arc length with latitude, giving bad behaviour at |
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197 | theta near +/- 90. Theta and phi operate somewhat differently, |
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198 | so a system with a-b-c dtheta-dphi-dpsi will not give the same |
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199 | value as one with b-a-c dphi-dtheta-dpsi, as would be the case |
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200 | for azimuthal equidistance. Free movement using theta or phi |
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201 | uniform over +/- 180 will work, but not as well as equirectangular |
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202 | phi, with theta being slightly worse. Computationally it is much |
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203 | cheaper for wide theta-phi meshes since it excludes points which |
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204 | lie outside the sinusoid near theta +/- 90 rather than packing |
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205 | them close together as in equirectangle. Note that the poles |
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206 | will be slightly overweighted for theta > 90 with the circle |
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207 | from theta at 90+dt winding backwards around the pole, overlapping |
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208 | the circle from theta at 90-dt. |
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209 | Guyou (hemisphere-in-a-square) **not weighted** |
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210 | <https://en.wikipedia.org/wiki/Guyou_hemisphere-in-a-square_projection> |
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211 | With tiling, allows rotation in phi or theta through +/- 180, with |
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212 | uniform spacing. Both theta and phi allow free rotation, with wobble |
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213 | in the orthogonal direction reasonably well behaved (though not as |
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214 | good as equirectangular phi). The forward/reverse transformations |
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215 | relies on elliptic integrals that are somewhat expensive, so the |
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216 | behaviour has to be very good to justify the cost and complexity. |
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217 | The weighting function for each point has not yet been computed. |
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218 | Note: run the module *guyou.py* directly and it will show the forward |
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219 | and reverse mappings. |
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220 | azimuthal_equal_area **incomplete** |
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221 | <https://en.wikipedia.org/wiki/Lambert_azimuthal_equal-area_projection> |
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222 | Preserves the relative density of the surface patches. Not that |
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223 | useful and not completely implemented |
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224 | Gauss-Kreuger **not implemented** |
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225 | <https://en.wikipedia.org/wiki/Transverse_Mercator_projection#Ellipsoidal_transverse_Mercator> |
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226 | Should allow free movement in theta, but phi is distorted. |
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227 | """ |
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228 | theta, phi, psi = view |
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229 | dtheta, dphi, dpsi = jitter |
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230 | |
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231 | t = np.linspace(-1, 1, n) |
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232 | weights = np.ones_like(t) |
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233 | if dist == 'gaussian': |
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234 | t *= 3 |
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235 | weights = exp(-0.5*t**2) |
