Exemplo n.º 1
0
    private static void test03(int degree, int n, string header)

    //****************************************************************************80
    //
    //  Purpose:
    //
    //    TEST03 gets a rule and creates GNUPLOT input files.
    //
    //  Licensing:
    //
    //    This code is distributed under the GNU GPL license.
    //
    //  Modified:
    //
    //    02 July 2014
    //
    //  Author:
    //
    //    Original FORTRAN77 version by Hong Xiao, Zydrunas Gimbutas.
    //    C++ version by John Burkardt.
    //
    //  Reference:
    //
    //    Hong Xiao, Zydrunas Gimbutas,
    //    A numerical algorithm for the construction of efficient quadrature
    //    rules in two and higher dimensions,
    //    Computers and Mathematics with Applications,
    //    Volume 59, 2010, pages 663-676.
    //
    //  Parameters:
    //
    //    Input, int DEGREE, the desired total polynomial degree exactness
    //    of the quadrature rule.  0 <= DEGREE <= 50.
    //
    //    Input, int N, the number of nodes to be used by the rule.
    //
    //    Input, string HEADER, an identifier for the filenames.
    //
    {
        Console.WriteLine("");
        Console.WriteLine("TEST03");
        Console.WriteLine("  Get a quadrature rule for the symmetric square.");
        Console.WriteLine("  Set up GNUPLOT graphics input.");
        Console.WriteLine("  Polynomial exactness degree DEGREE = " + degree + "");
        //
        //  Retrieve a symmetric quadrature rule.
        //
        double[] x = new double[2 * n];
        double[] w = new double[n];

        Arq.square_arbq(degree, n, ref x, ref w);
        //
        //  Create files for input to GNUPLOT.
        //
        Arq.square_arbq_gnuplot(n, x, header);
    }
Exemplo n.º 2
0
    private static void test01(int degree, int n)

    //****************************************************************************80
    //
    //  Purpose:
    //
    //    TEST01 calls SQUAREARBQ for a quadrature rule of given order.
    //
    //  Licensing:
    //
    //    This code is distributed under the GNU GPL license.
    //
    //  Modified:
    //
    //    02 July 2014
    //
    //  Author:
    //
    //    Original FORTRAN77 version by Hong Xiao, Zydrunas Gimbutas.
    //    C++ version by John Burkardt.
    //
    //  Reference:
    //
    //    Hong Xiao, Zydrunas Gimbutas,
    //    A numerical algorithm for the construction of efficient quadrature
    //    rules in two and higher dimensions,
    //    Computers and Mathematics with Applications,
    //    Volume 59, 2010, pages 663-676.
    //
    //  Parameters:
    //
    //    Input, int DEGREE, the desired total polynomial degree exactness
    //    of the quadrature rule.
    //
    //    Input, int N, the number of nodes.
    //
    {
        int j;

        Console.WriteLine("");
        Console.WriteLine("TEST01");
        Console.WriteLine("  Symmetric quadrature rule for a square.");
        Console.WriteLine("  Polynomial exactness degree DEGREE = " + degree + "");

        const double area = 4.0;

        //
        //  Retrieve and print a symmetric quadrature rule.
        //
        double[] x = new double[2 * n];
        double[] w = new double[n];

        Arq.square_arbq(degree, n, ref x, ref w);

        Console.WriteLine("");
        Console.WriteLine("  Number of nodes N = " + n + "");

        Console.WriteLine("");
        Console.WriteLine("     J  W       X       Y");
        Console.WriteLine("");
        for (j = 0; j < n; j++)
        {
            Console.WriteLine(j.ToString().PadLeft(4) + "  "
                              + w[j].ToString(CultureInfo.InvariantCulture).PadLeft(14) + "  "
                              + x[0 + j * 2].ToString(CultureInfo.InvariantCulture).PadLeft(14) + "  "
                              + x[1 + j * 2].ToString(CultureInfo.InvariantCulture).PadLeft(14) + "");
        }

        double d = typeMethods.r8vec_sum(n, w);

        Console.WriteLine("   Sum  " + d + "");
        Console.WriteLine("  Area  " + area + "");
    }
Exemplo n.º 3
0
    private static void test04(int degree, int n)

