Is there a good tutorial or textbook-like source on implementing ENO/WENO with limiters in one (and more than one) dimension?

Question

I've inherited a finite volume code that does a second-order discretization of flux terms for a set of mixed parabolic-elliptic equations with discontinuous diffusion coefficients. The impression I get is that Discontinuous Galerkin (DG) methods are preferable for this sort of problem; however, since I have some time constraints, and know more about finite volume methods than any type of finite element methods (or DG), for now, I'm forging ahead with finite volume methods. As a disclaimer, I don't know a lot about the finite volume method, either (I've read up to Chapter 8 in LeVeque's Finite Volume Methods for Hyperbolic Problems on my own), so feel free to correct any misconceptions I have here.

Since my colleagues will be interested in unsteady problems, and results will be compared against previous work in more regular geometries that used the method of lines with high order temporal discretizations, I would like to investigate using higher order spatial discretizations to enable the use of higher order time integrators.

Is there a good textbook-like or tutorial-like source that someone can recommend on ENO/WENO methods that covers limiters in more than one dimension? The internal interfaces between materials will create, in essence, transmission boundary conditions that I don't want to handle explicitly in the code. These interfaces will probably cause oscillations that will need to be addressed by a limiter. The best source I've seen is Essentially Non-oscillatory and Weighted Essentially Non-Oscillatory Schemes for Hyperbolic Conservation Laws by C. W. Shu; the book by LeVeque seems to focus mostly on Lax-Wendroff schemes from a wave propagation standpoint (which isn't being used in the code), and the book by Toro seems to focus on higher order schemes in the one-dimensional case.

As a follow-up question: given that the problem is mainly diffusive, is it particularly important to use an strong stability-preserving (SSP) integrator for this type of problem? I know that for hyperbolic problems employing higher-order discretizations, preserving the total variation diminishing property is important, which is why SSP integrators are used. This problem isn't hyperbolic, so the only place where being total variation bounded might actually matter will be any spurious oscillations that arise as a result of the interfaces between materials of different diffusivities.

Answer 1

The sources you are looking at are all looking at hyperbolic problems. The issues are different for elliptic problems and "limiters" are generally not the preferred tool. I outlined some of the methods and tradeoffs in this answer.

As for time integration, $L$-stability is the important property to prevent bad overshoots for parabolic systems. Integrators that are not $L$-stable (such as Crank-Nicolson) will show spurious oscillations even on smooth problems, so long as you start with a steep initial value.

Answer 2

As Jed says, limiters are not usually an efficient approach for parabolic/elliptic problems. WENO is much more expensive than simple piecewise-polynomial interpolation, so I would first try vanilla interpolation and see if you actually have oscillations. WENO is really designed for situations in which the solution is discontinuous; yours is not.

In case someone interested in hyperbolic PDEs reads this question, I would say that the report you have linked is the most practical introduction to WENO, and better than Shu's more recent review paper in terms of helping one to implement it. Another useful tool for understanding and implementing WENO is Matthew Emmett's PyWENO code, which can generate routines in other languages.

For a multidimensional finite volume implementation, Shu's report suggests doing expensive multidimensional quadratures, but I would not go that route. The first option is to just implement dimension-by-dimension WENO (as if for a finite difference scheme), which will be formally second order but can still give high-order-like resolution. Better still, there is a new technique for recovering full accuracy without multidimensional quadratures, which is forthcoming work by Christiane Helzel. I will add a link here when it appears.