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236 | elif dist == 'rectangle': |
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237 | # Note: uses sasmodels ridiculous definition of rectangle width |
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238 | t *= sqrt(3) |
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239 | elif dist == 'uniform': |
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240 | pass |
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241 | else: |
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242 | raise ValueError("expected dist to be gaussian, rectangle or uniform") |
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243 | |
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244 | if projection == 'equirectangular': #define PROJECTION 1 |
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245 | def rotate(theta_i, phi_j): |
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246 | return Rx(phi_j)*Ry(theta_i) |
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247 | def weight(theta_i, phi_j, wi, wj): |
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248 | return wi*wj*abs(cos(radians(theta_i))) |
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249 | elif projection == 'sinusoidal': #define PROJECTION 2 |
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250 | def rotate(theta_i, phi_j): |
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251 | latitude = theta_i |
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252 | scale = cos(radians(latitude)) |
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253 | longitude = phi_j/scale if abs(phi_j) < abs(scale)*180 else 0 |
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254 | #print("(%+7.2f, %+7.2f) => (%+7.2f, %+7.2f)"%(theta_i, phi_j, latitude, longitude)) |
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255 | return Rx(longitude)*Ry(latitude) |
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256 | def weight(theta_i, phi_j, wi, wj): |
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257 | latitude = theta_i |
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258 | scale = cos(radians(latitude)) |
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259 | w = 1 if abs(phi_j) < abs(scale)*180 else 0 |
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260 | return w*wi*wj |
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261 | elif projection == 'guyou': #define PROJECTION 3 (eventually?) |
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262 | def rotate(theta_i, phi_j): |
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263 | from guyou import guyou_invert |
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264 | #latitude, longitude = guyou_invert([theta_i], [phi_j]) |
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265 | longitude, latitude = guyou_invert([phi_j], [theta_i]) |
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266 | return Rx(longitude[0])*Ry(latitude[0]) |
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267 | def weight(theta_i, phi_j, wi, wj): |
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268 | return wi*wj |
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269 | elif projection == 'azimuthal_equidistance': # Note: Rz Ry, not Rx Ry |
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270 | def rotate(theta_i, phi_j): |
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271 | latitude = sqrt(theta_i**2 + phi_j**2) |
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272 | longitude = degrees(np.arctan2(phi_j, theta_i)) |
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273 | #print("(%+7.2f, %+7.2f) => (%+7.2f, %+7.2f)"%(theta_i, phi_j, latitude, longitude)) |
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274 | return Rz(longitude)*Ry(latitude) |
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275 | def weight(theta_i, phi_j, wi, wj): |
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276 | # Weighting for each point comes from the integral: |
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277 | # \int\int I(q, lat, log) sin(lat) dlat dlog |
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278 | # We are doing a conformal mapping from disk to sphere, so we need |
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279 | # a change of variables g(theta, phi) -> (lat, long): |
