Example #1
0
        /// <summary>
        /// Accumulates the DG-projection (with respect to the DG-basis
        /// of this field, <see cref="Basis"/>) of
        /// <paramref name="alpha"/>*<paramref name="f"/>^<paramref name="pow"/> to this field;
        /// </summary>
        /// <param name="alpha">scaling for accumulation</param>
        /// <param name="f">operand</param>
        /// <param name="pow">exponent</param>
        /// <param name="em">
        /// An optional restriction to the domain in which the projection is
        /// computed (it may, e.g. be only required in boundary cells, so a
        /// computation over the whole domain would be a waste of computation
        /// power. A proper execution mask would be see e.g.
        /// <see cref="GridData.BoundaryCells"/>.)
        /// if null, the computation is carried out in the whole domain;
        /// </param>
        virtual public void ProjectPow(double alpha, DGField f, double pow, CellMask em)
        {
            if (!object.ReferenceEquals(f.Basis.GridDat, this.Basis.GridDat))
            {
                throw new ArgumentException("field is associated to another context.", "a");
            }

            SpatialOperator powOp = new SpatialOperator(new string[] { "f" },
                                                        new string[] { "res" },
                                                        QuadOrderFunc.SumOfMaxDegrees());

            powOp.EquationComponents["res"].Add(new PowSource(pow));
            powOp.Commit();

            CoordinateVector coDom = this.CoordinateVector;

            var ev = powOp.GetEvaluatorEx(
                new CoordinateMapping(f), null, coDom.Mapping,
                edgeQrCtx: new EdgeQuadratureScheme(true, EdgeMask.GetEmptyMask(this.Basis.GridDat)),
                volQrCtx: new CellQuadratureScheme(true, em));

            ev.Evaluate <CoordinateVector>(alpha, 1.0, coDom); // only sources, no edge integrals required
        }
        /// <summary>
        /// accumulates the projection of some vector field to this field, i.e.
        /// \f[
        ///   this = this + \alpha \cdot \| \vec{vec} \|.
        /// \f]
        /// </summary>
        /// <param name="alpha">factor \f$ \alpha \f$ </param>
        /// <param name="vec">vector field \f$ \vec{vec} \f$ </param>
        /// <param name="em">
        /// An optional restriction to the domain in which the projection is computed (it may, e.g.
        /// be only required in boundary cells, so a computation over the whole domain
        /// would be a waste of computation power. If null, the computation is carried out in the whole domain;
        /// </param>
        virtual public void ProjectAbs(double alpha, CellMask em, params DGField[] vec)
        {
            int K = vec.Length;

            string[] args = new string[K];
            for (int k = 0; k < K; k++)
            {
                args[k] = "_" + k;
            }

            SpatialOperator powOp = new SpatialOperator(args, new string[] { "res" }, QuadOrderFunc.SumOfMaxDegrees());

            powOp.EquationComponents["res"].Add(new AbsSource(args));

            powOp.EdgeQuadraturSchemeProvider   = g => new EdgeQuadratureScheme(true, EdgeMask.GetEmptyMask(this.Basis.GridDat));
            powOp.VolumeQuadraturSchemeProvider = g => new CellQuadratureScheme(true, em);

            powOp.Commit();

            CoordinateVector coDom = new CoordinateVector(this);

            var ev = powOp.GetEvaluatorEx(
                new CoordinateMapping(vec),
                null,
                coDom.Mapping);

            ev.Evaluate <CoordinateVector>(alpha, 1.0, coDom); // only sources, no edge integrals required
        }