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Rev | Author | Line No. | Line |
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25 | f9daq | 1 | #include "include/guide.h" |
2 | |||
3 | #include <iostream> |
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4 | |||
5 | // vector output shortcut |
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6 | void printv(TVector3 v) |
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7 | { |
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8 | printf("(x,y,z) = (%.4lf, %.4lf, %.4lf)\n", v.x(), v.y(), v.z()); |
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9 | } |
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10 | // TVector3::Rotate does not seem accurate enough |
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11 | TVector3 rotatey(TVector3 v, double theta) |
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12 | { |
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13 | return TVector3(v.x() * TMath::Cos(theta) + v.z() * TMath::Sin(theta), |
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14 | v.y(), |
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15 | -v.x() * TMath::Sin(theta) + v.z() * TMath::Cos(theta)); |
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16 | } |
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17 | // another shortcut not found in TMath |
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18 | int sign(double in) |
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19 | { |
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20 | if(in >= 0.0) return 1; |
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21 | else return -1; |
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22 | } |
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23 | //================================================================================= |
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24 | |||
25 | //----------------------------------------------------------------------------- |
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26 | void CRay::Set(TVector3 r0, TVector3 n0) |
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27 | { |
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28 | r = r0; n = n0.Unit(); |
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29 | } |
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30 | //----------------------------------------------------------------------------- |
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31 | //void CRay::Set(double x0, double y0, double z0, double l0, double m0, double n0) |
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32 | //{ |
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33 | //r.SetXYZ(x0, y0, z0); |
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34 | //n.SetXYZ(l0, m0, n0); n = n.Unit(); |
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35 | //} |
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36 | //----------------------------------------------------------------------------- |
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37 | /* |
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38 | CRay& CRay::operator = (const CRay& p) |
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39 | { |
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40 | r.SetXYZ(p.GetR().x(), p.GetR().y(), p.GetR().z()); |
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41 | //this->r.SetXYZ(p.x(), p.y(), p.z()); |
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42 | n.SetXYZ(p.GetN().x(), p.GetN().y(), p.GetN().z()); |
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43 | return *this; |
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44 | } */ |
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45 | //----------------------------------------------------------------------------- |
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46 | void CRay::Print() |
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47 | { |
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48 | printf("---> CRay::Print() <---\n"); |
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49 | printf("(x,y,z)=(%.2lf, %.2lf, %.2lf); (l,m,n)=(%.2lf, %.2lf, %.2lf)\n", |
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50 | r.x(), r.y(), r.z(), n.x(), n.y(), n.z()); |
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51 | } |
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52 | //----------------------------------------------------------------------------- |
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53 | void CRay::Draw() |
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54 | { |
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55 | double t = 50.0; |
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56 | TPolyLine3D *line3d = new TPolyLine3D(2); |
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57 | //line3d->SetPoint(0, r.x() - t*n.x(), r.y() - t*n.y(), r.z() - t*n.z()); |
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58 | line3d->SetPoint(0, r.x(), r.y(), r.z()); |
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59 | line3d->SetPoint(1, r.x() + t*n.x(), r.y() + t*n.y(), r.z() + t*n.z()); |
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60 | line3d->SetLineWidth(1); |
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61 | line3d->SetLineColor(color); |
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62 | |||
63 | line3d->Draw(); |
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64 | } |
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65 | //----------------------------------------------------------------------------- |
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66 | void CRay::Draw(double x_from, double x_to) |
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67 | { |
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68 | double A1, A2; |
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69 | TPolyLine3D *line3d = new TPolyLine3D(2); |
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70 | |||
71 | if(n.x() < MARGIN) { |
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72 | A1 = A2 = 0.0; |
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73 | } else { |
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74 | A1 = (x_from - r.x())/n.x(); |
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75 | A2 = (x_to - r.x())/n.x(); |
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76 | } |
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77 | |||
78 | line3d->SetPoint(0, x_from, A1*n.y()+r.y(), A1*n.z()+r.z()); |
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79 | line3d->SetPoint(1, x_to, A2*n.y()+r.y(), A2*n.z()+r.z()); |
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80 | line3d->SetLineWidth(1); |
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81 | line3d->SetLineColor(color); |
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82 | |||
83 | line3d->Draw(); |
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84 | } |
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85 | //----------------------------------------------------------------------------- |
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86 | void CRay::DrawS(double x_from, double t) |
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87 | { |
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88 | double A1; |
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89 | TPolyLine3D *line3d = new TPolyLine3D(2); |
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90 | |||
91 | if(n.x() < MARGIN) |
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92 | A1 = 0.0; |
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93 | else |
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94 | A1 = (x_from - r.x())/n.x(); |
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95 | |||
96 | line3d->SetPoint(0, x_from, A1*n.y()+r.y(), A1*n.z()+r.z()); |
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97 | line3d->SetPoint(1, r.x() + t*n.x(), r.y() + t*n.y(), r.z() + t*n.z()); |
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98 | line3d->SetLineWidth(1); |
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99 | line3d->SetLineColor(color); |
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100 | |||
101 | line3d->Draw(); |
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102 | } |
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103 | //================================================================================= |
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104 | |||
105 | |||
106 | //================================================================================= |
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107 | CPlane4::CPlane4() : |
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108 | n(TVector3(1.0, 0.0, 0.0)), |
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109 | A(0), |
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110 | B(0), |
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111 | C(0), |
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112 | D(0) |
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113 | { r[0] = TVector3(0.0,-1.0,-1.0); |