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280 | # lat, long = sqrt(theta^2 + phi^2), arctan(phi/theta) |
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281 | # giving: |
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282 | # dtheta dphi = det(J) dlat dlong |
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283 | # where J is the jacobian from the partials of g. Using |
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284 | # R = sqrt(theta^2 + phi^2), |
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285 | # then |
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286 | # J = [[x/R, Y/R], -y/R^2, x/R^2]] |
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287 | # and |
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288 | # det(J) = 1/R |
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289 | # with the final integral being: |
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290 | # \int\int I(q, theta, phi) sin(R)/R dtheta dphi |
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291 | # |
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292 | # This does approximately the right thing, decreasing the weight |
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293 | # of each point as you go farther out on the disk, but it hasn't |
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294 | # yet been checked against the 1D integral results. Prior |
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295 | # to declaring this "good enough" and checking that integrals |
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296 | # work in practice, we will examine alternative mappings. |
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297 | # |
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298 | # The issue is that the mapping does not support the case of free |
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299 | # rotation about a single axis correctly, with a small deviation |
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300 | # in the orthogonal axis independent of the first axis. Like the |
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301 | # usual polar coordiates integration, the integrated sections |
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302 | # form wedges, though at least in this case the wedge cuts through |
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303 | # the entire sphere, and treats theta and phi identically. |
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304 | latitude = sqrt(theta_i**2 + phi_j**2) |
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305 | w = sin(radians(latitude))/latitude if latitude != 0 else 1 |
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306 | return w*wi*wj if latitude < 180 else 0 |
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307 | elif projection == 'azimuthal_equal_area': |
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308 | def rotate(theta_i, phi_j): |
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309 | R = min(1, sqrt(theta_i**2 + phi_j**2)/180) |
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310 | latitude = 180-degrees(2*np.arccos(R)) |
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311 | longitude = degrees(np.arctan2(phi_j, theta_i)) |
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312 | #print("(%+7.2f, %+7.2f) => (%+7.2f, %+7.2f)"%(theta_i, phi_j, latitude, longitude)) |
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313 | return Rz(longitude)*Ry(latitude) |
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314 | def weight(theta_i, phi_j, wi, wj): |
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315 | latitude = sqrt(theta_i**2 + phi_j**2) |
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316 | w = sin(radians(latitude))/latitude if latitude != 0 else 1 |
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317 | return w*wi*wj if latitude < 180 else 0 |
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318 | else: |
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319 | raise ValueError("unknown projection %r"%projection) |
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320 | |
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321 | # mesh in theta, phi formed by rotating z |
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322 | z = np.matrix([[0], [0], [radius]]) |
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323 | points = np.hstack([rotate(theta_i, phi_j)*z |
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324 | for theta_i in dtheta*t |
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325 | for phi_j in dphi*t]) |
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326 | # select just the active points (i.e., those with phi < 180 |
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327 | w = np.array([weight(theta_i, phi_j, wi, wj) |
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328 | for wi, theta_i in zip(weights, dtheta*t) |
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329 | for wj, phi_j in zip(weights, dphi*t)]) |
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330 | #print(max(w), min(w), min(w[w>0])) |
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331 | points = points[:, w>0] |
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332 | w = w[w>0] |
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333 | w /= max(w) |
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334 | |
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335 | if 0: # Kent distribution |
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336 | points = np.hstack([Rx(phi_j)*Ry(theta_i)*z for theta_i in 30*t for phi_j in 60*t]) |
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337 | xp, yp, zp = [np.array(v).flatten() for v in points] |
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338 | kappa = max(1e6, radians(dtheta)/(2*pi)) |
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339 | beta = 1/max(1e-6, radians(dphi)/(2*pi))/kappa |
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340 | w = exp(kappa*zp) #+ beta*(xp**2 + yp**2) |
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341 | print(kappa, dtheta, radians(dtheta), min(w), max(w), sum(w)) |
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342 | #w /= abs(cos(radians( |
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343 | #w /= sum(w) |
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344 | |
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345 | # rotate relative to beam |
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346 | points = orient_relative_to_beam(view, points) |
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347 | |
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348 | x, y, z = [np.array(v).flatten() for v in points] |
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349 | #plt.figure(2); plt.clf(); plt.hist(z, bins=np.linspace(-1, 1, 51)) |
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350 | ax.scatter(x, y, z, c=w, marker='o', vmin=0., vmax=1.) |
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351 | |
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352 | def draw_labels(ax, view, jitter, text): |
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353 | """ |
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354 | Draw text at a particular location. |
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355 | """ |
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356 | labels, locations, orientations = zip(*text) |
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357 | px, py, pz = zip(*locations) |
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358 | dx, dy, dz = zip(*orientations) |
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359 | |
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360 | px, py, pz = transform_xyz(view, jitter, px, py, pz) |
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361 | dx, dy, dz = transform_xyz(view, jitter, dx, dy, dz) |
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362 | |
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363 | # TODO: zdir for labels is broken, and labels aren't appearing. |
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364 | for label, p, zdir in zip(labels, zip(px, py, pz), zip(dx, dy, dz)): |
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365 | zdir = np.asarray(zdir).flatten() |
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366 | ax.text(p[0], p[1], p[2], label, zdir=zdir) |
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367 | |
