Lax–Wendroff method

The Lax–Wendroff method, named after Peter Lax and Burton Wendroff,^[1] is a numerical method for the solution of hyperbolic partial differential equations, based on finite differences. It is second-order accurate in both space and time. This method is an example of explicit time integration where the function that defines the governing equation is evaluated at the current time.

Suppose one has an equation of the following form: $${\displaystyle \frac{\partial u(x,t)}{\partial t}+\frac{\partial f(u(x,t))}{\partial x}=0}$$ where x and t are independent variables, and the initial state, u(x, 0) is given.

In the linear case, where f(u) = Au, and A is a constant,^[2] $${\displaystyle u_i^{n+1}=u_i^n-\frac{\mathrm{\Delta }t}{2\mathrm{\Delta }x}A[u_{i+1}^n-u_{i-1}^n]+\frac{\mathrm{\Delta }{t}^2}{2\mathrm{\Delta }{x}^2}{A}^2[u_{i+1}^n-2u_i^n+u_{i-1}^n].}$$ Here ${\displaystyle n}$ refers to the ${\displaystyle t}$ dimension and ${\displaystyle i}$ refers to the ${\displaystyle x}$ dimension. This linear scheme can be extended to the general non-linear case in different ways. One of them is letting $${\displaystyle A(u)=f^{\prime }(u)=\frac{\partial f}{\partial u}}$$

The conservative form of Lax-Wendroff for a general non-linear equation is then: $${\displaystyle u_i^{n+1}=u_i^n-\frac{\mathrm{\Delta }t}{2\mathrm{\Delta }x}[f(u_{i+1}^n)-f(u_{i-1}^n)]+\frac{\mathrm{\Delta }{t}^2}{2\mathrm{\Delta }{x}^2}[A_{i+1/2}(f(u_{i+1}^n)-f(u_i^n))-A_{i-1/2}(f(u_i^n)-f(u_{i-1}^n))].}$$ where ${\displaystyle A_{i\pm 1/2}}$ is the Jacobian matrix evaluated at $\frac{1}{2}(u_i^n+u_{i\pm 1}^n)$.

To avoid the Jacobian evaluation, use a two-step procedure.

What follows is the Richtmyer two-step Lax–Wendroff method. The first step in the Richtmyer two-step Lax–Wendroff method calculates values for f(u(x, t)) at half time steps, t_{n + 1/2} and half grid points, x_{i + 1/2}. In the second step values at t_{n + 1} are calculated using the data for t_n and t_{n + 1/2}.

First (Lax) steps: $${\displaystyle u_{i+1/2}^{n+1/2}=\frac{1}{2}(u_{i+1}^n+u_i^n)-\frac{\mathrm{\Delta }t}{2\mathrm{\Delta }x}(f(u_{i+1}^n)-f(u_i^n)),}$$ $${\displaystyle u_{i-1/2}^{n+1/2}=\frac{1}{2}(u_i^n+u_{i-1}^n)-\frac{\mathrm{\Delta }t}{2\mathrm{\Delta }x}(f(u_i^n)-f(u_{i-1}^n)).}$$

Second step: $${\displaystyle u_i^{n+1}=u_i^n-\frac{\mathrm{\Delta }t}{\mathrm{\Delta }x}[f(u_{i+1/2}^{n+1/2})-f(u_{i-1/2}^{n+1/2})].}$$

Another method of this same type was proposed by MacCormack. MacCormack's method uses first forward differencing and then backward differencing:

First step: $${\displaystyle u_i^{*}=u_i^n-\frac{\mathrm{\Delta }t}{\mathrm{\Delta }x}(f(u_{i+1}^n)-f(u_i^n)).}$$ Second step: $${\displaystyle u_i^{n+1}=\frac{1}{2}(u_i^n+u_i^{*})-\frac{\mathrm{\Delta }t}{2\mathrm{\Delta }x}[f(u_i^{*})-f(u_{i-1}^{*})].}$$

Alternatively, First step: $${\displaystyle u_i^{*}=u_i^n-\frac{\mathrm{\Delta }t}{\mathrm{\Delta }x}(f(u_i^n)-f(u_{i-1}^n)).}$$ Second step: $${\displaystyle u_i^{n+1}=\frac{1}{2}(u_i^n+u_i^{*})-\frac{\mathrm{\Delta }t}{2\mathrm{\Delta }x}[f(u_{i+1}^{*})-f(u_i^{*})].}$$

• Michael J. Thompson, An Introduction to Astrophysical Fluid Dynamics, Imperial College Press, London, 2006.
• Press, WH; Teukolsky, SA; Vetterling, WT; Flannery, BP (2007). "Section 20.1. Flux Conservative Initial Value Problems". Numerical Recipes: The Art of Scientific Computing (3rd ed.). New York: Cambridge University Press. p. 1040. ISBN 978-0-521-88068-8. http://apps.nrbook.com/empanel/index.html#pg=1040. 

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