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114 | r[1] = TVector3(0.0,-1.0, 1.0); |
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115 | r[2] = TVector3(0.0, 1.0, 1.0); |
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116 | r[3] = TVector3(0.0, 1.0,-1.0); |
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117 | for(int i=0;i<4;i++) edge[i] = TVector3(0,0,0); |
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118 | for(int i=0;i<4;i++) angle_r[i] = 0; |
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119 | }; |
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120 | //----------------------------------------------------------------------------- |
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121 | CPlane4::CPlane4(TVector3 r1, TVector3 r2, TVector3 r3, TVector3 r4) |
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122 | { |
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123 | //Set(r1, r2, r3, r4); |
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124 | //} |
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125 | //----------------------------------------------------------------------------- |
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126 | // za izracun parametrov ravnine je en vektor prevec, vendar tega |
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127 | // rabim kot zadnji vogal poligona |
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128 | //void CPlane4::Set(TVector3 r1, TVector3 r2, TVector3 r3, TVector3 r4) |
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129 | //{ |
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130 | double x1,y1,z1, x2,y2,z2, x3,y3,z3; |
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131 | |||
132 | x1 = r1.x(); y1 = r1.y(); z1 = r1.z(); |
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133 | x2 = r2.x(); y2 = r2.y(); z2 = r2.z(); |
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134 | x3 = r3.x(); y3 = r3.y(); z3 = r3.z(); |
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135 | |||
136 | A = y3*(z1 - z2) + y1*(z2 - z3) + y2*(z3 - z1); |
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137 | B = x3*(z2 - z1) + x1*(z3 - z2) + x2*(z1 - z3); |
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138 | C = x3*(y1 - y2) + x1*(y2 - y3) + x2*(y3 - y1); |
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139 | D = y3*(x1*z2 - x2*z1) + x3*(y2*z1 - y1*z2) + z3*(x2*y1 - x1*y2); |
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140 | |||
141 | r[0] = r1; r[1] = r2; r[2] = r3; r[3] = r4; |
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142 | n.SetXYZ(A, B, C); |
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143 | n = n.Unit(); |
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144 | |||
145 | for(int i=0;i<4;i++) |
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146 | edge[i] = r[i-3 ? i+1 : 0] - r[i]; |
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147 | |||
148 | for(int i=0;i<4;i++) |
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149 | angle_r[i] = TMath::ACos(/*TMath::Abs*/( ((-edge[i ? i-1 : 3]).Unit()) * (edge[i].Unit()) )); |
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150 | }; |
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151 | |||
152 | void CPlane4::Set(TVector3 r1, TVector3 r2, TVector3 r3, TVector3 r4) |
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153 | { |
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154 | double x1,y1,z1, x2,y2,z2, x3,y3,z3; |
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155 | |||
156 | x1 = r1.x(); y1 = r1.y(); z1 = r1.z(); |
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157 | x2 = r2.x(); y2 = r2.y(); z2 = r2.z(); |
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158 | x3 = r3.x(); y3 = r3.y(); z3 = r3.z(); |
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159 | |||
160 | A = y3*(z1 - z2) + y1*(z2 - z3) + y2*(z3 - z1); |
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161 | B = x3*(z2 - z1) + x1*(z3 - z2) + x2*(z1 - z3); |
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162 | C = x3*(y1 - y2) + x1*(y2 - y3) + x2*(y3 - y1); |
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163 | D = y3*(x1*z2 - x2*z1) + x3*(y2*z1 - y1*z2) + z3*(x2*y1 - x1*y2); |
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164 | |||
165 | r[0] = r1; r[1] = r2; r[2] = r3; r[3] = r4; |
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166 | n.SetXYZ(A, B, C); |
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167 | n = n.Unit(); |
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168 | |||
169 | for(int i=0;i<4;i++) |
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170 | edge[i] = r[i-3 ? i+1 : 0] - r[i]; |
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171 | |||
172 | for(int i=0;i<4;i++) |
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173 | angle_r[i] = TMath::ACos(/*TMath::Abs*/( ((-edge[i ? i-1 : 3]).Unit()) * (edge[i].Unit()) )); |
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174 | }; |
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175 | |||
176 | CPlane4::CPlane4(TVector3 *vr) |
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177 | { |
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178 | double x1,y1,z1, x2,y2,z2, x3,y3,z3; |
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179 | |||
180 | x1 = vr[0].x(); y1 = vr[0].y(); z1 = vr[0].z(); |
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181 | x2 = vr[1].x(); y2 = vr[1].y(); z2 = vr[1].z(); |
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182 | x3 = vr[2].x(); y3 = vr[2].y(); z3 = vr[2].z(); |
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183 | |||
184 | A = y3*(z1 - z2) + y1*(z2 - z3) + y2*(z3 - z1); |
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185 | B = x3*(z2 - z1) + x1*(z3 - z2) + x2*(z1 - z3); |
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186 | C = x3*(y1 - y2) + x1*(y2 - y3) + x2*(y3 - y1); |
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187 | D = y3*(x1*z2 - x2*z1) + x3*(y2*z1 - y1*z2) + z3*(x2*y1 - x1*y2); |
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188 | |||
189 | r[0] = vr[0]; r[1] = vr[1]; r[2] = vr[2]; r[3] = vr[3]; |
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190 | n.SetXYZ(A, B, C); |
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191 | n = n.Unit(); |
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192 | |||
193 | for(int i=0;i<4;i++) |
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194 | edge[i] = r[i-3 ? i+1 : 0] - r[i]; |
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195 | |||
196 | for(int i=0;i<4;i++) |
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197 | angle_r[i] = TMath::ACos(/*TMath::Abs*/( ((-edge[i ? i-1 : 3]).Unit()) * (edge[i].Unit()) )); |
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198 | }; |
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199 | //----------------------------------------------------------------------------- |
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200 | // posce presecisce !neskoncne! ravnine s premico (class CRay) |
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201 | // ce najde presecisce vrne 1 |
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202 | int CPlane4::GetIntersection(TVector3 *vec, CRay ray) |
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203 | { |
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204 | TVector3 N; //nenormirani vektor (A,B,C) |
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205 | double num, den; //stevec, imenovalec |
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206 | double t; |
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207 | TVector3 tmp; |
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208 | |||
209 | N.SetXYZ(A,B,C); |
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210 | |||
211 | num = N*ray.GetR() + D; |
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212 | den = N*ray.GetN(); |
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213 | |||
214 | if (dbg) printf("t = %6.3lf / %6.3lf = %6.3lf\n", num, den, num/den); |
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215 | |||
216 | //if(den == 0) |
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217 | if(TMath::Abs(den) < MARGIN) { |
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218 | //if(num == 0) |
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219 | if(TMath::Abs(num) < MARGIN) { |
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220 | if (dbg) printf("The ray is on the surface!\n"); |
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221 | return 0; //return 2; // premica lezi na ravnini |
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222 | } |
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223 | else { |
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224 | if (dbg) printf("The ray is parallel to the surface!\n"); |
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225 | return 0; // ni presecisca |
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226 | } |
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227 | } |
