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Geant4/geometry/magneticfield/src/G4BorisScheme.cc

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Differences between /geometry/magneticfield/src/G4BorisScheme.cc (Version 11.3.0) and /geometry/magneticfield/src/G4BorisScheme.cc (Version 10.3.p2)


  1 // *******************************************      1 
  2 // * License and Disclaimer                       
  3 // *                                              
  4 // * The  Geant4 software  is  copyright of th    
  5 // * the Geant4 Collaboration.  It is provided    
  6 // * conditions of the Geant4 Software License    
  7 // * LICENSE and available at  http://cern.ch/    
  8 // * include a list of copyright holders.         
  9 // *                                              
 10 // * Neither the authors of this software syst    
 11 // * institutes,nor the agencies providing fin    
 12 // * work  make  any representation or  warran    
 13 // * regarding  this  software system or assum    
 14 // * use.  Please see the license in the file     
 15 // * for the full disclaimer and the limitatio    
 16 // *                                              
 17 // * This  code  implementation is the result     
 18 // * technical work of the GEANT4 collaboratio    
 19 // * By using,  copying,  modifying or  distri    
 20 // * any work based  on the software)  you  ag    
 21 // * use  in  resulting  scientific  publicati    
 22 // * acceptance of all terms of the Geant4 Sof    
 23 // *******************************************    
 24 //                                                
 25 // G4BorisScheme implementation                   
 26 //                                                
 27 // Author: Divyansh Tiwari, Google Summer of C    
 28 // Supervision: John Apostolakis,Renee Fatemi,    
 29 // -------------------------------------------    
 30                                                   
 31 #include "G4BorisScheme.hh"                       
 32 #include "G4FieldUtils.hh"                        
 33 #include"G4SystemOfUnits.hh"                      
 34 #include "globals.hh"                             
 35 #include "G4PhysicalConstants.hh"                 
 36                                                   
 37 #include "G4EquationOfMotion.hh"                  
 38 //#include "G4EqMagElectricField.hh"              
 39                                                   
 40 using namespace field_utils;                      
 41                                                   
 42 G4BorisScheme::G4BorisScheme( G4EquationOfMoti    
 43                                         G4int     
 44   : fEquation(equation), fnvar(nvar)              
 45 {                                                 
 46   if (nvar <= 0)                                  
 47   {                                               
 48     G4Exception("G4BorisScheme::G4BorisScheme(    
 49                 "GeomField0002", FatalExceptio    
 50                 "Invalid number of variables;     
 51   }                                               
 52 }                                                 
 53                                                   
 54 void G4BorisScheme::DoStep(const G4double rest    
 55                                  G4double yOut    
 56 {                                                 
 57   G4double yOut1Temp[G4FieldTrack::ncompSVEC];    
 58   G4double yOut2Temp[G4FieldTrack::ncompSVEC];    
 59                                                   
 60   // Used the scheme described in the followin    
 61   UpdatePosition(restMass, charge,  yIn, yOut1    
 62   UpdateVelocity(restMass, charge, yOut1Temp,     
 63   UpdatePosition(restMass, charge, yOut2Temp,     
 64 }                                                 
 65                                                   
 66 void G4BorisScheme::UpdatePosition(const G4dou    
 67                                    G4double yO    
 68 {                                                 
 69     // Particle information                       
 70     copy(yOut, yIn);                              
 71                                                   
 72     // Obtaining velocity                         
 73     G4ThreeVector momentum_vec =G4ThreeVector(    
 74     G4double momentum_mag = momentum_vec.mag()    
 75     G4ThreeVector momentum_dir =(1.0/momentum_    
 76                                                   
 77     G4double velocity_mag = momentum_mag*(c_l)    
 78     G4ThreeVector velocity = momentum_dir*velo    
 79                                                   
 80     //Obtaining the time step from the length     
 81                                                   
 82     hstep /= velocity_mag*CLHEP::m;               
 83                                                   
 84     // Updating the Position                      
 85     for(G4int i = 0; i <3; i++ )                  
 86     {                                             
 87       G4double pos = yIn[i]/CLHEP::m;             
 88       pos += hstep*velocity[i];                   
 89       yOut[i] = pos*CLHEP::m;                     
 90     }                                             
 91 }                                                 
 92                                                   
