GodunovPhysics Class Reference

#include <GodunovPhysics.H>

Inheritance diagram for GodunovPhysics:

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Collaboration diagram for GodunovPhysics:

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List of all members.

Detailed Description

The base class GodunovPhysics provides the physics-dependent components for a higher-order Godunov method for a single patch: characteristic analysis, Riemann solver, quasilinear update, conservative update, and transformations between conserved, primitive, and flux variables. This class is essentially pure virtual, i.e. all of its member functions are virtual, and the ones that have default implementations are ones which are optionally defined, i.e. the default definition is to send an error message. Physics-dependent versions of this class that are required in real applications are derived from this class by inheritance.


Public Member Functions
	GodunovPhysics ()
	Constructor.
PhysIBC *	getPhysIBC () const
	Get the initial and boundary condition object.
void	setPhysIBC (PhysIBC *a_bc)
	Set the initial and boundary condition object.
virtual	~GodunovPhysics ()
	Destructor.
virtual void	define (const ProblemDomain &a_domain, const Real &a_dx)
	Define the object.
virtual void	setCurrentBox (const Box &a_currentBox)
	Set the current box (default implementation - do nothing).
virtual Real	getMaxWaveSpeed (const FArrayBox &a_U, const Box &a_box)=0
	Compute the maximum wave speed.
virtual GodunovPhysics *	new_godunovPhysics () const =0
	Object factory for this class.
virtual int	numConserved ()=0
	Number of conserved variables.
virtual Vector< string >	stateNames ()=0
	Names of the conserved variables.
virtual int	numFluxes ()=0
	Number of flux variables.
virtual void	computeUpdate (FArrayBox &a_dU, FluxBox &a_F, const FArrayBox &a_U, const FluxBox &a_WHalf, const bool &a_useArtificialViscosity, const Real &a_artificialViscosity, const Real &a_currentTime, const Real &a_dx, const Real &a_dt, const Box &a_box)
	Compute the increment in the conserved variables from face variables.
virtual void	getFlux (FArrayBox &a_flux, const FArrayBox &a_WHalf, const int &a_dir, const Box &a_box)
	Compute the fluxes from primitive variable values on a face.
virtual bool	isDefined () const
	Is the object completely defined.
virtual int	numPrimitives ()=0
	Number of primitive variables.
virtual void	charAnalysis (FArrayBox &a_dW, const FArrayBox &a_W, const int &a_dir, const Box &a_box)=0
	Transform a_dW from primitive to characteristic variables.
virtual void	charSynthesis (FArrayBox &a_dW, const FArrayBox &a_W, const int &a_dir, const Box &a_box)=0
	Transform a_dW from characteristic to primitive variables.
virtual void	charValues (FArrayBox &a_lambda, const FArrayBox &a_W, const int &a_dir, const Box &a_box)=0
	Compute the characteristic values (eigenvalues).
virtual void	incrementSource (FArrayBox &a_S, const FArrayBox &a_W, const Box &a_box)=0
	Add to (increment) the source terms given the current state.
virtual void	riemann (FArrayBox &a_WStar, const FArrayBox &a_WLeft, const FArrayBox &a_WRight, const FArrayBox &a_W, const Real &a_time, const int &a_dir, const Box &a_box)=0
	Compute the solution to the Riemann problem.
virtual void	postNormalPred (FArrayBox &a_dWMinus, FArrayBox &a_dWPlus, const FArrayBox &a_W, const Real &a_dt, const Real &a_dx, const int &a_dir, const Box &a_box)=0
	Post-normal predictor calculation.
virtual void	quasilinearUpdate (FArrayBox &a_AdWdx, const FArrayBox &a_wHalf, const FArrayBox &a_W, const Real &a_scale, const int &a_dir, const Box &a_box)=0
	Compute the quasilinear update A*dW/dx.
virtual void	consToPrim (FArrayBox &a_W, const FArrayBox &a_U, const Box &a_box)=0
	Compute primitive variables from conserved variables.
virtual Interval	velocityInterval ()=0
	Interval within the primitive variables corresponding to the velocities.
virtual int	pressureIndex ()=0
	Component index within the primitive variables of the pressure.
virtual Real	smallPressure ()=0
	Used to limit the absolute value of a "pressure" difference.
virtual int	bulkModulusIndex ()=0
	Component index within the primitive variables of the bulk modulus.
virtual void	artVisc (FArrayBox &a_F, const FArrayBox &a_U, const Real &a_artificialViscosity, const Real &a_currentTime, const int &a_dir, const Box &a_box)
	Compute the artificial viscosity contribution to the flux.
Protected Attributes
bool	m_isDefined
ProblemDomain	m_domain
Real	m_dx
GodunovUtilities	m_util
PhysIBC *	m_bc
bool	m_isBCSet
Private Member Functions
void	operator= (const GodunovPhysics &a_input)
	GodunovPhysics (const GodunovPhysics &a_input)