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228 | |||
229 | t = num / den; |
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230 | |||
231 | tmp = ray.GetR(); |
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232 | tmp -= t*ray.GetN(); |
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233 | *vec = tmp; |
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234 | return 1; |
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235 | } |
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236 | //----------------------------------------------------------------------------- |
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237 | // ali je vektor vec, ki lezi na ravnini skupaj z e1 in e2, med njima |
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238 | // angle_r je kot med e1 in e2, vsi vektorji imajo skupno izhodisce |
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239 | int CPlane4::IsInTri(TVector3 vec, TVector3 e1, TVector3 e2, double angle) |
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240 | { |
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241 | double angle_ve1, angle_ve2; |
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242 | |||
243 | if(dbg) printf("--- CPlane4::IsInTri ---\n"); |
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244 | |||
245 | angle_ve1 = TMath::ACos(/*TMath::Abs*/( (e1.Unit()) * (vec.Unit()) )); |
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246 | angle_ve2 = TMath::ACos(/*TMath::Abs*/( (e2.Unit()) * (vec.Unit()) )); |
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247 | |||
248 | if(dbg) |
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249 | { |
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70 | f9daq | 250 | printf("angle_ve1 = %lf\n", angle_ve1*DEGREE); |
251 | printf("angle_ve2 = %lf\n", angle_ve2*DEGREE); |
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252 | printf("angle_sum = %lf\n", (angle_ve1 + angle_ve2)*DEGREE); |
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25 | f9daq | 253 | printf(" angle_r = %lf\n", angle*DEGREE); |
254 | } |
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255 | |||
256 | bool difference = (MARGIN < TMath::Abs(angle - (angle_ve1 + angle_ve2))); |
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257 | if (dbg) printf(" MARGIN < Difference = %d\n", difference); |
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258 | return (int) !difference; |
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259 | } |
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260 | //----------------------------------------------------------------------------- |
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261 | // ali je vektor vec, ki lezi na ravnini!, znotraj meja, ki jih definirajo |
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262 | // strije vogali te ravnine r[i] |
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263 | int CPlane4::IsVectorIn(TVector3 vec) |
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264 | { |
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265 | int status; |
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266 | |||
267 | if(dbg) printf("--- CPlane4::IsVectorIn ---\n"); |
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268 | |||
269 | for(int i=0;i<3;i++) |
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270 | { |
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271 | status = IsInTri(vec - r[i], edge[i], -edge[i ? i-1 : 3], angle_r[i]); |
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272 | if(dbg) printf(" [%d] vec is %s\n", i, status ? "inside" : "outside"); |
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273 | if(!status) return 0; |
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274 | } |
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275 | |||
276 | return 1; |
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277 | } |
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278 | //----------------------------------------------------------------------------- |
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279 | int CPlane4::TestIntersection(CRay in) |
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280 | { |
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281 | TVector3 tmp; |
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282 | |||
283 | if( GetIntersection(&tmp, in) ) |
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284 | if( IsVectorIn(tmp) ) |
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285 | return 1; |
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286 | |||
287 | return 0; |
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288 | } |
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289 | //----------------------------------------------------------------------------- |
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290 | int CPlane4::TestIntersection(TVector3 *vec, CRay in) |
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291 | { |
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292 | TVector3 tmp; |
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293 | |||
294 | if( GetIntersection(&tmp, in) ) |
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295 | if( IsVectorIn(tmp) ) { |
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296 | *vec = tmp; |
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297 | return 1; |
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298 | } |
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299 | |||
300 | return 0; |
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301 | } |
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302 | //----------------------------------------------------------------------------- |
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303 | void CPlane4::Print() |
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304 | { |
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305 | printf("--- CPlane4::Print() ---\n"); |
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306 | printf(" r=(%.2lf, %.2lf, %.2lf); n=(%.2lf, %.2lf, %.2lf); ", |
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307 | r[0].x(), r[0].y(), r[0].z(), n.x(), n.y(), n.z()); |
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308 | printf( "(A,B,C,D)=(%.2lf, %.2lf, %.2lf, %.2lf) \n", A, B, C, D); |
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309 | for(int i=0;i<4;i++) printf(" edge[%d] = (%lf, %lf, %lf)\n", i, edge[i].x(), edge[i].y(), edge[i].z()); |
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310 | for(int i=0;i<4;i++) printf(" angle[%d] = %lf\n", i, angle_r[i]*DEGREE); |
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311 | } |
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312 | //----------------------------------------------------------------------------- |
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313 | void CPlane4::Draw(int color, int width) |
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314 | { |
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315 | TPolyLine3D *line3d = new TPolyLine3D(5); |
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316 | |||
317 | for(int i=0;i<4;i++) line3d->SetPoint(i, r[i].x(), r[i].y(), r[i].z()); |
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318 | line3d->SetPoint(4, r[0].x(), r[0].y(), r[0].z()); |
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319 | line3d->SetLineWidth(width); line3d->SetLineColor(color); |
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320 | |||
321 | line3d->Draw(); |
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322 | } |
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323 | //================================================================================= |
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324 | |||
325 | |||
326 | //================================================================================= |
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327 | CSurface::CSurface(int type0): |
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328 | type(type0) |
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329 | { |
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330 | TVector3 vr[4]; |
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331 | TDatime now; |
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332 | |||
333 | vr[0].SetXYZ(0.0,-1.0,-1.0); |
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334 | vr[1].SetXYZ(0.0,-1.0, 1.0); |
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335 | vr[2].SetXYZ(0.0, 1.0, 1.0); |
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336 | vr[3].SetXYZ(0.0, 1.0,-1.0); |
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337 | //CPlane4::Set(vr); |
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338 | SetIndex(1.0, 1.5); |
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339 | |||
340 | reflection = c_reflectivity; |
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341 | rand.SetSeed(now.Get()); |
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342 | |||
343 | SetFresnel(); |
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344 | } |
