1 | //FJSTARTHEADER
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2 | // $Id: ClusterSequenceVoronoiArea.cc 3433 2014-07-23 08:17:03Z salam $
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3 | //
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4 | // Copyright (c) 2006-2014, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
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5 | //
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6 | //----------------------------------------------------------------------
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7 | // This file is part of FastJet.
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8 | //
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9 | // FastJet is free software; you can redistribute it and/or modify
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10 | // it under the terms of the GNU General Public License as published by
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11 | // the Free Software Foundation; either version 2 of the License, or
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12 | // (at your option) any later version.
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13 | //
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14 | // The algorithms that underlie FastJet have required considerable
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15 | // development. They are described in the original FastJet paper,
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16 | // hep-ph/0512210 and in the manual, arXiv:1111.6097. If you use
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17 | // FastJet as part of work towards a scientific publication, please
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18 | // quote the version you use and include a citation to the manual and
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19 | // optionally also to hep-ph/0512210.
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20 | //
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21 | // FastJet is distributed in the hope that it will be useful,
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22 | // but WITHOUT ANY WARRANTY; without even the implied warranty of
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23 | // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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24 | // GNU General Public License for more details.
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25 | //
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26 | // You should have received a copy of the GNU General Public License
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27 | // along with FastJet. If not, see <http://www.gnu.org/licenses/>.
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28 | //----------------------------------------------------------------------
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29 | //FJENDHEADER
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30 |
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31 | #include "fastjet/ClusterSequenceVoronoiArea.hh"
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32 | #include "fastjet/internal/Voronoi.hh"
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33 | #include <list>
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34 | #include <cassert>
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35 | #include <ostream>
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36 | #include <fstream>
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37 | #include <iterator>
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38 | #include <cmath>
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39 | #include <limits>
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40 |
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41 | using namespace std;
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42 |
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43 | FASTJET_BEGIN_NAMESPACE // defined in fastjet/internal/base.hh
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44 |
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45 | typedef ClusterSequenceVoronoiArea::VoronoiAreaCalc VAC;
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46 |
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47 | /// class for carrying out a voronoi area calculation on a set of
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48 | /// initial vectors
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49 | class ClusterSequenceVoronoiArea::VoronoiAreaCalc {
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50 | public:
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51 | /// constructor that takes a range of a vector together with the
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52 | /// effective radius for the intersection of discs with voronoi
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53 | /// cells
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54 | VoronoiAreaCalc(const vector<PseudoJet>::const_iterator &,
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55 | const vector<PseudoJet>::const_iterator &,
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56 | double effective_R);
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57 |
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58 | /// return the area of the particle associated with the given
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59 | /// index
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60 | inline double area (int index) const {return _areas[index];};
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61 |
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62 | private:
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63 | std::vector<double> _areas; ///< areas, numbered as jets
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64 | double _effective_R; ///< effective radius
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65 | double _effective_R_squared; ///< effective radius squared
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66 |
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67 | /**
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68 | * compute the intersection of one triangle with the circle
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69 | * the area is returned
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70 | */
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71 | double edge_circle_intersection(const VPoint &p0,
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72 | const GraphEdge &edge);
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73 |
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74 | /// get the area of a circle of radius R centred on the point 0 with
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75 | /// 1 and 2 on each "side" of the arc. dij is the distance between
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76 | /// point i and point j and all distances are squared
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77 | inline double circle_area(const double d12_2, double d01_2, double d02_2){
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78 | return 0.5*_effective_R_squared
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79 | *acos(min(1.0,(d01_2+d02_2-d12_2)/(2*sqrt(d01_2*d02_2))));
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80 | }
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81 | };
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82 |
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83 |
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84 | /**
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85 | * compute the intersection of one triangle with the circle
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86 | * the area is returned
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87 | */
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88 | double VAC::edge_circle_intersection(const VPoint &p0,
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89 | const GraphEdge &edge){
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90 | VPoint p1(edge.x1-p0.x, edge.y1-p0.y);
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91 | VPoint p2(edge.x2-p0.x, edge.y2-p0.y);
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92 | VPoint pdiff = p2-p1;
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93 |
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94 | //fprintf(stdout, "\tpt(%f,%f)\n", p0.x, p0.y);
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95 |
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96 | double cross = vector_product(p1, p2);
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97 | double d12_2 = norm(pdiff);
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98 | double d01_2 = norm(p1);
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99 | double d02_2 = norm(p2);
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100 |
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101 | // compute intersections between edge line and circle
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102 | double delta = d12_2*_effective_R_squared - cross*cross;
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103 |
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104 | // if no intersection, area=area_circle