Constructor & Destructor Documentation

GodunovPhysics::GodunovPhysics ( )

Constructor.

virtual GodunovPhysics::~GodunovPhysics ( ) [virtual]

Destructor.

GodunovPhysics::GodunovPhysics ( const GodunovPhysics & a_input ) [inline, private]

References MayDay::Error().

Member Function Documentation

PhysIBC* GodunovPhysics::getPhysIBC ( ) const

Get the initial and boundary condition object.

void GodunovPhysics::setPhysIBC ( PhysIBC * a_bc )

Set the initial and boundary condition object.

virtual void GodunovPhysics::define	(	const ProblemDomain &	a_domain,
		const Real &	a_dx
	)			`[virtual]`

Define the object.

virtual void GodunovPhysics::setCurrentBox ( const Box & a_currentBox ) [virtual]

Set the current box (default implementation - do nothing).

virtual Real GodunovPhysics::getMaxWaveSpeed	(	const FArrayBox &	a_U,
		const Box &	a_box
	)			`[pure virtual]`

Compute the maximum wave speed.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual GodunovPhysics* GodunovPhysics::new_godunovPhysics ( ) const [pure virtual]

Object factory for this class.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual int GodunovPhysics::numConserved ( ) [pure virtual]

Number of conserved variables.

Return the number of conserved variables.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual Vector<string> GodunovPhysics::stateNames ( ) [pure virtual]

Names of the conserved variables.

Return the names of the conserved variables.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual int GodunovPhysics::numFluxes ( ) [pure virtual]

Number of flux variables.

Return the number of flux variables. This can be greater than the number of conserved variables if addition fluxes/face-centered quantities are computed.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::computeUpdate	(	FArrayBox &	a_dU,
		FluxBox &	a_F,
		const FArrayBox &	a_U,
		const FluxBox &	a_WHalf,
		const bool &	a_useArtificialViscosity,
		const Real &	a_artificialViscosity,
		const Real &	a_currentTime,
		const Real &	a_dx,
		const Real &	a_dt,
		const Box &	a_box
	)			`[virtual]`

Compute the increment in the conserved variables from face variables.

Compute dU = dt*dUdt, the change in the conserved variables over the time step. The fluxes are returned are suitable for use in refluxing. This has a default implementation but can be redefined as needed.

virtual void GodunovPhysics::getFlux	(	FArrayBox &	a_flux,
		const FArrayBox &	a_WHalf,
		const int &	a_dir,
		const Box &	a_box
	)			`[virtual]`

Compute the fluxes from primitive variable values on a face.

This has a default implementation which throws an error. The method is here so that the default implementation of "computeUpdate" can use it and the user can supply it. It has an implementation so if the user redefines "computeUpdate" they aren't force to implement "getFlux" - which is only used by the default implementation of "computeUpdate".

Reimplemented in AdvectPhysics, and PolytropicPhysics.

virtual bool GodunovPhysics::isDefined ( ) const [virtual]

Is the object completely defined.

Return true if the object is completely defined.

Reimplemented in AdvectPhysics.

virtual int GodunovPhysics::numPrimitives ( ) [pure virtual]

Number of primitive variables.

Return the number of primitive variables. This may be greater than the number of conserved variables if derived/redundant quantities are also stored for convenience.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::charAnalysis	(	FArrayBox &	a_dW,
		const FArrayBox &	a_W,
		const int &	a_dir,
		const Box &	a_box
	)			`[pure virtual]`

Transform a_dW from primitive to characteristic variables.

On input, a_dW contains the increments of the primitive variables. On output, it contains the increments in the characteristic variables.