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345 | //----------------------------------------------------------------------------- |
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346 | CSurface::CSurface(int type0, TVector3 r1, TVector3 r2, TVector3 r3, TVector3 r4, double n10, double n20, double reflectivity) |
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347 | { |
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348 | TDatime now; |
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349 | |||
350 | type = type0; CPlane4::Set(r1, r2, r3, r4); |
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351 | SetIndex(n10, n20); |
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352 | |||
353 | reflection = reflectivity; |
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354 | rand.SetSeed(now.Get()); |
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355 | |||
356 | SetFresnel(); |
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357 | } |
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358 | //----------------------------------------------------------------------------- |
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359 | CSurface::CSurface(int type0, TVector3 *vr, double n10, double n20, double reflectivity) |
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360 | { |
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361 | TDatime now; |
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362 | |||
363 | type = type0; CPlane4::Set(vr); |
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364 | SetIndex(n10, n20); |
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365 | |||
366 | reflection = reflectivity; |
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367 | rand.SetSeed(now.Get()); |
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368 | |||
369 | SetFresnel(); |
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370 | } |
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371 | //----------------------------------------------------------------------------- |
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372 | void CSurface::SetIndex(double n10, double n20) |
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373 | { |
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374 | n1 = n10; n2 = n20; n1_n2 = n1/n2; |
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375 | |||
376 | if(n1 > n2) |
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377 | cosTtotal = TMath::Sqrt( 1 - TMath::Power(n2/n1, 2) ); |
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378 | else |
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379 | cosTtotal = 0.0; |
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380 | } |
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381 | //----------------------------------------------------------------------------- |
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382 | // sprejme zarek, vrne uklonjen/odbit zarek in presecisce |
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383 | // vrne 0 ce ni presecisca; 1 ce se je lomil |
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384 | // 2 ce se je odbil; -2 ce se je absorbiral |
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385 | int CSurface::PropagateRay(CRay in, CRay *out, TVector3 *intersection) |
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386 | { |
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387 | if (dbg) printf("--- CSurface::PropagateRay ---\n"); |
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71 | f9daq | 388 | double cosTi; // incident ray angle |
389 | double cosTt; // transmited ray angle |
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25 | f9daq | 390 | TVector3 intersect, transmit; |
391 | |||
392 | if( !(GetIntersection(&intersect, in) == 1) ) |
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393 | return 0; |
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394 | |||
395 | *intersection = intersect; |
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396 | if( !IsVectorIn(intersect) ) |
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397 | return 0; |
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398 | |||
399 | // --------------- Fresnel ---------------------------------------------------- |
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400 | // R_f = a_te * R_te + a_tm * R_tm |
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70 | f9daq | 401 | // e - electrical/perependicular |
402 | // m - magnetic polarization/parallel |
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25 | f9daq | 403 | double r_te=0; |
404 | double r_tm=0; |
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70 | f9daq | 405 | double R_te=0; // s reflection coefficient |
406 | double R_tm=0; // p reflection coefficient |
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25 | f9daq | 407 | double R_f = 0.0; |
70 | f9daq | 408 | double a_te = 0.0; // s-wave amplitude, cos Alpha |
409 | double a_tm = 0.0; // p-wave amplitude, sin Alpha |
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410 | TVector3 v_te; // unit s-polarization vector |
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411 | TVector3 v_tm; // unit p-polarization vector |
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25 | f9daq | 412 | TVector3 v_tm_t;// transmited polarization parallel with the plane of incidence |
413 | TVector3 pol_t = in.GetP(); // transmited polarization |
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414 | int sign_n; // sign of normal direction vs. inbound ray |
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415 | double cosTN; // debug |
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416 | |||
70 | f9daq | 417 | if(fresnel) { |
418 | // p-polarization unit vector v_te |
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419 | // is in the plane orthogonal to the plane of incidence |
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420 | // defined as the plane spanned by |
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421 | // incident surface vector n and wave vector k |
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422 | // k in this notation is in.GetN() |
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423 | v_te = n.Cross(in.GetN()); |
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424 | v_te = v_te.Unit(); |
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425 | v_tm = -v_te.Cross(in.GetN()); |
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426 | v_tm = v_tm.Unit(); |
||
25 | f9daq | 427 | if(dbg) { |
428 | printf(" v_te = "); printv(v_te); |
||
429 | printf(" v_tm = "); printv(v_tm); |
||
430 | } |
||
431 | |||
432 | double cosAf = v_te * in.GetP(); |
||
433 | if(dbg) printf(" cosAf = %lf (Af = %lf)\n", cosAf, TMath::ACos(cosAf)*DEGREE); |
||
434 | |||
435 | a_te = cosAf; |
||
436 | a_tm = TMath::Sqrt(1 - cosAf*cosAf); |
||
437 | if(dbg) printf(" a_te = %lf, a_tm = %lf\n", a_te, a_tm); |
||
438 | } |
||
439 | // ---------------------------------------------------------------------------- |
||
440 | |||
71 | f9daq | 441 | // reflection probability |
442 | double p_ref = rand.Uniform(0.0, 1.0); |
||
443 | |||
70 | f9daq | 444 | if(type == SURF_TOTAL) type = SURF_REFRA; |
25 | f9daq | 445 | switch(type){ |
446 | // ---------------------------------------------------------------------------- |
||
447 | // --------------- refraction from n1 to n2 ----------------------------------- |
||
448 | // ---------------------------------------------------------------------------- |
||
449 | case SURF_REFRA: |
||
450 | cosTi = in.GetN() * n; |
||
451 | if(dbg) printf(" cosTi = %lf (Ti = %lf)\n", cosTi, TMath::ACos(cosTi)*DEGREE); |
||
452 | sign_n = -sign(cosTi); |
||
453 | if(dbg) printf(" sign_n = %d\n", sign_n); |
||
454 | cosTi = TMath::Abs(cosTi); |
||
455 | |||
456 | // Check if there can be total reflection: n1 > n2 |
||
457 | if(N1_N2(-sign_n) < 1.0) |
||
458 | cosTtotal = TMath::Sqrt( 1 - TMath::Power(N1_N2(-sign_n), 2) ); |
||
459 | else |
||
460 | cosTtotal = 0.0; |
||
461 | |||
462 | if(dbg) printf(" cosTtotal = %lf (Ttotal = %lf)\n", cosTtotal, TMath::ACos(cosTtotal)*DEGREE); |
||
54 | f9daq | 463 | // reflection dependance on polarization missing |
464 | // reflection hardcoded to 0.96 |
||
465 | if (dbg) printf(" reflection probability = %f\n", p_ref); |
||
25 | f9daq | 466 | |
70 | f9daq | 467 | // If n1>n2 and theta>thetaCritical, total reflection |
71 | f9daq | 468 | if(cosTi < cosTtotal) { |
25 | f9daq | 469 | if(dbg) printf(" TOTAL\n"); |
470 | transmit = in.GetN() + sign_n*2*cosTi*n; |
||
471 | |||
472 | if(dbg) { |
||
473 | cosTN = TMath::Abs(transmit.Unit() * n); |
||
474 | printf(" cosTN = %lf (TN = %lf) (Abs(TN) = %lf)\n", cosTN, TMath::ACos(cosTN)*DEGREE, TMath::ACos(TMath::Abs(cosTN))*DEGREE); |
||
475 | } |
||
476 | out->Set(intersect, transmit); |
||
477 | |||
478 | pol_t = -in.GetP() + sign_n*2*cosTi*n; |
||
479 | out->SetPolarization(pol_t); |
||
54 | f9daq | 480 | return REFLECTION; |
70 | f9daq | 481 | } else { |
54 | f9daq | 482 | // reflection or refraction according to Fresnel equations |
25 | f9daq | 483 | if(dbg) printf(" REFRACTION\n"); |
484 | if(dbg) printf(" N1_N2(sign_n) = %lf\n", N1_N2(sign_n)); |
||