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105 | if (delta<=0){
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106 | return circle_area(d12_2, d01_2, d02_2);
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107 | }
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108 |
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109 | // we'll only need delta's sqrt now
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110 | delta = sqrt(delta);
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111 |
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112 | // b is the projection of 01 onto 12
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113 | double b = scalar_product(pdiff, p1);
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114 |
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115 | // intersections with the circle:
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116 | // we compute the "coordinate along the line" of the intersection
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117 | // with t=0 (1) corresponding to p1 (p2)
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118 | // points with 0<t<1 are within the circle others are outside
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119 |
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120 | // positive intersection
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121 | double tp = (delta-b)/d12_2;
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122 |
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123 | // if tp is negative, tm also => inters = circle
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124 | if (tp<0)
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125 | return circle_area(d12_2, d01_2, d02_2);
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126 |
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127 | // we need the second intersection
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128 | double tm = -(delta+b)/d12_2;
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129 |
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130 | // if tp<1, it lies in the circle
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131 | if (tp<1){
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132 | // if tm<0, the segment has one intersection
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133 | // with the circle at p (t=tp)
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134 | // the area is a triangle from 1 to p
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135 | // then a circle from p to 2
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136 | // several tricks can be used:
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137 | // - the area of the triangle is tp*area triangle
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138 | // - the lenght for the circle are easily obtained
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139 | if (tm<0)
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140 | return tp*0.5*fabs(cross)
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141 | +circle_area((1-tp)*(1-tp)*d12_2, _effective_R_squared, d02_2);
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142 |
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143 | // now, 0 < tm < tp < 1
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144 | // the segment intersects twice the circle
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145 | // area = 2 cirles at ends + a triangle in the middle
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146 | // again, simplifications are staightforward
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147 | return (tp-tm)*0.5*fabs(cross)
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148 | + circle_area(tm*tm*d12_2, d01_2, _effective_R_squared)
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149 | + circle_area((1-tp)*(1-tp)*d12_2, _effective_R_squared, d02_2);
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150 | }
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151 |
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152 | // now, we have tp>1
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153 |
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154 | // if in addition tm>1, intersectino is a circle
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155 | if (tm>1)
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156 | return circle_area(d12_2, d01_2, d02_2);
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157 |
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158 | // if tm<0, the triangle is inside the circle
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159 | if (tm<0)
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160 | return 0.5*fabs(cross);
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161 |
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162 | // otherwise, only the "tm point" is on the segment
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163 | // area = circle from 1 to m and triangle from m to 2
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164 |
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165 | return (1-tm)*0.5*fabs(cross)
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166 | +circle_area(tm*tm*d12_2, d01_2, _effective_R_squared);
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167 | }
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168 |
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169 |
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170 | // the constructor...
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171 | //----------------------------------------------------------------------
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172 | VAC::VoronoiAreaCalc(const vector<PseudoJet>::const_iterator &jet_begin,
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173 | const vector<PseudoJet>::const_iterator &jet_end,
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174 | double effective_R) {
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175 |
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176 | assert(effective_R < 0.5*pi);
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177 |
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178 | vector<VPoint> voronoi_particles;
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179 | vector<int> voronoi_indices;
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180 |
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181 | _effective_R = effective_R;
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182 | _effective_R_squared = effective_R*effective_R;
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183 |
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184 | double minrap = numeric_limits<double>::max();
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185 | double maxrap = -minrap;
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186 |
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187 | unsigned int n_tot = 0, n_added = 0;
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188 |
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189 | // loop over jets and create the triangulation, as well as cross-referencing
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190 | // info
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191 | for (vector<PseudoJet>::const_iterator jet_it = jet_begin;
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192 | jet_it != jet_end; jet_it++) {
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193 | _areas.push_back(0.0);
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194 | if ((jet_it->perp2()) != 0.0 || (jet_it->E() != jet_it->pz())){
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195 | // generate the corresponding point
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196 | double rap = jet_it->rap(), phi = jet_it->phi();
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197 | voronoi_particles.push_back(VPoint(rap, phi));
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198 | voronoi_indices.push_back(n_tot);
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199 | n_added++;
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200 |
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201 | // insert a copy of the point if it falls within 2*_R_effective
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202 | // of the 0,2pi borders (because we are interested in any
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203 | // voronoi edge within _R_effective of the other border)
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204 | if (phi < 2*_effective_R) {
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205 | voronoi_particles.push_back(VPoint(rap,phi+twopi));
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206 | voronoi_indices.push_back(-1);
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207 | n_added++;
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208 | } else if (twopi-phi < 2*_effective_R) {
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209 | voronoi_particles.push_back(VPoint(rap,phi-twopi));
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210 | voronoi_indices.push_back(-1);
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211 | n_added++;
