Ejemplo n.º 1
0
        /// <summary>
        /// Based on the Ideas by
        /// C. Basting and D. Kuzmin,
        /// “A minimization-based finite element formulation for interface-preserving level set reinitialization”,
        /// Computing, vol. 95, no. 1, pp. 13–25, Dec. 2012.
        /// </summary>
        /// <param name="LSTrck"></param>
        /// <param name="bcmap">Boundary Conditions for the LevelSet Equations</param>
        /// <param name="Control">various parameters <paramref name="EllipticReinitControl"/></param>
        public Extender(SinglePhaseField Extension, LevelSetTracker LSTrck, ILevelSetComponent InterfaceFlux, List <DGField> InterfaceParams, VectorField <SinglePhaseField> LevelSetGradient, EllipticExtVelAlgoControl Control)
        {
            if (InterfaceFlux.ParameterOrdering.Count != InterfaceParams.Count)
            {
                throw new ArgumentException("Missmatch in Number of Parameters and expected amount in the given flux.");
            }
            this.InterfaceParams = InterfaceParams;

            this.Control = Control;
            int D = LSTrck.GridDat.SpatialDimension;

            //this.InterfaceValue = InterfaceValue;
            //InterfaceValue.Identification = "InterfaceValue";
            this.Extension = Extension;

            this.LevelSetTracker = LSTrck;
            Phi = LevelSetTracker.LevelSets[0] as LevelSet;
            this.LevelSetGradient = LevelSetGradient;

            switch (Control.FluxVariant)
            {
            case FluxVariant.GradientBased:
                // Flux Direction based on Mean Level Set Gradient
                MeanLevelSetGradient = new VectorField <SinglePhaseField>(
                    D.ForLoop(
                        d => new SinglePhaseField(
                            new Basis(LSTrck.GridDat, 0), VariableNames.MeanLevelSetGradientComponent(d)
                            )
                        )
                    );
                BulkParams = new List <DGField> {
                };
                BulkParams = ArrayTools.Cat(BulkParams, LevelSetGradient.ToArray(), Phi, MeanLevelSetGradient.ToArray(), InterfaceParams.ToArray());
                break;

            case FluxVariant.ValueBased:
                // Flux Direction Based on Cell-Averaged Level-Set Value
                MeanLevelSet = new SinglePhaseField(new Basis(LSTrck.GridDat, 0), "MeanLevelSet");
                BulkParams   = ArrayTools.Cat(LevelSetGradient.ToArray(), Phi, MeanLevelSet);
                break;

            case FluxVariant.SWIP:
                BulkParams = LevelSetGradient.ToArray();
                break;

            default:
                throw new NotImplementedException();
            }


            this.D = LevelSetTracker.GridDat.SpatialDimension;

            double PenaltyBase = Control.PenaltyMultiplierFlux * ((double)((Phi.Basis.Degree + 1) * (Phi.Basis.Degree + D))) / ((double)D);

            DefineBulkOperator(LSTrck, InterfaceFlux, D, PenaltyBase);

            Operator_interface = InterfaceFlux.XOperator(QuadOrderFunc.FixedOrder(2 * Extension.Basis.Degree + 2));
        }
Ejemplo n.º 2
0
        /// <summary>
        /// Based on the Ideas by
        /// C. Basting and D. Kuzmin,
        /// “A minimization-based finite element formulation for interface-preserving level set reinitialization”,
        /// Computing, vol. 95, no. 1, pp. 13–25, Dec. 2012.
        /// Create Spatial Operators and build the corresponding Matrices
        /// For the Left-Hand Side of the ReInitProblem
        /// RHS is computed on the fly in <see cref="ReInitSingleStep"/>
        /// The Bulk component is constant unless the grid changes, thus it is computed in <see cref="BuildOperators(CellQuadratureScheme)"/>.
        /// The Interface component changes with its motion.
        /// This component is calculated in <see cref="UpdateOperators(CellQuadratureScheme)"/>.
        /// </summary>
        /// <param name="LSTrck"></param>
        /// <param name="Control">various parameters <paramref name="EllipticReinitControl"/></param>
        /// <param name="HMFOrder">order of tghe interface quadrature</param>
        public EllipticReInit(LevelSetTracker LSTrck, EllipticReInitAlgoControl Control, SinglePhaseField LevelSetForReInit = null)
        {
            this.Control         = Control;
            this.LevelSetTracker = LSTrck;
            if (LevelSetForReInit == null)
            {
                Phi = LevelSetTracker.LevelSets[0] as SinglePhaseField;
            }
            else
            {
                Phi = LevelSetForReInit;
            }
            this.underrelaxation = Control.underrelaxation;

            Residual = new SinglePhaseField(Phi.Basis);
            OldPhi   = new SinglePhaseField(Phi.Basis);
            NewPhi   = new SinglePhaseField(Phi.Basis);
            foreach (SinglePhaseField f in new List <SinglePhaseField> {
                Residual, OldPhi, NewPhi
            })
            {
                f.Clear();
                f.Acc(1.0, Phi);
            }


            this.D = LevelSetTracker.GridDat.SpatialDimension;

            this.ConvergenceCriterion = Control.ConvergenceCriterion;
            this.MaxIteration         = Control.MaxIt;

            double PenaltyBase = ((double)((Phi.Basis.Degree + 1) * (Phi.Basis.Degree + D))) / ((double)D);