    //****************************************************************************80
    //
    //  Purpose:
    //
    //    TEST04 gets a rule and tests its accuracy.
    //
    //  Licensing:
    //
    //    This code is distributed under the GNU GPL license.
    //
    //  Modified:
    //
    //    02 July 2014
    //
    //  Author:
    //
    //    Original FORTRAN77 version by Hong Xiao, Zydrunas Gimbutas.
    //    C++ version by John Burkardt.
    //
    //  Reference:
    //
    //    Hong Xiao, Zydrunas Gimbutas,
    //    A numerical algorithm for the construction of efficient quadrature
    //    rules in two and higher dimensions,
    //    Computers and Mathematics with Applications,
    //    Volume 59, 2010, pages 663-676.
    //
    //  Parameters:
    //
    //    Input, int DEGREE, the desired total polynomial degree exactness
    //    of the quadrature rule.  0 <= DEGREE <= 50.
    //
    //    Input, int N, the number of nodes to be used by the rule.
    //
    {
        int i;
        int j;

        double[] z = new double[2];

        Console.WriteLine("");
        Console.WriteLine("TEST04");
        Console.WriteLine("  Get a quadrature rule for the symmetric square.");
        Console.WriteLine("  Test its accuracy.");
        Console.WriteLine("  Polynomial exactness degree DEGREE = " + degree + "");
        //
        //  Retrieve a symmetric quadrature rule.
        //
        double[] x = new double[2 * n];
        double[] w = new double[n];

        Arq.square_arbq(degree, n, ref x, ref w);

        int npols = (degree + 1) * (degree + 2) / 2;

        double[] rints = new double[npols];

        for (j = 0; j < npols; j++)
        {
            rints[j] = 0.0;
        }

        for (i = 0; i < n; i++)
        {
            z[0] = x[0 + i * 2];
            z[1] = x[1 + i * 2];

            double[] pols = Polynomial.lege2eva(degree, z);
            for (j = 0; j < npols; j++)
            {
                rints[j] += w[i] * pols[j];
            }
        }

        const double area = 4.0;

        double d = Math.Pow(rints[0] - Math.Sqrt(area), 2);

        for (i = 1; i < npols; i++)
        {
            d += Math.Pow(rints[i], 2);
        }

        d = Math.Sqrt(d) / npols;

        Console.WriteLine("");
        Console.WriteLine("  RMS error = " + d + "");
    }
Exemplo n.º 4
0
    private static void test02(int degree, int n, string header)

    //****************************************************************************80
    //
    //  Purpose:
    //
    //    TEST02 gets a rule and writes it to a file.
    //
    //  Licensing:
    //
    //    This code is distributed under the GNU GPL license.
    //
    //  Modified:
    //
    //    02 July 2014
    //
    //  Author:
    //
    //    Original FORTRAN77 version by Hong Xiao, Zydrunas Gimbutas.
    //    C++ version by John Burkardt.
    //
    //  Reference:
    //
    //    Hong Xiao, Zydrunas Gimbutas,
    //    A numerical algorithm for the construction of efficient quadrature
    //    rules in two and higher dimensions,
    //    Computers and Mathematics with Applications,
    //    Volume 59, 2010, pages 663-676.
    //
    //  Parameters:
    //
    //    Input, int DEGREE, the desired total polynomial degree exactness
    //    of the quadrature rule.  0 <= DEGREE <= 50.
    //
    //    Input, int N, the number of nodes to be used by the rule.
    //
    //    Input, string HEADER, an identifier for the filenames.
    //
    {
        int           i;
        List <string> rule_unit = new();

        Console.WriteLine("");
        Console.WriteLine("TEST02");
        Console.WriteLine("  Get a quadrature rule for the symmetric square.");
        Console.WriteLine("  Then write it to a file.");
        Console.WriteLine("  Polynomial exactness degree DEGREE = " + degree + "");
        //
        //  Retrieve a symmetric quadrature rule.
        //
        double[] x = new double[2 * n];
        double[] w = new double[n];

        Arq.square_arbq(degree, n, ref x, ref w);
        //
        //  Write the points and weights to a file.
        //
        string rule_filename = header + ".txt";

        for (i = 0; i < n; i++)
        {
            rule_unit.Add(x[0 + i * 2] + "  "
                          + x[1 + i * 2] + "  "
                          + w[i] + "");
        }

        File.WriteAllLines(rule_filename, rule_unit);

        Console.WriteLine("");
        Console.WriteLine("  Quadrature rule written to file '" + rule_filename + "'");
    }