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Main Authors: Piatnitski, Andrey, Sloushch, Vladimir, Suslina, Tatiana, Zhizhina, Elena
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.20408
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author Piatnitski, Andrey
Sloushch, Vladimir
Suslina, Tatiana
Zhizhina, Elena
author_facet Piatnitski, Andrey
Sloushch, Vladimir
Suslina, Tatiana
Zhizhina, Elena
contents The paper deals with homogenization of self-adjoint operators in $L_2(\mathbb R^d)$ of the form $$ ({\mathbb A}_\eps u) (\x) = \int_{\R^d} μ(\x/\eps, \y/\eps) \frac{\left( u(\x) - u(\y) \right)}{|\x - \y|^{d+α}}\,d\y, $$ where $0< α< 2$, and $\eps>0$ is a small parameter. It is assumed that the function $μ(\x,\y)$ is $\Z^d$-periodic in each variable, $μ(\x,\y)=μ(\y,\x)$ for all $\x$ and $\y$, and $0< μ_- \leqslant μ(\x,\y) \leqslant μ_+< \infty$. Under these assumptions we show that the resolvent $({\mathbb A}_\eps + I)^{-1}$ converges, as $\eps\to0$, in the operator norm in $L_2(\R^d)$ to the resolvent $({\mathbb A}^0 + I)^{-1}$ of the limit operator ${\mathbb A}^0$ given by $$ ({\mathbb A}^0 u) (\x) = \int_{\R^d} μ^0 \frac{\left( u(\x) - u(\y) \right)}{|\x - \y|^{d+α}}\,d\y, $$ where $μ^0$ is the mean value of $μ(\x,\y)$. We also show that the operator norm of the discrepancy $\|({\mathbb A}_\eps + I)^{-1} - (\A^0 + I)^{-1}\|_{L_2(\mathbb R^d)\to L_2(\mathbb R^d)}$ can be estimated by $O(\eps^α)$, if $0< α< 1$, by $O(\eps (1 + | \operatorname{ln} \eps|)^2)$, if $ α=1$, and by $O(\eps^{2- α})$, if $1< α< 2$.
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institution arXiv
publishDate 2024
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spellingShingle Operator estimates in homogenization of Lévy-type operators with periodic coefficients
Piatnitski, Andrey
Sloushch, Vladimir
Suslina, Tatiana
Zhizhina, Elena
Analysis of PDEs
Functional Analysis
The paper deals with homogenization of self-adjoint operators in $L_2(\mathbb R^d)$ of the form $$ ({\mathbb A}_\eps u) (\x) = \int_{\R^d} μ(\x/\eps, \y/\eps) \frac{\left( u(\x) - u(\y) \right)}{|\x - \y|^{d+α}}\,d\y, $$ where $0< α< 2$, and $\eps>0$ is a small parameter. It is assumed that the function $μ(\x,\y)$ is $\Z^d$-periodic in each variable, $μ(\x,\y)=μ(\y,\x)$ for all $\x$ and $\y$, and $0< μ_- \leqslant μ(\x,\y) \leqslant μ_+< \infty$. Under these assumptions we show that the resolvent $({\mathbb A}_\eps + I)^{-1}$ converges, as $\eps\to0$, in the operator norm in $L_2(\R^d)$ to the resolvent $({\mathbb A}^0 + I)^{-1}$ of the limit operator ${\mathbb A}^0$ given by $$ ({\mathbb A}^0 u) (\x) = \int_{\R^d} μ^0 \frac{\left( u(\x) - u(\y) \right)}{|\x - \y|^{d+α}}\,d\y, $$ where $μ^0$ is the mean value of $μ(\x,\y)$. We also show that the operator norm of the discrepancy $\|({\mathbb A}_\eps + I)^{-1} - (\A^0 + I)^{-1}\|_{L_2(\mathbb R^d)\to L_2(\mathbb R^d)}$ can be estimated by $O(\eps^α)$, if $0< α< 1$, by $O(\eps (1 + | \operatorname{ln} \eps|)^2)$, if $ α=1$, and by $O(\eps^{2- α})$, if $1< α< 2$.
title Operator estimates in homogenization of Lévy-type operators with periodic coefficients
topic Analysis of PDEs
Functional Analysis
url https://arxiv.org/abs/2412.20408