            // Choose Forms according to Upwinding or Central Fluxes
            string[] paramNames;
            int      noOfParamFields;

            IEquationComponent BulkForm;
            RHSForm            myRHSForm;

            LevelSetGradient     = new VectorField <SinglePhaseField>(D, Phi.Basis, "LevelSetGradient", SinglePhaseField.Factory);
            MeanLevelSetGradient = new VectorField <SinglePhaseField>(D, new Basis(Phi.GridDat, 0), "MeanLevelSetGradient", SinglePhaseField.Factory);

            if (Control.Upwinding)
            {
                paramNames      = new string[] { "OldLevelSet", "MeanLevelSetGradient[0]", "MeanLevelSetGradient[1]" };
                noOfParamFields = D;
                LevelSetGradient.Clear();
                LevelSetGradient.Gradient(1.0, Phi);
                //LevelSetGradient.GradientByFlux(1.0, Phi);
                MeanLevelSetGradient.Clear();
                MeanLevelSetGradient.AccLaidBack(1.0, LevelSetGradient);

                parameterFields = ArrayTools.Cat(new SinglePhaseField[] { OldPhi }, MeanLevelSetGradient.ToArray());
                //throw new NotImplementedException("ToDO");
                BulkForm  = new EllipticReInitUpwindForm_Laplace(Control.PenaltyMultiplierFlux * PenaltyBase, LSTrck);
                myRHSForm = new EllipticReInitUpwindForm_RHS(Control.PenaltyMultiplierFlux * PenaltyBase, LSTrck);

                OldDirection = new double[MeanLevelSetGradient.CoordinateVector.ToArray().Length];
                for (int i = 0; i < MeanLevelSetGradient.CoordinateVector.Length; i++)
                {
                    OldDirection[i] = Math.Sign(MeanLevelSetGradient.CoordinateVector[i]);
                }
                NewDirection = OldDirection.CloneAs();
            }
            else
            {
                paramNames      = new string[] { };
                noOfParamFields = 0;
                parameterFields = new SinglePhaseField[] { };
                BulkForm        = new CentralDifferencesLHSForm(Control.PenaltyMultiplierFlux * PenaltyBase, LSTrck.GridDat.Cells.cj);
                myRHSForm       = new CentralDifferencesRHSForm(Control.PenaltyMultiplierFlux * PenaltyBase, LSTrck);
            }


            // SIP for the bulk Phase
            //this.Operator_bulk = new SpatialOperator(1, noOfParamFields, 1, QuadOrderFunc.SumOfMaxDegrees(1, RoundUp: false), variableNames);
            this.Operator_bulk = BulkForm.Operator();



            // Zero at the Interface
            // Calculate Quadrature Order
            Func <int[], int[], int[], int> InterfaceQuadOrder;

            InterfaceQuadOrder = QuadOrderFunc.FixedOrder(Phi.Basis.Degree * 2 + 2);

            // Generate Interface Operator
            this.Operator_interface = (new EllipticReInitInterfaceForm(Control.PenaltyMultiplierInterface * PenaltyBase, LSTrck)).XOperator(new[] { "A" }, InterfaceQuadOrder);

            // Nonlinear Part on the RHS
            // switch for the potential functions
            switch (Control.Potential)
            {
            case ReInitPotential.BastingDoubleWell: {
                myRHSForm.DiffusionRate = ((d, b) => DiffusionRates.DoubleWell(d, b));
                break;
            };

            case ReInitPotential.BastingSingleWell: {
                myRHSForm.DiffusionRate = ((d, b) => DiffusionRates.SingleWell(d, b));
                break;
            };

            case ReInitPotential.SingleWellNear: {
                myRHSForm.DiffusionRate = ((d, b) => DiffusionRates.SingleWellNear(d, b));
                break;
            };

            case ReInitPotential.P4DoubleWell: {
                Console.WriteLine("Warning - This Option for Elliptic ReInit does not work well");
                myRHSForm.DiffusionRate = ((d, b) => DiffusionRates.DoubleWellAlternative(d, b));
                break;
            };

            case ReInitPotential.SingleWellOnCutDoubleWellElse: {
                myRHSForm.DiffusionRate = ((d, b) => DiffusionRates.SingleWellOnCutDoubleWellElse(d, b));
                break;
            }
            }
            Operator_RHS = myRHSForm.Operator(QuadOrderFunc.SumOfMaxDegrees(2, RoundUp: true));


            // The result of the nonlinear part on the rhs is projected on a single-phase field
            RHSField = new SinglePhaseField(Phi.Basis, "RHS");

            OpMatrix = new MsrMatrix(this.Phi.Mapping, this.Phi.Mapping);
            OpAffine = new double[OpMatrix.RowPartitioning.LocalLength];

            // Matrix and RHS for the Bulk component
            OpMatrix_bulk = new MsrMatrix(this.Phi.Mapping, this.Phi.Mapping);
            OpAffine_bulk = new double[OpMatrix.RowPartitioning.LocalLength];

            // Matrix and RHS for the Interface Penalty
            OpMatrix_interface = new MsrMatrix(this.Phi.Mapping, this.Phi.Mapping);
            OpAffine_interface = new double[OpMatrix.RowPartitioning.LocalLength];

            // Init Parameter Fields
            OldPhi.Clear();
            OldPhi.Acc(1.0, Phi);

            // Compute Matrices
            UpdateBulkMatrix();
        }