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Main Authors: Olivera, Christian, Richard, Alexandre, Tomasevic, Milica
Format: Preprint
Published: 2020
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Online Access:https://arxiv.org/abs/2004.03177
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author Olivera, Christian
Richard, Alexandre
Tomasevic, Milica
author_facet Olivera, Christian
Richard, Alexandre
Tomasevic, Milica
contents In this work we obtain rates of convergence for two moderately interacting stochastic particle systems with singular kernels associated to the viscous Burgers and Keller-Segel equations. The main novelty of this work is to consider a non-locally integrable kernel. Namely for the viscous Burgers equation in $\mathbb{R}$, we obtain almost sure convergence of the mollified empirical measure to the solution of the PDE in some Bessel space with a rate of convergence of order $N^{-1/6}$, on any time interval. With the same rate, convergence also holds for the genuine empirical measure in Wasserstein distance, and at the level of the trajectories of the particles with the standard coupling to McKean-Vlasov particles. In the case of the Keller-Segel equation on a $d$-dimensional torus, we obtain almost sure convergence of the mollified empirical measure to the solution of the PDE in some $L^q$ space with a rate of order $N^{-\frac{1}{2(d+1)}}$. The result holds up to the maximal existence time of the PDE, for any value of the chemo-attractant sensitivity $χ$.
format Preprint
id arxiv_https___arxiv_org_abs_2004_03177
institution arXiv
publishDate 2020
record_format arxiv
spellingShingle Quantitative approximation of the Burgers and Keller-Segel equations by moderately interacting particles
Olivera, Christian
Richard, Alexandre
Tomasevic, Milica
Probability
In this work we obtain rates of convergence for two moderately interacting stochastic particle systems with singular kernels associated to the viscous Burgers and Keller-Segel equations. The main novelty of this work is to consider a non-locally integrable kernel. Namely for the viscous Burgers equation in $\mathbb{R}$, we obtain almost sure convergence of the mollified empirical measure to the solution of the PDE in some Bessel space with a rate of convergence of order $N^{-1/6}$, on any time interval. With the same rate, convergence also holds for the genuine empirical measure in Wasserstein distance, and at the level of the trajectories of the particles with the standard coupling to McKean-Vlasov particles. In the case of the Keller-Segel equation on a $d$-dimensional torus, we obtain almost sure convergence of the mollified empirical measure to the solution of the PDE in some $L^q$ space with a rate of order $N^{-\frac{1}{2(d+1)}}$. The result holds up to the maximal existence time of the PDE, for any value of the chemo-attractant sensitivity $χ$.
title Quantitative approximation of the Burgers and Keller-Segel equations by moderately interacting particles
topic Probability
url https://arxiv.org/abs/2004.03177