Evolution variational inequality and Wasserstein control in variable curvature context
Abstract
In this note we continue the analysis of metric measure space with variable ricci curvature bounds. First, we study -convex functions on metric spaces where is a lower semi-continuous function, and gradient flow curves in the sense of a new evolution variational inequality that captures the information that is provided by . Then, in the spirit of previous work by Erbar, Kuwada and Sturm \cite{erbarkuwadasturm} we introduce an entropic curvature-dimension condition for metric measure spaces and lower semi-continuous . This condition is stable with respect to Gromov convergence and we show that is equivalent to the reduced curvature-dimension condition provided the space is non-branching. Finally, we introduce a Riemannian curvature-dimension condition in terms of an evolution variational inequality on the Wasserstein space. A consequence is a new differential Wasserstein contraction estimate.
Cite
@article{arxiv.1509.02178,
title = {Evolution variational inequality and Wasserstein control in variable curvature context},
author = {Christian Ketterer},
journal= {arXiv preprint arXiv:1509.02178},
year = {2015}
}
Comments
the compactness assumption in Theorem 5.7 has been replaced by a lower bound for the curvature function, additional properties on distortion coefficients and their derivatives, comments are welcome