 93 void G4BorisScheme::UpdateVelocity(const G4dou    
 94                                    G4double yO    
 95 {                                                 
 96    //Particle information                         
 97     G4ThreeVector momentum_vec =G4ThreeVector(    
 98     G4double momentum_mag = momentum_vec.mag()    
 99     G4ThreeVector momentum_dir =(1.0/momentum_    
100                                                   
101     G4double gamma = std::sqrt(sqr(momentum_ma    
102                                                   
103     G4double mass = (restMass/c_squared)/CLHEP    
104                                                   
105     //Obtaining velocity                          
106                                                   
107     G4double velocity_mag = momentum_mag*(c_l)    
108     G4ThreeVector velocity = momentum_dir*velo    
109                                                   
110     ////Obtaining the time step from the lengt    
111                                                   
112     hstep /= velocity_mag*CLHEP::m;               
113                                                   
114     // Obtaining the field values                 
115     G4double dydx[G4FieldTrack::ncompSVEC];       
116     G4double fieldValue[6] ={0,0,0,0,0,0};        
117     fEquation->EvaluateRhsReturnB(yIn, dydx, f    
118                                                   
119     //Initializing Vectors                        
120     G4ThreeVector B;                              
121     G4ThreeVector E;                              
122     copy(yOut, yIn);                              
123     for( G4int i = 0; i < 3; i++)                 
124     {                                             
125         E[i] = fieldValue[i+3]/CLHEP::volt*CLH    
126         B[i] = fieldValue[i]/CLHEP::tesla;        
127     }                                             
128                                                   
129     //Boris Algorithm                             
130     G4double qd = hstep*(charge/(2*mass*gamma)    
131     G4ThreeVector h = qd*B;                       
132     G4ThreeVector u = velocity + qd*E;            
133     G4double h_l = h[0]*h[0] + h[1]*h[1] + h[2    
134     G4ThreeVector s_1 = (2*h)/(1 + h_l);          
135     G4ThreeVector ud = u + (u + u.cross(h)).cr    
136     G4ThreeVector v_fi = ud +qd*E;                
137     G4double v_mag = std::sqrt(v_fi.mag2());      
138     G4ThreeVector v_dir = v_fi/v_mag;             
139     G4double momen_mag = (restMass*v_mag)/(std    
140     G4ThreeVector momen = momen_mag*v_dir;        
141                                                   
142     // Storing the updated momentum               
143     for(int i = 3; i < 6; i++)                    
144     {                                             
145         yOut[i] = momen[i-3];                     
146     }                                             
147 }                                                 
148                                                   
149 // -------------------------------------------    
150                                                   
151 void G4BorisScheme::copy(G4double dst[], const    
152 {                                                 
153   std::memcpy(dst, src, sizeof(G4double) * fnv    
154 }                                                 
155                                                   
156 // -------------------------------------------    
157 // - Methods using the Boris Scheme Stepping t    
158 // -------------------------------------------    
159 void G4BorisScheme::                              
160 StepWithErrorEstimate(const G4double yIn[], G4    
161                       G4double yOut[], G4doubl    
162 {                                                 
163    // Use two half-steps (comparing to a full     
164    G4double yMid[G4FieldTrack::ncompSVEC];        
165    StepWithMidAndErrorEstimate(yIn, restMass,     
166 }                                                 
167                                                   
168 // -------------------------------------------    
169                                                   
170 void G4BorisScheme::                              
171 StepWithMidAndErrorEstimate(const G4double yIn    
172                                   G4double yMi    
173    ) const                                        
174 {                                                 
175    G4double halfStep= 0.5*hstep;                  
176    G4double yOutAlt[G4FieldTrack::ncompSVEC];     
177                                                   
178    // In a single step                            
179    DoStep(restMass, charge, yIn,  yOutAlt, hst    
180                                                   
181    // Same, and also return mid-point evaluati    
182    DoStep(restMass, charge, yIn,  yMid, halfSt    
183    DoStep(restMass, charge, yMid, yOut, halfSt    
184                                                   
185    for( G4int i= 0; i<fnvar; i++ )                
186    {                                              
187       yErr[i] = yOutAlt[i] - yOut[i];             
188    }                                              
189 }                                                 
190