Conservativity and Weak Consistency of a Class of Staggered Finite Volume Methods for the Euler Equations

TL;DR

This paper analyzes a class of staggered finite volume schemes for the Euler equations, demonstrating their conservativity and consistency, and providing theoretical foundations for their numerical stability and accuracy.

Contribution

The paper proves that these schemes are conservative and consistent in the Lax-Wendroff sense, enhancing their theoretical understanding.

Findings

Schemes preserve convex admissible states.

Schemes are proven to be conservative.

Schemes are consistent in the Lax-Wendroff sense.

Abstract

We address a class of schemes for the Euler equations with the following features: the space discretization is staggered, possible upwinding is performed with respect to the material velocity only and the internal energy balance is solved, with a correction term designed on consistency arguments. These schemes have been shown in previous works to preserve the convex of admissible states and have been extensively tested numerically. The aim of the present paper is twofold: we derive a local total energy equation satisfied by the solutions, so that the schemes are in fact conservative, and we prove that they are consistent in the Lax-Wendroff sense.