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368 | # Definition of rotation matrices comes from wikipedia: |
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369 | # https://en.wikipedia.org/wiki/Rotation_matrix#Basic_rotations |
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370 | def Rx(angle): |
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371 | """Construct a matrix to rotate points about *x* by *angle* degrees.""" |
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372 | a = radians(angle) |
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373 | R = [[1, 0, 0], |
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374 | [0, +cos(a), -sin(a)], |
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375 | [0, +sin(a), +cos(a)]] |
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376 | return np.matrix(R) |
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377 | |
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378 | def Ry(angle): |
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379 | """Construct a matrix to rotate points about *y* by *angle* degrees.""" |
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380 | a = radians(angle) |
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381 | R = [[+cos(a), 0, +sin(a)], |
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382 | [0, 1, 0], |
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383 | [-sin(a), 0, +cos(a)]] |
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384 | return np.matrix(R) |
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385 | |
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386 | def Rz(angle): |
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387 | """Construct a matrix to rotate points about *z* by *angle* degrees.""" |
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388 | a = radians(angle) |
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389 | R = [[+cos(a), -sin(a), 0], |
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390 | [+sin(a), +cos(a), 0], |
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391 | [0, 0, 1]] |
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392 | return np.matrix(R) |
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393 | |
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394 | def transform_xyz(view, jitter, x, y, z): |
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395 | """ |
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396 | Send a set of (x,y,z) points through the jitter and view transforms. |
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397 | """ |
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398 | x, y, z = [np.asarray(v) for v in (x, y, z)] |
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399 | shape = x.shape |
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400 | points = np.matrix([x.flatten(),y.flatten(),z.flatten()]) |
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401 | points = apply_jitter(jitter, points) |
---|
402 | points = orient_relative_to_beam(view, points) |
---|
403 | x, y, z = [np.array(v).reshape(shape) for v in points] |
---|
404 | return x, y, z |
---|
405 | |
---|
406 | def apply_jitter(jitter, points): |
---|
407 | """ |
---|
408 | Apply the jitter transform to a set of points. |
---|
409 | |
---|
410 | Points are stored in a 3 x n numpy matrix, not a numpy array or tuple. |
---|
411 | """ |
---|
412 | dtheta, dphi, dpsi = jitter |
---|
413 | points = Rx(dphi)*Ry(dtheta)*Rz(dpsi)*points |
---|
414 | return points |
---|
415 | |
---|
416 | def orient_relative_to_beam(view, points): |
---|
417 | """ |
---|
418 | Apply the view transform to a set of points. |
---|
419 | |
---|
420 | Points are stored in a 3 x n numpy matrix, not a numpy array or tuple. |
---|
421 | """ |
---|
422 | theta, phi, psi = view |
---|
423 | points = Rz(phi)*Ry(theta)*Rz(psi)*points |
---|
424 | return points |
---|
425 | |
---|
426 | # translate between number of dimension of dispersity and the number of |
---|
427 | # points along each dimension. |
---|
428 | PD_N_TABLE = { |
---|
429 | (0, 0, 0): (0, 0, 0), # 0 |
---|
430 | (1, 0, 0): (100, 0, 0), # 100 |
---|
431 | (0, 1, 0): (0, 100, 0), |
---|
432 | (0, 0, 1): (0, 0, 100), |
---|
433 | (1, 1, 0): (30, 30, 0), # 900 |
---|
434 | (1, 0, 1): (30, 0, 30), |
---|
435 | (0, 1, 1): (0, 30, 30), |
---|
436 | (1, 1, 1): (15, 15, 15), # 3375 |
