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#include "AbstractCardiacMechanicsSolver.hpp"

#include "AbstractContractionCellFactory.hpp"

#include "FakeBathContractionModel.hpp"


template<class ELASTICITY_SOLVER,unsigned DIM>


AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::AbstractCardiacMechanicsSolver(QuadraticMesh<DIM>& rQuadMesh,

                                                                                      ElectroMechanicsProblemDefinition<DIM>& rProblemDefinition,

                                                                                      std::string outputDirectory)

   : ELASTICITY_SOLVER(rQuadMesh,

                       rProblemDefinition,

                       outputDirectory),

     mpMeshPair(NULL),

     mCurrentTime(DBL_MAX),

     mNextTime(DBL_MAX),

     mOdeTimestep(DBL_MAX),

     mrElectroMechanicsProblemDefinition(rProblemDefinition)

{

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::Initialise()

{

    // compute total num quad points

    unsigned num_quad_pts_per_element = this->mpQuadratureRule->GetNumQuadPoints();

    mTotalQuadPoints = this->mrQuadMesh.GetNumElements()*num_quad_pts_per_element;


    std::vector<ElementAndWeights<DIM> > fine_elements = mpMeshPair->rGetElementsAndWeights();

    assert(fine_elements.size()==mTotalQuadPoints);

    assert(mpMeshPair!=NULL);


    AbstractContractionCellFactory<DIM>* p_factory = mrElectroMechanicsProblemDefinition.GetContractionCellFactory();


    for (typename AbstractTetrahedralMesh<DIM, DIM>::ElementIterator iter = this->mrQuadMesh.GetElementIteratorBegin();

         iter != this->mrQuadMesh.GetElementIteratorEnd();

         ++iter)

    {

        Element<DIM, DIM>& element = *iter;


        if (element.GetOwnership() == true)

        {

            for (unsigned j=0; j<num_quad_pts_per_element; j++)

            {

                unsigned quad_pt_global_index = element.GetIndex()*num_quad_pts_per_element + j;


                // We construct a set of data to be assigned to each quadrature point

                // this includes a contraction cell model set as bath or by the contraction

                // cell factory.

                DataAtQuadraturePoint data_at_quad_point;

                data_at_quad_point.Stretch = 1.0;

                data_at_quad_point.StretchLastTimeStep = 1.0;


                if (mpMeshPair->GetFineMesh().GetElement(fine_elements[quad_pt_global_index].ElementNum)

                        ->GetUnsignedAttribute() == HeartRegionCode::GetValidBathId() )

                {

                    // Bath

                    data_at_quad_point.ContractionModel = new FakeBathContractionModel;

                }

                else

                {

                    // Tissue

                    data_at_quad_point.ContractionModel = p_factory->CreateContractionCellForElement( &element );

                }

                mQuadPointToDataAtQuadPointMap[quad_pt_global_index] = data_at_quad_point;

            }

        }

    }


    // initialise the iterator to point at the beginning

    mMapIterator = mQuadPointToDataAtQuadPointMap.begin();


    // initialise fibre/sheet direction matrix to be the identity, fibres in X-direction, and sheet in XY-plane

    mConstantFibreSheetDirections = zero_matrix<double>(DIM,DIM);

    for (unsigned i=0; i<DIM; i++)

    {

        mConstantFibreSheetDirections(i,i) = 1.0;

    }


    mpVariableFibreSheetDirections = NULL;


    // Check that we are using the right kind of solver.

    for (std::map<unsigned,DataAtQuadraturePoint>::iterator iter = this->mQuadPointToDataAtQuadPointMap.begin();

            iter != this->mQuadPointToDataAtQuadPointMap.end();

            iter++)

    {

        if (!IsImplicitSolver() && (*iter).second.ContractionModel->IsStretchRateDependent())

        {

            EXCEPTION("stretch-rate-dependent contraction model requires an IMPLICIT cardiac mechanics solver.");

