#include #include #include #include #include #include "fieldlines.hpp" namespace netgen { RKStepper :: ~RKStepper() { delete a; } RKStepper :: RKStepper(int type) : a(NULL), tolerance(1e100) { notrestarted = 0; if (type == 0) // explicit Euler { c.SetSize(1); c[0] = 0; b.SetSize(1); b[0] = 1; steps = order = 1; } else if (type == 1) // Euler-Cauchy { c.SetSize(2); c[0] = 0; c[1] = 0.5; b.SetSize(2); b[0] = 0; b[1] = 1; NgArray size(2); size[0] = 0; size[1] = 1; a = new TABLE(size); a->Set(2,1,0.5); // Set, Get: 1-based! steps = order = 2; } else if (type == 2) // Simpson { c.SetSize(3); c[0] = 0; c[1] = 1; c[2] = 0.5; b.SetSize(3); b[0] = b[1] = 1./6.; b[2] = 2./3.; NgArray size(3); size[0] = 0; size[1] = 1; size[2] = 2; a = new TABLE(size); a->Set(2,1,1); a->Set(3,1,0.25); a->Set(3,2,0.25); steps = order = 3; } else if (type == 3) // classical Runge-Kutta { c.SetSize(4); c[0] = 0; c[1] = c[2] = 0.5; c[3] = 1; b.SetSize(4); b[0] = b[3] = 1./6.; b[1] = b[2] = 1./3.; NgArray size(4); size[0] = 0; size[1] = 1; size[2] = 2; size[3] = 3; a = new TABLE(size); a->Set(2,1,0.5); a->Set(3,1,0); a->Set(3,2,0.5); a->Set(4,1,0); a->Set(4,2,0); a->Set(4,3,1); steps = order = 4; } K.SetSize(steps); } void RKStepper :: StartNextValCalc(const Point<3> & astartval, const double astartt, const double ah, const bool aadaptive) { //cout << "Starting RK-Step with h=" << ah << endl; stepcount = 0; h = ah; startt = astartt; startval = astartval; adaptive = aadaptive; adrun = 0; } bool RKStepper :: GetNextData(Point<3> & val, double & t, double & ah) { bool finished = false; if(stepcount <= steps && stepcount>0) { t = startt + c[stepcount-1]*h; val = startval; for(int i=0; iGet(stepcount,i+1) * K[i]; } if(stepcount == steps) { val = startval; for(int i=0; i valh2 = val; val = valh2 + 1./(pow(2.,order)-1.) * (valh2 - valh); auto errvec = val - valh; double err = errvec.Length(); double fac = 0.7 * pow(tolerance/err,1./(order+1.)); if(fac > 1.3) fac = 1.3; if(fac < 1 || notrestarted >= 2) ah = 2.*h * fac; if(err < tolerance) { finished = true; notrestarted++; //(*testout) << "finished RK-Step, new h=" << ah << " tolerance " << tolerance << " err " << err << endl; } else { //ah *= 0.9; notrestarted = 0; //(*testout) << "restarting h " << 2.*h << " ah " << ah << " tolerance " << tolerance << " err " << err << endl; StartNextValCalc(startval_bak,startt_bak, ah, adaptive); } } } else { t = startt + h; finished = true; } } if(stepcount == 0) { t = startt + c[stepcount]*h; val = startval; for(int i=0; iGet(stepcount,i) * K[i]; } return finished; } bool RKStepper :: FeedNextF(const Vec<3> & f) { K[stepcount] = f; stepcount++; return true; } void FieldLineCalc :: GenerateFieldLines(Array> & potential_startpoints, const int numlines) { Array> line_points; Array line_values; Array drawelems; Array dirstart; pstart.SetSize0(); pend.SetSize0(); values.SetSize0(); double crit = 1.0; if(randomized) { double sum = 0; double lami[3]; Vec<3> v; for(int i=0; i= numlines) break; Calc(potential_startpoints[i],line_points,line_values,drawelems,dirstart); bool usable = false; for(int j=1; j 0) ? rel_length : 0.5; maxlength *= 2.*rad; thickness = (rel_thickness > 0) ? rel_thickness : 0.0015; thickness *= 2.*rad; double auxtolerance = (rel_tolerance > 0) ? rel_tolerance : 1.5e-3; auxtolerance *= 2.*rad; stepper.SetTolerance(auxtolerance); direction = adirection; maxpoints = amaxpoints; if(direction == 0) { maxlength *= 0.5; maxpoints /= 2; } critical_value = -1; randomized = false; } FieldLineCalc :: ~FieldLineCalc() {;} void FieldLineCalc :: Calc(const Point<3> & startpoint, Array> & points, Array & vals, Array & drawelems, Array & dirstart) { Vec<3> v = 0.0; double startlami[3] = {0.0, 0.0, 0.0}; points.SetSize(0); vals.SetSize(0); drawelems.SetSize(0); dirstart.SetSize(0); dirstart.Append(0); int startelnr = mesh.GetElementOfPoint(startpoint,startlami,true) - 1; (*testout) << "p = " << startpoint << "; elnr = " << startelnr << endl; if (startelnr == -1) return; mesh.SetPointSearchStartElement(startelnr); Vec<3> startv; bool startdraw = func(startelnr, startlami, startv); double startval = startv.Length(); if(critical_value > 0 && fabs(startval) < critical_value) return; //cout << "p = " << startpoint << "; elnr = " << startelnr << endl; for(int dir = 1; dir >= -1; dir -= 2) { if(dir*direction < 0) continue; points.Append(startpoint); vals.Append(startval); drawelems.Append(startdraw); double h = 0.001*rad/startval; // otherwise no nice lines; should be made accessible from outside v = startv; if(dir == -1) v *= -1.; int elnr = startelnr; double lami[3] = { startlami[0], startlami[1], startlami[2]}; for(double length = 0; length < maxlength; length += h*vals.Last()) { if(v.Length() < 1e-12*rad) { (*testout) << "Current fieldlinecalculation came to a stillstand at " << points.Last() << endl; break; } double dummyt; stepper.StartNextValCalc(points.Last(),dummyt,h,true); stepper.FeedNextF(v); bool drawelem = false; Point<3> newp; while(!stepper.GetNextData(newp,dummyt,h) && elnr != -1) { elnr = mesh.GetElementOfPoint(newp,lami,true) - 1; if(elnr != -1) { mesh.SetPointSearchStartElement(elnr); drawelem = func(elnr, lami, v); if(dir == -1) v *= -1.; stepper.FeedNextF(v); } } if (elnr == -1) { //cout << "direction " < 1) (*testout) << "Points in current fieldline: " << points.Size() << ", current position: " << newp << endl; if(maxpoints > 0 && points.Size() >= maxpoints) { break; } //cout << "length " << length << " h " << h << " vals.Last() " << vals.Last() << " maxlength " << maxlength << endl; } dirstart.Append(points.Size()); } } }