Quantitative convergence in relative entropy for a moderately interacting particle system on Rd
Abstract
This article shows how to combine the relative entropy method by D. Bresch, P.-E. Jabin, and Z. Wang in arXiv:1706.09564, arXiv:1906.04093 and the regularized L2(Rd)-estimate by Oelschl\"ager (Probability theory and related fields, 1987) to prove a strong propagation of chaos result for the viscous porous medium equation from a moderately interacting particle system in L∞(0,T; L1(Rd))-norm. In the moderate interacting setting, the interacting potential is a smoothed Dirac Delta distribution, however, current results regarding the relative entropy methods for singular potentials do not apply. The result holds on Rd for any dimension d≥ 1 and provides a quantitative result where the rate of convergence depends on the moderate scaling parameter and the dimension d≥ 1. Additionally, the presented method can be adapted for moderately interacting systems for which a certain convergence probability holds -- thus a propagation of chaos result in relative entropy can be obtained for kernels approximating Coulomb potentials.
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