Nektar::HLLSolver Class Reference

#include <HLLSolver.h>

Inheritance diagram for Nektar::HLLSolver:

Collaboration diagram for Nektar::HLLSolver:

Static Public Member Functions
static RiemannSolverSharedPtr	create ()
static RiemannSolverSharedPtr	create ()

Static Public Attributes
static std::string	solverName

Protected Member Functions
	HLLSolver ()
virtual void	v_PointSolve (double rhoL, double rhouL, double rhovL, double rhowL, double EL, double rhoR, double rhouR, double rhovR, double rhowR, double ER, double &rhof, double &rhouf, double &rhovf, double &rhowf, double &Ef)
	HLL Riemann solver.
	HLLSolver ()
virtual void	v_PointSolve (double hL, double huL, double hvL, double hR, double huR, double hvR, double &hf, double &huf, double &hvf)
	HLL Riemann solver for the Nonlinear Shallow Water Equations.
Protected Member Functions inherited from Nektar::NonlinearSWESolver
	NonlinearSWESolver ()
virtual void	v_Solve (const int nDim, const Array< OneD, const Array< OneD, NekDouble > > &Fwd, const Array< OneD, const Array< OneD, NekDouble > > &Bwd, Array< OneD, Array< OneD, NekDouble > > &flux)
virtual void	v_ArraySolve (const Array< OneD, const Array< OneD, NekDouble > > &Fwd, const Array< OneD, const Array< OneD, NekDouble > > &Bwd, Array< OneD, Array< OneD, NekDouble > > &flux)
Protected Member Functions inherited from Nektar::SolverUtils::RiemannSolver
SOLVER_UTILS_EXPORT	RiemannSolver ()
void	GenerateRotationMatrices (const Array< OneD, const Array< OneD, NekDouble > > &normals)
	Generate rotation matrices for 3D expansions.
void	FromToRotation (Array< OneD, const NekDouble > &from, Array< OneD, const NekDouble > &to, NekDouble *mat)
	A function for creating a rotation matrix that rotates a vector from into another vector to.
SOLVER_UTILS_EXPORT void	rotateToNormal (const Array< OneD, const Array< OneD, NekDouble > > &inarray, const Array< OneD, const Array< OneD, NekDouble > > &normals, const Array< OneD, const Array< OneD, NekDouble > > &vecLocs, Array< OneD, Array< OneD, NekDouble > > &outarray)
	Rotate a vector field to trace normal.
SOLVER_UTILS_EXPORT void	rotateFromNormal (const Array< OneD, const Array< OneD, NekDouble > > &inarray, const Array< OneD, const Array< OneD, NekDouble > > &normals, const Array< OneD, const Array< OneD, NekDouble > > &vecLocs, Array< OneD, Array< OneD, NekDouble > > &outarray)
	Rotate a vector field from trace normal.
bool	CheckScalars (std::string name)
	Determine whether a scalar has been defined in m_scalars.
bool	CheckVectors (std::string name)
	Determine whether a vector has been defined in m_vectors.
bool	CheckParams (std::string name)
	Determine whether a parameter has been defined in m_params.
bool	CheckAuxScal (std::string name)
	Determine whether a scalar has been defined in m_auxScal.
bool	CheckAuxVec (std::string name)
	Determine whether a vector has been defined in m_auxVec.
Protected Member Functions inherited from Nektar::CompressibleSolver
	CompressibleSolver ()
virtual void	v_Solve (const int nDim, const Array< OneD, const Array< OneD, NekDouble > > &Fwd, const Array< OneD, const Array< OneD, NekDouble > > &Bwd, Array< OneD, Array< OneD, NekDouble > > &flux)
virtual void	v_ArraySolve (const Array< OneD, const Array< OneD, NekDouble > > &Fwd, const Array< OneD, const Array< OneD, NekDouble > > &Bwd, Array< OneD, Array< OneD, NekDouble > > &flux)
virtual void	v_PointSolveVisc (NekDouble rhoL, NekDouble rhouL, NekDouble rhovL, NekDouble rhowL, NekDouble EL, NekDouble EpsL, NekDouble rhoR, NekDouble rhouR, NekDouble rhovR, NekDouble rhowR, NekDouble ER, NekDouble EpsR, NekDouble &rhof, NekDouble &rhouf, NekDouble &rhovf, NekDouble &rhowf, NekDouble &Ef, NekDouble &Epsf)

