# Analysis of the edge finite element approximation of the Maxwell   equations with low regularity solutions

**Authors:** Alexandre Ern, Jean-Luc Guermond

arXiv: 1706.00600 · 2017-10-17

## TL;DR

This paper develops new error estimates for edge finite element approximations of Maxwell equations, especially effective for solutions with very low regularity, using innovative quasi-interpolation techniques.

## Contribution

It introduces novel quasi-interpolation operators that achieve optimal approximation decay rates for low-regularity solutions, bypassing traditional discrete compactness methods.

## Key findings

- Error estimates valid for solutions with Sobolev regularity close to zero
- Improved $L^2$-error bounds for heterogeneous materials
- Analysis applicable to low-regularity electromagnetic problems

## Abstract

We derive $H_{\text{curl}}$-error estimates and improved $L^2$-error estimates for the Maxwell equations approximated using edge finite elements. These estimates only invoke the expected regularity pickup of the exact solution in the scale of the Sobolev spaces, which is typically lower than $\frac12$ and can be arbitrarily close to $0$ when the material properties are heterogeneous. The key tools for the analysis are commuting quasi-interpolation operators in $H_{\text{curl}}$- and $H_{\text{div}}$-conforming finite element spaces and, most crucially, newly-devised quasi-interpolation operators delivering optimal estimates on the decay rate of the best-approximation error for functions with Sobolev smoothness index arbitrarily close to $0$. The proposed analysis entirely bypasses the technique known in the literature as the discrete compactness argument.

## Full text

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## References

34 references — full list in the complete paper: https://tomesphere.com/paper/1706.00600/full.md

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Source: https://tomesphere.com/paper/1706.00600