fd1d_heat_implicit.html

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      FD1D_HEAT_IMPLICIT - TIme Dependent 1D Heat Equation, Finite Difference, Implicit Time Stepping
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    <h1 align = "center">
      FD1D_HEAT_IMPLICIT <br> 
      Finite Difference Solution of the<br> 
      Time Dependent 1D Heat Equation<br>
      using Implicit Time Stepping
    </h1>

    <hr>

    <p>
      <b>FD1D_HEAT_IMPLICIT</b> 
      is a C++ program which
      solves the time-dependent 1D heat equation, using the finite difference
      method in space, and an implicit version of the method of lines to handle
      integration in time.
    </p>

    <p>
      This program solves
      <pre>
        dUdT - k * d2UdX2 = F(X,T)
      </pre>
      over the interval [A,B] with boundary conditions
      <pre>
        U(A,T) = UA(T),
        U(B,T) = UB(T),
      </pre>
      over the time interval [T0,T1] with initial conditions
      <pre>
        U(X,T0) = U0(X)
      </pre>
    </p>

    <p>
      A second order finite difference is used to approximate the
      second derivative in space.
    </p>

    <p>
      The solver applies an
      implicit backward Euler approximation to the first derivative in time.
    </p>

    <p>
      The resulting finite difference form can be written as
      <pre>
       U(X,T+dt) - U(X,T)                     ( U(X-dx,+dtT) - 2 U(X,+dtT) + U(X+dx,+dtT) )
       ------------------  = F(X,T+dt) + k *  ---------------------------------------------
                dt                                   dx * dx
      </pre>
      or, assuming we have solved for all values of U at time T, we have
      <pre>
            -     k * dt / dx / dx   * U(X-dt,T+dt)
      + ( 1 + 2 * k * dt / dx / dx ) * U(X,   T+dt)
            -     k * dt / dx / dx   * U(X+dt,T+dt)
      =               dt             * F(X,   T+dt)
      +                                U(X,   T)
      </pre>
      which can be written as A*x=b, where A is a tridiagonal matrix whose
      entries are the same for every time step.  
    </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>FD1D_HEAT_IMPLICIT</b> is available in
      <a href = "../../c_src/fd1d_heat_implicit/fd1d_heat_implicit.html">a C version</a> and
      <a href = "../../cpp_src/fd1d_heat_implicit/fd1d_heat_implicit.html">a C++ version</a> and
      <a href = "../../f77_src/fd1d_heat_implicit/fd1d_heat_implicit.html">a FORTRAN77 version</a> and
      <a href = "../../f_src/fd1d_heat_implicit/fd1d_heat_implicit.html">a FORTRAN90 version</a> and
      <a href = "../../m_src/fd1d_heat_implicit/fd1d_heat_implicit.html">a MATLAB version</a> and
      <a href = "../../py_src/fd1d_heat_implicit/fd1d_heat_implicit.html">a Python version</a>.
    </p>

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

    <p>
      <a href = "../../cpp_src/fd1d_burgers_lax/fd1d_burgers_lax.html">
      FD1D_BURGERS_LAX</a>, 
      a C++ program which 
      applies the finite difference method and the Lax-Wendroff method
      to solve the non-viscous time-dependent Burgers equation 
      in one spatial dimension.
    </p>

    <p>
      <a href = "../../cpp_src/fd1d_burgers_leap/fd1d_burgers_leap.html">
      FD1D_BURGERS_LEAP</a>, 
      a C++ program which 
      applies the finite difference method and the leapfrog approach
      to solve the non-viscous time-dependent Burgers equation in one spatial dimension.
    </p>

    <p>
      <a href = "../../cpp_src/fd1d_bvp/fd1d_bvp.html">
      FD1D_BVP</a>,
      a C++ program which
      applies the finite difference method
      to a two point boundary value problem in one spatial dimension.
    </p>

    <p>
      <a href = "../../cpp_src/fd1d_heat_explicit/fd1d_heat_explicit.html">
      FD1D_HEAT_EXPLICIT</a>,
      a C++ program which
      uses the finite difference method to solve the time dependent
      heat equation in 1D, using an explicit time step method.
    </p>