---|
437 | } |
---|
438 | |
---|
439 | def clipped_range(data, portion=1.0, mode='central'): |
---|
440 | """ |
---|
441 | Determine range from data. |
---|
442 | |
---|
443 | If *portion* is 1, use full range, otherwise use the center of the range |
---|
444 | or the top of the range, depending on whether *mode* is 'central' or 'top'. |
---|
445 | """ |
---|
446 | if portion == 1.0: |
---|
447 | return data.min(), data.max() |
---|
448 | elif mode == 'central': |
---|
449 | data = np.sort(data.flatten()) |
---|
450 | offset = int(portion*len(data)/2 + 0.5) |
---|
451 | return data[offset], data[-offset] |
---|
452 | elif mode == 'top': |
---|
453 | data = np.sort(data.flatten()) |
---|
454 | offset = int(portion*len(data) + 0.5) |
---|
455 | return data[offset], data[-1] |
---|
456 | |
---|
457 | def draw_scattering(calculator, ax, view, jitter, dist='gaussian'): |
---|
458 | """ |
---|
459 | Plot the scattering for the particular view. |
---|
460 | |
---|
461 | *calculator* is returned from :func:`build_model`. *ax* are the 3D axes |
---|
462 | on which the data will be plotted. *view* and *jitter* are the current |
---|
463 | orientation and orientation dispersity. *dist* is one of the sasmodels |
---|
464 | weight distributions. |
---|
465 | """ |
---|
466 | if dist == 'uniform': # uniform is not yet in this branch |
---|
467 | dist, scale = 'rectangle', 1/sqrt(3) |
---|
468 | else: |
---|
469 | scale = 1 |
---|
470 | |
---|
471 | # add the orientation parameters to the model parameters |
---|
472 | theta, phi, psi = view |
---|
473 | theta_pd, phi_pd, psi_pd = [scale*v for v in jitter] |
---|
474 | theta_pd_n, phi_pd_n, psi_pd_n = PD_N_TABLE[(theta_pd>0, phi_pd>0, psi_pd>0)] |
---|
475 | ## increase pd_n for testing jitter integration rather than simple viz |
---|
476 | #theta_pd_n, phi_pd_n, psi_pd_n = [5*v for v in (theta_pd_n, phi_pd_n, psi_pd_n)] |
---|
477 | |
---|
478 | pars = dict( |
---|
479 | theta=theta, theta_pd=theta_pd, theta_pd_type=dist, theta_pd_n=theta_pd_n, |
---|
480 | phi=phi, phi_pd=phi_pd, phi_pd_type=dist, phi_pd_n=phi_pd_n, |
---|
481 | psi=psi, psi_pd=psi_pd, psi_pd_type=dist, psi_pd_n=psi_pd_n, |
---|
482 | ) |
---|
483 | pars.update(calculator.pars) |
---|
484 | |
---|
485 | # compute the pattern |
---|
486 | qx, qy = calculator._data.x_bins, calculator._data.y_bins |
---|
487 | Iqxy = calculator(**pars).reshape(len(qx), len(qy)) |
---|
488 | |
---|
489 | # scale it and draw it |
---|
490 | Iqxy = np.log(Iqxy) |
---|
491 | if calculator.limits: |
---|
492 | # use limits from orientation (0,0,0) |
---|
493 | vmin, vmax = calculator.limits |
---|
494 | else: |
---|
495 | vmax = Iqxy.max() |
---|
496 | vmin = vmax*10**-7 |
---|
497 | #vmin, vmax = clipped_range(Iqxy, portion=portion, mode='top') |
---|
498 | #print("range",(vmin,vmax)) |
---|
499 | #qx, qy = np.meshgrid(qx, qy) |
---|
500 | if 0: |
---|
501 | level = np.asarray(255*(Iqxy - vmin)/(vmax - vmin), 'i') |
---|
502 | level[level<0] = 0 |
---|
503 | colors = plt.get_cmap()(level) |
---|
504 | ax.plot_surface(qx, qy, -1.1, rstride=1, cstride=1, facecolors=colors) |
---|
505 | elif 1: |
---|
506 | ax.contourf(qx/qx.max(), qy/qy.max(), Iqxy, zdir='z', offset=-1.1, |
---|
507 | levels=np.linspace(vmin, vmax, 24)) |
---|
508 | else: |
---|
509 | ax.pcolormesh(qx, qy, Iqxy) |
---|
510 | |
---|
511 | def build_model(model_name, n=150, qmax=0.5, **pars): |
---|
512 | """ |
---|
513 | Build a calculator for the given shape. |
---|
514 | |
---|
515 | *model_name* is any sasmodels model. *n* and *qmax* define an n x n mesh |
---|
516 | on which to evaluate the model. The remaining parameters are stored in |
---|
517 | the returned calculator as *calculator.pars*. They are used by |
---|
518 | :func:`draw_scattering` to set the non-orientation parameters in the |
---|
519 | calculation. |
---|
520 | |
---|
521 | Returns a *calculator* function which takes a dictionary or parameters and |
---|
522 | produces Iqxy. The Iqxy value needs to be reshaped to an n x n matrix |
---|
523 | for plotting. See the :class:`sasmodels.direct_model.DirectModel` class |
---|
524 | for details. |
---|
525 | """ |
---|
526 | from sasmodels.core import load_model_info, build_model |
---|
527 | from sasmodels.data import empty_data2D |
---|
528 | from sasmodels.direct_model import DirectModel |
---|
529 | |
---|
530 | model_info = load_model_info(model_name) |