        }


        if (!IsImplicitSolver() && (*iter).second.ContractionModel->IsStretchDependent())

        {

            WARN_ONCE_ONLY("stretch-dependent contraction model may require an IMPLICIT cardiac mechanics solver.");

        }

    }

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::SetFineCoarseMeshPair(FineCoarseMeshPair<DIM>* pMeshPair)

{

    assert(pMeshPair!=NULL);

    if (pMeshPair->GetCoarseMesh().GetNumElements() != this->mrQuadMesh.GetNumElements())

    {

        EXCEPTION("When setting a mesh pair into the solver, the coarse mesh of the mesh pair must be the same as the quadratic mesh");

    }

    mpMeshPair = pMeshPair;

}


template<class ELASTICITY_SOLVER,unsigned DIM>


AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::~AbstractCardiacMechanicsSolver()

{

    for (mMapIterator = mQuadPointToDataAtQuadPointMap.begin();

        mMapIterator != mQuadPointToDataAtQuadPointMap.end();

        ++mMapIterator)

    {

        AbstractContractionModel* p_model = mMapIterator->second.ContractionModel;

        if (p_model)

        {

            delete p_model;

        }

    }


    if (mpVariableFibreSheetDirections)

    {

        delete mpVariableFibreSheetDirections;

    }

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::SetCalciumAndVoltage(std::vector<double>& rCalciumConcentrations,

                                                                                 std::vector<double>& rVoltages)


{

    assert(rCalciumConcentrations.size() == mTotalQuadPoints);

    assert(rVoltages.size() == mTotalQuadPoints);


    ContractionModelInputParameters input_parameters;


    for (unsigned i=0; i<rCalciumConcentrations.size(); i++)

    {

        input_parameters.intracellularCalciumConcentration = rCalciumConcentrations[i];

        input_parameters.voltage = rVoltages[i];


        std::map<unsigned,DataAtQuadraturePoint>::iterator iter = mQuadPointToDataAtQuadPointMap.find(i);

        if (iter != mQuadPointToDataAtQuadPointMap.end())

        {

            iter->second.ContractionModel->SetInputParameters(input_parameters);

        }

    }

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::SetupChangeOfBasisMatrix(unsigned elementIndex,

                                                                                     unsigned currentQuadPointGlobalIndex)

{

    if (!mpVariableFibreSheetDirections) // constant fibre directions

    {

        this->mChangeOfBasisMatrix = mConstantFibreSheetDirections;

    }

    else if (!mFibreSheetDirectionsDefinedByQuadraturePoint) // fibre directions defined for each mechanics mesh element

    {

        this->mChangeOfBasisMatrix = (*mpVariableFibreSheetDirections)[elementIndex];

    }

    else // fibre directions defined for each mechanics mesh quadrature point

    {

        this->mChangeOfBasisMatrix = (*mpVariableFibreSheetDirections)[currentQuadPointGlobalIndex];

    }

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::AddActiveStressAndStressDerivative(c_matrix<double,DIM,DIM>& rC,

                                                                                               unsigned elementIndex,

                                                                                               unsigned currentQuadPointGlobalIndex,

                                                                                               c_matrix<double,DIM,DIM>& rT,

                                                                                               FourthOrderTensor<DIM,DIM,DIM,DIM>& rDTdE,

                                                                                               bool addToDTdE)

{

    for (unsigned i=0; i<DIM; i++)

    {

        mCurrentElementFibreDirection(i) = this->mChangeOfBasisMatrix(i,0);

    }


    //Compute the active tension and add to the stress and stress-derivative

    double I4_fibre = inner_prod(mCurrentElementFibreDirection, prod(rC, mCurrentElementFibreDirection));

    double lambda_fibre = sqrt(I4_fibre);


    double active_tension = 0;

    double d_act_tension_dlam = 0.0;     // Set and used if assembleJacobian==true

    double d_act_tension_d_dlamdt = 0.0; // Set and used if assembleJacobian==true


    GetActiveTensionAndTensionDerivs(lambda_fibre, currentQuadPointGlobalIndex, addToDTdE,

