# Shock Capturing by Bernstein Polynomials for Scalar Conservation Laws

**Authors:** Jan Glaubitz

arXiv: 1907.04115 · 2019-07-30

## TL;DR

This paper introduces a novel shock capturing method using Bernstein polynomials to stabilize high-order spectral element solutions of hyperbolic conservation laws, effectively reducing oscillations near discontinuities without compromising computational efficiency.

## Contribution

The authors develop a Bernstein-based shock capturing procedure that is total variation diminishing, preserves monotonicity, and can enforce bounds, improving stability of spectral methods for conservation laws.

## Key findings

- The method stabilizes spectral approximations near shocks.
- It preserves monotone and bounded solutions.
- It does not reduce the time step or CFL condition.

## Abstract

A main disadvantage of many high-order methods for hyperbolic conservation laws lies in the famous Gibbs-Wilbraham phenomenon, once discontinuities appear in the solution. Due to the Gibbs-Wilbraham phenomenon, the numerical approximation will be polluted by spurious oscillations, which produce unphysical numerical solutions and might finally blow up the computation. In this work, we propose a new shock capturing procedure to stabilise high-order spectral element approximations. The procedure consists of going over from the original (polluted) approximation to a convex combination of the original approximation and its Bernstein reconstruction, yielding a stabilised approximation. The coefficient in the convex combination, and therefore the procedure, is steered by a discontinuity sensor and is only activated in troubled elements. Building up on classical Bernstein operators, we are thus able to prove that the resulting Bernstein procedure is total variation diminishing and preserves monotone (shock) profiles. Further, the procedure can be modified to not just preserve but also to enforce certain bounds for the solution, such as positivity. In contrast to other shock capturing methods, e.g. artificial viscosity methods, the new procedure does not reduce the time step or CFL condition and can be easily and efficiently implemented into any existing code. Numerical tests demonstrate that the proposed shock-capturing procedure is able to stabilise and enhance spectral element approximations in the presence of shocks.

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## Figures

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## References

60 references — full list in the complete paper: https://tomesphere.com/paper/1907.04115/full.md

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Source: https://tomesphere.com/paper/1907.04115