    <p>
      <a href = "../../cpp_src/fd1d_heat_steady/fd1d_heat_steady.html">
      FD1D_HEAT_STEADY</a>,
      a C++ program which
      uses the finite difference method to solve the steady (time independent)
      heat equation in 1D.
    </p>

    <p>
      <a href = "../../cpp_src/fd1d_wave/fd1d_wave.html">
      FD1D_WAVE</a>,
      a C++ program which
      applies the finite difference method to solve the time-dependent
      wave equation utt = c * uxx in one spatial dimension.
    </p>

    <p>
      <a href = "../../m_src/fem_50_heat/fem_50_heat.html">
      FEM_50_HEAT</a>,
      a MATLAB program which
      applies the finite element method to solve the 2D heat equation.
    </p>

    <p>
      <a href = "../../cpp_src/fem1d/fem1d.html">
      FEM1D</a>,
      a C++ program which 
      applies the finite element 
      method, with piecewise linear basis functions, to a linear
      two point boundary value problem;
    </p>

    <p>
      <a href = "../../cpp_src/fem2d_heat/fem2d_heat.html">
      FEM2D_HEAT</a>,
      a C++ program which
      applies the finite element method to solve the 2D heat equation.
    </p>

    <p>
      <a href = "../../m_src/hot_pipe/hot_pipe.html">
      HOT_PIPE</a>,
      a MATLAB program which
      uses <b>FEM_50_HEAT</b> to solve a heat problem in a pipe.
    </p>

    <p>
      <a href = "../../m_src/hot_point/hot_point.html">
      HOT_POINT</a>,
      a MATLAB program which
      uses <b>FEM_50_HEAT</b> to solve a heat problem with a point source.
    </p>

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

    <p>
      <ol>
        <li>
          George Lindfield, John Penny,<br>
          Numerical Methods Using MATLAB,<br>
          Second Edition,<br>
          Prentice Hall, 1999,<br>
          ISBN: 0-13-012641-1,<br>
          LC: QA297.P45.
        </li>
      </ol>
    </p>

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

    <p>
      <ul>
        <li>
          <a href = "fd1d_heat_implicit.cpp">fd1d_heat_implicit.cpp</a>, the source code.
        </li>
        <li>
          <a href = "fd1d_heat_implicit.sh">fd1d_heat_implicit.sh</a>,
          commands to compile the source code.
        </li>
      </ul>
    </p>

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

    <p>
      <ul>
        <li>
          <a href = "x,txt">x.txt</a>
          a file containing the spatial coordinates.
        </li>
        <li>
          <a href = "t,txt">t.txt</a>
          a file containing the times.
        </li>
        <li>
          <a href = "u,txt">u.txt</a>
          a file containing the values of the computed solution at each point X and time T.
        </li>
        <li>
          <a href = "solution.png">solution.png</a>
          a PNG image of the MATLAB graphics created by the commands:
          <pre>
            x = load ( 'x.txt' );
            t = load ( 't.txt' );
            u = load ( 'u.txt' );
            [ xg, tg ] = meshgrid ( x, t );
            mesh ( xg, tg, u );
          </pre>
        </li>
      </ul>
    </p>

    <h3 align = "center">
      List of Routines:
    </h3>

    <p>
      <ul>
        <li>
          <b>MAIN</b> is the main program for FD1D_HEAT_IMPLICIT.
        </li>
        <li>
          <b>F</b> returns the right hand side of the heat equation.
        </li>
        <li>
          <b>GET_UNIT</b> returns a free FORTRAN unit number.
        </li>
        <li>
          <b>R83_NP_FA</b> factors an R83 matrix without pivoting.
        </li>
        <li>
          <b>R83_NP_SL</b> solves an R83 system factored by R83_NP_FA.
        </li>
        <li>
          <b>TIMESTAMP</b> prints the current YMDHMS date as a time stamp.
        </li>
        <li>
          <b>U0</b> returns the initial condition at the starting time.
        </li>
        <li>
          <b>UA</b> returns the Dirichlet boundary condition at the left endpoint.
        </li>
        <li>
          <b>UB</b> returns the Dirichlet boundary condition at the right endpoint.
        </li>
      </ul>
    </p>

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

    <hr>

    <i>
      Last revised on 31 May 2009.
    </i>

    <!-- John Burkardt -->

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