fem2d_heat_rectangle.html

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      FEM2D_HEAT_RECTANGLE - Finite Element Solution of the 2D Heat Equation
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    <h1 align = "center">
      FEM2D_HEAT_RECTANGLE <br>
      Finite Element Solution in 2D <br>
      Time Dependent Heat Equation
    </h1>

    <hr>

    <p>
      <b>FEM2D_HEAT_RECTANGLE</b>
      is a MATLAB program which
      solves the time-dependent
      2D heat equation using the finite element method in space, and
      a method of lines in time with the backward Euler approximation for the
      time derivative.
    </p>

    <p>
      The computational region is a rectangle, with homogenous Dirichlet
      boundary conditions applied along the boundary.  The state variable
      U(X,Y,T) is then constrained by:
      <pre>
        Ut - ( Uxx + Uyy ) = F(x,y,t)  in the box;
                  U(x,y,t) = G(x,y,t) for (x,y) on the boundary;
                  U(x,y,t) = H(x,y,t) for t = t_init.
      </pre>
    </p>

    <p>
      The computational region is first covered with an NX by NY
      rectangular array of points, creating (NX-1)*(NY-1) subrectangles.
      Each subrectangle is divided into two triangles, creating a total
      of 2*(NX-1)*(NY-1) geometric "elements".  Because quadratic basis
      functions are to be used, each triangle will be associated not only
      with the three corner nodes that defined it, but with three extra
      midside nodes.  If we include these additional nodes, there are
      now a total of (2*NX-1)*(2*NY-1) nodes in the region.
    </p>

    <p>
      We now assume that, at any fixed time <t>b</b>, the unknown function
      U(x,y,t) can be represented as a linear combination of the basis
      functions associated with each node.  The value of U at the boundary
      nodes is obvious, so we concentrate on the NUNK interior nodes where
      U(x,y,t) is unknown.  For each node I, we determine a basis function
      PHI(I)(x,y), and evaluate the following finite element integral:
      <pre>
        Integral ( Ux(x,y,t) * dPHIdx(I)(x,y) + dUdy(x,y,t) * dPHIdy(I)(x,y) ) =
        Integral ( F(x,y,t) * PHI(I)(x,y)
      </pre>
    </p>

    <p>
      The time derivative is handled by the backward Euler approximation.
    </p>

    <p>
      The program allows the user to supply two routines:
      <ul>
        <li>
          <b>FUNCTION VALUE = RHS ( X, Y, T )</b> returns the right hand side
          F(x,y,t) of the heat equation.
        </li>
        <li>
          <b>FUNCTION U_EXACT = EXACT_U ( X, Y, T )</b> returns
          the exact solution of the equation (assuming this is
          known.)  This routine is necessary so that error analysis
          can be performed, reporting the L2 and H1 seminorm errors
          between the true and computed solutions.
        </li>
      </ul>
    </p>

    <p>
      There are a few variables that are easy to manipulate.  In particular,
      the user can change the variables NX and NY in the main program,
      to change the number of nodes and elements.  The variables (XL,YB)
      and (XR,YT) define the location of the lower left and upper right
      corners of the rectangular region, and these can also be changed
      in a single place in the main program.
    </p>

    <p>
      The program writes out a file containing an Encapsulated
      PostScript image of the nodes and elements, with numbers.
      Unfortunately, for values of NX and NY over 10, the plot is
      too cluttered to read.  For lower values, however, it is
      a valuable map of what is going on in the geometry.
    </p>

    <p>
      The program is also able to write out a file containing the
      solution value at every node.  This file may be used to create
      contour plots of the solution.
    </p>

    <h3 align = "center">
      Licensing:
    </h3>

    <p>
      The computer code and data files described and made available on this web page
      are distributed under
      <a href = "../../txt/gnu_lgpl.txt">the GNU LGPL license.</a>
    </p>

    <h3 align = "center">
      Languages:
    </h3>

    <p>
      <b>FEM2D_HEAT_RECTANGLE</b> is available in
      <a href = "../../cpp_src/fem2d_heat_rectangle/fem2d_heat_rectangle.html">a C++ version</a> and
      <a href = "../../f_src/fem2d_heat_rectangle/fem2d_heat_rectangle.html">a FORTRAN90 version</a> and
      <a href = "../../m_src/fem2d_heat_rectangle/fem2d_heat_rectangle.html">a MATLAB version</a>.
    </p>

    <h3 align = "center">
      Related Data and Programs:
    </h3>

    <p>
      <a href = "../../m_src/fem2d_heat_rectangle_steady_spmd/fem2d_heat_rectangle_steady_spmd.html">
      FEM2D_HEAT_RECTANGLE_STEADY_SPMD</a>,
      a MATLAB program which
      uses the MATLAB Parallel Computing Toolbox in SPMD mode to set up
      and solve a distributed linear system for the steady 2D heat equation.
    </p>

