English

Nonlocal-interaction equation on graphs: gradient flow structure and continuum limit

Analysis of PDEs 2021-03-17 v2 Numerical Analysis Numerical Analysis Probability Statistics Theory Statistics Theory

Abstract

We consider dynamics driven by interaction energies on graphs. We introduce graph analogues of the continuum nonlocal-interaction equation and interpret them as gradient flows with respect to a graph Wasserstein distance. The particular Wasserstein distance we consider arises from the graph analogue of the Benamou-Brenier formulation where the graph continuity equation uses an upwind interpolation to define the density along the edges. While this approach has both theoretical and computational advantages, the resulting distance is only a quasi-metric. We investigate this quasi-metric both on graphs and on more general structures where the set of "vertices" is an arbitrary positive measure. We call the resulting gradient flow of the nonlocal-interaction energy the nonlocal nonlocal-interaction equation (NL2^2IE). We develop the existence theory for the solutions of the NL2^2IE as curves of maximal slope with respect to the upwind Wasserstein quasi-metric. Furthermore, we show that the solutions of the NL2^2IE on graphs converge as the empirical measures of the set of vertices converge weakly, which establishes a valuable discrete-to-continuum convergence result.

Keywords

Cite

@article{arxiv.1912.09834,
  title  = {Nonlocal-interaction equation on graphs: gradient flow structure and continuum limit},
  author = {Antonio Esposito and Francesco S. Patacchini and André Schlichting and Dejan Slepčev},
  journal= {arXiv preprint arXiv:1912.09834},
  year   = {2021}
}

Comments

46 pages. Minor revision with improved presentation and fixed typos

R2 v1 2026-06-23T12:52:27.459Z