Additional Inherited Members
Public Member Functions inherited from Nektar::SolverUtils::RiemannSolver
SOLVER_UTILS_EXPORT void	Solve (const int nDim, const Array< OneD, const Array< OneD, NekDouble > > &Fwd, const Array< OneD, const Array< OneD, NekDouble > > &Bwd, Array< OneD, Array< OneD, NekDouble > > &flux)
	Perform the Riemann solve given the forwards and backwards spaces.
template<typename FuncPointerT , typename ObjectPointerT >
void	SetScalar (std::string name, FuncPointerT func, ObjectPointerT obj)
void	SetScalar (std::string name, RSScalarFuncType fp)
template<typename FuncPointerT , typename ObjectPointerT >
void	SetVector (std::string name, FuncPointerT func, ObjectPointerT obj)
void	SetVector (std::string name, RSVecFuncType fp)
template<typename FuncPointerT , typename ObjectPointerT >
void	SetParam (std::string name, FuncPointerT func, ObjectPointerT obj)
void	SetParam (std::string name, RSParamFuncType fp)
template<typename FuncPointerT , typename ObjectPointerT >
void	SetAuxScal (std::string name, FuncPointerT func, ObjectPointerT obj)
template<typename FuncPointerT , typename ObjectPointerT >
void	SetAuxVec (std::string name, FuncPointerT func, ObjectPointerT obj)
std::map< std::string, RSScalarFuncType > &	GetScalars ()
std::map< std::string, RSVecFuncType > &	GetVectors ()
std::map< std::string, RSParamFuncType > &	GetParams ()
Public Attributes inherited from Nektar::SolverUtils::RiemannSolver
int	m_spacedim
Protected Attributes inherited from Nektar::NonlinearSWESolver
bool	m_pointSolve
Protected Attributes inherited from Nektar::CompressibleSolver
bool	m_pointSolve

Detailed Description

Definition at line 43 of file CompressibleFlowSolver/RiemannSolvers/HLLSolver.h.

Constructor & Destructor Documentation

Nektar::HLLSolver::HLLSolver ( )

protected

Definition at line 46 of file CompressibleFlowSolver/RiemannSolvers/HLLSolver.cpp.

Referenced by create().

                         : CompressibleSolver()
    {

    }

Nektar::HLLSolver::HLLSolver ( )

protected

Member Function Documentation

static RiemannSolverSharedPtr Nektar::HLLSolver::create ( )

inlinestatic

Definition at line 46 of file CompressibleFlowSolver/RiemannSolvers/HLLSolver.h.

References HLLSolver().

        {
            return RiemannSolverSharedPtr(
                new HLLSolver());
        }

static RiemannSolverSharedPtr Nektar::HLLSolver::create ( )

inlinestatic

Definition at line 46 of file ShallowWaterSolver/RiemannSolvers/HLLSolver.h.

References HLLSolver().

        {
            return RiemannSolverSharedPtr(
                new HLLSolver());
        }

void Nektar::HLLSolver::v_PointSolve ( double  hL, double  huL, double  hvL, double  hR, double  huR, double  hvR, double &  hf, double &  huf, double &  hvf  )

protectedvirtual

HLL Riemann solver for the Nonlinear Shallow Water Equations.

Parameters

hL	Water depth left state.
hR	Water depth right state.
huL	x-momentum component left state.
huR	x-momentum component right state.
hvL	y-momentum component left state.
hvR	y-momentum component right state.
hf	Computed Riemann flux for density.
huf	Computed Riemann flux for x-momentum component
hvf	Computed Riemann flux for y-momentum component

Reimplemented from Nektar::NonlinearSWESolver.

Definition at line 64 of file ShallowWaterSolver/RiemannSolvers/HLLSolver.cpp.

References Nektar::SolverUtils::RiemannSolver::m_params.

    {        
        static NekDouble g = m_params["gravity"]();
        
        // Left and Right velocities
        NekDouble uL = huL / hL;
        NekDouble vL = hvL / hL;
    NekDouble uR = huR / hR;
        NekDouble vR = hvR / hR;
      

        // Left and right wave speeds
    NekDouble cL = sqrt(g * hL);
    NekDouble cR = sqrt(g * hR);
    
    // the two-rarefaction wave assumption
    NekDouble hstar,ustar,fL,fR;
    hstar = 0.5 * (cL + cR) + 0.25 * (uL - uR);
    hstar *= hstar;
    hstar *= (1.0/g);
    ustar = 0.5*(uL + uR) + cL - cR;

    
    // Compute SL
    NekDouble SL;
    if (hstar > hL)
      SL = uL - cL * sqrt(0.5*((hstar*hstar + hstar*hL)/(hL*hL)));
    else
      SL = uL - cL;
    
    // Compute SR
    NekDouble SR;
    if (hstar > hR)
      SR = uR + cR * sqrt(0.5*((hstar*hstar + hstar*hR)/(hR*hR)));
    else
      SR = uR + cR;
    
    if (SL >= 0)
      {
        hf  = hL * uL;
        huf  = uL * uL * hL + 0.5 * g * hL * hL;
        hvf  = hL * uL * vL;
      }
    else if (SR <= 0)
      {
        hf  = hR * uR;
        huf  = uR * uR * hR + 0.5 * g * hR * hR;
        hvf  = hR * uR *vR;
      }
    else 
      {
        hf = (SR * hL * uL - SL * hR * uR + 
          SL * SR * (hR - hL)) / (SR - SL);
        fL =  uL * uL * hL + 0.5 * g * hL * hL;
        fR =  uR * uR * hR + 0.5 * g * hR * hR;
        huf =(SR * fL - SL * fR + 
          SL * SR * (hR * uR - hL * uL)) / (SR - SL);
        fL =  uL * vL * hL;
        fR =  uR * vR * hR;
        hvf =(SR * fL - SL * fR + 
          SL * SR * (hR * vR - hL * vL)) / (SR - SL);
      }
    }

void Nektar::HLLSolver::v_PointSolve ( double  rhoL, double  rhouL, double  rhovL, double  rhowL, double  EL, double  rhoR, double  rhouR, double  rhovR, double  rhowR, double  ER, double &  rhof, double &  rhouf, double &  rhovf, double &  rhowf, double &  Ef  )

protectedvirtual

HLL Riemann solver.

