1 | /** |
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2 | This software was developed by the University of Tennessee as part of the |
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3 | Distributed Data Analysis of Neutron Scattering Experiments (DANSE) |
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4 | project funded by the US National Science Foundation. |
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5 | |
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6 | If you use DANSE applications to do scientific research that leads to |
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7 | publication, we ask that you acknowledge the use of the software with the |
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8 | following sentence: |
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9 | |
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10 | "This work benefited from DANSE software developed under NSF award DMR-0520547." |
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11 | |
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12 | copyright 2009, University of Tennessee |
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13 | */ |
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14 | #include "smearer.hh" |
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15 | #include <stdio.h> |
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16 | #include <math.h> |
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17 | using namespace std; |
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18 | |
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19 | #if defined(_MSC_VER) |
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20 | extern "C" { |
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21 | #include "winFuncs.h" |
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22 | } |
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23 | #endif |
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24 | /** |
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25 | * Constructor for BaseSmearer |
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26 | * |
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27 | * @param qmin: minimum Q value |
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28 | * @param qmax: maximum Q value |
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29 | * @param nbins: number of Q bins |
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30 | */ |
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31 | BaseSmearer :: BaseSmearer(double qmin, double qmax, int nbins) { |
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32 | // Number of bins |
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33 | this->nbins = nbins; |
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34 | this->qmin = qmin; |
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35 | this->qmax = qmax; |
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36 | // Flag to keep track of whether we have a smearing matrix or |
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37 | // whether we need to compute one |
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38 | has_matrix = false; |
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39 | even_binning = true; |
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40 | }; |
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41 | |
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42 | /** |
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43 | * Constructor for BaseSmearer |
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44 | * |
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45 | * Used for uneven binning |
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46 | * @param q: array of Q values |
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47 | * @param nbins: number of Q bins |
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48 | */ |
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49 | BaseSmearer :: BaseSmearer(double* q, int nbins) { |
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50 | // Number of bins |
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51 | this->nbins = nbins; |
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52 | this->q_values = q; |
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53 | // Flag to keep track of whether we have a smearing matrix or |
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54 | // whether we need to compute one |
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55 | has_matrix = false; |
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56 | even_binning = false; |
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57 | }; |
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58 | |
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59 | /** |
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60 | * Constructor for SlitSmearer |
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61 | * |
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62 | * @param width: slit width in Q units |
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63 | * @param height: slit height in Q units |
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64 | * @param qmin: minimum Q value |
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65 | * @param qmax: maximum Q value |
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66 | * @param nbins: number of Q bins |
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67 | */ |
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68 | SlitSmearer :: SlitSmearer(double width, double height, double qmin, double qmax, int nbins) : |
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69 | BaseSmearer(qmin, qmax, nbins){ |
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70 | this->height = height; |
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71 | this->width = width; |
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72 | }; |
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73 | |
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74 | /** |
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75 | * Constructor for SlitSmearer |
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76 | * |
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77 | * @param width: slit width in Q units |
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78 | * @param height: slit height in Q units |
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79 | * @param q: array of Q values |
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80 | * @param nbins: number of Q bins |
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81 | */ |
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82 | SlitSmearer :: SlitSmearer(double width, double height, double* q, int nbins) : |
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83 | BaseSmearer(q, nbins){ |
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84 | this->height = height; |
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85 | this->width = width; |
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86 | }; |
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87 | |
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88 | /** |
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89 | * Constructor for QSmearer |
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90 | * |
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91 | * @param width: array slit widths for each Q point, in Q units |
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92 | * @param qmin: minimum Q value |
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93 | * @param qmax: maximum Q value |
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94 | * @param nbins: number of Q bins |
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95 | */ |
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96 | QSmearer :: QSmearer(double* width, double qmin, double qmax, int nbins) : |
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97 | BaseSmearer(qmin, qmax, nbins){ |
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98 | this->width = width; |
