fd1d_burgers_leap


fd1d_burgers_leap a FORTRAN90 code which solves the nonviscous time-dependent Burgers equation using finite differences and the leapfrog method.

The function u(x,t) is to be solved for in the equation:

du/dt + u * du/dx = 0
for a <= x <= b and t_init <= t <= t_last.

Problem data includes an initial condition for u(x,t_init), and the boundary value functions u(a,t) and u(b,t).

The non-viscous Burgers equation can develop shock waves or discontinuities.

Usage:

fd1d_burgers_leap
runs the code.

Licensing:

The computer code and data files described and made available on this web page are distributed under the MIT license

Languages:

fd1d_burgers_leap is available in a C version and a C++ version and a FORTRAN90 version and a MATLAB version.

Related Data and codes:

BURGERS, a dataset directory which contains some solutions to the viscous Burgers equation.

BURGERS_SOLUTION, a FORTRAN90 code which evaluates an exact solution of the time-dependent 1D viscous Burgers equation.

FD1D_BURGERS_LAX, a FORTRAN90 code which applies the finite difference method and the Lax-Wendroff method to solve the non-viscous time-dependent Burgers equation in one spatial dimension.

fd1d_burgers_leap_test

FD1D_BVP, a FORTRAN90 code which applies the finite difference method to a two point boundary value problem in one spatial dimension.

FD1D_HEAT_EXPLICIT, a FORTRAN90 code which uses the finite difference method and explicit time stepping to solve the time dependent heat equation in 1D.

FD1D_HEAT_IMPLICIT, a FORTRAN90 code which uses the finite difference method and implicit time stepping to solve the time dependent heat equation in 1D.

FD1D_HEAT_STEADY, a FORTRAN90 code which uses the finite difference method to solve the steady (time independent) heat equation in 1D.

FD1D_PREDATOR_PREY, a FORTRAN90 code which implements a finite difference algorithm for predator-prey system with spatial variation in 1D.

FD1D_WAVE, a FORTRAN90 code which applies the finite difference method to solve the time-dependent wave equation utt = c * uxx in one spatial dimension.

Reference:

  1. Daniel Zwillinger,
    Handbook of Differential Equations,
    Academic Press, 1997,
    ISBN: 0127843965,
    LC: QA371.Z88.

Source Code:


Last revised on 27 June 2020.