485 | cosTt = TMath::Sqrt(1 - TMath::Power(N1_N2(sign_n), 2)*(1 - TMath::Power(cosTi, 2))); |
||
486 | if(dbg) printf(" cosTt = %lf (Tt = %lf) \n", cosTt, TMath::ACos(cosTt)*DEGREE); |
||
487 | |||
488 | transmit = N1_N2(sign_n)*in.GetN() + sign_n*(N1_N2(sign_n)*cosTi - cosTt)*n; |
||
489 | if(dbg) {printf(" transmit.Unit() = "); printv(transmit.Unit());} |
||
490 | if(dbg) { |
||
491 | cosTN = transmit.Unit() * n; |
||
492 | printf(" cosTN = %lf (TN = %lf) (Abs(TN) = %lf)\n", cosTN, TMath::ACos(cosTN)*DEGREE, TMath::ACos(TMath::Abs(cosTN))*DEGREE); |
||
71 | f9daq | 493 | } |
494 | |||
25 | f9daq | 495 | //if(cosTi<=cosTtotal) cosTt = TMath::Sqrt(1 - TMath::Power(N1_N2(sign_n), 2)*(1 - TMath::Power(cosTi, 2))); |
54 | f9daq | 496 | //if(fresnel) { |
71 | f9daq | 497 | r_te = (n1*cosTi - n2*cosTt)/(n1*cosTi + n2*cosTt); // transverse |
498 | r_tm = (n2*cosTi - n1*cosTt)/(n1*cosTt + n2*cosTi); // paralel |
||
25 | f9daq | 499 | |
71 | f9daq | 500 | if(dbg) printf(" r_te = %lf, r_tm = %lf\n", r_te, r_tm); |
25 | f9daq | 501 | |
71 | f9daq | 502 | // transmited polarization |
503 | v_tm_t = -v_te.Cross(transmit); |
||
504 | v_tm_t = v_tm_t.Unit(); |
||
505 | pol_t = a_te * (1.0 - TMath::Abs(r_te)) * v_te + a_tm * (1.0 - TMath::Abs(r_tm)) * v_tm_t; |
||
25 | f9daq | 506 | |
71 | f9daq | 507 | if(dbg) { |
25 | f9daq | 508 | printf(" v_tm_t = "); printv(v_tm_t); |
509 | printf(" pol_t = "); printv(pol_t); |
||
71 | f9daq | 510 | } |
70 | f9daq | 511 | |
71 | f9daq | 512 | // Fresnel coefficients |
513 | R_te = TMath::Power(r_te, 2); |
||
514 | R_tm = TMath::Power(r_tm, 2); |
||
515 | R_f = a_te*a_te*R_te + a_tm*a_tm*R_tm; |
||
25 | f9daq | 516 | |
71 | f9daq | 517 | if (dbg) printf(" R_te = %lf, R_tm = %lf, R_f = %lf\n", R_te, R_tm, R_f); |
518 | } |
||
54 | f9daq | 519 | |
71 | f9daq | 520 | if(p_ref >= R_f) { // se lomi |
521 | if (dbg) printf(" SURFACE REFRACTED. Return.\n"); |
||
25 | f9daq | 522 | out->Set(intersect, transmit); |
523 | out->SetPolarization(pol_t); |
||
54 | f9daq | 524 | return REFRACTION; |
25 | f9daq | 525 | } else { // se odbije |
54 | f9daq | 526 | if (dbg) printf(" SURFACE REFLECTED. p_ref=%f, R_f=%f\n", p_ref, R_f); |
25 | f9daq | 527 | transmit = in.GetN() + sign_n*2*cosTi*n; |
528 | out->Set(intersect, transmit); |
||
529 | pol_t = -in.GetP() + sign_n*2*cosTi*n; |
||
530 | out->SetPolarization(pol_t); |
||
54 | f9daq | 531 | return REFLECTION; |
532 | } |
||
533 | |||
534 | //} |
||
25 | f9daq | 535 | break; |
54 | f9daq | 536 | |
25 | f9daq | 537 | // ---------------------------------------------------------------------------- |
538 | // --------------- reflection at "reflection" probability --------------------- |
||
539 | // ---------------------------------------------------------------------------- |
||
540 | case SURF_REFLE: |
||
541 | p_ref = rand.Uniform(0.0, 1.0); |
||
542 | if(p_ref < reflection) { // se odbije |
||
543 | cosTi = in.GetN() * n; |
||
544 | transmit = in.GetN() - 2*cosTi*n; |
||
545 | out->Set(intersect, transmit); |
||
54 | f9daq | 546 | return REFLECTION; //sdhfvjhsdbfjhsdbcvjhsb |
25 | f9daq | 547 | } else { // se ne odbije |
548 | transmit = in.GetN(); |
||
549 | out->Set(intersect, transmit); |
||
54 | f9daq | 550 | return ABSORBED; |
25 | f9daq | 551 | } |
552 | break; |
||
553 | |||
554 | // total reflection from n1 to n2 with R probbability |
||
555 | case SURF_IMPER: |
||
556 | p_ref = rand.Uniform(0.0, 1.0); |
||
557 | if(p_ref < reflection) { // se odbije |
||
558 | cosTi = in.GetN() * n; |
||
559 | if(TMath::Abs(cosTi) < cosTtotal) { // totalni odboj |
||
560 | transmit = in.GetN() - 2*cosTi*n; |
||
561 | out->Set(intersect, transmit); |
||
562 | } else { // ni tot. odboja |
||
563 | transmit = in.GetN(); |
||
564 | out->Set(intersect, transmit); |
||
54 | f9daq | 565 | return ABSORBED; |
25 | f9daq | 566 | } |
567 | } else { // se ne odbije |
||
568 | transmit = in.GetN(); |
||
569 | out->Set(intersect, transmit); |
||
54 | f9daq | 570 | return ABSORBED; |
25 | f9daq | 571 | } |
572 | break; |
||
573 | |||
574 | default: |
||
575 | *out = in; |
||
576 | break; |
||
577 | } |
||
578 | |||
54 | f9daq | 579 | return REFRACTION; |
25 | f9daq | 580 | } |
581 | //================================================================================= |
||
582 | |||
583 | |||
584 | //================================================================================= |
||
585 | Guide::Guide(TVector3 center0, DetectorParameters ¶meters) |
||
586 | { |
||
587 | double t; |
||
588 | |||
70 | f9daq | 589 | TDatime now; |
590 | rand.SetSeed(now.Get()); |
||
25 | f9daq | 591 | |
592 | center = center0; |
||
593 | double b = parameters.getB(); |
||
594 | double a = parameters.getA(); |
||
595 | _d = parameters.getD(); |
||
596 | n1 = parameters.getN1(); |
||
597 | n2 = parameters.getN2(); |
||
598 | // if PlateOn, then n0 = n3 (optical grease), else = n1 (air) |
||
70 | f9daq | 599 | //double n0 = (parameters.getPlateOn() ? parameters.getN3(): n1); |
600 | double n0 = (parameters.getPlateOn() ? n2 : n1); |
||
25 | f9daq | 601 | n3 = parameters.getN3(); |
602 | _r = c_reflectivity; |
||
603 | int fresnel = parameters.getFresnel(); |
||
604 | |||
70 | f9daq | 605 | // light guide edges |
25 | f9daq | 606 | t = b/2.0; |
70 | f9daq | 607 | vodnik_edge[0].SetXYZ(0.0, t,-t); |
608 | vodnik_edge[1].SetXYZ(0.0, t, t); |
||
609 | vodnik_edge[2].SetXYZ(0.0,-t, t); |
||
610 | vodnik_edge[3].SetXYZ(0.0,-t,-t); |
||
25 | f9daq | 611 | t = a/2.0; |
70 | f9daq | 612 | vodnik_edge[4].SetXYZ(_d, t,-t); |
613 | vodnik_edge[5].SetXYZ(_d, t, t); |
||
614 | vodnik_edge[6].SetXYZ(_d,-t, t); |
||
615 | vodnik_edge[7].SetXYZ(_d,-t,-t); |
||
25 | f9daq | 616 | |
617 | for(int i = 0; i<8; i++) vodnik_edge[i] += center; |
||
70 | f9daq | 618 | |
619 | // light guide surfaces |
||
25 | f9daq | 620 | s_side[0] = new CSurface(SURF_REFRA, vodnik_edge, n0, n2, _r); |
621 | s_side[0]->FlipN(); |
||
70 | f9daq | 622 | |
25 | f9daq | 623 | s_side[1] = new CSurface(SURF_REFRA, vodnik_edge[3], vodnik_edge[2], vodnik_edge[6], vodnik_edge[7], n2, n1, _r); |
624 | s_side[2] = new CSurface(SURF_REFRA, vodnik_edge[2], vodnik_edge[1], vodnik_edge[5], vodnik_edge[6], n2, n1, _r); |
||
625 | s_side[3] = new CSurface(SURF_REFRA, vodnik_edge[1], vodnik_edge[0], vodnik_edge[4], vodnik_edge[5], n2, n1, _r); |
||
626 | s_side[4] = new CSurface(SURF_REFRA, vodnik_edge[0], vodnik_edge[3], vodnik_edge[7], vodnik_edge[4], n2, n1, _r); |
||
627 | |||
70 | f9daq | 628 | s_side[5] = new CSurface(SURF_REFRA, &vodnik_edge[4], n2, n3, _r); // n3 - ref ind at the exit, grease, air, epoxy |
25 | f9daq | 629 | s_side[5]->FlipN(); |
630 | |||
631 | if(fresnel) for(int i=0; i<6; i++) s_side[i]->SetFresnel(1); |
||
632 | |||
70 | f9daq | 633 | // statistics histograms |
25 | f9daq | 634 | hfate = (TH1F*)gROOT->FindObject("hfate"); if(hfate) delete hfate; |
635 | hfate = new TH1F("hfate", "Ray fate", 8, -3.5, 4.5); |
||
636 | (hfate->GetXaxis())->SetBinLabel(1, "Back Ref"); |
||
54 | f9daq | 637 | (hfate->GetXaxis())->SetBinLabel(2, "No Ref"); |
638 | (hfate->GetXaxis())->SetBinLabel(3, "Refrac"); |
||
25 | f9daq | 639 | (hfate->GetXaxis())->SetBinLabel(4, "LG Miss"); |
640 | (hfate->GetXaxis())->SetBinLabel(5, "Exit"); |
||
641 | (hfate->GetXaxis())->SetBinLabel(6, "Enter"); |
||
642 | (hfate->GetXaxis())->SetBinLabel(7, "Rays"); |
||
643 | (hfate->GetXaxis())->SetBinLabel(8, "Absorb"); |
||
644 | |||
645 | hnodb_all = (TH1F*)gROOT->FindObject("hnodb_all"); if(hnodb_all) delete hnodb_all; |
||
54 | f9daq | 646 | hnodb_all = new TH1F("hnodb_all", "N reflected", MAX_REFLECTIONS, -0.5, MAX_REFLECTIONS-0.5); |
25 | f9daq | 647 | |
648 | hnodb_exit = (TH1F*)gROOT->FindObject("hnodb_exit"); if(hnodb_exit) delete hnodb_exit; |
||
54 | f9daq | 649 | hnodb_exit = new TH1F("hnodb_exit", "N reflected and exit", MAX_REFLECTIONS, -0.5, MAX_REFLECTIONS-0.5); |
25 | f9daq | 650 | |
651 | int nBins = nch + 1; |
||
652 | hin = (TH2F*)gROOT->FindObject("hin"); if(hin) delete hin; |
||
653 | hin = new TH2F("hin", "Guide entrance window", nBins, -b/2.0, +b/2.0, nBins, -b/2.0, +b/2.0); |
||
654 | |||
655 | hout = (TH2F*)gROOT->FindObject("hout"); if(hout) delete hout; |
||
656 | hout = new TH2F("hout", "Guide exit window", nBins, -a/2.0, +a/2.0, nBins, -a/2.0, +a/2.0); |
||
657 | |||
658 | absorption = 0; |
||
659 | A = 0; |
||
660 | } |
||
661 | //----------------------------------------------------------------------------- |
||
662 | // Sledi zarku skozi vodnik. Vrne: |
||
663 | // 0, ce zgresi vstopno ploskev |
||
664 | // 1, ce zadane izstopno ploskev |
||
665 | // -1, ce se v vodniku ne odbije totalno |
||
666 | // 2, enter the light guide, bin 2 of hfate = refraction |
||
667 | // -2, ce se ne odbije zaradi koncnega R stranic |
||
668 | // -3, ce se odbije nazaj in gre nazaj ven skozi sprednjo ploskev |
||
669 | // +4, ce se absorbira v materialu |
||
670 | Fate Guide::PropagateRay(CRay in, CRay *out, int *n_points, TVector3 *points) |
||
671 | { |
||
672 | if (dbg) printf("--- GUIDE::PropagateRay ---\n"); |
||
673 | CRay ray0; |
||
674 | CRay ray1; |
||
675 | TVector3 vec0, vec1; |
||
676 | int inters_i = 0; |
||
677 | |||
678 | ray0 = in; |
||
679 | int n_odb = 0; |
||
680 | int last_hit = 0; |
||
681 | int propagation = 0; |
||
54 | f9daq | 682 | int result = s_side[0]->PropagateRay(ray0, &ray1, &vec1); |
