openEMS/Common/operator_base.h

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/*
* 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 <http://www.gnu.org/licenses/>.
*/
#ifndef OPERATOR_BASE_H
#define OPERATOR_BASE_H
#include "ContinuousStructure.h"
#include "tools/global.h"
#include "Common/processing.h"
#include "string"
typedef struct
{
vector<unsigned int> posPath[3];
vector<unsigned short> dir;
} Grid_Path;
//! Abstract base-class for a common operator
class Operator_Base
{
public:
virtual ~Operator_Base();
virtual bool SetGeometryCSX(ContinuousStructure* geo);
virtual ContinuousStructure* GetGeometryCSX() const {return CSX;}
//! Get the timestep used by this operator
virtual double GetTimestep() const {return dT;}
//! Get the number of cells or nodes defined by this operator
virtual double GetNumberCells() const =0;
//! Get the number of timesteps satisfying the nyquist condition (may depend on the excitation)
virtual unsigned int GetNumberOfNyquistTimesteps() const =0;
//! Returns the number of lines as needed for post-processing etc.
virtual unsigned int GetNumberOfLines(int ny, bool full=false) const =0;
//! Get the name for the given direction: 0 -> x, 1 -> y, 2 -> z
virtual std::string GetDirName(int ny) const;
//! Get the grid drawing unit in m
virtual double GetGridDelta() const =0;
//! Get the disc line in \a n direction (in drawing units)
virtual double GetDiscLine(int n, unsigned int pos, bool dualMesh=false) const =0;
//! Get the disc line delta in \a n direction (in drawing units)
virtual double GetDiscDelta(int n, unsigned int pos, bool dualMesh=false) const =0;
//! Get the node width for a given direction \a n and a given mesh position \a pos
virtual double GetNodeWidth(int ny, const unsigned int pos[3], bool dualMesh = false) const =0;
//! Get the node area for a given direction \a n and a given mesh position \a pos
virtual double GetNodeArea(int ny, const unsigned int pos[3], bool dualMesh = false) const =0;
//! Get the length of an FDTD edge (unit is meter).
virtual double GetEdgeLength(int ny, const unsigned int pos[3], bool dualMesh = false) const =0;
//! Get the area around an edge for a given direction \a n and a given mesh posisition \a pos
/*!
This will return the area around an edge with a given direction, measured at the middle of the edge.
In a cartesian mesh this is equal to the NodeArea, may be different in other coordinate systems.
*/
virtual double GetEdgeArea(int ny, const unsigned int pos[3], bool dualMesh = false) const =0;
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//! Get the volume of an FDTD cell
virtual double GetCellVolume(const unsigned int pos[3], bool dualMesh = false) const =0;
//! Snap the given coodinates to mesh indices, return box dimension
virtual bool SnapToMesh(const double* coord, unsigned int* uicoord, bool dualMesh=false, bool fullMesh=false, bool* inside=NULL) const =0;
//! Snap a given box to the operator mesh, uiStart will be always <= uiStop
/*!
\param[in] start the box-start coorindate
\param[in] stop the box-stopt coorindate
\param[out] uiStart the snapped box-start coorindate index
\param[out] uiStop the snapped box-stop coorindate index
\param[in] dualMesh snap to main or dual mesh (default is main mesh)
\param[in] SnapMethod Snapping method, 0=snap to closest line, 1/(2)=snap such that given box is inside (outside) the snapped lines
\return returns the box dimension or -1 if box is not inside the simulation domain
*/
virtual int SnapBox2Mesh(const double* start, const double* stop, unsigned int* uiStart, unsigned int* uiStop, bool dualMesh=false, bool fullMesh=false, int SnapMethod=0, bool* bStartIn=NULL, bool* bStopIn=NULL) const =0;
//! Set the boundary conditions
virtual void SetBoundaryCondition(int* BCs) {for (int n=0; n<6; ++n) m_BC[n]=BCs[n];}
//! Set flags to store material data for post-processing
virtual void SetMaterialStoreFlags(int type, bool val);
//! Check storage flags and cleanup
virtual void CleanupMaterialStorage() = 0;
//! Get stored discrete material (if storage is enabled).
virtual double GetDiscMaterial(int type, int ny, const unsigned int pos[3]) const = 0;
//! Set the background material (default is vacuum)
virtual void SetBackgroundMaterial(double epsR=0, double mueR=0, double kappa=0, double sigma=0, double density=0);
//! Get background rel. electric permittivity
double GetBackgroundEpsR() const {return m_BG_epsR;}
//! Set background rel. electric permittivity
void SetBackgroundEpsR(double val);
//! Get background rel. magnetic permeability
double GetBackgroundMueR() const {return m_BG_mueR;}
//! Set background rel. magnetic permeability
void SetBackgroundMueR(double val);
//! Get background electric conductivity
double GetBackgroundKappa() const {return m_BG_kappa;}
//! Set background electric conductivity
void SetBackgroundKappa(double val);
//! Get background magnetic conductivity (artificial)
double GetBackgroundSigma() const {return m_BG_sigma;}
//! Set background magnetic conductivity (artificial)
void SetBackgroundSigma(double val);
//! Get background mass density
double GetBackgroundDensity() const {return m_BG_density;}
//! Set background mass density
void SetBackgroundDensity(double val);
protected:
Operator_Base();
ContinuousStructure* CSX;
virtual void Init();
//! Cleanup data and reset
void Delete();
virtual void Reset();
//! boundary conditions
int m_BC[6];
//! The operator timestep
double dT;
//! bool flag array to store material data for post-processing
bool m_StoreMaterial[4];
//! background materials
double m_BG_epsR;
double m_BG_mueR;
double m_BG_kappa;
double m_BG_sigma;
double m_BG_density;
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CoordinateSystem m_MeshType;
unsigned int numLines[3];
double* discLines[3];
double gridDelta;
};
#endif // OPERATOR_BASE_H