/* * Copyright (C) 2010 Thorsten Liebig (Thorsten.Liebig@gmx.de) * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "engine_interface_fdtd.h" Engine_Interface_FDTD::Engine_Interface_FDTD(Operator* op, Engine* eng) : Engine_Interface_Base(op) { m_Op = op; m_Eng = eng; } Engine_Interface_FDTD::~Engine_Interface_FDTD() { } double* Engine_Interface_FDTD::GetEField(const unsigned int* pos, double* out) const { unsigned int iPos[] = {pos[0],pos[1],pos[2]}; int nP,nPP; double delta; switch (m_InterpolType) { default: case NO_INTERPOLATION: for (int n=0; n<3; ++n) { delta = m_Op->GetEdgeLength(n,pos,false); if (delta) out[n] = m_Eng->GetVolt(n,pos) / delta; else out[n] = 0.0; } break; case NODE_INTERPOLATE: for (int n=0; n<3; ++n) { delta = m_Op->GetEdgeLength(n,iPos); out[n] = m_Eng->GetVolt(n,iPos); if (delta==0) { out[n]=0; continue; } if (pos[n]==0) { out[n] /= (delta * 2.0); //make it consistant with upper PEC boundary continue; } --iPos[n]; double deltaDown = m_Op->GetEdgeLength(n,iPos); double deltaRel = delta / (delta+deltaDown); out[n] = out[n]*(1.0-deltaRel)/delta + (double)m_Eng->GetVolt(n,iPos)/deltaDown*deltaRel; ++iPos[n]; } break; case CELL_INTERPOLATE: for (int n=0; n<3; ++n) { nP = (n+1)%3; nPP = (n+2)%3; if ((pos[0]==m_Op->GetNumberOfLines(0)-1) || (pos[1]==m_Op->GetNumberOfLines(1)-1) || (pos[2]==m_Op->GetNumberOfLines(2)-1)) { out[n] = 0; //electric field outside the field domain is always zero continue; } delta = m_Op->GetEdgeLength(n,iPos); if (delta) out[n]=m_Eng->GetVolt(n,iPos)/delta; ++iPos[nP]; delta = m_Op->GetEdgeLength(n,iPos); if (delta) out[n]+=m_Eng->GetVolt(n,iPos)/delta; ++iPos[nPP]; delta = m_Op->GetEdgeLength(n,iPos); if (delta) out[n]+=m_Eng->GetVolt(n,iPos)/delta; --iPos[nP]; delta = m_Op->GetEdgeLength(n,iPos); if (delta) out[n]+=m_Eng->GetVolt(n,iPos)/delta; --iPos[nPP]; out[n]/=4; } break; } return out; } double* Engine_Interface_FDTD::GetHField(const unsigned int* pos, double* out) const { unsigned int iPos[] = {pos[0],pos[1],pos[2]}; int nP,nPP; double delta; switch (m_InterpolType) { default: case NO_INTERPOLATION: out[0] = m_Eng->GetCurr(0,pos) / m_Op->GetEdgeLength(0,pos,true); out[1] = m_Eng->GetCurr(1,pos) / m_Op->GetEdgeLength(1,pos,true); out[2] = m_Eng->GetCurr(2,pos) / m_Op->GetEdgeLength(2,pos,true); break; case NODE_INTERPOLATE: for (int n=0; n<3; ++n) { nP = (n+1)%3; nPP = (n+2)%3; if ((pos[0]==m_Op->GetNumberOfLines(0)-1) || (pos[1]==m_Op->GetNumberOfLines(1)-1) || (pos[2]==m_Op->GetNumberOfLines(2)-1) || (pos[nP]==0) || (pos[nPP]==0)) { out[n] = 0; continue; } out[n]=m_Eng->GetCurr(n,iPos)/m_Op->GetEdgeLength(n,iPos,true); --iPos[nP]; out[n]+=m_Eng->GetCurr(n,iPos)/m_Op->GetEdgeLength(n,iPos,true); --iPos[nPP]; out[n]+=m_Eng->GetCurr(n,iPos)/m_Op->GetEdgeLength(n,iPos,true); ++iPos[nP]; out[n]+=m_Eng->GetCurr(n,iPos)/m_Op->GetEdgeLength(n,iPos,true); ++iPos[nPP]; out[n]/=4; } break; case CELL_INTERPOLATE: for (int n=0; n<3; ++n) { delta = m_Op->GetEdgeLength(n,iPos,true); out[n] = m_Eng->GetCurr(n,iPos); if ((pos[n]>=m_Op->GetNumberOfLines(n)-1)) { out[n] = 0; //magnetic field on the outer boundaries is always zero continue; } ++iPos[n]; double deltaUp = m_Op->GetEdgeLength(n,iPos,true); double deltaRel = delta / (delta+deltaUp); out[n] = out[n]*(1.0-deltaRel)/delta + (double)m_Eng->GetCurr(n,iPos)/deltaUp*deltaRel; --iPos[n]; } break; } return out; } double Engine_Interface_FDTD::CalcVoltageIntegral(const unsigned int* start, const unsigned int* stop) const { double result=0; for (int n=0; n<3; ++n) { if (start[n]GetVolt(n,pos[0],pos[1],pos[2]); } else { unsigned int pos[3]={stop[0],stop[1],stop[2]}; for (; pos[n]GetVolt(n,pos[0],pos[1],pos[2]); } } return result; }