                                     active_tension, d_act_tension_dlam, d_act_tension_d_dlamdt);


    double detF = sqrt(Determinant(rC));

    rT += (active_tension*detF/I4_fibre)*outer_prod(mCurrentElementFibreDirection,mCurrentElementFibreDirection);


    // amend the stress and dTdE using the active tension

    double dTdE_coeff1 = -2*active_tension*detF/(I4_fibre*I4_fibre); // note: I4_fibre*I4_fibre = lam^4

    double dTdE_coeff2 = active_tension*detF/I4_fibre;

    double dTdE_coeff_s1 = 0.0; // only set non-zero if we apply cross fibre tension (in 2/3D)

    double dTdE_coeff_s2 = 0.0; // only set non-zero if we apply cross fibre tension (in 2/3D)

    double dTdE_coeff_s3 = 0.0; // only set non-zero if we apply cross fibre tension and implicit (in 2/3D)

    double dTdE_coeff_n1 = 0.0; // only set non-zero if we apply cross fibre tension in 3D

    double dTdE_coeff_n2 = 0.0; // only set non-zero if we apply cross fibre tension in 3D

    double dTdE_coeff_n3 = 0.0; // only set non-zero if we apply cross fibre tension in 3D and implicit


    if (IsImplicitSolver())

    {

        double dt = mNextTime-mCurrentTime;

        //std::cout << "d sigma / d lamda = " << d_act_tension_dlam << ", d sigma / d lamdat = " << d_act_tension_d_dlamdt << "\n" << std::flush;

        dTdE_coeff1 += (d_act_tension_dlam + d_act_tension_d_dlamdt/dt)*detF/(lambda_fibre*I4_fibre); // note: I4_fibre*lam = lam^3

    }


    bool apply_cross_fibre_tension = (this->mrElectroMechanicsProblemDefinition.GetApplyCrossFibreTension()) && (DIM > 1);

    if (apply_cross_fibre_tension)

    {

        double sheet_cross_fraction = mrElectroMechanicsProblemDefinition.GetSheetTensionFraction();


        for (unsigned i=0; i<DIM; i++)

        {

            mCurrentElementSheetDirection(i) = this->mChangeOfBasisMatrix(i,1);

        }


        double I4_sheet = inner_prod(mCurrentElementSheetDirection, prod(rC, mCurrentElementSheetDirection));


        // amend the stress and dTdE using the active tension

        dTdE_coeff_s1 = -2*sheet_cross_fraction*detF*active_tension/(I4_sheet*I4_sheet); // note: I4*I4 = lam^4


        if (IsImplicitSolver())

        {

            double dt = mNextTime-mCurrentTime;

            dTdE_coeff_s3 = sheet_cross_fraction*(d_act_tension_dlam + d_act_tension_d_dlamdt/dt)*detF/(lambda_fibre*I4_sheet); // note: I4*lam = lam^3

        }


        rT += sheet_cross_fraction*(active_tension*detF/I4_sheet)*outer_prod(mCurrentElementSheetDirection,mCurrentElementSheetDirection);


        dTdE_coeff_s2 = active_tension*sheet_cross_fraction*detF/I4_sheet;


        if (DIM>2)

        {

            double sheet_normal_cross_fraction = mrElectroMechanicsProblemDefinition.GetSheetNormalTensionFraction();

            for (unsigned i=0; i<DIM; i++)

            {

                mCurrentElementSheetNormalDirection(i) = this->mChangeOfBasisMatrix(i,2);