---|
531 | model = build_model(model_info) #, dtype='double!') |
---|
532 | q = np.linspace(-qmax, qmax, n) |
---|
533 | data = empty_data2D(q, q) |
---|
534 | calculator = DirectModel(data, model) |
---|
535 | |
---|
536 | # stuff the values for non-orientation parameters into the calculator |
---|
537 | calculator.pars = pars.copy() |
---|
538 | calculator.pars.setdefault('backgound', 1e-3) |
---|
539 | |
---|
540 | # fix the data limits so that we can see if the pattern fades |
---|
541 | # under rotation or angular dispersion |
---|
542 | Iqxy = calculator(theta=0, phi=0, psi=0, **calculator.pars) |
---|
543 | Iqxy = np.log(Iqxy) |
---|
544 | vmin, vmax = clipped_range(Iqxy, 0.95, mode='top') |
---|
545 | calculator.limits = vmin, vmax+1 |
---|
546 | |
---|
547 | return calculator |
---|
548 | |
---|
549 | def select_calculator(model_name, n=150, size=(10,40,100)): |
---|
550 | """ |
---|
551 | Create a model calculator for the given shape. |
---|
552 | |
---|
553 | *model_name* is one of sphere, cylinder, ellipsoid, triaxial_ellipsoid, |
---|
554 | parallelepiped or bcc_paracrystal. *n* is the number of points to use |
---|
555 | in the q range. *qmax* is chosen based on model parameters for the |
---|
556 | given model to show something intersting. |
---|
557 | |
---|
558 | Returns *calculator* and tuple *size* (a,b,c) giving minor and major |
---|
559 | equitorial axes and polar axis respectively. See :func:`build_model` |
---|
560 | for details on the returned calculator. |
---|
561 | """ |
---|
562 | a, b, c = size |
---|
563 | if model_name == 'sphere': |
---|
564 | calculator = build_model('sphere', n=n, radius=c) |
---|
565 | a = b = c |
---|
566 | elif model_name == 'bcc_paracrystal': |
---|
567 | calculator = build_model('bcc_paracrystal', n=n, dnn=c, |
---|
568 | d_factor=0.06, radius=40) |
---|
569 | a = b = c |
---|
570 | elif model_name == 'cylinder': |
---|
571 | calculator = build_model('cylinder', n=n, qmax=0.3, radius=b, length=c) |
---|
572 | a = b |
---|
573 | elif model_name == 'ellipsoid': |
---|
574 | calculator = build_model('ellipsoid', n=n, qmax=1.0, |
---|
575 | radius_polar=c, radius_equatorial=b) |
---|
576 | a = b |
---|
577 | elif model_name == 'triaxial_ellipsoid': |
---|
578 | calculator = build_model('triaxial_ellipsoid', n=n, qmax=0.5, |
---|
579 | radius_equat_minor=a, |
---|
580 | radius_equat_major=b, |
---|
581 | radius_polar=c) |
---|
582 | elif model_name == 'parallelepiped': |
---|
583 | calculator = build_model('parallelepiped', n=n, a=a, b=b, c=c) |
---|
584 | else: |
---|
585 | raise ValueError("unknown model %s"%model_name) |
---|
586 | |
---|
587 | return calculator, (a, b, c) |
---|
588 | |
---|
589 | SHAPES = [ |
---|
590 | 'parallelepiped', 'triaxial_ellipsoid', 'bcc_paracrystal', |
---|
591 | 'cylinder', 'ellipsoid', |
---|
592 | 'sphere', |
---|
593 | ] |
---|
594 | |
---|
595 | DISTRIBUTIONS = [ |
---|
596 | 'gaussian', 'rectangle', 'uniform', |
---|
597 | ] |
---|
598 | DIST_LIMITS = { |
---|
599 | 'gaussian': 30, |
---|
600 | 'rectangle': 90/sqrt(3), |
---|
601 | 'uniform': 90, |
---|
602 | } |
---|
603 | |
---|
604 | def run(model_name='parallelepiped', size=(10, 40, 100), |
---|
605 | dist='gaussian', mesh=30, |
---|
606 | projection='equirectangular'): |
---|
607 | """ |
---|
608 | Show an interactive orientation and jitter demo. |
---|
609 | |
---|
610 | *model_name* is one of the models available in :func:`select_model`. |
---|
611 | """ |
---|
612 | # projection number according to 1-order position in list, but |
---|
613 | # only 1 and 2 are implemented so far. |
---|
614 | from sasmodels import generate |
---|
615 | generate.PROJECTION = PROJECTIONS.index(projection) + 1 |
---|
616 | if generate.PROJECTION > 2: |
---|
617 | print("*** PROJECTION %s not implemented in scattering function ***"%projection) |
---|
618 | generate.PROJECTION = 2 |
---|
619 | |
---|
620 | # set up calculator |
---|
621 | calculator, size = select_calculator(model_name, n=150, size=size) |
---|
622 | |
---|
623 | ## uncomment to set an independent the colour range for every view |
---|
624 | ## If left commented, the colour range is fixed for all views |
---|
625 | calculator.limits = None |
---|
626 | |
---|
627 | ## initial view |
---|
628 | #theta, dtheta = 70., 10. |
---|
629 | #phi, dphi = -45., 3. |
---|
630 | #psi, dpsi = -45., 3. |