    <h3 align = "center">
      Reference:
    </h3>

    <p>
      <ol>
        <li>
          Hans Rudolf Schwarz,<br>
          Finite Element Methods,<br>
          Academic Press, 1988,<br>
          ISBN: 0126330107,<br>
          LC: TA347.F5.S3313..
        </li>
        <li>
          Gilbert Strang, George Fix,<br>
          An Analysis of the Finite Element Method,<br>
          Cambridge, 1973,<br>
          ISBN: 096140888X,<br>
          LC: TA335.S77.
        </li>
        <li>
          Olgierd Zienkiewicz,<br>
          The Finite Element Method,<br>
          Sixth Edition,<br>
          Butterworth-Heinemann, 2005,<br>
          ISBN: 0750663200,<br>
          LC: TA640.2.Z54
        </li>
      </ol>
    </p>

    <h3 align = "center">
      Source Code:
    </h3>

    <p>
      <ul>
        <li>
          <a href = "fem2d_heat_rectangle.m">fem2d_heat_rectangle.m</a>,
          the source code.
        </li>
      </ul>
    </p>

    <h3 align = "center">
      Examples and Tests:
    </h3>

    <p>
      <ul>
        <li>
          <a href = "fem2d_heat_rectangle_output.txt">fem2d_heat_rectangle_output.txt</a>,
          the output file.
        </li>
        <li>
          <a href = "fem2d_heat_rectangle_nodes.png">fem2d_heat_rectangle_nodes.png</a>,
          a <a href = "../../data/png/png.html">PNG</a> image of
          the nodes, for NX = NY = 7  (the picture is
          hard to read for larger values of NX and NY);
        </li>
        <li>
          <a href = "nodes.txt">nodes.txt</a>,
          a text file containing a list, for each node, of its X and Y
          coordinates;
        </li>
        <li>
          <a href = "elements.png">elements.png</a>,
          a <a href = "../../data/png/png.html">PNG</a> image of
          the elements, for NX = NY = 7  (the picture is
          hard to read for larger values of NX and NY);
        </li>
        <li>
          <a href = "elements.txt">elements.txt</a>,
          a text file containing a list, for each element, of the six
          nodes that compose it;
        </li>
        <li>
          <a href = "time.txt">time.txt</a>,
          a text file containing the solution times;
        </li>
        <li>
          <a href = "u0000.txt">u0000.txt</a>,
          the solution U at time step 0;
        </li>
        <li>
          <a href = "u0001.txt">u0001.txt</a>,
          the solution U at time step 1;
        </li>
        <li>
          <a href = "u0002.txt">u0002.txt</a>,
          the solution U at time step 2;
        </li>
        <li>
          <a href = "u0003.txt">u0003.txt</a>,
          the solution U at time step 3;
        </li>
        <li>
          <a href = "u0004.txt">u0004.txt</a>,
          the solution U at time step 4;
        </li>
        <li>
          <a href = "u0005.txt">u0005.txt</a>,
          the solution U at time step 5;
        </li>
        <li>
          <a href = "u0006.txt">u0006.txt</a>,
          the solution U at time step 6;
        </li>
        <li>
          <a href = "u0007.txt">u0007.txt</a>,
          the solution U at time step 7;
        </li>
        <li>
          <a href = "u0008.txt">u0008.txt</a>,
          the solution U at time step 8;
        </li>
        <li>
          <a href = "u0009.txt">u0009.txt</a>,
          the solution U at time step 9;
        </li>
        <li>
          <a href = "u0010.txt">u0010.txt</a>,
          the solution U at time step 10;
        </li>
      </ul>
    </p>

    <p>
      The MATLAB program <b>CONTOUR_SEQUENCE4</b> can make contour
      plots from the sequence of solutions:
      <ul>
        <li>
          <a href = "u0000.png">u0000.png</a>,
          the solution U at time step 0;
        </li>
        <li>
          <a href = "u0001.png">u0001.png</a>,
          the solution U at time step 1;
        </li>
        <li>
          <a href = "u0002.png">u0002.png</a>,
          the solution U at time step 2;
        </li>
        <li>
          <a href = "u0003.png">u0003.png</a>,
          the solution U at time step 3;
        </li>
        <li>
          <a href = "u0004.png">u0004.png</a>,
          the solution U at time step 4;
        </li>
        <li>
          <a href = "u0005.png">u0005.png</a>,
          the solution U at time step 5;
        </li>
        <li>
          <a href = "u0006.png">u0006.png</a>,
          the solution U at time step 6;
        </li>
        <li>
          <a href = "u0007.png">u0007.png</a>,
          the solution U at time step 7;
        </li>
        <li>
          <a href = "u0008.png">u0008.png</a>,
          the solution U at time step 8;
        </li>
        <li>
          <a href = "u0009.png">u0009.png</a>,
          the solution U at time step 9;
        </li>
        <li>
          <a href = "u0010.png">u0010.png</a>,
          the solution U at time step 10;
        </li>
      </ul>
    </p>

    <p>
      You can go up one level to <a href = "../m_src.html">
      the MATLAB source codes</a>.
    </p>

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    <i>
      Last revised on 16 May 2009.
    </i>

    <!-- John Burkardt -->

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