IMPORTANT NOTE: It is assumed that the characteristic analysis puts the smallest eigenvalue first, the largest eigenvalue last, and orders the characteristic variables accordingly.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::charSynthesis	(	FArrayBox &	a_dW,
		const FArrayBox &	a_W,
		const int &	a_dir,
		const Box &	a_box
	)			`[pure virtual]`

Transform a_dW from characteristic to primitive variables.

On input, a_dW contains the increments of the characteristic variables. On output, it contains the increments in the primitive variables.

IMPORTANT NOTE: It is assumed that the characteristic analysis puts the smallest eigenvalue first, the largest eigenvalue last, and orders the characteristic variables accordingly.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::charValues	(	FArrayBox &	a_lambda,
		const FArrayBox &	a_W,
		const int &	a_dir,
		const Box &	a_box
	)			`[pure virtual]`

Compute the characteristic values (eigenvalues).

IMPORTANT NOTE: It is assumed that the characteristic analysis puts the smallest eigenvalue first, the largest eigenvalue last, and orders the characteristic variables accordingly.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::incrementSource	(	FArrayBox &	a_S,
		const FArrayBox &	a_W,
		const Box &	a_box
	)			`[pure virtual]`

Add to (increment) the source terms given the current state.

On input, a_S contains the current source terms. On output, a_S has had any additional source terms (based on the current state, a_W) added to it. This should all be done on the region defined by a_box.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::riemann	(	FArrayBox &	a_WStar,
		const FArrayBox &	a_WLeft,
		const FArrayBox &	a_WRight,
		const FArrayBox &	a_W,
		const Real &	a_time,
		const int &	a_dir,
		const Box &	a_box
	)			`[pure virtual]`

Compute the solution to the Riemann problem.

Given input left and right states in a direction, a_dir, compute a Riemann problem and generate fluxes at the faces within a_box.

Parameters:

a_WStar	face-centered solution to Riemann problem
a_WLeft	left state, on cells to left of each face
a_WRight	right state, on cells to right of each face
a_W	state on cells, used to set boundary conditions
a_time	current time
a_dir	direction of faces
a_box	face-centered box on which to set a_WStar

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::postNormalPred	(	FArrayBox &	a_dWMinus,
		FArrayBox &	a_dWPlus,
		const FArrayBox &	a_W,
		const Real &	a_dt,
		const Real &	a_dx,
		const int &	a_dir,
		const Box &	a_box
	)			`[pure virtual]`

Post-normal predictor calculation.

Add increment to normal predictor, e.g. to account for source terms due to spatially-varying coefficients, to bound primitive variable ranges.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::quasilinearUpdate	(	FArrayBox &	a_AdWdx,
		const FArrayBox &	a_wHalf,
		const FArrayBox &	a_W,
		const Real &	a_scale,
		const int &	a_dir,
		const Box &	a_box
	)			`[pure virtual]`

Compute the quasilinear update A*dW/dx.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::consToPrim	(	FArrayBox &	a_W,
		const FArrayBox &	a_U,
		const Box &	a_box
	)			`[pure virtual]`

Compute primitive variables from conserved variables.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual Interval GodunovPhysics::velocityInterval ( ) [pure virtual]

Interval within the primitive variables corresponding to the velocities.

Return the interval of component indices within the primitive variable of the velocities. Used for slope flattening (slope computation) and computing the divergence of the velocity (artificial viscosity).

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual int GodunovPhysics::pressureIndex ( ) [pure virtual]

Component index within the primitive variables of the pressure.

Return the component index withn the primitive variables for the pressure. Used for slope flattening (slope computation).

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual Real GodunovPhysics::smallPressure ( ) [pure virtual]

Used to limit the absolute value of a "pressure" difference.

Return a value that is used by slope flattening to limit (away from zero) the absolute value of a slope in the pressureIndex() component (slope computation).

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual int GodunovPhysics::bulkModulusIndex ( ) [pure virtual]

Component index within the primitive variables of the bulk modulus.

Return the component index withn the primitive variables for the bulk modulus. Used for slope flattening (slope computation) used as a normalization to measure shock strength.

Implemented in AdvectPhysics, and PolytropicPhysics.

virtual void GodunovPhysics::artVisc	(	FArrayBox &	a_F,
		const FArrayBox &	a_U,
		const Real &	a_artificialViscosity,
		const Real &	a_currentTime,
		const int &	a_dir,
		const Box &	a_box
	)			`[virtual]`