683 | if( !(result) ) { |
||
25 | f9daq | 684 | // ce -NI- presecisca z vstopno |
685 | if (dbg) printf(" GUIDE: missed the light guide\n"); |
||
686 | fate = missed; |
||
54 | f9daq | 687 | //hfate->Fill(0); |
688 | } else if(result == REFLECTION) { |
||
689 | if (dbg) printf(" REFLECTED on the entry surface!\n"); |
||
690 | fate = backreflected; |
||
691 | //hfate->Fill(-3); |
||
25 | f9daq | 692 | } else { |
693 | if (dbg) printf(" GUIDE: ray entered\n"); |
||
694 | points[0] = ray1.GetR(); |
||
70 | f9daq | 695 | hfate->Fill(enter); // enter |
25 | f9daq | 696 | hin->Fill(vec1.y(), vec1.z()); |
697 | if (dbg) printf(" GUIDE: n_odb = %d\n", n_odb); |
||
54 | f9daq | 698 | |
699 | while (n_odb++ < MAX_REFLECTIONS) { |
||
25 | f9daq | 700 | if (dbg) printf(" GUIDE: Boundary test: %d\n",n_odb); |
701 | ray0 = ray1; |
||
702 | vec0 = vec1; |
||
703 | propagation = 11; |
||
704 | for(inters_i=0; inters_i<6; inters_i++) { |
||
705 | if (dbg) printf(" GUIDE: Test intersection with surface %d \n", inters_i); |
||
706 | if( inters_i != last_hit) { |
||
707 | int testBoundary = s_side[inters_i]->TestIntersection(&vec1, ray1); |
||
708 | if( testBoundary ) { |
||
709 | if (dbg) printf(" GUIDE: ray intersects with LG surface %d\n",inters_i); |
||
710 | break; |
||
711 | } |
||
712 | } |
||
713 | } |
||
714 | points[n_odb] = vec1; |
||
715 | if(inters_i == 0) { |
||
716 | fate = backreflected; |
||
54 | f9daq | 717 | //hfate->Fill(backreflected); |
25 | f9daq | 718 | break; |
719 | } // backreflection |
||
54 | f9daq | 720 | |
721 | // the passage is possible, test propagation |
||
25 | f9daq | 722 | propagation = s_side[inters_i]->PropagateRay(ray0, &ray1, &vec1); |
54 | f9daq | 723 | |
25 | f9daq | 724 | if (dbg) printf(" GUIDE: surface = %d, propagation = %d\n", inters_i, propagation); |
54 | f9daq | 725 | |
726 | if(propagation == REFRACTION) { |
||
727 | fate = refracted; |
||
728 | n_odb++; |
||
729 | points[n_odb] = vec1; |
||
730 | ray0 = ray1; |
||
731 | break; |
||
732 | } // no total reflection when should be |
||
733 | if(propagation == ABSORBED) { |
||
734 | fate = noreflection; |
||
735 | break; |
||
736 | } //refraction due to finite reflectivity |
||
737 | |||
25 | f9daq | 738 | if(inters_i == 5) { // successfull exit |
739 | // check on which side the vector is? |
||
740 | TVector3 ray = ray1.GetN(); |
||
741 | TVector3 exitNormal = s_side[5]->GetN(); |
||
742 | //printf("theta(ray) = %lf, theta(normal5) = %lf ", ray.Theta()*DEGREE, exitNormal.Theta()*DEGREE); |
||
743 | //printf("phi(ray) = %lf, phi(normal5) = %lf\n", ray.Phi()*DEGREE, exitNormal.Phi()*DEGREE); |
||
744 | if (dbg) printf("ray*n_5 = %lf\n", ray*exitNormal); |
||
745 | if (ray*exitNormal > 0) { |
||
746 | if (dbg) printf(" GUIDE: ray is backreflected from exit window.\n"); |
||
747 | fate = backreflected; |
||
748 | n_odb++; |
||
749 | points[n_odb] = vec1; |
||
750 | ray0 = ray1; |
||
751 | break; |
||
752 | } |
||
54 | f9daq | 753 | fate = hitExit; |
25 | f9daq | 754 | hout->Fill(vec1.y(), vec1.z()); |
755 | hnodb_exit->Fill(n_odb-1); |
||
756 | n_odb++; |
||
757 | points[n_odb] = vec1; |
||
758 | ray0 = ray1; |
||
759 | break; |
||
760 | } |
||
761 | last_hit = inters_i; |
||
762 | } |
||
763 | } |
||
764 | |||
765 | //--- material absorption --- |
||
766 | if(absorption) { |
||
767 | double travel = 0.0; |
||
768 | printf("n_odb = %d\n", n_odb); //dbg |
||
769 | for(int point = 0; point < n_odb-1; point++) { |
||
770 | travel += (points[point] - points[point+1]).Mag(); |
||
771 | printf("travel = %lf\n", travel); //dbg |
||
772 | } |
||
773 | double T_abs = TMath::Exp(-travel/A); |
||
774 | printf("T_abs = %lf\n", T_abs); //dbg |
||
775 | double p_abs = rand.Uniform(0.0, 1.0); |
||
776 | printf("p_abs = %lf\n", p_abs); //dbg |
||
777 | |||
778 | if(p_abs > T_abs) fate = absorbed; // absorption |
||
779 | } |
||
780 | //--- material absorption --- |
||
781 | |||
782 | hfate->Fill(fate); |
||
54 | f9daq | 783 | hfate->Fill(rays); |
25 | f9daq | 784 | hnodb_all->Fill(n_odb-2); |
785 | *n_points = n_odb+1; |
||
786 | *out = ray0; |
||
787 | return fate; |
||
788 | } |
||
789 | //----------------------------------------------------------------------------- |
||
790 | void Guide::GetVFate(int *out) |
||
791 | { |
||
792 | for(int i=0;i<7;i++) out[i] = (int)hfate->GetBinContent(i+1); |
||
793 | } |
||
794 | //----------------------------------------------------------------------------- |
||
795 | void Guide::Draw(int color, int width) |
||
796 | { |
||
797 | for(int i = 0; i<6; i++) s_side[i]->Draw(color, width); |
||
798 | } |
||
799 | //----------------------------------------------------------------------------- |
||
800 | void Guide::DrawSkel(int color, int width) |
||
801 | { |
||
802 | TPolyLine3D *line3d = new TPolyLine3D(2); |
||
803 | line3d->SetLineWidth(width); line3d->SetLineColor(color); |
||
804 | |||
805 | for(int i=0; i<4; i++) { |
||
806 | line3d->SetPoint(0, vodnik_edge[i+0].x(), vodnik_edge[i+0].y(), vodnik_edge[i+0].z()); |
||
807 | line3d->SetPoint(1, vodnik_edge[i+4].x(), vodnik_edge[i+4].y(), vodnik_edge[i+4].z()); |
||
808 | line3d->DrawClone(); |
||
809 | } |
||
810 | } |
||
811 | //================================================================================= |
||
812 | |||
813 | //================================================================================= |
||
814 | int CPlaneR::TestIntersection(TVector3 *vec, CRay ray) |
||
815 | { |
||
816 | double num, den; //stevec, imenovalec |
||
817 | double t; |
||
818 | TVector3 tmp; |
||
819 | |||
820 | if(dbg) printf("---> CPlaneR::TestIntersection <---\n"); |
||
821 | if(dbg) {printf("c = "); printv(center); printf(" | n = "); printv(n); printf("\n");} |
||
822 | |||
823 | double D = - n*center; |
||
824 | num = n*ray.GetR() + D; |
||
825 | den = n*ray.GetN(); |
||
826 | |||
827 | if(dbg) printf("D = %.4lf | num = %.4lf | den = %.4lf\n", D, num, den); |
||
828 | |||
829 | if(TMath::Abs(den) < MARGIN) { |
||
830 | if(TMath::Abs(num) < MARGIN) |
||
831 | return 0; |
||
832 | else |
||
833 | return 0; |
||
834 | } |
||
835 | |||
836 | t = num / den; |
||
837 | |||
838 | if(dbg) printf("t = %.4lf | ", t); |
||
839 | |||
840 | tmp = ray.GetR(); |
||
841 | tmp -= t*ray.GetN(); |
||
842 | *vec = tmp; |
||
843 | |||
844 | if(dbg) {printv(tmp); printf(" | Rv = %.4lf <> R = %.4lf\n", ((tmp - center).Mag()), _r);} |
||
845 | |||
846 | |||
847 | if( ((tmp - center).Mag()) < _r ) |
||
848 | return 1; |
||
849 | else |
||
850 | return 0; |
||
851 | } |
||
852 | //----------------------------------------------------------------------------- |
||
853 | void CPlaneR::Draw(int color, int width) |
||
854 | { |
||
855 | const int NN = 32; |
||
856 | double phi, x, y; |
||
857 | |||
858 | TPolyLine3D *arc; |
||
859 | arc = new TPolyLine3D(NN+1); |
||
860 | arc->SetLineWidth(width); |
||
861 | arc->SetLineColor(color); |
||
862 | |||
863 | for(int i=0; i<=NN; i++) { |
||
864 | phi = i*2.0*TMath::Pi()/NN; |
||
865 | x = _r*TMath::Cos(phi); |
||
866 | y = _r*TMath::Sin(phi); |
||
867 | arc->SetPoint(i, center.x(), x, y); |
||
868 | } |
||
869 | arc->Draw(); |
||
870 | } |
||
871 | //================================================================================= |
||
872 | |||
873 | |||
874 | //================================================================================= |
||
875 | CDetector::CDetector(TVector3 center0, DetectorParameters& parameters) : |
||
876 | center(center0), |
||
877 | glass_on(parameters.getGlassOn()), |
||
878 | glass_d(parameters.getGlassD()), |
||
879 | //x_gap(parameters.getGap().X()), |
||
880 | //y_gap(parameters.getGap().Y()), |
||
881 | //z_gap(parameters.getGap().Z()), |
||
882 | //glass(new CSurface), |
||
883 | //glass_circle(new CPlaneR), |
||
884 | //active(new CPlane4), |
||
885 | col_in(2), |
||
886 | col_lg(8), |
||
887 | col_out(4), |
||
888 | col_rgla(6), |
||
889 | col_LG(1), |
||
890 | col_glass(4), |
||
891 | col_active(7), |
||
892 | guide_on(parameters.getGuideOn()), |
||
893 | //window_R( parameters.getB() ), |
||
894 | //window_d(0), |
||
895 | guide(new Guide(center0, parameters)), |
||
896 | plate(new Plate(parameters)), |
||
897 | _plateWidth(parameters.getPlateWidth()), |
||
54 | f9daq | 898 | _plateOn(parameters.getPlateOn()), |
899 | offsetY(parameters.getOffsetY()), |
||
900 | offsetZ(parameters.getOffsetZ()) |
||
25 | f9daq | 901 | { |
902 | // }; |
||
903 | |||
904 | //----------------------------------------------------------------------------- |
||
905 | //void CDetector::Init() |
||
906 | //{ |
||
907 | double d = parameters.getD(); |
||
908 | double x_offset; |
||
909 | if(guide_on) x_offset = center.x(); |
||
910 | else x_offset = center.x() - d; |
||
911 | |||
912 | //guide = new CVodnik(center, SiPM, M, d, type_in, type_side, type_out, n1, n2, n3, reflectivity, fresnel, absorption, A); |
||
913 | |||
914 | double b = parameters.getB(); |
||
70 | f9daq | 915 | //double n1 = parameters.getN1(); |
916 | //double n2 = parameters.getN2(); |
||
917 | double n3 = parameters.getN3(); |
||
918 | double reflectivity = c_reflectivity; |
||
25 | f9daq | 919 | double x_gap = parameters.getGap().X(); |
920 | double y_gap = parameters.getGap().Y(); |
||
921 | double z_gap = parameters.getGap().Z(); |
||
922 | |||
70 | f9daq | 923 | // additional glass between at top of SiPM |