            }


            double I4_sheet_normal = inner_prod(mCurrentElementSheetNormalDirection, prod(rC, mCurrentElementSheetNormalDirection));


            dTdE_coeff_n1 =-2*sheet_normal_cross_fraction*detF*active_tension/(I4_sheet_normal*I4_sheet_normal); // note: I4*I4 = lam^4


            rT += sheet_normal_cross_fraction*(active_tension*detF/I4_sheet_normal)*outer_prod(mCurrentElementSheetNormalDirection,mCurrentElementSheetNormalDirection);


            dTdE_coeff_n2 = active_tension*sheet_normal_cross_fraction*detF/I4_sheet_normal;

            if (IsImplicitSolver())

            {

                double dt = mNextTime-mCurrentTime;

                dTdE_coeff_n3 = sheet_normal_cross_fraction*(d_act_tension_dlam + d_act_tension_d_dlamdt/dt)*detF/(lambda_fibre*I4_sheet_normal); // note: I4*lam = lam^3

            }

        }

    }


    if (addToDTdE)

    {

        c_matrix<double,DIM,DIM> invC = Inverse(rC);


        for (unsigned M=0; M<DIM; M++)

        {

            for (unsigned N=0; N<DIM; N++)

            {

                for (unsigned P=0; P<DIM; P++)

                {

                    for (unsigned Q=0; Q<DIM; Q++)

                    {

                        rDTdE(M,N,P,Q) +=   dTdE_coeff1 * mCurrentElementFibreDirection(M)

                                                        * mCurrentElementFibreDirection(N)

                                                        * mCurrentElementFibreDirection(P)

                                                        * mCurrentElementFibreDirection(Q)


                                         +  dTdE_coeff2 * mCurrentElementFibreDirection(M)

                                                        * mCurrentElementFibreDirection(N)

                                                        * invC(P,Q);

                        if (apply_cross_fibre_tension)

                        {

                            rDTdE(M,N,P,Q) += dTdE_coeff_s1 * mCurrentElementSheetDirection(M)

                                                            * mCurrentElementSheetDirection(N)

                                                            * mCurrentElementSheetDirection(P)

                                                            * mCurrentElementSheetDirection(Q)


                                           +  dTdE_coeff_s2 * mCurrentElementSheetDirection(M)

                                                            * mCurrentElementSheetDirection(N)

                                                            * invC(P,Q)


                                           + dTdE_coeff_s3 * mCurrentElementSheetDirection(M)

                                                           * mCurrentElementSheetDirection(N)

                                                           * mCurrentElementFibreDirection(P)

                                                           * mCurrentElementFibreDirection(Q);

                            if (DIM>2)

                            {

                                rDTdE(M,N,P,Q) += dTdE_coeff_n1 * mCurrentElementSheetNormalDirection(M)

                                                                * mCurrentElementSheetNormalDirection(N)

                                                                * mCurrentElementSheetNormalDirection(P)

                                                                * mCurrentElementSheetNormalDirection(Q)


                                                + dTdE_coeff_n2 * mCurrentElementSheetNormalDirection(M)

                                                                * mCurrentElementSheetNormalDirection(N)

                                                                * invC(P,Q)


                                                + dTdE_coeff_n3 * mCurrentElementSheetNormalDirection(M)

                                                                * mCurrentElementSheetNormalDirection(N)

                                                                * mCurrentElementFibreDirection(P)

                                                                * mCurrentElementFibreDirection(Q);

                            }

                        }

                    }

                }

            }

        }

    }


//    ///\todo #2180 The code below applies a cross fibre tension in the 2D case. Things that need doing:

//    // * Refactor the common code between the block below and the block above to avoid duplication.

//    // * Handle the 3D case.