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99 | }; |
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100 | |
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101 | /** |
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102 | * Constructor for QSmearer |
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103 | * |
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104 | * @param width: array slit widths for each Q point, in Q units |
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105 | * @param q: array of Q values |
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106 | * @param nbins: number of Q bins |
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107 | */ |
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108 | QSmearer :: QSmearer(double* width, double* q, int nbins) : |
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109 | BaseSmearer(q, nbins){ |
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110 | this->width = width; |
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111 | }; |
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112 | |
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113 | /** |
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114 | * Compute the slit smearing matrix |
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115 | * |
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116 | * For even binning (q_min to q_max with nbins): |
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117 | * |
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118 | * step = (q_max-q_min)/(nbins-1) |
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119 | * first bin goes from q_min to q_min+step |
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120 | * last bin goes from q_max to q_max+step |
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121 | * |
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122 | * For binning according to q array: |
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123 | * |
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124 | * Each q point represents a bin going from half the distance between it |
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125 | * and the previous point to half the distance between it and the next point. |
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126 | * |
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127 | * Example: bin i goes from (q_values[i-1]+q_values[i])/2 to (q_values[i]+q_values[i+1])/2 |
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128 | * |
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129 | * The exceptions are the first and last bins, which are centered at the first and |
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130 | * last q-values, respectively. The width of the first and last bins is the distance between |
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131 | * their respective neighboring q-value. |
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132 | */ |
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133 | void SlitSmearer :: compute_matrix(){ |
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134 | |
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135 | weights = new vector<double>(nbins*nbins,0); |
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136 | |
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137 | // Check the length of the data |
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138 | if (nbins<2) return; |
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139 | int npts_h = height>0.0 ? npts : 1; |
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140 | int npts_w = width>0.0 ? npts : 1; |
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141 | |
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142 | // If both height and width are great than zero, |
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143 | // modify the number of points in each direction so |
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144 | // that the total number of points is still what |
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145 | // the user would expect (downgrade resolution) |
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146 | //if(npts_h>1 && npts_w>1){ |
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147 | // npts_h = (int)ceil(sqrt((double)npts)); |
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148 | // npts_w = npts_h; |
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149 | //} |
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150 | double shift_h, shift_w, hbin_size, wbin_size; |
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151 | // Make sure height and width are all positive (FWMH/2) |
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152 | // Assumption; height and width are all same for all q points |
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153 | if(npts_h == 1){ |
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154 | shift_h = 0.0; |
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155 | } else { |
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156 | shift_h = fabs(height); |
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157 | } |
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158 | if(npts_w == 1){ |
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159 | shift_w = 0.0; |
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160 | } else { |
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161 | shift_w = fabs(width); |
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162 | } |
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163 | // size of the h bin and w bin |
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164 | hbin_size = shift_h / nbins; |
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165 | wbin_size = shift_w / nbins; |
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166 | |
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167 | // Loop over all q-values |
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168 | for(int i=0; i<nbins; i++) { |
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169 | // Find Weights |
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170 | // Find q where the resolution smearing calculation of I(q) occurs |
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171 | double q, q_min, q_max, q_0=0.0; |
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172 | get_bin_range(i, &q, &q_min, &q_max); |
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173 | // Block q becomes <=0 |
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174 | if (q <= 0){ |
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175 | continue; |
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176 | } |
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177 | // Find q[0] value to normalize the weight later, |
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178 | // otherwise, we will have a precision problem. |
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179 | if (i == 0){ |
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180 | q_0 = q; |
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181 | } |
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182 | // Loop over all qj-values |
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183 | for(int j=0; j<nbins; j++) { |
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184 | double q_j, q_high, q_low; |
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185 | // Calculate bin size of q_j |
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186 | get_bin_range(j, &q_j, &q_low, &q_high); |
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187 | // Block q_j becomes <=0 |
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188 | if (q_j <= 0){ |
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189 | continue; |
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190 | } |
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191 | // Check q_low that can not be negative. |
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192 | if (q_low < 0.0){ |
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193 | q_low = 0.0; |