Parameters

rhoL	Density left state.
rhoR	Density right state.
rhouL	x-momentum component left state.
rhouR	x-momentum component right state.
rhovL	y-momentum component left state.
rhovR	y-momentum component right state.
rhowL	z-momentum component left state.
rhowR	z-momentum component right state.
EL	Energy left state.
ER	Energy right state.
rhof	Computed Riemann flux for density.
rhouf	Computed Riemann flux for x-momentum component
rhovf	Computed Riemann flux for y-momentum component
rhowf	Computed Riemann flux for z-momentum component
Ef	Computed Riemann flux for energy.

Reimplemented from Nektar::CompressibleSolver.

Definition at line 70 of file CompressibleFlowSolver/RiemannSolvers/HLLSolver.cpp.

References Nektar::SolverUtils::RiemannSolver::m_params.

    {        
        static NekDouble gamma = m_params["gamma"]();
        
        // Left and Right velocities
        NekDouble uL = rhouL / rhoL;
        NekDouble vL = rhovL / rhoL;
        NekDouble wL = rhowL / rhoL;
        NekDouble uR = rhouR / rhoR;
        NekDouble vR = rhovR / rhoR;
        NekDouble wR = rhowR / rhoR;

        // Left and right pressures
        NekDouble pL = (gamma - 1.0) *
            (EL - 0.5 * (rhouL * uL + rhovL * vL + rhowL * wL));
        NekDouble pR = (gamma - 1.0) *
            (ER - 0.5 * (rhouR * uR + rhovR * vR + rhowR * wR));
        NekDouble cL = sqrt(gamma * pL / rhoL);
        NekDouble cR = sqrt(gamma * pR / rhoR);
        NekDouble hL = (EL + pL) / rhoL;
        NekDouble hR = (ER + pR) / rhoR;
        
        // Square root of rhoL and rhoR.
        NekDouble srL  = sqrt(rhoL);
        NekDouble srR  = sqrt(rhoR);
        NekDouble srLR = srL + srR;
        
        // Velocity Roe averages
        NekDouble uRoe   = (srL * uL + srR * uR) / srLR;
        NekDouble vRoe   = (srL * vL + srR * vR) / srLR;
        NekDouble wRoe   = (srL * wL + srR * wR) / srLR;
        NekDouble hRoe   = (srL * hL + srR * hR) / srLR;
        NekDouble cRoe   = sqrt((gamma - 1.0)*(hRoe - 0.5 * 
            (uRoe * uRoe + vRoe * vRoe + wRoe * wRoe)));

        // Maximum wave speeds
        NekDouble SL = std::min(uL-cL, uRoe-cRoe);
        NekDouble SR = std::max(uR+cR, uRoe+cRoe);

        // HLL Riemann fluxes (positive case)
        if (SL >= 0)
        {
            rhof  = rhouL;
            rhouf = rhouL * uL + pL;
            rhovf = rhouL * vL;
            rhowf = rhouL * wL;
            Ef    = uL * (EL + pL);
        }
        // HLL Riemann fluxes (negative case)
        else if (SR <= 0)
        {
            rhof  = rhouR;
            rhouf = rhouR * uR + pR;
            rhovf = rhouR * vR;
            rhowf = rhouR * wR;
            Ef    = uR * (ER + pR);
        }
        // HLL Riemann fluxes (general case (SL < 0 | SR > 0)
        else
        {
            NekDouble tmp1 = 1.0 / (SR - SL);
            NekDouble tmp2 = SR * SL;
            rhof  = (SR * rhouL - SL * rhouR + tmp2 * (rhoR - rhoL)) * tmp1;
            rhouf = (SR * (rhouL * uL + pL) - SL * (rhouR * uR + pR) +
                     tmp2 * (rhouR - rhouL)) * tmp1;
            rhovf = (SR * rhouL * vL - SL * rhouR * vR +
                     tmp2 * (rhovR - rhovL)) * tmp1;
            rhowf = (SR * rhouL * wL - SL * rhouR * wR +
                     tmp2 * (rhowR - rhowL)) * tmp1;
            Ef    = (SR * uL * (EL + pL) - SL * uR * (ER + pR) + 
                     tmp2 * (ER - EL)) * tmp1;
        }
    }

Member Data Documentation

static std::string Nektar::HLLSolver::solverName

static

Initial value:

        SolverUtils::GetRiemannSolverFactory().RegisterCreatorFunction(
            "HLL",
            HLLSolver::create,
            "HLL Riemann solver")

Definition at line 52 of file CompressibleFlowSolver/RiemannSolvers/HLLSolver.h.