//    if (this->mrElectroMechanicsProblemDefinition.GetApplyCrossFibreTension() && DIM > 1)

//    {

//        double sheet_cross_fraction = mrElectroMechanicsProblemDefinition.GetSheetTensionFraction();

//

//        for (unsigned i=0; i<DIM; i++)

//        {

//            mCurrentElementSheetDirection(i) = this->mChangeOfBasisMatrix(i,1);

//        }

//

//        double I4_sheet = inner_prod(mCurrentElementSheetDirection, prod(rC, mCurrentElementSheetDirection));

//

//        // amend the stress and dTdE using the active tension

//        double dTdE_coeff_s1 = -2*sheet_cross_fraction*detF*active_tension/(I4_sheet*I4_sheet); // note: I4*I4 = lam^4

//

//        ///\todo #2180 The code below is specific to the implicit cardiac mechanics solver. Currently

//        // the cross-fibre code is only tested using the explicit solver so the code below fails coverage.

//        // This will need to be added back in once an implicit test is in place.

//        double lambda_sheet = sqrt(I4_sheet);

//        if (IsImplicitSolver())

//        {

//           double dt = mNextTime-mCurrentTime;

//           dTdE_coeff_s1 += (d_act_tension_dlam + d_act_tension_d_dlamdt/dt)/(lambda_sheet*I4_sheet); // note: I4*lam = lam^3

//        }

//

//        rT += sheet_cross_fraction*(active_tension*detF/I4_sheet)*outer_prod(mCurrentElementSheetDirection,mCurrentElementSheetDirection);

//

//        double dTdE_coeff_s2 = active_tension*detF/I4_sheet;

//        if (addToDTdE)

//        {

//           for (unsigned M=0; M<DIM; M++)

//           {

//               for (unsigned N=0; N<DIM; N++)

//               {

//                   for (unsigned P=0; P<DIM; P++)

//                   {

//                       for (unsigned Q=0; Q<DIM; Q++)

//                       {

//                           rDTdE(M,N,P,Q) +=  dTdE_coeff_s1 * mCurrentElementSheetDirection(M)

//                                                            * mCurrentElementSheetDirection(N)

//                                                            * mCurrentElementSheetDirection(P)

//                                                            * mCurrentElementSheetDirection(Q)

//

//                                           +  dTdE_coeff_s2 * mCurrentElementFibreDirection(M)

//                                                            * mCurrentElementFibreDirection(N)

//                                                            * invC(P,Q);

//

//                       }

//                   }

//               }

//           }

//        }

//    }

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::ComputeDeformationGradientAndStretchInEachElement(

    std::vector<c_matrix<double,DIM,DIM> >& rDeformationGradients,

    std::vector<double>& rStretches)

{

    assert(rStretches.size()==this->mrQuadMesh.GetNumElements());


    // this will only work currently if the coarse mesh fibre info is defined per element, not per quad point

    assert(!mpVariableFibreSheetDirections || !mFibreSheetDirectionsDefinedByQuadraturePoint);


    static c_matrix<double,DIM,NUM_VERTICES_PER_ELEMENT> element_current_displacements;

    static c_matrix<double,DIM,NUM_VERTICES_PER_ELEMENT> grad_lin_phi;

    static c_matrix<double,DIM,DIM> F;      // the deformation gradient, F = dx/dX, F_{iM} = dx_i/dX_M


    static c_matrix<double,DIM,DIM> jacobian;

    static c_matrix<double,DIM,DIM> inverse_jacobian;

    double jacobian_determinant;

    ChastePoint<DIM> quadrature_point; // not needed, but has to be passed in


    // loop over all the elements

    for (unsigned elem_index=0; elem_index<this->mrQuadMesh.GetNumElements(); elem_index++)

    {

        Element<DIM,DIM>* p_elem = this->mrQuadMesh.GetElement(elem_index);


        // get the fibre direction for this element

        SetupChangeOfBasisMatrix(elem_index, 0); // 0 is quad index, and doesn't matter as checked that fibres not defined by quad pt above.

        for (unsigned i=0; i<DIM; i++)

        {

            mCurrentElementFibreDirection(i) = this->mChangeOfBasisMatrix(i,0);

