Norm-based convergence bounds for nonsymmetric algebraic V-cycle multigrid methods
Abstract
Recently a new approach to analyze and create algebraic multigrid methods (AMG) for nonsymmetric and indefinite matrices was established. Convergence is measured in general norms induced by a certain HPD matrix and -orthogonal projections built by compatible transfer operators are used. Here we continue our theoretical framework, started in Nabben and Rooch (2026), for nonsymmetric algebraic multigrid methods using any HPD matrix to induce a norm. Our framework not only includes all recent results but also provides many new results. We consider two, slightly different, multigrid operators. The first one is the natural generalization of the error operator in the HPD case. The second operator is simpler to apply and has been studied before. However, an additional condition for the smoother is needed, which is in our terminology the -normality. We explain the differences and similarities of both operators in detail and show, why the extra condition is needed. We consider arbitrary interpolation and restriction operators that result in -orthogonal coarse-grid corrections and give sharp estimates for the norm of the error propagation matrices for the two-grid methods. We also show, that the norms are decreasing if we increase the size of the coarse space. Moreover, we are able to extend the landmark -cycle bound by McCormick to the nonsymmetric case.
Cite
@article{arxiv.2604.21815,
title = {Norm-based convergence bounds for nonsymmetric algebraic V-cycle multigrid methods},
author = {Reinhard Nabben and Ludwig Rooch},
journal= {arXiv preprint arXiv:2604.21815},
year = {2026}
}
Comments
26 pages, updated reference 24 to include a link to article