/* * 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 "processmodematch.h" #include "CSFunctionParser.h" #include "Common/operator_base.h" #include "tools/array_ops.h" using namespace std; ProcessModeMatch::ProcessModeMatch(Engine_Interface_Base* eng_if) : ProcessIntegral(eng_if) { for (int n=0; n<2; ++n) { m_ModeParser[n] = new CSFunctionParser(); m_ModeDist[n] = NULL; } delete[] m_Results; m_Results = new double[2]; } ProcessModeMatch::~ProcessModeMatch() { for (int n=0; n<2; ++n) { delete m_ModeParser[n]; m_ModeParser[n] = NULL; } Reset(); } string ProcessModeMatch::GetIntegralName(int row) const { if (row==0) { if (m_ModeFieldType==0) return "voltage"; if (m_ModeFieldType==1) return "current"; } if (row==1) { return "mode_purity"; } return "unknown"; } string ProcessModeMatch::GetProcessingName() const { if (m_ModeFieldType==0) return "voltage mode matching"; if (m_ModeFieldType==1) return "current mode matching"; return "unknown mode matching"; } void ProcessModeMatch::InitProcess() { if (!Enabled) return; if (m_Eng_Interface==NULL) { cerr << "ProcessModeMatch::InitProcess: Error, Engine_Interface is NULL, abort mode mathcing..." << endl; Enabled=false; return; } m_Eng_Interface->SetInterpolationType(Engine_Interface_Base::NODE_INTERPOLATE); int Dump_Dim=0; m_ny = -1; for (int n=0; n<3; ++n) { if (start[n]>stop[n]) { unsigned int help=start[n]; start[n]=stop[n]; stop[n]=help; } //exclude boundaries from mode-matching if (start[n]==0) ++start[n]; if (stop[n]==Op->GetNumberOfLines(n)-1) --stop[n]; if (stop[n]!=start[n]) ++Dump_Dim; if (stop[n] == start[n]) m_ny = n; } if ((Dump_Dim!=2) || (m_ny<0)) { cerr << "ProcessModeMatch::InitProcess(): Warning Mode Matching Integration Box \"" << m_filename << "\" is not a surface (found dimension: " << Dump_Dim << ")" << endl; SetEnable(false); Reset(); return; } int nP = (m_ny+1)%3; int nPP = (m_ny+2)%3; m_numLines[0] = stop[nP] - start[nP] + 1; m_numLines[1] = stop[nPP] - start[nPP] + 1; for (int n=0; n<2; ++n) { int ny = (m_ny+n+1)%3; int res = m_ModeParser[n]->Parse(m_ModeFunction[ny], "x,y,z,rho,a,r,t"); if (res >= 0) { cerr << "ProcessModeMatch::InitProcess(): Warning, an error occured parsing the mode matching function (see below) ..." << endl; cerr << m_ModeFunction[ny] << "\n" << string(res, ' ') << "^\n" << m_ModeParser[n]->ErrorMsg() << "\n"; SetEnable(false); Reset(); } } for (int n=0; n<2; ++n) { m_ModeDist[n] = Create2DArray(m_numLines); } bool dualMesh = m_ModeFieldType==1; unsigned int pos[3] = {0,0,0}; double discLine[3] = {0,0,0}; double gridDelta = 1; // 1 -> mode-matching function is definied in drawing units... double var[7]; pos[m_ny] = start[m_ny]; discLine[m_ny] = Op->GetDiscLine(m_ny,pos[m_ny],dualMesh); double norm = 0; double area = 0; for (unsigned int posP = 0; posPGetDiscLine(nP,pos[nP],dualMesh); for (unsigned int posPP = 0; posPPGetDiscLine(nPP,pos[nPP],dualMesh); var[0] = discLine[0] * gridDelta; // x var[1] = discLine[1] * gridDelta; // y var[2] = discLine[2] * gridDelta; // z var[3] = sqrt(discLine[0]*discLine[0] + discLine[1]*discLine[1]) * gridDelta; // rho = sqrt(x^2 + y^2) var[4] = atan2(discLine[1], discLine[0]); // a = atan(y,x) var[5] = sqrt(pow(discLine[0],2)+pow(discLine[1],2)+pow(discLine[2],2)) * gridDelta; // r var[6] = asin(1)-atan(var[2]/var[3]); //theta (t) if (m_Mesh_Type == CYLINDRICAL_MESH) { var[3] = discLine[0] * gridDelta; // rho var[4] = discLine[1]; // a var[0] = discLine[0] * cos(discLine[1]) * gridDelta; // x = r*cos(a) var[1] = discLine[0] * sin(discLine[1]) * gridDelta; // y = r*sin(a) var[5] = sqrt(pow(discLine[0],2)+pow(discLine[2],2)) * gridDelta; // r var[6] = asin(1)-atan(var[2]/var[3]); //theta (t) } area = Op->GetNodeArea(m_ny,pos,dualMesh); for (int n=0; n<2; ++n) { m_ModeDist[n][posP][posPP] = m_ModeParser[n]->Eval(var); //calc mode template if ((isnan(m_ModeDist[n][posP][posPP])) || (isinf(m_ModeDist[n][posP][posPP]))) m_ModeDist[n][posP][posPP] = 0.0; norm += pow(m_ModeDist[n][posP][posPP],2) * area; } // cerr << discLine[0] << " " << discLine[1] << " : " << m_ModeDist[0][posP][posPP] << " , " << m_ModeDist[1][posP][posPP] << endl; } } norm = sqrt(norm); // cerr << norm << endl; // normalize template function... for (unsigned int posP = 0; posP(m_ModeDist[n],m_numLines); m_ModeDist[n] = NULL; } } void ProcessModeMatch::SetModeFunction(int ny, string function) { if ((ny<0) || (ny>2)) return; m_ModeFunction[ny] = function; } void ProcessModeMatch::SetFieldType(int type) { m_ModeFieldType = type; if ((type<0) || (type>1)) cerr << "ProcessModeMatch::SetFieldType: Warning, unknown field type..." << endl; } double* ProcessModeMatch::CalcMultipleIntegrals() { double value = 0; double field = 0; double purity = 0; double area = 0; bool dualMesh = m_ModeFieldType==1; int nP = (m_ny+1)%3; int nPP = (m_ny+2)%3; unsigned int pos[3] = {0,0,0}; pos[m_ny] = start[m_ny]; double out[3]={0,0,0}; for (unsigned int posP = 0; posPGetNodeArea(m_ny,pos,dualMesh); if (m_ModeFieldType==0) m_Eng_Interface->GetEField(pos,out); if (m_ModeFieldType==1) m_Eng_Interface->GetHField(pos,out); for (int n=0; n<2; ++n) { field = out[(m_ny+n+1)%3]; value += field * m_ModeDist[n][posP][posPP] * area; purity += field*field * area; } } } if (purity!=0) m_Results[1] = value*value/purity; else m_Results[1] = 0; m_Results[0] = value; return m_Results; }