        }


        // get the displacement at this element

        for (unsigned II=0; II<NUM_VERTICES_PER_ELEMENT; II++)

        {

            for (unsigned JJ=0; JJ<DIM; JJ++)

            {

                // mProblemDimension = DIM for compressible elasticity and DIM+1 for incompressible elasticity

                element_current_displacements(JJ,II) = this->mCurrentSolution[this->mProblemDimension*p_elem->GetNodeGlobalIndex(II) + JJ];

            }

        }


        // set up the linear basis functions

        this->mrQuadMesh.GetInverseJacobianForElement(elem_index, jacobian, jacobian_determinant, inverse_jacobian);

        LinearBasisFunction<DIM>::ComputeTransformedBasisFunctionDerivatives(quadrature_point, inverse_jacobian, grad_lin_phi);


        F = identity_matrix<double>(DIM,DIM);


        // loop over the vertices and interpolate F, the deformation gradient

        // (note: could use matrix-mult if this becomes inefficient

        for (unsigned node_index=0; node_index<NUM_VERTICES_PER_ELEMENT; node_index++)

        {

            for (unsigned i=0; i<DIM; i++)

            {

                for (unsigned M=0; M<DIM; M++)

                {

                    F(i,M) += grad_lin_phi(M,node_index)*element_current_displacements(i,node_index);

                }

            }

        }


        rDeformationGradients[elem_index] = F;


        // compute and save the stretch: m^T C m = ||Fm||

        c_vector<double,DIM> deformed_fibre = prod(F, mCurrentElementFibreDirection);

        rStretches[elem_index] = norm_2(deformed_fibre);

    }

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::SetVariableFibreSheetDirections(const FileFinder& rOrthoFile, bool definedPerQuadraturePoint)

{

    mFibreSheetDirectionsDefinedByQuadraturePoint = definedPerQuadraturePoint;


    FibreReader<DIM> reader(rOrthoFile, ORTHO);


    unsigned num_entries = reader.GetNumLinesOfData();


    if (!mFibreSheetDirectionsDefinedByQuadraturePoint && (num_entries!=this->mrQuadMesh.GetNumElements()) )

    {

        EXCEPTION("Number of entries defined at top of file " << rOrthoFile.GetAbsolutePath() <<

                  " does not match number of elements in the mesh, " << "found " <<  num_entries <<

                  ", expected " << this->mrQuadMesh.GetNumElements());

    }


    if (mFibreSheetDirectionsDefinedByQuadraturePoint && (num_entries!=mTotalQuadPoints) )

    {

        EXCEPTION("Number of entries defined at top of file " << rOrthoFile.GetAbsolutePath() <<

                  " does not match number of quadrature points defined, " << "found " <<  num_entries <<

                  ", expected " << mTotalQuadPoints);

    }


    mpVariableFibreSheetDirections = new std::vector<c_matrix<double,DIM,DIM> >(num_entries, zero_matrix<double>(DIM,DIM));

    for (unsigned index=0; index<num_entries; index++)

    {

        reader.GetFibreSheetAndNormalMatrix(index, (*mpVariableFibreSheetDirections)[index] );

    }

}


template<class ELASTICITY_SOLVER,unsigned DIM>


void AbstractCardiacMechanicsSolver<ELASTICITY_SOLVER,DIM>::SetConstantFibreSheetDirections(const c_matrix<double,DIM,DIM>& rFibreSheetMatrix)

{

    mConstantFibreSheetDirections = rFibreSheetMatrix;

    // check orthogonality

    c_matrix<double,DIM,DIM>  temp = prod(trans(rFibreSheetMatrix),rFibreSheetMatrix);

    for (unsigned i=0; i<DIM; i++)

    {

        for (unsigned j=0; j<DIM; j++)

        {

            double val = (i==j ? 1.0 : 0.0);

            if (fabs(temp(i,j)-val)>1e-4)