---|
631 | theta, phi, psi = 0, 0, 0 |
---|
632 | dtheta, dphi, dpsi = 0, 0, 0 |
---|
633 | |
---|
634 | ## create the plot window |
---|
635 | #plt.hold(True) |
---|
636 | plt.subplots(num=None, figsize=(5.5, 5.5)) |
---|
637 | plt.set_cmap('gist_earth') |
---|
638 | plt.clf() |
---|
639 | plt.gcf().canvas.set_window_title(projection) |
---|
640 | #gs = gridspec.GridSpec(2,1,height_ratios=[4,1]) |
---|
641 | #ax = plt.subplot(gs[0], projection='3d') |
---|
642 | ax = plt.axes([0.0, 0.2, 1.0, 0.8], projection='3d') |
---|
643 | try: # CRUFT: not all versions of matplotlib accept 'square' 3d projection |
---|
644 | ax.axis('square') |
---|
645 | except Exception: |
---|
646 | pass |
---|
647 | |
---|
648 | axcolor = 'lightgoldenrodyellow' |
---|
649 | |
---|
650 | ## add control widgets to plot |
---|
651 | axtheta = plt.axes([0.1, 0.15, 0.45, 0.04], axisbg=axcolor) |
---|
652 | axphi = plt.axes([0.1, 0.1, 0.45, 0.04], axisbg=axcolor) |
---|
653 | axpsi = plt.axes([0.1, 0.05, 0.45, 0.04], axisbg=axcolor) |
---|
654 | stheta = Slider(axtheta, 'Theta', -90, 90, valinit=theta) |
---|
655 | sphi = Slider(axphi, 'Phi', -180, 180, valinit=phi) |
---|
656 | spsi = Slider(axpsi, 'Psi', -180, 180, valinit=psi) |
---|
657 | |
---|
658 | axdtheta = plt.axes([0.75, 0.15, 0.15, 0.04], axisbg=axcolor) |
---|
659 | axdphi = plt.axes([0.75, 0.1, 0.15, 0.04], axisbg=axcolor) |
---|
660 | axdpsi= plt.axes([0.75, 0.05, 0.15, 0.04], axisbg=axcolor) |
---|
661 | # Note: using ridiculous definition of rectangle distribution, whose width |
---|
662 | # in sasmodels is sqrt(3) times the given width. Divide by sqrt(3) to keep |
---|
663 | # the maximum width to 90. |
---|
664 | dlimit = DIST_LIMITS[dist] |
---|
665 | sdtheta = Slider(axdtheta, 'dTheta', 0, 2*dlimit, valinit=dtheta) |
---|
666 | sdphi = Slider(axdphi, 'dPhi', 0, 2*dlimit, valinit=dphi) |
---|
667 | sdpsi = Slider(axdpsi, 'dPsi', 0, 2*dlimit, valinit=dpsi) |
---|
668 | |
---|
669 | ## callback to draw the new view |
---|
670 | def update(val, axis=None): |
---|
671 | view = stheta.val, sphi.val, spsi.val |
---|
672 | jitter = sdtheta.val, sdphi.val, sdpsi.val |
---|
673 | # set small jitter as 0 if multiple pd dims |
---|
674 | dims = sum(v > 0 for v in jitter) |
---|
675 | limit = [0, 0, 0.5, 5][dims] |
---|
676 | jitter = [0 if v < limit else v for v in jitter] |
---|
677 | ax.cla() |
---|
678 | draw_beam(ax, (0, 0)) |
---|
679 | draw_jitter(ax, view, jitter, dist=dist, size=size) |
---|
680 | #draw_jitter(ax, view, (0,0,0)) |
---|
681 | draw_mesh(ax, view, jitter, dist=dist, n=mesh, projection=projection) |
---|
682 | draw_scattering(calculator, ax, view, jitter, dist=dist) |
---|
683 | plt.gcf().canvas.draw() |
---|
684 | |
---|
685 | ## bind control widgets to view updater |
---|
686 | stheta.on_changed(lambda v: update(v,'theta')) |
---|
687 | sphi.on_changed(lambda v: update(v, 'phi')) |
---|
688 | spsi.on_changed(lambda v: update(v, 'psi')) |
---|
689 | sdtheta.on_changed(lambda v: update(v, 'dtheta')) |
---|
690 | sdphi.on_changed(lambda v: update(v, 'dphi')) |
---|
691 | sdpsi.on_changed(lambda v: update(v, 'dpsi')) |
---|
692 | |
---|
693 | ## initialize view |
---|
694 | update(None, 'phi') |
---|
695 | |
---|
696 | ## go interactive |
---|
697 | plt.show() |
---|
698 | |
---|
699 | def main(): |
---|
700 | parser = argparse.ArgumentParser( |
---|
701 | description="Display jitter", |
---|
702 | formatter_class=argparse.ArgumentDefaultsHelpFormatter, |
---|
703 | ) |
---|
704 | parser.add_argument('-p', '--projection', choices=PROJECTIONS, default=PROJECTIONS[0], help='coordinate projection') |
---|
705 | parser.add_argument('-s', '--size', type=str, default='10,40,100', help='a,b,c lengths') |
---|
706 | parser.add_argument('-d', '--distribution', choices=DISTRIBUTIONS, default=DISTRIBUTIONS[0], help='jitter distribution') |
---|
707 | parser.add_argument('-m', '--mesh', type=int, default=30, help='#points in theta-phi mesh') |
---|
708 | parser.add_argument('shape', choices=SHAPES, nargs='?', default=SHAPES[0], help='oriented shape') |
---|
709 | opts = parser.parse_args() |
---|
710 | size = tuple(int(v) for v in opts.size.split(',')) |
---|
711 | run(opts.shape, size=size, |
---|
712 | mesh=opts.mesh, dist=opts.distribution, |
---|
713 | projection=opts.projection) |
---|
714 | |
---|
715 | if __name__ == "__main__": |
---|
716 | main() |
---|