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194 | } |
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195 | // default parameter values |
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196 | (*weights)[i*nbins+j] = 0.0; |
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197 | // protect for negative q |
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198 | if (q <= 0.0 || q_j <= 0.0){ |
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199 | continue; |
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200 | } |
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201 | double shift_w = 0.0; |
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202 | // Condition: zero slit smear. |
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203 | if (npts_w == 1 && npts_h == 1){ |
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204 | if(q_j == q) { |
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205 | (*weights)[i*nbins+j] = 1.0; |
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206 | } |
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207 | } |
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208 | //Condition:Smear weight integration for width >0 when the height (=0) does not present. |
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209 | //Or height << width. |
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210 | else if((npts_w!=1 && npts_h == 1)|| (npts_w!=1 && npts_h != 1 && width/height > 100.0)){ |
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211 | shift_w = width; |
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212 | //del_w = width/((double)npts_w-1.0); |
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213 | double q_shifted_low = q - shift_w; |
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214 | // High limit of the resolution range |
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215 | double q_shifted_high = q + shift_w; |
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216 | // Go through all the q_js for weighting those points |
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217 | if(q_j >= q_shifted_low && q_j <= q_shifted_high) { |
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218 | // The weighting factor comes, |
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219 | // Give some weight (delq_bin) for the q_j within the resolution range |
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220 | // Weight should be same for all qs except |
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221 | // for the q bin size at j. |
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222 | // Note that the division by q_0 is only due to the precision problem |
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223 | // where q_high - q_low gets to very small. |
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224 | // Later, it will be normalized again. |
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225 | (*weights)[i*nbins+j] += (q_high - q_low)/q_0 ; |
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226 | } |
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227 | } |
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228 | else{ |
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229 | // Loop for width (;Height is analytical.) |
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230 | // Condition: height >>> width, otherwise, below is not accurate enough. |
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231 | // Smear weight numerical iteration for width >0 when the height (>0) presents. |
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232 | // When width = 0, the numerical iteration will be skipped. |
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233 | // The resolution calculation for the height is done by direct integration, |
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234 | // assuming the I(q'=sqrt(q_j^2-(q+shift_w)^2)) is constant within a q' bin, [q_high, q_low]. |
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235 | // In general, this weight numerical iteration for width >0 might be a rough approximation, |
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236 | // but it must be good enough when height >>> width. |
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237 | for(int k=(-npts_w + 1); k<npts_w; k++){ |
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238 | if(npts_w!=1){ |
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239 | shift_w = width/((double)npts_w-1.0)*(double)k; |
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240 | } |
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241 | // For each q-value, compute the weight of each other q-bin |
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242 | // in the I(q) array |
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243 | // Low limit of the resolution range |
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244 | double q_shift = q + shift_w; |
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245 | if (q_shift < 0.0){ |
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246 | q_shift = 0.0; |
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247 | } |
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248 | double q_shifted_low = q_shift; |
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249 | // High limit of the resolution range |
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250 | double q_shifted_high = sqrt(q_shift * q_shift + shift_h * shift_h); |
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251 | |
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252 | |
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253 | // Go through all the q_js for weighting those points |
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254 | if(q_j >= q_shifted_low && q_j <= q_shifted_high) { |
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255 | // The weighting factor comes, |
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256 | // Give some weight (delq_bin) for the q_j within the resolution range |
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257 | // Weight should be same for all qs except |
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258 | // for the q bin size at j. |
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259 | // Note that the division by q_0 is only due to the precision problem |
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260 | // where q_high - q_low gets to very small. |
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261 | // Later, it will be normalized again. |
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262 | |
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263 | // The fabs below are not necessary but in case: the weight should never be imaginary. |
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264 | // At the edge of each sub_width. weight += u(at q_high bin) - u(0), where u(0) = 0, |
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265 | // and weighted by (2.0* npts_w -1.0)once for each q. |
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266 | //if (q == q_j) { |
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267 | if (q_low <= q_shift && q_high > q_shift) { |
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268 | //if (k==0) |
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269 | (*weights)[i*nbins+j] += (sqrt(fabs((q_high)*(q_high)-q_shift * q_shift)))/q_0;// * (2.0*double(npts_w)-1.0); |
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270 | } |
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271 | // For the rest of sub_width. weight += u(at q_high bin) - u(at q_low bin) |
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272 | else{// if (u > 0.0){ |
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273 | (*weights)[i*nbins+j] += (sqrt(fabs((q_high)*(q_high)- q_shift * q_shift))-sqrt(fabs((q_low)*(q_low)- q_shift * q_shift)))/q_0 ; |
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274 | } |
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275 | } |
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276 | } |