            {

                EXCEPTION("The given fibre-sheet matrix, " << rFibreSheetMatrix << ", is not orthogonal");

            }

        }

    }

}


template class AbstractCardiacMechanicsSolver<IncompressibleNonlinearElasticitySolver<2>,2>;

template class AbstractCardiacMechanicsSolver<IncompressibleNonlinearElasticitySolver<3>,3>;

template class AbstractCardiacMechanicsSolver<CompressibleNonlinearElasticitySolver<2>,2>;

template class AbstractCardiacMechanicsSolver<CompressibleNonlinearElasticitySolver<3>,3>;


EXCEPTION
#define EXCEPTION(message)
Definition Exception.hpp:156

Determinant
T Determinant(const boost::numeric::ublas::c_matrix< T, 1, 1 > &rM)
Definition UblasCustomFunctions.hpp:59

Inverse
boost::numeric::ublas::c_matrix< T, 1, 1 > Inverse(const boost::numeric::ublas::c_matrix< T, 1, 1 > &rM)
Definition UblasCustomFunctions.hpp:367

AbstractCardiacMechanicsSolver
Definition AbstractCardiacMechanicsSolver.hpp:82

AbstractCardiacMechanicsSolver::SetCalciumAndVoltage
void SetCalciumAndVoltage(std::vector< double > &rCalciumConcentrations, std::vector< double > &rVoltages)
Definition AbstractCardiacMechanicsSolver.cpp:165

AbstractCardiacMechanicsSolver::ComputeDeformationGradientAndStretchInEachElement
void ComputeDeformationGradientAndStretchInEachElement(std::vector< c_matrix< double, DIM, DIM > > &rDeformationGradients, std::vector< double > &rStretches)
Definition AbstractCardiacMechanicsSolver.cpp:418

AbstractCardiacMechanicsSolver::Initialise
void Initialise()
Definition AbstractCardiacMechanicsSolver.cpp:56

AbstractCardiacMechanicsSolver::SetFineCoarseMeshPair
void SetFineCoarseMeshPair(FineCoarseMeshPair< DIM > *pMeshPair)
Definition AbstractCardiacMechanicsSolver.cpp:134

AbstractCardiacMechanicsSolver::~AbstractCardiacMechanicsSolver
virtual ~AbstractCardiacMechanicsSolver()
Definition AbstractCardiacMechanicsSolver.cpp:145

AbstractCardiacMechanicsSolver::SetVariableFibreSheetDirections
void SetVariableFibreSheetDirections(const FileFinder &rOrthoFile, bool definedPerQuadraturePoint)
Definition AbstractCardiacMechanicsSolver.cpp:487

AbstractCardiacMechanicsSolver::AbstractCardiacMechanicsSolver
AbstractCardiacMechanicsSolver(QuadraticMesh< DIM > &rQuadMesh, ElectroMechanicsProblemDefinition< DIM > &rProblemDefinition, std::string outputDirectory)
Definition AbstractCardiacMechanicsSolver.cpp:41

AbstractCardiacMechanicsSolver::SetupChangeOfBasisMatrix
void SetupChangeOfBasisMatrix(unsigned elementIndex, unsigned currentQuadPointGlobalIndex)
Definition AbstractCardiacMechanicsSolver.cpp:190

AbstractCardiacMechanicsSolver::SetConstantFibreSheetDirections
void SetConstantFibreSheetDirections(const c_matrix< double, DIM, DIM > &rFibreSheetMatrix)
Definition AbstractCardiacMechanicsSolver.cpp:517

AbstractCardiacMechanicsSolver::AddActiveStressAndStressDerivative
void AddActiveStressAndStressDerivative(c_matrix< double, DIM, DIM > &rC, unsigned elementIndex, unsigned currentQuadPointGlobalIndex, c_matrix< double, DIM, DIM > &rT, FourthOrderTensor< DIM, DIM, DIM, DIM > &rDTdE, bool addToDTdE)
Definition AbstractCardiacMechanicsSolver.cpp:208

