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view +time/SBPInTimeImplicitFormulation.m @ 774:66eb4a2bbb72 feature/grids

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Remove default scaling of the system. The scaling doens't seem to help actual solutions. One example that fails in the flexural code. With large timesteps the solutions seems to blow up. One particular example is profilePresentation on the tdb_presentation_figures branch with k = 0.0005
author Jonatan Werpers <jonatan@werpers.com>
date Wed, 18 Jul 2018 15:42:52 -0700
parents 5df7f99206b2
children 47e86b5270ad
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classdef SBPInTimeImplicitFormulation < time.Timestepper
    % The SBP in time method.
    % Implemented for A*v_t = B*v + f(t), v(0) = v0
    properties
        A,B
        f

        k % total time step.

        blockSize % number of points in each block
        N % Number of components

        order
        nodes

        M,K     % System matrices
        L,U,p,q % LU factorization of M
        e_T

        % Time state
        t
        v
        n
    end

    methods
        function obj = SBPInTimeImplicitFormulation(A, B, f, k, t0, v0, TYPE, order, blockSize)

            default_arg('TYPE','gauss');
            default_arg('f',[]);

            if(strcmp(TYPE,'gauss'))
                default_arg('order',4)
                default_arg('blockSize',4)
            else
                default_arg('order', 8);
                default_arg('blockSize',time.SBPInTimeImplicitFormulation.smallestBlockSize(order,TYPE));
            end

            obj.A = A;
            obj.B = B;

            if ~isempty(f)
                obj.f = f;
            else
                obj.f = @(t)sparse(length(v0),1);
            end

            obj.k = k;
            obj.blockSize = blockSize;
            obj.N = length(v0);

            obj.n = 0;
            obj.t = t0;

            %==== Build the time discretization matrix =====%
            switch TYPE
                case 'equidistant'
                    ops = sbp.D2Standard(blockSize,{0,obj.k},order);
                case 'optimal'
                    ops = sbp.D1Nonequidistant(blockSize,{0,obj.k},order);
                case 'minimal'
                    ops = sbp.D1Nonequidistant(blockSize,{0,obj.k},order,'minimal');
                case 'gauss'
                    ops = sbp.D1Gauss(blockSize,{0,obj.k});
            end

            I = speye(size(A));
            I_t = speye(blockSize,blockSize);

            D1 = kron(ops.D1, I);
            HI = kron(ops.HI, I);
            e_0 = kron(ops.e_l, I);
            e_T = kron(ops.e_r, I);
            obj.nodes = ops.x;

            % Convert to form M*w = K*v0 + f(t)
            tau = kron(I_t, A) * e_0;
            M = kron(I_t, A)*D1 + HI*tau*e_0' - kron(I_t, B);

            K = HI*tau;

            obj.M = M;
            obj.K = K;
            obj.e_T = e_T;

            % LU factorization
            [obj.L,obj.U,obj.p,obj.q] = lu(obj.M, 'vector');

            obj.v = v0;
        end

        function [v,t] = getV(obj)
            v = obj.v;
            t = obj.t;
        end

        function obj = step(obj)
            RHS = zeros(obj.blockSize*obj.N,1);

            for i = 1:obj.blockSize
                RHS((1 + (i-1)*obj.N):(i*obj.N)) = obj.f(obj.t + obj.nodes(i));
            end

            RHS = RHS + obj.K*obj.v;

            y = obj.L\RHS(obj.p);
            z = obj.U\y;

            w = zeros(size(z));
            w(obj.q) = z;

            obj.v = obj.e_T'*w;

            obj.t = obj.t + obj.k;
            obj.n = obj.n + 1;
        end
    end

    methods(Static)
        function N = smallestBlockSize(order,TYPE)
            default_arg('TYPE','gauss')

            switch TYPE
                case 'gauss'
                    N = 4;
            end
        end
    end
end