Finite volume methods for hyperbolic conservation laws

K. W. Morton; T. Sonar

doi:10.1017/S0962492906300013

Abstract

Finite volume methods apply directly to the conservation law form of a differential equation system; and they commonly yield cell average approximations to the unknowns rather than point values. The discrete equations that they generate on a regular mesh look rather like finite difference equations; but they are really much closer to finite element methods, sharing with them a natural formulation on unstructured meshes. The typical projection onto a piecewise constant trial space leads naturally into the theory of optimal recovery to achieve higher than first-order accuracy. They have dominated aerodynamics computation for over forty years, but they have never before been the subject of an Acta Numerica article. We shall therefore survey their early formulations before describing powerful developments in both their theory and practice that have taken place in the last few years.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Nikolos, I.K. and Delis, A.I. 2009. An unstructured node-centered finite volume scheme for shallow water flows with wet/dry fronts over complex topography. Computer Methods in Applied Mechanics and Engineering, Vol. 198, Issue. 47-48, p. 3723.

Ekström, Sven-Erik and Berggren, Martin 2010. ADIGMA - A European Initiative on the Development of Adaptive Higher-Order Variational Methods for Aerospace Applications. Vol. 113, Issue. , p. 39.

Aboiyar, Terhemen Georgoulis, Emmanuil H. and Iske, Armin 2010. Adaptive ADER Methods Using Kernel-Based Polyharmonic Spline WENO Reconstruction. SIAM Journal on Scientific Computing, Vol. 32, Issue. 6, p. 3251.

Lukáčová-Medvid’ová, M. and Morton, K. W. 2010. Finite volume evolution Galerkin methods — A survey. Indian Journal of Pure and Applied Mathematics, Vol. 41, Issue. 2, p. 329.

Delis, A. I. Nikolos, I. K. and Kazolea, M. 2011. Performance and Comparison of Cell-Centered and Node-Centered Unstructured Finite Volume Discretizations for Shallow Water Free Surface Flows. Archives of Computational Methods in Engineering, Vol. 18, Issue. 1, p. 57.

Sonar, Thomas 2015. Encyclopedia of Applied and Computational Mathematics. p. 450.

Beljadid, Abdelaziz Mohammadian, Abdolmajid and Kurganov, Alexander 2016. Well-balanced positivity preserving cell-vertex central-upwind scheme for shallow water flows. Computers & Fluids, Vol. 136, Issue. , p. 193.

Sonar, T. 2016. Handbook of Numerical Methods for Hyperbolic Problems - Basic and Fundamental Issues. Vol. 17, Issue. , p. 55.

Beljadid, Abdelaziz and LeFloch, Philippe 2017. A central-upwind geometry-preserving method for hyperbolic conservation laws on the sphere. Communications in Applied Mathematics and Computational Science, Vol. 12, Issue. 1, p. 81.

Kim, Mi-Young Park, Eun-Jae and Shin, Jaemin 2017. High-order discontinuous Galerkin methods with Lagrange multiplier for hyperbolic systems of conservation laws. Computers & Mathematics with Applications, Vol. 73, Issue. 9, p. 1945.

Reyes, Adam Lee, Dongwook Graziani, Carlo and Tzeferacos, Petros 2018. A New Class of High-Order Methods for Fluid Dynamics Simulations Using Gaussian Process Modeling: One-Dimensional Case. Journal of Scientific Computing, Vol. 76, Issue. 1, p. 443.

Sevilla, Ruben Giacomini, Matteo and Huerta, Antonio 2018. A face‐centred finite volume method for second‐order elliptic problems. International Journal for Numerical Methods in Engineering, Vol. 115, Issue. 8, p. 986.

Guermond, Jean-Luc Popov, Bojan and Tomas, Ignacio 2019. Invariant domain preserving discretization-independent schemes and convex limiting for hyperbolic systems. Computer Methods in Applied Mechanics and Engineering, Vol. 347, Issue. , p. 143.

Reyes, Adam Lee, Dongwook Graziani, Carlo and Tzeferacos, Petros 2019. A variable high-order shock-capturing finite difference method with GP-WENO. Journal of Computational Physics, Vol. 381, Issue. , p. 189.

Iske, Armin 2020. Continuum Mechanics, Applied Mathematics and Scientific Computing: Godunov's Legacy. p. 193.

Tsiolakis, Vasileios Giacomini, Matteo Sevilla, Ruben Othmer, Carsten and Huerta, Antonio 2020. Nonintrusive proper generalised decomposition for parametrised incompressible flow problems in OpenFOAM. Computer Physics Communications, Vol. 249, Issue. , p. 107013.

Giacomini, Matteo and Sevilla, Ruben 2020. A second‐order face‐centred finite volume method on general meshes with automatic mesh adaptation. International Journal for Numerical Methods in Engineering, Vol. 121, Issue. 23, p. 5227.

Vieira, Luan M. Giacomini, Matteo Sevilla, Ruben and Huerta, Antonio 2020. A second-order face-centred finite volume method for elliptic problems. Computer Methods in Applied Mechanics and Engineering, Vol. 358, Issue. , p. 112655.

Roe, Philip 2021. Designing CFD methods for bandwidth—A physical approach. Computers & Fluids, Vol. 214, Issue. , p. 104774.

Tsiolakis, Vasileios Giacomini, Matteo Sevilla, Ruben Othmer, Carsten and Huerta, Antonio 2022. Parametric solutions of turbulent incompressible flows in OpenFOAM via the proper generalised decomposition. Journal of Computational Physics, Vol. 449, Issue. , p. 110802.

Download full list

Article contents

Finite volume methods for hyperbolic conservation laws

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Finite volume methods for hyperbolic conservation laws

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests