/usr/include/ASL/num/aslFDAdvectionDiffusion.h is in libasl-dev 0.1.7-2build1.
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* Advanced Simulation Library <http://asl.org.il>
*
* Copyright 2015 Avtech Scientific <http://avtechscientific.com>
*
*
* This file is part of Advanced Simulation Library (ASL).
*
* ASL is free software: you can redistribute it and/or modify it
* under the terms of the GNU Affero General Public License as
* published by the Free Software Foundation, version 3 of the License.
*
* ASL 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 Affero General Public License for more details.
*
* You should have received a copy of the GNU Affero General Public License
* along with ASL. If not, see <http://www.gnu.org/licenses/>.
*
*/
#ifndef ASLFDADVECTIONDIFFUSION_H
#define ASLFDADVECTIONDIFFUSION_H
#include "aslSingleKernelNM.h"
namespace acl
{
class VectorOfElementsData;
class VectorOfElements;
}
namespace asl
{
class VectorTemplate;
template <typename V> class DataWithGhostNodes;
typedef DataWithGhostNodes<acl::VectorOfElementsData> DataWithGhostNodesACLData;
typedef std::shared_ptr<DataWithGhostNodesACLData> SPDataWithGhostNodesACLData;
class AbstractDataWithGhostNodes;
typedef std::shared_ptr<AbstractDataWithGhostNodes> SPAbstractDataWithGhostNodes;
/// Numerical method which computes multicomponent transport processes
/**
\ingroup TransportProcesses
\ingroup NumMethods
\f[ \partial_t c_i= D_i \Delta c_i - \nabla (\vec v c_i)
-\nabla\left(\frac{c_i q}{k} \nabla(\phi+f_2) \right)\f]
where
\param cData corresponds to \f$c_i\f$
\param diffusionCoefficient corresponds to \f$D_i\f$
\param efFactor1 corresponds to \f$k\f$
\param efFactor2 corresponds to \f$f_2\f$
\param efPhi corresponds to \f$\phi\f$
\param efChargeAnd corresponds to \f$q\f$
\param velocity corresponds to \f$\vec v\f$
*/
class FDAdvectionDiffusion: public SingleKernelNM
{
public:
typedef SPDataWithGhostNodesACLData Data;
typedef SPAbstractDataWithGhostNodes Field;
private:
std::vector<Data> cData;
std::vector<Data> cInternalData;
bool electricField;
Field efPhi;
Field efFactor1;
Field efFactor2;
std::vector<Field> efChargeAnd;
Field velocity;
/// advection process described by distribution function instead of velocity field
Field distributionFunction;
bool compressibilityCorrectionFlag;
const VectorTemplate* vectorTemplate;
int t;
std::vector<acl::VectorOfElements> diffusionCoefficient;
virtual void init0();
virtual void postProcessing();
public:
FDAdvectionDiffusion();
FDAdvectionDiffusion(Data c,
const acl::VectorOfElements & dC,
const VectorTemplate* vT);
void setDiffusionCoefficient(acl::VectorOfElements d,
unsigned int i = 0);
inline const acl::VectorOfElements & getDiffusionCoefficient(unsigned int i=0) const;
void setVectorTemplate(VectorTemplate* vT);
inline const VectorTemplate* getVectorTemplate() const;
void setElectricFieldParameters(Field phi,
Field f1,
Field f2,
Field qAnd);
void setVelocity(Field v, bool compressibilityCorrection=false);
void setDistributionFunction(Field f);
inline Field getVelocity();
inline Field getDistributionFunction();
inline std::vector<Data> & getData();
void addComponent(Data c, acl::VectorOfElements & dC);
void addComponent(Data c, acl::VectorOfElements & dC, Field qAnd);
};
typedef std::shared_ptr<FDAdvectionDiffusion> SPFDAdvectionDiffusion;
/**
\ingroup TransportProcesses
\ingroup NumMethods
\f[ \partial_t c_i= D_i \Delta c_i - \nabla (\vec v c_i)\f]
where
\param cData corresponds to \f$c_i\f$
\param diffusionCoefficient corresponds to \f$D_i\f$
\param velocity corresponds to \f$\vec v\f$
*/
SPFDAdvectionDiffusion generateFDAdvectionDiffusion(SPDataWithGhostNodesACLData c,
double diffustionCoeff,
SPAbstractDataWithGhostNodes v,
const VectorTemplate* vt,
bool compressibilityCorrection = false);
/**
\ingroup TransportProcesses
\ingroup NumMethods
\f[ \partial_t c_i= D_i \Delta c_i \f]
where
\param cData corresponds to \f$ c_i \f$
\param diffusionCoefficient corresponds to \f$ D_i \f$
*/
SPFDAdvectionDiffusion generateFDAdvectionDiffusion(SPDataWithGhostNodesACLData c,
double diffustionCoeff,
const VectorTemplate* vt);
// ------------------------- Implementation ------------------------
inline FDAdvectionDiffusion::Field FDAdvectionDiffusion::getVelocity()
{
return velocity;
}
inline FDAdvectionDiffusion::Field FDAdvectionDiffusion::getDistributionFunction()
{
return distributionFunction;
}
inline std::vector<FDAdvectionDiffusion::Data> & FDAdvectionDiffusion::getData()
{
return cData;
}
inline const VectorTemplate* FDAdvectionDiffusion::getVectorTemplate() const
{
return vectorTemplate;
}
inline const acl::VectorOfElements &
FDAdvectionDiffusion::getDiffusionCoefficient(unsigned int i) const
{
return diffusionCoefficient[i];
}
} // asl
#endif // ASLFDADVECTIONDIFFUSION_H
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