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Main Authors: Baers, Hendrik, Covi, Giovanni, Rüland, Angkana
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.08381
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author Baers, Hendrik
Covi, Giovanni
Rüland, Angkana
author_facet Baers, Hendrik
Covi, Giovanni
Rüland, Angkana
contents We prove exponential instability properties for the fractional Calderón problem and the conductivity formulation of the fractional Calderón problem in the regime of fractional powers $s\in (0,1)$. We particularly focus on two settings: First, we discuss instability properties in general domain geometries with scaling critical $L^{\frac{n}{2s}}$ potentials and constant background metrics. Secondly, we investigate instability properties in general geometries with $L^{\frac{n}{2s}}$ potentials and low regularity, variable coefficient, possibly anisotropic background metrics. In both settings we make use of the methods introduced in \cite{KRS21} and we deduce strong compression estimates for the forward problem. In the first setting this is based on analytic smoothing estimates for a suitable comparison operator while in the second setting involving low regularity metrics this is based on an iterated compression gain. We thus generalize the results from \cite{RS18} to generic geometries and variable coefficients and further also discuss the setting of fractional conductivity equations. In particular, this proves that the logarithmic stability estimates for the fractional Calderón problem from \cite{RS20} are optimal.
format Preprint
id arxiv_https___arxiv_org_abs_2405_08381
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On Instability Properties of the Fractional Calderón Problem
Baers, Hendrik
Covi, Giovanni
Rüland, Angkana
Analysis of PDEs
We prove exponential instability properties for the fractional Calderón problem and the conductivity formulation of the fractional Calderón problem in the regime of fractional powers $s\in (0,1)$. We particularly focus on two settings: First, we discuss instability properties in general domain geometries with scaling critical $L^{\frac{n}{2s}}$ potentials and constant background metrics. Secondly, we investigate instability properties in general geometries with $L^{\frac{n}{2s}}$ potentials and low regularity, variable coefficient, possibly anisotropic background metrics. In both settings we make use of the methods introduced in \cite{KRS21} and we deduce strong compression estimates for the forward problem. In the first setting this is based on analytic smoothing estimates for a suitable comparison operator while in the second setting involving low regularity metrics this is based on an iterated compression gain. We thus generalize the results from \cite{RS18} to generic geometries and variable coefficients and further also discuss the setting of fractional conductivity equations. In particular, this proves that the logarithmic stability estimates for the fractional Calderón problem from \cite{RS20} are optimal.
title On Instability Properties of the Fractional Calderón Problem
topic Analysis of PDEs
url https://arxiv.org/abs/2405.08381