Courant–Friedrichs–Lewy condition

In mathematics, the Courant–Friedrichs–Lewy condition (CFL condition) is a necessary condition for stability while solving certain partial differential equations (usually hyperbolic PDEs) numerically by the method of finite differences.^[1] It arises in the numerical analysis of explicit time-marching schemes, when these are used for the numerical solution. As a consequence, the time step must be less than a certain time in many explicit time-marching computer simulations, otherwise the simulation will produce incorrect results. The condition is named after Richard Courant, Kurt Friedrichs, and Hans Lewy who described it in their 1928 paper.^[2] This condition is an example of explicit time integration where the function that defines governing equation is evaluated at the current time.^{[clarification needed]}

Heuristic description

The principle behind the condition is that, for example, if a wave is moving across a discrete spatial grid and we want to compute its amplitude at discrete time steps of equal length,^[3] then this length must be less than the time for the wave to travel to adjacent grid points. As a corollary, when the grid point separation is reduced, the upper limit for the time step also decreases. In essence, the numerical domain of dependence of any point in space and time (which data values in the initial conditions affect the numerical computed value at that point) must include the analytical domain of dependence (where in the initial conditions has an effect on the exact value of the solution at that point) in order to assure that the scheme can access the information required to form the solution.

The CFL condition

In order to make a reasonably formally precise statement of the condition, it is necessary to define the following quantities

• Spatial coordinate: it is one of the coordinates of the physical space in which the problem is posed.
• Spatial dimension of the problem: it is the number ${\displaystyle n}$ of spatial dimensions i.e. the number of spatial coordinates of the physical space where the problem is posed. Typical values are ${\displaystyle n=1}$, ${\displaystyle n=2}$ and ${\displaystyle n=3}$.
• Time: it is the coordinate, acting as a parameter, which describes the evolution of the system, distinct from the spatial coordinates.

The spatial coordinates and the time are supposed to be discrete-valued independent variables, which are placed at regular distances called the interval length^[4] and the time step, respectively. Using these names, the CFL condition relates the length of the time step to a function of the interval lengths of each spatial coordinate and of the maximum speed with which information can travel in the physical space.

Operatively, the CFL condition is commonly prescribed for those terms of the finite-difference approximation of general partial differential equations which model the advection phenomenon.^[5]

The one-dimensional case

For one-dimensional case, the CFL has the following form:

${\displaystyle C={\frac {u\,\Delta t}{\Delta x}}\leq C_{max}}$

where the dimensionless number is called the Courant number,

• ${\displaystyle u}$ is the magnitude of the velocity (whose dimension is length/time)
• ${\displaystyle \Delta t}$ is the time step (whose dimension is time)
• ${\displaystyle \Delta x}$ is the length interval (whose dimension is length).

The value of ${\displaystyle C_{max}}$ changes with the method used to solve the discretised equation, especially depending on whether the method is explicit or implicit. If an explicit (time-marching) solver is used then typically ${\displaystyle C_{max}=1}$. Implicit (matrix) solvers are usually less sensitive to numerical instability and so larger values of ${\displaystyle C_{max}}$ may be tolerated.

The two and general n-dimensional case

In the two-dimensional case, the CFL condition becomes

${\displaystyle C={\frac {u_{x}\,\Delta t}{\Delta x}}+{\frac {u_{y}\,\Delta t}{\Delta y}}\leq C_{max}}$

with obvious meaning of the symbols involved. By analogy with the two-dimensional case, the general CFL condition for the ${\displaystyle n}$-dimensional case is the following one:

${\displaystyle C=\Delta t\sum _{i=1}^{n}{\frac {u_{x_{i}}}{\Delta x_{i}}}\leq C_{max}.}$

The interval length is not required to be the same for each spatial variable ${\displaystyle \Delta x_{i},i=1,...,n}$. This "degree of freedom" can be used in order to somewhat optimize the value of the time step for a particular problem, by varying the values of the different interval in order to keep it not too small.

Implications of the CFL condition

The CFL condition is only a necessary one

The CFL condition is a necessary condition, but may not be sufficient for the convergence of the finite-difference approximation of a given numerical problem. Thus, in order to establish the convergence of the finite-difference approximation, it is necessary to use other methods, which in turn could imply further limitations on the length of the time step and/or the lengths of the spatial intervals.

The CFL condition can be a very strong requirement

The CFL condition can be a very limiting constraint on the time step ${\displaystyle \Delta t}$: for example, in the finite-difference approximation of certain fourth-order nonlinear partial differential equations, it can have the following form:^{[citation needed]}

${\displaystyle {\frac {\Delta t}{(\Delta x)^{4}}}<Cu}$

meaning that a decrease in the length interval ${\displaystyle \Delta x}$ requires a fourth order decrease in the time step ${\displaystyle \Delta t}$ for the condition to be fulfilled. Therefore, when solving particularly stiff problems, efforts are often made to avoid the CFL condition, for example by using implicit methods.

Notes

1. In general, it is not a sufficient condition; also, it can be a demanding condition for some problems. See the "Implications of the CFL condition" section of this article for a brief survey of these issues.
2. See reference Courant, Friedrichs & Lewy 1928. There exists also an English translation of the 1928 German original: see references Courant, Friedrichs & Lewy 1956 and Courant, Friedrichs & Lewy 1967.
3. This situation commonly occurs when a hyperbolic partial differential operator has been approximated by a finite difference equation, which is then solved by numerical linear algebra methods.
4. This quantity is not necessarily the same for each spatial variable, as it is shown in the "The two and general n–dimensional case" section of this entry : it can be chosen in order to somewhat relax the condition.
5. Precisely, this is the hyperbolic part of the PDE under analysis.

References

• Courant, R.; Friedrichs, K.; Lewy, H. (1928), "Über die partiellen Differenzengleichungen der mathematischen Physik", Mathematische Annalen (in German), 100 (1): 32–74, Bibcode:1928MatAn.100...32C, doi:10.1007/BF01448839, JFM 54.0486.01, MR 1512478 {{citation}}: Cite has empty unknown parameter: |month= (help).
• Courant, R.; Friedrichs, K.; Lewy, H. (1956) [1928], On the partial difference equations of mathematical physics, AEC Research and Development Report, vol. NYO-7689, New York: AEC Computing and Applied Mathematics Centre – Courant Institute of Mathematical Sciences, pp. V + 76, archived from the original on October 23, 2008 {{citation}}: Unknown parameter |month= ignored (help).: translated from the German by Phyllis Fox. This is an earlier version of the paper Courant, Friedrichs & Lewy 1967, circulated as a research report.
• Courant, R.; Friedrichs, K.; Lewy, H. (1967) [1928], "On the partial difference equations of mathematical physics", IBM Journal of Research and Development, 11 (2): 215–234, MR 0213764, Zbl 0145.40402 {{citation}}: External link in |journal= (help); Unknown parameter |month= ignored (help). A freely downlodable copy can be found here.

External links

• Bakhvalov, N. S. (2001) [1994], "Courant–Friedrichs–Lewy condition", Encyclopedia of Mathematics, EMS Press
• Weisstein, Eric W. "Courant-Friedrichs-Lewy Condition". MathWorld.