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277 | } |
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278 | } |
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279 | } |
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280 | }; |
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281 | |
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282 | /** |
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283 | * Compute the point smearing matrix |
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284 | */ |
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285 | void QSmearer :: compute_matrix(){ |
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286 | weights = new vector<double>(nbins*nbins,0); |
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287 | |
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288 | // Loop over all q-values |
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289 | double q, q_min, q_max; |
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290 | double q_j, q_jmax, q_jmin; |
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291 | for(int i=0; i<nbins; i++) { |
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292 | get_bin_range(i, &q, &q_min, &q_max); |
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293 | |
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294 | for(int j=0; j<nbins; j++) { |
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295 | get_bin_range(j, &q_j, &q_jmin, &q_jmax); |
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296 | |
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297 | // Compute the fraction of the Gaussian contributing |
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298 | // to the q_j bin between q_jmin and q_jmax |
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299 | long double value = erf( (q_jmax-q)/(sqrt(2.0)*width[i]) ); |
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300 | value -= erf( (q_jmin-q)/(sqrt(2.0)*width[i]) ); |
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301 | (*weights)[i*nbins+j] += value; |
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302 | } |
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303 | } |
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304 | } |
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305 | |
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306 | /** |
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307 | * Computes the Q range of a given bin of the Q distribution. |
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308 | * The range is computed according the the data distribution that |
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309 | * was given to the object at initialization. |
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310 | * |
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311 | * @param i: number of the bin in the distribution |
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312 | * @param q: q-value of bin i |
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313 | * @param q_min: lower bound of the bin |
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314 | * @param q_max: higher bound of the bin |
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315 | * |
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316 | */ |
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317 | int BaseSmearer :: get_bin_range(int i, double* q, double* q_min, double* q_max) { |
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318 | if (even_binning) { |
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319 | double step = (qmax-qmin)/((double)nbins-1.0); |
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320 | *q = qmin + (double)i*step; |
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321 | *q_min = *q - 0.5*step; |
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322 | *q_max = *q + 0.5*step; |
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323 | return 1; |
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324 | } else if (i>=0 && i<nbins) { |
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325 | *q = q_values[i]; |
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326 | if (i==0) { |
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327 | double step = (q_values[1]-q_values[0])/2.0; |
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328 | *q_min = *q - step; |
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329 | *q_max = *q + step; |
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330 | } else if (i==nbins-1) { |
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331 | double step = (q_values[i]-q_values[i-1])/2.0; |
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332 | *q_min = *q - step; |
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333 | *q_max = *q + step; |
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334 | } else { |
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335 | *q_min = *q - (q_values[i]-q_values[i-1])/2.0; |
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336 | *q_max = *q + (q_values[i+1]-q_values[i])/2.0; |
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337 | } |
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338 | return 1; |
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339 | } |
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340 | return -1; |
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341 | } |
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342 | |
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343 | /** |
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344 | * Perform smearing by applying the smearing matrix to the input Q array |
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345 | */ |
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346 | void BaseSmearer :: smear(double *iq_in, double *iq_out, int first_bin, int last_bin){ |
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347 | |
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348 | // If we haven't computed the smearing matrix, do it now |
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349 | if(!has_matrix) { |
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350 | compute_matrix(); |
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351 | has_matrix = true; |
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352 | } |
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353 | |
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354 | // Loop over q-values and multiply apply matrix |
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355 | for(int q_i=first_bin; q_i<=last_bin; q_i++){ |
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356 | double sum = 0.0; |
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357 | double counts = 0.0; |
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358 | |
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359 | for(int i=first_bin; i<=last_bin; i++){ |
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360 | // Skip if weight is less than 1e-03(this value is much smaller than |
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361 | // the weight at the 3*sigma distance |
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362 | // Will speed up a little bit... |
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363 | if ((*weights)[q_i*nbins+i] < 1.0e-003){ |
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364 | continue; |
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365 | } |
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366 | sum += iq_in[i] * (*weights)[q_i*nbins+i]; |
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367 | counts += (*weights)[q_i*nbins+i]; |
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368 | } |
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369 | |
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370 | // Normalize counts |
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371 | iq_out[q_i] = (counts>0.0) ? sum/counts : 0.0; |
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372 | } |
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373 | } |
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