AbstractContractionCellFactory
Definition AbstractContractionCellFactory.hpp:55

AbstractContractionCellFactory::CreateContractionCellForElement
virtual AbstractContractionModel * CreateContractionCellForElement(Element< DIM, DIM > *pElement)=0

AbstractContractionModel
Definition AbstractContractionModel.hpp:59

AbstractElement::GetNodeGlobalIndex
unsigned GetNodeGlobalIndex(unsigned localIndex) const
Definition AbstractElement.cpp:109

AbstractElement::GetOwnership
bool GetOwnership() const
Definition AbstractElement.cpp:153

AbstractElement::GetIndex
unsigned GetIndex() const
Definition AbstractElement.cpp:141

AbstractTetrahedralMesh::ElementIterator
Definition AbstractTetrahedralMesh.hpp:634

AbstractTetrahedralMesh::GetNumElements
virtual unsigned GetNumElements() const
Definition AbstractTetrahedralMesh.cpp:87

ChastePoint
Definition ChastePoint.hpp:50

ELASTICITY_SOLVER

ElectroMechanicsProblemDefinition
Definition ElectroMechanicsProblemDefinition.hpp:53

Element
Definition Element.hpp:54

FakeBathContractionModel
Definition FakeBathContractionModel.hpp:47

FibreReader
Definition FibreReader.hpp:62

FibreReader::GetFibreSheetAndNormalMatrix
void GetFibreSheetAndNormalMatrix(unsigned fibreIndex, c_matrix< double, DIM, DIM > &rFibreMatrix, bool checkOrthogonality=true)
Definition FibreReader.cpp:125

FibreReader::GetNumLinesOfData
unsigned GetNumLinesOfData()
Definition FibreReader.hpp:155

FileFinder
Definition FileFinder.hpp:71

FileFinder::GetAbsolutePath
std::string GetAbsolutePath() const
Definition FileFinder.cpp:223

FineCoarseMeshPair
Definition FineCoarseMeshPair.hpp:107

FineCoarseMeshPair::GetCoarseMesh
const AbstractTetrahedralMesh< DIM, DIM > & GetCoarseMesh() const
Definition FineCoarseMeshPair.cpp:55

FourthOrderTensor
Definition FourthOrderTensor.hpp:52

HeartRegionCode::GetValidBathId
static HeartRegionType GetValidBathId()
Definition HeartRegionCodes.cpp:47

LinearBasisFunction::ComputeTransformedBasisFunctionDerivatives
static void ComputeTransformedBasisFunctionDerivatives(const ChastePoint< ELEMENT_DIM > &rPoint, const c_matrix< double, ELEMENT_DIM, ELEMENT_DIM > &rInverseJacobian, c_matrix< double, ELEMENT_DIM, ELEMENT_DIM+1 > &rReturnValue)
Definition LinearBasisFunction.cpp:347

QuadraticMesh
Definition QuadraticMesh.hpp:52

ContractionModelInputParameters_
Definition AbstractContractionModel.hpp:47

ContractionModelInputParameters_::voltage
double voltage
Definition AbstractContractionModel.hpp:48

ContractionModelInputParameters_::intracellularCalciumConcentration
double intracellularCalciumConcentration
Definition AbstractContractionModel.hpp:49

DataAtQuadraturePoint_
Definition AbstractCardiacMechanicsSolver.hpp:59

DataAtQuadraturePoint_::StretchLastTimeStep
double StretchLastTimeStep
Definition AbstractCardiacMechanicsSolver.hpp:63

DataAtQuadraturePoint_::ContractionModel
AbstractContractionModel * ContractionModel
Definition AbstractCardiacMechanicsSolver.hpp:60

DataAtQuadraturePoint_::Stretch
double Stretch
Definition AbstractCardiacMechanicsSolver.hpp:62