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212 | }
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213 |
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214 | // track the rapidity range
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215 | maxrap = max(maxrap,rap);
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216 | minrap = min(minrap,rap);
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217 | }
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218 | n_tot++;
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219 | }
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220 |
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221 | // allow for 0-particle case in graceful way
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222 | if (n_added == 0) return;
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223 | // assert(n_added > 0); // old (pre 2.4) non-graceful exit
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224 |
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225 | // add extreme cases (corner particles):
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226 | double max_extend = 2*max(maxrap-minrap+4*_effective_R, twopi+8*_effective_R);
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227 | voronoi_particles.push_back(VPoint(0.5*(minrap+maxrap)-max_extend, pi));
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228 | voronoi_particles.push_back(VPoint(0.5*(minrap+maxrap)+max_extend, pi));
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229 | voronoi_particles.push_back(VPoint(0.5*(minrap+maxrap), pi-max_extend));
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230 | voronoi_particles.push_back(VPoint(0.5*(minrap+maxrap), pi+max_extend));
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231 |
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232 | // Build the VD
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233 | VoronoiDiagramGenerator vdg;
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234 | vdg.generateVoronoi(&voronoi_particles,
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235 | 0.5*(minrap+maxrap)-max_extend, 0.5*(minrap+maxrap)+max_extend,
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236 | pi-max_extend, pi+max_extend);
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237 |
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238 | vdg.resetIterator();
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239 | GraphEdge *e=NULL;
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240 | unsigned int v_index;
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241 | int p_index;
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242 | vector<PseudoJet>::const_iterator jet;
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243 |
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244 | while(vdg.getNext(&e)){
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245 | v_index = e->point1;
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246 | if (v_index<n_added){ // this removes the corner particles
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247 | p_index = voronoi_indices[v_index];
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248 | if (p_index!=-1){ // this removes the copies
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249 | jet = jet_begin+voronoi_indices[v_index];
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250 | _areas[p_index]+=
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251 | edge_circle_intersection(voronoi_particles[v_index], *e);
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252 | }
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253 | }
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254 | v_index = e->point2;
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255 | if (v_index<n_added){ // this removes the corner particles
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256 | p_index = voronoi_indices[v_index];
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257 | if (p_index!=-1){ // this removes the copies
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258 | jet = jet_begin+voronoi_indices[v_index];
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259 | _areas[p_index]+=
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260 | edge_circle_intersection(voronoi_particles[v_index], *e);
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261 | }
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262 | }
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263 | }
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264 |
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265 |
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266 | }
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267 |
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268 |
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269 | //----------------------------------------------------------------------
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270 | ///
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271 | void ClusterSequenceVoronoiArea::_initializeVA () {
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272 | // run the VAC on our original particles
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273 | _pa_calc = new VAC(_jets.begin(),
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274 | _jets.begin()+n_particles(),
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275 | _effective_Rfact*_jet_def.R());
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276 |
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277 | // transfer the areas to our local structure
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278 | // -- first the initial ones
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279 | _voronoi_area.reserve(2*n_particles());
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280 | _voronoi_area_4vector.reserve(2*n_particles());
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281 | for (unsigned int i=0; i<n_particles(); i++) {
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282 | _voronoi_area.push_back(_pa_calc->area(i));
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283 | // make a stab at a 4-vector area
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284 | if (_jets[i].perp2() > 0) {
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285 | _voronoi_area_4vector.push_back((_pa_calc->area(i)/_jets[i].perp())
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286 | * _jets[i]);
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287 | } else {
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288 | // not sure what to do here -- just put zero (it won't be meaningful
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289 | // anyway)
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290 | _voronoi_area_4vector.push_back(PseudoJet(0.0,0.0,0.0,0.0));
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291 | }
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292 | }
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293 |
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294 | // -- then the combined areas that arise from the clustering
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295 | for (unsigned int i = n_particles(); i < _history.size(); i++) {
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296 | double area_local;
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297 | PseudoJet area_4vect;
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298 | if (_history[i].parent2 >= 0) {
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299 | area_local = _voronoi_area[_history[i].parent1] +
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300 | _voronoi_area[_history[i].parent2];
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301 | area_4vect = _voronoi_area_4vector[_history[i].parent1] +
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302 | _voronoi_area_4vector[_history[i].parent2];
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303 | } else {
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304 | area_local = _voronoi_area[_history[i].parent1];
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305 | area_4vect = _voronoi_area_4vector[_history[i].parent1];
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306 | }
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307 | _voronoi_area.push_back(area_local);
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308 | _voronoi_area_4vector.push_back(area_4vect);
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309 | }
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310 |
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311 | }
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312 |
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313 | //----------------------------------------------------------------------
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314 | ClusterSequenceVoronoiArea::~ClusterSequenceVoronoiArea() {
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315 | delete _pa_calc;
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316 | }
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317 |
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318 | FASTJET_END_NAMESPACE
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