English

Gradient Flows and Nonlinear Power Methods for the Computation of Nonlinear Eigenfunctions

Numerical Analysis 2022-03-15 v2 Numerical Analysis Analysis of PDEs Optimization and Control Spectral Theory

Abstract

This chapter describes how gradient flows and nonlinear power methods in Banach spaces can be used to solve nonlinear eigenvector-dependent eigenvalue problems, and how convergence of (discretized) approximations can be verified. We review several flows from literature, which were proposed to compute nonlinear eigenfunctions, and show that they all relate to normalized gradient flows. Furthermore, we show that the implicit Euler discretization of gradient flows gives rise to a nonlinear power method of the proximal operator and prove their convergence to nonlinear eigenfunctions. Finally, we prove that Γ\Gamma-convergence of functionals implies convergence of their ground states, which is important for discrete approximations.

Keywords

Cite

@article{arxiv.2105.08405,
  title  = {Gradient Flows and Nonlinear Power Methods for the Computation of Nonlinear Eigenfunctions},
  author = {Leon Bungert and Martin Burger},
  journal= {arXiv preprint arXiv:2105.08405},
  year   = {2022}
}

Comments

To appear in Handbook of Numerical Analysis, Numerical Control: Part A, Volume 23

R2 v1 2026-06-24T02:12:59.876Z