171 lines
5.1 KiB
C++
171 lines
5.1 KiB
C++
/*
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* Copyright (C) 2011 Thorsten Liebig (Thorsten.Liebig@gmx.de)
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "engine_ext_excitation.h"
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#include "operator_ext_excitation.h"
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#include "FDTD/engine_sse.h"
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Engine_Ext_Excitation::Engine_Ext_Excitation(Operator_Ext_Excitation* op_ext) : Engine_Extension(op_ext)
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{
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m_Op_Exc = op_ext;
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m_Priority = ENG_EXT_PRIO_EXCITATION;
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}
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Engine_Ext_Excitation::~Engine_Ext_Excitation()
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{
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}
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void Engine_Ext_Excitation::Apply2Voltages()
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{
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//soft voltage excitation here (E-field excite)
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int exc_pos;
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unsigned int ny;
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unsigned int pos[3];
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int numTS = m_Eng->GetNumberOfTimesteps();
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unsigned int length = m_Op_Exc->m_Exc->GetLength();
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FDTD_FLOAT* exc_volt = m_Op_Exc->m_Exc->GetVoltageSignal();
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int p = numTS+1;
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if (m_Op_Exc->m_Exc->GetSignalPeriod()>0)
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p = int(m_Op_Exc->m_Exc->GetSignalPeriod()/m_Op_Exc->m_Exc->GetTimestep());
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//switch for different engine types to access faster inline engine functions
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switch (m_Eng->GetType())
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{
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case Engine::BASIC:
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{
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for (unsigned int n=0; n<m_Op_Exc->Volt_Count; ++n)
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{
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exc_pos = numTS - (int)m_Op_Exc->Volt_delay[n];
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exc_pos *= (exc_pos>0);
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exc_pos %= p;
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exc_pos *= (exc_pos<(int)length);
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ny = m_Op_Exc->Volt_dir[n];
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pos[0]=m_Op_Exc->Volt_index[0][n];
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pos[1]=m_Op_Exc->Volt_index[1][n];
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pos[2]=m_Op_Exc->Volt_index[2][n];
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m_Eng->Engine::SetVolt(ny,pos, m_Eng->Engine::GetVolt(ny,pos) + m_Op_Exc->Volt_amp[n]*exc_volt[exc_pos]);
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}
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break;
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}
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case Engine::SSE:
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{
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for (unsigned int n=0; n<m_Op_Exc->Volt_Count; ++n)
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{
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Engine_sse* eng_sse = (Engine_sse*) m_Eng;
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exc_pos = numTS - (int)m_Op_Exc->Volt_delay[n];
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exc_pos *= (exc_pos>0);
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exc_pos %= p;
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exc_pos *= (exc_pos<(int)length);
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ny = m_Op_Exc->Volt_dir[n];
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pos[0]=m_Op_Exc->Volt_index[0][n];
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pos[1]=m_Op_Exc->Volt_index[1][n];
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pos[2]=m_Op_Exc->Volt_index[2][n];
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eng_sse->Engine_sse::SetVolt(ny,pos, eng_sse->Engine_sse::GetVolt(ny,pos) + m_Op_Exc->Volt_amp[n]*exc_volt[exc_pos]);
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}
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break;
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}
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default:
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{
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for (unsigned int n=0; n<m_Op_Exc->Volt_Count; ++n)
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{
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exc_pos = numTS - (int)m_Op_Exc->Volt_delay[n];
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exc_pos *= (exc_pos>0);
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exc_pos %= p;
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exc_pos *= (exc_pos<(int)length);
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ny = m_Op_Exc->Volt_dir[n];
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pos[0]=m_Op_Exc->Volt_index[0][n];
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pos[1]=m_Op_Exc->Volt_index[1][n];
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pos[2]=m_Op_Exc->Volt_index[2][n];
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m_Eng->SetVolt(ny,pos, m_Eng->GetVolt(ny,pos) + m_Op_Exc->Volt_amp[n]*exc_volt[exc_pos]);
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}
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break;
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}
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}
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}
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void Engine_Ext_Excitation::Apply2Current()
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{
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//soft current excitation here (H-field excite)
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int exc_pos;
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unsigned int ny;
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unsigned int pos[3];
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int numTS = m_Eng->GetNumberOfTimesteps();
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unsigned int length = m_Op_Exc->m_Exc->GetLength();
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FDTD_FLOAT* exc_curr = m_Op_Exc->m_Exc->GetCurrentSignal();
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int p = numTS+1;
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if (m_Op_Exc->m_Exc->GetSignalPeriod()>0)
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p = int(m_Op_Exc->m_Exc->GetSignalPeriod()/m_Op_Exc->m_Exc->GetTimestep());
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//switch for different engine types to access faster inline engine functions
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switch (m_Eng->GetType())
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{
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case Engine::BASIC:
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{
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for (unsigned int n=0; n<m_Op_Exc->Curr_Count; ++n)
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{
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exc_pos = numTS - (int)m_Op_Exc->Curr_delay[n];
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exc_pos *= (exc_pos>0);
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exc_pos %= p;
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exc_pos *= (exc_pos<(int)length);
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ny = m_Op_Exc->Curr_dir[n];
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pos[0]=m_Op_Exc->Curr_index[0][n];
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pos[1]=m_Op_Exc->Curr_index[1][n];
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pos[2]=m_Op_Exc->Curr_index[2][n];
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m_Eng->Engine::SetCurr(ny,pos, m_Eng->Engine::GetCurr(ny,pos) + m_Op_Exc->Curr_amp[n]*exc_curr[exc_pos]);
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}
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break;
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}
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case Engine::SSE:
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{
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for (unsigned int n=0; n<m_Op_Exc->Curr_Count; ++n)
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{
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Engine_sse* eng_sse = (Engine_sse*) m_Eng;
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exc_pos = numTS - (int)m_Op_Exc->Curr_delay[n];
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exc_pos *= (exc_pos>0);
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exc_pos %= p;
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exc_pos *= (exc_pos<(int)length);
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ny = m_Op_Exc->Curr_dir[n];
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pos[0]=m_Op_Exc->Curr_index[0][n];
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pos[1]=m_Op_Exc->Curr_index[1][n];
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pos[2]=m_Op_Exc->Curr_index[2][n];
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eng_sse->Engine_sse::SetCurr(ny,pos, eng_sse->Engine_sse::GetCurr(ny,pos) + m_Op_Exc->Curr_amp[n]*exc_curr[exc_pos]);
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}
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break;
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}
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default:
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{
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for (unsigned int n=0; n<m_Op_Exc->Curr_Count; ++n)
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{
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exc_pos = numTS - (int)m_Op_Exc->Curr_delay[n];
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exc_pos *= (exc_pos>0);
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exc_pos %= p;
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exc_pos *= (exc_pos<(int)length);
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ny = m_Op_Exc->Curr_dir[n];
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pos[0]=m_Op_Exc->Curr_index[0][n];
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pos[1]=m_Op_Exc->Curr_index[1][n];
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pos[2]=m_Op_Exc->Curr_index[2][n];
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m_Eng->SetCurr(ny,pos, m_Eng->GetCurr(ny,pos) + m_Op_Exc->Curr_amp[n]*exc_curr[exc_pos]);
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}
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break;
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}
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}
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}
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