924 | // example: epoxy n=1.60 |
||
71 | f9daq | 925 | double n4 = 1.57; |
25 | f9daq | 926 | TVector3 plane_v[4]; |
927 | int nBins = nch + 1; |
||
928 | double p_size = b/2.0; |
||
929 | plane_v[0].SetXYZ(x_offset+d+glass_d, y_gap + p_size, z_gap - p_size); |
||
930 | plane_v[1].SetXYZ(x_offset+d+glass_d, y_gap + p_size, z_gap + p_size); |
||
931 | plane_v[2].SetXYZ(x_offset+d+glass_d, y_gap - p_size, z_gap + p_size); |
||
932 | plane_v[3].SetXYZ(x_offset+d+glass_d, y_gap - p_size, z_gap - p_size); |
||
70 | f9daq | 933 | glass = new CSurface(SURF_REFRA, plane_v, n3, n4, reflectivity); |
934 | glass->FlipN(); |
||
25 | f9daq | 935 | |
70 | f9daq | 936 | // additional circular glass between LG and SiPM |
25 | f9daq | 937 | glass_circle = new CPlaneR(TVector3(x_offset+d+glass_d, y_gap, z_gap), TVector3(-1.0, 0.0, 0.0), b); |
938 | |||
939 | hglass = (TH2F*)gROOT->FindObject("hglass"); if(hglass) delete hglass; |
||
940 | hglass = new TH2F("hglass", "Hits glass", |
||
941 | nBins, y_gap - p_size, y_gap + p_size, |
||
942 | nBins, z_gap - p_size, z_gap + p_size); |
||
943 | |||
70 | f9daq | 944 | // SiPM active surface |
25 | f9daq | 945 | p_size = parameters.getActive()/2.0; |
946 | //cout<<"SiPM active length "<<detectorActive<<endl; |
||
947 | //p_size = 1.0/2.0; |
||
948 | plane_v[0].SetXYZ(x_offset+d+x_gap, y_gap + p_size, z_gap - p_size); |
||
949 | plane_v[1].SetXYZ(x_offset+d+x_gap, y_gap + p_size, z_gap + p_size); |
||
950 | plane_v[2].SetXYZ(x_offset+d+x_gap, y_gap - p_size, z_gap + p_size); |
||
951 | plane_v[3].SetXYZ(x_offset+d+x_gap, y_gap - p_size, z_gap - p_size); |
||
952 | active = new CPlane4(plane_v); |
||
953 | |||
954 | hactive = (TH2F*)gROOT->FindObject("hactive"); if(hactive) delete hactive; |
||
54 | f9daq | 955 | //hactive = new TH2F("hactive", "Active area hits", nBins, y_gap - p_size, y_gap + p_size, nBins, z_gap - p_size, z_gap + p_size); |
956 | hactive = new TH2F("hactive", "Active area hits", nBins, y_gap - p_size + offsetY, y_gap + p_size + offsetY, nBins, z_gap - p_size + offsetZ, z_gap + p_size + offsetZ); |
||
25 | f9daq | 957 | |
958 | p_size = b/2.0; |
||
959 | //p_size = 2.5; |
||
960 | //p_size = M*0.6; |
||
961 | hlaser = (TH2F*)gROOT->FindObject("hlaser"); if(hlaser) delete hlaser; |
||
54 | f9daq | 962 | hlaser = new TH2F("hlaser", ";x [mm]; y [mm]", nBins, -p_size+offsetY, p_size+offsetY, nBins, -p_size+offsetZ, p_size+offsetZ); |
25 | f9daq | 963 | |
70 | f9daq | 964 | // collection surface in SiPM plane |
54 | f9daq | 965 | p_size = 1.4*b/2.0; |
25 | f9daq | 966 | plane_v[0].SetXYZ(x_offset+d+x_gap, y_gap + p_size, z_gap - p_size); |
967 | plane_v[1].SetXYZ(x_offset+d+x_gap, y_gap + p_size, z_gap + p_size); |
||
968 | plane_v[2].SetXYZ(x_offset+d+x_gap, y_gap - p_size, z_gap + p_size); |
||
969 | plane_v[3].SetXYZ(x_offset+d+x_gap, y_gap - p_size, z_gap - p_size); |
||
970 | detector = new CPlane4(plane_v); |
||
971 | |||
972 | hdetector = (TH2F*)gROOT->FindObject("hdetector"); if(hdetector) delete hdetector; |
||
54 | f9daq | 973 | //hdetector = new TH2F("hdetector", "Hits detector plane", nBins, y_gap - p_size, y_gap + p_size, nBins, z_gap - p_size, z_gap + p_size); |
974 | hdetector = new TH2F("hdetector", ";x [mm]; y [mm]", nBins, y_gap-p_size + offsetY, y_gap + p_size + offsetY, nBins, z_gap - p_size + offsetZ, z_gap + p_size + offsetZ); |
||
25 | f9daq | 975 | |
976 | /* |
||
977 | window_circle = new CPlaneR(TVector3(x_offset+d+window_d, y_gap, z_gap), TVector3(-1.0, 0.0, 0.0), window_R); |
||
978 | |||
979 | p_size = M*a; |
||
980 | plane_v[0].SetXYZ(x_offset+d+window_d, y_gap + p_size, z_gap - p_size); |
||
981 | plane_v[1].SetXYZ(x_offset+d+window_d, y_gap + p_size, z_gap + p_size); |
||
982 | plane_v[2].SetXYZ(x_offset+d+window_d, y_gap - p_size, z_gap + p_size); |
||
983 | plane_v[3].SetXYZ(x_offset+d+window_d, y_gap - p_size, z_gap - p_size); |
||
984 | window = new CSurface(SURF_REFRA, plane_v, n1, n2, reflectivity); window->FlipN(); |
||
985 | |||
986 | hwindow = (TH2F*)gROOT->FindObject("hwindow"); if(hwindow) delete hwindow; |
||
987 | hwindow = new TH2F("hwindow", "Hits Window", nch, y_gap - window_R, y_gap + window_R, nch, z_gap - window_R, z_gap + window_R); |
||
988 | */ |
||
989 | p_size = b/2.0; |
||
990 | histoPlate = (TH2F*)gROOT->FindObject("histoPlate"); if(histoPlate) delete histoPlate; |
||
991 | histoPlate = new TH2F("histoPlate", "Hits on glass plate", nBins, -p_size, +p_size, nBins, -p_size, +p_size); |
||
992 | } |
||
54 | f9daq | 993 | |
25 | f9daq | 994 | //----------------------------------------------------------------------------- |
995 | // vrne 1 ce je zadel aktvino povrsino |
||
996 | // vrne <1 ce jo zgresi |
||
997 | int CDetector::Propagate(CRay in, CRay *out, int draw) |
||
54 | f9daq | 998 | |
25 | f9daq | 999 | // Sledi zarku skozi vodnik. Vrne: |
1000 | // 0, ce zgresi vstopno ploskev MISSED |
||
1001 | // 1, ce zadane izstopno ploskev HIT |
||
1002 | // -1, ce se v vodniku ne odbije totalno REFRACTED |
||
1003 | // 2, enter the light guide, bin 2 of hfate EXIT |
||
1004 | // -2, ce se ne odbije zaradi koncnega R stranic - no total reflection REFRACTED |
||
1005 | // -3, ce se odbije nazaj in gre nazaj ven skozi sprednjo ploskev BACK_REFLECTED |
||
1006 | // +4, ce se absorbira v materialu ABSORBED |
||
1007 | { |
||
1008 | if (dbg) printf("--- Detector::Propagate ---\n"); |
||
1009 | //CRay *ray0 = new CRay; ray0->Set(in.GetR(), in.GetN()); ray0->SetColor(col_in); |
||
1010 | CRay *rayin = new CRay(in); |
||
1011 | rayin->SetColor(col_in); |
||
70 | f9daq | 1012 | CRay *rayout = new CRay(in); |
1013 | rayout->SetColor(col_in); |
||
25 | f9daq | 1014 | |
1015 | const int max_n_points = guide->GetMAXODB() + 2; |
||
1016 | TVector3 pointsPlate[max_n_points]; |
||
1017 | //TVector3 intersection; |
||
54 | f9daq | 1018 | Fate fatePlate; |
25 | f9daq | 1019 | int nPointsPlate; |
1020 | TPolyLine3D *line3d = new TPolyLine3D(2); |
||
1021 | line3d->SetLineWidth(1); |
||
1022 | line3d->SetLineColor(4); |
||
1023 | |||
1024 | // Draw the plate and propagate the ray through |
||
1025 | // check if the ray should be reflected?? |
||
1026 | |||
1027 | if(_plateOn) { |
||
1028 | |||
1029 | fatePlate = plate->propagateRay(*rayin, rayout, &nPointsPlate, pointsPlate); |
||
70 | f9daq | 1030 | if(draw) rayin->DrawS(center.x()- _plateWidth, -10.0); |
25 | f9daq | 1031 | if(draw) { |
54 | f9daq | 1032 | if(fatePlate == missed) { |
25 | f9daq | 1033 | rayout->SetColor(col_in); |
1034 | rayout->DrawS(center.x() - _plateWidth, -10.0); |
||
1035 | } |
||
70 | f9daq | 1036 | else if(fatePlate == backreflected){ |
1037 | if (dbg) printf("Backreflected at plate!\n"); |
||
1038 | } |
||
1039 | else { |
||
25 | f9daq | 1040 | int p_i; |
1041 | for(p_i = 0; p_i < nPointsPlate-1; p_i++) { |
||
1042 | line3d->SetPoint(0, pointsPlate[p_i].x(), pointsPlate[p_i].y(), pointsPlate[p_i].z()); |
||
1043 | line3d->SetPoint(1, pointsPlate[p_i+1].x(), pointsPlate[p_i+1].y(), pointsPlate[p_i+1].z()); |
||
1044 | line3d->DrawClone(); |
||
1045 | } |
||
70 | f9daq | 1046 | rayout->DrawS(pointsPlate[p_i].x(), -0.1); |
1047 | if(fatePlate == noreflection) { // lost on plate side |
||
1048 | rayout->SetColor(col_out); |
||
1049 | rayout->DrawS(pointsPlate[p_i].x(), 10.0); |
||
25 | f9daq | 1050 | } |
70 | f9daq | 1051 | } |
1052 | } |
||
25 | f9daq | 1053 | |
54 | f9daq | 1054 | if(! (fatePlate == hitExit or fatePlate == refracted) ) { |
70 | f9daq | 1055 | guide->GetHFate()->Fill(rays); |
1056 | if (dbg)printf("CDetector::propagate Simulated ray missed the entry surface!\n"); |
||
1057 | if (fatePlate == backreflected) |
||
1058 | guide->GetHFate()->Fill(fatePlate); // reflected back |
||
1059 | else |
||
1060 | guide->GetHFate()->Fill(noreflection); //lost on plate side |
||
25 | f9daq | 1061 | return fatePlate; |
1062 | } |
||
70 | f9daq | 1063 | |
1064 | //Ray hits light guide |
||
25 | f9daq | 1065 | histoPlate->Fill(pointsPlate[0].y(), pointsPlate[0].z()); // entry point |
70 | f9daq | 1066 | |
25 | f9daq | 1067 | } |
1068 | else { |
||
70 | f9daq | 1069 | //rayout = rayin; |
25 | f9daq | 1070 | if(draw) rayout->DrawS(center.x(), -10.0); |
1071 | } |
||
1072 | |||
1073 | // If the ray is not reflected in the plate |
||
1074 | // Draw the light guide and propagate the ray through |
||
1075 | |||
1076 | //const int max_n_points = guide->GetMAXODB() + 2; |
||
1077 | TVector3 points[max_n_points]; |
||
1078 | TVector3 presecisce; |
||
54 | f9daq | 1079 | |
25 | f9daq | 1080 | int n_points; |
1081 | int fate_glass; |
||
1082 | CRay *ray0 = new CRay(*rayout); |
||
1083 | // delete rayout; -> creates dangling reference when tries to delete ray0! |
||
70 | f9daq | 1084 | //delete rayin; -> delete rayout! |
25 | f9daq | 1085 | CRay *ray1 = new CRay; |
1086 | |||
1087 | fate = guide->PropagateRay(*ray0, ray1, &n_points, points); |
||
54 | f9daq | 1088 | if (dbg) { |
1089 | if (fate == backreflected) printf("DETECTOR::backreflected\n"); |
||
1090 | } |
||
25 | f9daq | 1091 | |
1092 | line3d->SetLineColor(col_lg); |
||
1093 | int p_i; |
||
1094 | if(guide_on) { |
||
1095 | if(draw) { |
||
1096 | if(fate == missed) { |
||
1097 | if (dbg) printf("Detector: fate=missed\n"); |
||
1098 | TVector3 r = ray1->GetR(); |
||
1099 | TVector3 n = ray1->GetN(); |
||
