English

Finsler structure for variable exponent Wasserstein space and gradient flows

Analysis of PDEs 2020-01-01 v1

Abstract

In this paper, we propose a variational approach based on optimal transportation to study the existence and unicity of solution for a class of parabolic equations involving q(x)q(x)-Laplacian operator \begin{equation*}\label{equation variable q(x)} \frac{\partial \rho(t,x)}{\partial t}=div_x\left(\rho(t,x)|\nabla_x G^{'}(\rho(t,x))|^{q(x)-2}\nabla_x G^{'}(\rho(t,x)) \right) .\end{equation*} The variational approach requires the setting of new tools such as appropiate distance on the probability space and an introduction of a Finsler metric in this space. The class of parabolic equations is derived as the flow of a gradient with respect the Finsler structure. For q(x)qq(x)\equiv q constant, we recover some known results existing in the literature for the qq-Laplacian operator.

Keywords

Cite

@article{arxiv.1912.12450,
  title  = {Finsler structure for variable exponent Wasserstein space and gradient flows},
  author = {Aboubacar Marcos and Ambroise Soglo},
  journal= {arXiv preprint arXiv:1912.12450},
  year   = {2020}
}

Comments

26 pages Submitted for publication in EJDE

R2 v1 2026-06-23T12:58:00.269Z