1100 | ray1->Set(r,n); |
||
1101 | ray1->DrawS(center.x(), 10.0); |
||
1102 | } else { |
||
1103 | for(p_i = 0; p_i < n_points-1; p_i++) { |
||
1104 | line3d->SetPoint(0, points[p_i].x(), points[p_i].y(), points[p_i].z()); |
||
1105 | line3d->SetPoint(1, points[p_i+1].x(), points[p_i+1].y(), points[p_i+1].z()); |
||
1106 | line3d->DrawClone(); |
||
1107 | } |
||
1108 | if(fate != noreflection) { |
||
1109 | if (dbg) printf("Detector: fate != noreflection, fate = %d\n", (int)fate); |
||
1110 | if(glass_on) {/*if(fate == 1)*/ ray1->Draw(points[p_i].x(), center.x() + guide->getD() + glass_d);} |
||
1111 | else { |
||
1112 | ray1->SetColor(col_out); |
||
1113 | ray1->DrawS(points[p_i].x(), 10.0); |
||
1114 | } |
||
1115 | } |
||
1116 | } |
||
1117 | } |
||
1118 | |||
1119 | |||
54 | f9daq | 1120 | if(! (fate == hitExit or fate == refracted) ) { |
1121 | if (dbg) printf("Detector: fate != hit, refracted\n"); |
||
25 | f9daq | 1122 | *out = *ray1; |
70 | f9daq | 1123 | delete ray0; |
1124 | delete ray1; |
||
1125 | delete rayout; |
||
1126 | delete rayin; |
||
25 | f9daq | 1127 | return fate; |
1128 | } |
||
1129 | } else { |
||
1130 | if (dbg) printf("Detector: fate = hit or refracted"); |
||
1131 | ray1 = ray0; |
||
1132 | if(draw) { |
||
71 | f9daq | 1133 | //double epoxy = parameters->getGlassD(); |
1134 | if(glass_on) ray1->Draw(center.x(), center.x() + glass_d); |
||
25 | f9daq | 1135 | else ray1->DrawS(center.x(), 10.0); |
1136 | } |
||
1137 | } |
||
1138 | |||
1139 | fate = missed; // zgresil aktivno povrsino |
||
1140 | if(glass_on) { |
||
71 | f9daq | 1141 | *ray0 = *ray1; |
1142 | ray1->SetColor(col_rgla); |
||
25 | f9daq | 1143 | fate_glass = glass->PropagateRay(*ray0, ray1, &presecisce); |
71 | f9daq | 1144 | if(fate_glass == REFRACTION) { |
25 | f9daq | 1145 | hglass->Fill(presecisce.y(), presecisce.z()); |
1146 | if(draw) ray1->DrawS(presecisce.x(), 10.0); |
||
71 | f9daq | 1147 | //if(active->TestIntersection(&presecisce, *ray1)) { |
1148 | //fate = hitExit; |
||
1149 | //hactive->Fill(offsetY + presecisce.y(), offsetZ + presecisce.z()); |
||
1150 | //hlaser->Fill((in.GetR()).y() + offsetY, (in.GetR()).z() + offsetZ); |
||
1151 | //} |
||
1152 | //if(detector->TestIntersection(&presecisce, *ray1)) |
||
1153 | //hdetector->Fill(offsetY + presecisce.y(), offsetZ + presecisce.z()); |
||
1154 | //} else if(fate_glass == REFLECTION) { |
||
1155 | else |
||
25 | f9daq | 1156 | if(draw) ray1->DrawS(presecisce.x(), 10.0); |
1157 | } |
||
71 | f9daq | 1158 | } |
1159 | |||
54 | f9daq | 1160 | // Main test: ray and SiPM surface |
25 | f9daq | 1161 | if(active->TestIntersection(&presecisce, *ray1)) { |
54 | f9daq | 1162 | fate = hitExit; |
1163 | hactive->Fill(offsetY + presecisce.y(), offsetZ + presecisce.z()); |
||
1164 | hlaser->Fill((in.GetR()).y() + offsetY, (in.GetR()).z() + offsetZ); |
||
25 | f9daq | 1165 | } |
54 | f9daq | 1166 | // If it is on the same plane as SiPM |
25 | f9daq | 1167 | if(detector->TestIntersection(&presecisce, *ray1)) |
54 | f9daq | 1168 | hdetector->Fill(offsetY + presecisce.y(), offsetZ + presecisce.z()); |
71 | f9daq | 1169 | //} |
25 | f9daq | 1170 | //} else { |
1171 | //if(draw) ray1->Draw(presecisce.x(), center.x()+d+window_d); |
||
1172 | //} |
||
1173 | |||
1174 | *out = *ray1; |
||
54 | f9daq | 1175 | delete ray0; |
1176 | delete ray1; |
||
1177 | delete rayout; |
||
70 | f9daq | 1178 | delete rayin; |
25 | f9daq | 1179 | return fate; |
1180 | } |
||
1181 | //----------------------------------------------------------------------------- |
||
1182 | void CDetector::Draw(int width) |
||
1183 | { |
||
1184 | if(guide_on) { |
||
1185 | if( TMath::Abs(guide->getN1()-guide->getN2()) < MARGIN ) { |
||
1186 | if(_plateOn) plate->drawSkel(col_LG, width); |
||
1187 | guide->DrawSkel(col_LG, width); |
||
1188 | } |
||
1189 | else { |
||
1190 | if(_plateOn) plate->draw(4, width); |
||
1191 | guide->Draw(col_LG, width); |
||
1192 | } |
||
1193 | } |
||
1194 | |||
1195 | if(glass_on) glass_circle->Draw(col_glass, width); |
||
1196 | //window_circle->Draw(col_glass, width); |
||
1197 | active->Draw(col_active, width); |
||
1198 | } |
||
1199 | //================================================================================= |
||
1200 | |||
1201 | Plate::Plate(DetectorParameters& parameters) |
||
1202 | { |
||
1203 | TVector3 center = CENTER; |
||
1204 | const double b = parameters.getB(); |
||
1205 | const double n1 = parameters.getN1(); |
||
1206 | const double n2 = parameters.getN2(); |
||
1207 | const double t = b/2.; |
||
1208 | const double plateWidth = parameters.getPlateWidth(); |
||
1209 | center.SetX( CENTER.X() - plateWidth ); |
||
1210 | |||
70 | f9daq | 1211 | plate_edge[0].SetXYZ(0.0, t,-t); |
1212 | plate_edge[1].SetXYZ(0.0, t, t); |
||
1213 | plate_edge[2].SetXYZ(0.0,-t, t); |
||
1214 | plate_edge[3].SetXYZ(0.0,-t,-t); |
||
1215 | plate_edge[4].SetXYZ(plateWidth, t,-t); |
||
1216 | plate_edge[5].SetXYZ(plateWidth, t, t); |
||
1217 | plate_edge[6].SetXYZ(plateWidth,-t, t); |
||
1218 | plate_edge[7].SetXYZ(plateWidth,-t,-t); |
||
1219 | |||
25 | f9daq | 1220 | for(int i = 0; i<8; i++) plate_edge[i] += center; |
1221 | |||
70 | f9daq | 1222 | sides[0] = new CSurface(SURF_REFRA, plate_edge, n1, n2, c_reflectivity); |
25 | f9daq | 1223 | sides[0]->FlipN(); |
1224 | |||
70 | f9daq | 1225 | sides[1] = new CSurface(SURF_REFRA, plate_edge[3], plate_edge[2], plate_edge[6], plate_edge[7], n2, n2, c_reflectivity); |
1226 | sides[2] = new CSurface(SURF_REFRA, plate_edge[2], plate_edge[1], plate_edge[5], plate_edge[6], n2, n2, c_reflectivity); |
||
1227 | sides[3] = new CSurface(SURF_REFRA, plate_edge[1], plate_edge[0], plate_edge[4], plate_edge[5], n2, n2, c_reflectivity); |
||
1228 | sides[4] = new CSurface(SURF_REFRA, plate_edge[0], plate_edge[3], plate_edge[7], plate_edge[4], n2, n2, c_reflectivity); |
||
25 | f9daq | 1229 | |
70 | f9daq | 1230 | sides[5] = new CSurface(SURF_REFRA, &plate_edge[4], n2, n2, c_reflectivity); |
25 | f9daq | 1231 | sides[5]->FlipN(); |
1232 | |||
1233 | for(int i=0; i<6; i++) sides[i]->SetFresnel(1); |
||
1234 | } |
||
1235 | |||
1236 | void Plate::draw(int color, int width) |
||
1237 | { |
||
1238 | for(int i = 0; i<6; i++) sides[i]->Draw(color, width); |
||
1239 | } |
||
1240 | |||
1241 | void Plate::drawSkel(int color, int width) |
||
1242 | { |
||
1243 | TPolyLine3D line3d(2); |
||
1244 | line3d.SetLineWidth(width); |
||
1245 | line3d.SetLineColor(color); |
||
1246 | |||
1247 | for(int i=0; i<4; i++) { |
||
1248 | line3d.SetPoint(0, plate_edge[i+0].x(), plate_edge[i+0].y(), plate_edge[i+0].z()); |
||
1249 | line3d.SetPoint(1, plate_edge[i+4].x(), plate_edge[i+4].y(), plate_edge[i+4].z()); |
||
1250 | line3d.DrawClone(); |
||
1251 | } |
||
1252 | } |
||
1253 | |||
54 | f9daq | 1254 | Fate Plate::propagateRay(CRay in, CRay *out, int *n_points, TVector3 *points) |
25 | f9daq | 1255 | { |
1256 | CRay ray0; |
||
1257 | CRay ray1; |
||
1258 | TVector3 vec0, vec1; |
||
54 | f9daq | 1259 | Fate fate = enter; |
25 | f9daq | 1260 | int inters_i = 0; |
1261 | |||
1262 | ray0 = in; |
||
1263 | int n_odb = 0; |
||
1264 | int last_hit = 0; |
||
1265 | int propagation = 0; |
||
1266 | |||
54 | f9daq | 1267 | int result = sides[0]->PropagateRay(ray0, &ray1, &vec1); |
1268 | if( !result ) { |
||
25 | f9daq | 1269 | // ce -NI- presecisca z vstopno |
54 | f9daq | 1270 | fate = missed; |
1271 | } else if(result == REFLECTION) { |
||
1272 | if (dbg) printf("PLATE: reflected\n"); |
||
1273 | fate = backreflected; |
||
25 | f9daq | 1274 | } else { |
1275 | points[0] = ray1.GetR(); |
||
70 | f9daq | 1276 | //hfate->Fill(enter); |
25 | f9daq | 1277 | //hin->Fill(vec1.y(), vec1.z()); |
54 | f9daq | 1278 | while (n_odb++ < MAX_REFLECTIONS) { |
25 | f9daq | 1279 | ray0 = ray1; |
1280 | vec0 = vec1; |
||
1281 | propagation = 11; |
||
1282 | for(inters_i=0; inters_i<6; inters_i++) { |
||
1283 | if( inters_i != last_hit) { |
||
1284 | if( sides[inters_i]->TestIntersection(&vec1, ray1) ) break; |
||
1285 | } |
||
1286 | } |
||
1287 | points[n_odb] = vec1; |
||
1288 | if(inters_i == 0) { |
||
54 | f9daq | 1289 | fate = backreflected; |
25 | f9daq | 1290 | break;} // backreflection |
1291 | |||
1292 | propagation = sides[inters_i]->PropagateRay(ray0, &ray1, &vec1); |
||
1293 | if(inters_i == 5) { // successfull exit |
||
54 | f9daq | 1294 | fate = hitExit; |
25 | f9daq | 1295 | //hout->Fill(vec1.y(), vec1.z()); |
1296 | //hnodb_exit->Fill(n_odb-1); |
||
1297 | n_odb++; |
||
1298 | points[n_odb] = vec1; |
||
1299 | ray0 = ray1; |
||
1300 | break; |
||
1301 | } |
||
1302 | if(propagation == 1) { |
||
70 | f9daq | 1303 | fate = noreflection; //at side |
25 | f9daq | 1304 | n_odb++; |
1305 | points[n_odb] = vec1; |
||
1306 | ray0 = ray1; |
||
1307 | break;} // no total reflection when should be |
||
1308 | |||
54 | f9daq | 1309 | if(propagation == -2) { |
1310 | fate = noreflection; |
||
1311 | break; |
||
1312 | } // absorption due to finite reflectivity |
||
1313 | |||
25 | f9daq | 1314 | last_hit = inters_i; |
1315 | } |
||
1316 | } |
||
1317 | |||
1318 | *n_points = n_odb+1; |
||
1319 | *out = ray0; |
||
1320 | return fate; |
||
1321 | }; |
||
1322 | //=============================================================================================================================== <<<<<<<< |
||
1323 | |||
1324 |