A1 Journal article (refereed)
Refined instability estimates for some inverse problems (2022)


Kow, P.-Z., & Wang, J.-N. (2022). Refined instability estimates for some inverse problems. Inverse Problems and Imaging, 16(6), 1619-1642. https://doi.org/10.3934/ipi.2022017


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Publication details

All authors or editorsKow, Pu-Zhao; Wang, Jenn-Nan

Journal or seriesInverse Problems and Imaging

ISSN1930-8337

eISSN1930-8345

Publication year2022

Volume16

Issue number6

Pages range1619-1642

PublisherAmerican Institute of Mathematical Sciences (AIMS)

Publication countryUnited States

Publication languageEnglish

DOIhttps://doi.org/10.3934/ipi.2022017

Publication open accessNot open

Publication channel open access

Publication is parallel published (JYX)https://jyx.jyu.fi/handle/123456789/83337


Abstract

Many inverse problems are known to be ill-posed. The ill-posedness can be manifested by an instability estimate of exponential type, first derived by Mandache [29]. In this work, based on Mandache's idea, we refine the instability estimates for two inverse problems, including the inverse inclusion problem and the inverse scattering problem. Our aim is to derive explicitly the dependence of the instability estimates on key parameters.

The first result of this work is to show how the instability depends on the depth of the hidden inclusion and the conductivity of the background medium. This work can be regarded as a counterpart of the depth-dependent and conductivity-dependent stability estimate proved by Li, Wang, and Wang [28], or pure dependent stability estimate proved by Nagayasu, Uhlmann, and Wang [31]. We rigorously justify the intuition that the exponential instability becomes worse as the inclusion is hidden deeper inside a conductor or the conductivity is larger.

The second result is to justify the optimality of increasing stability in determining the near-field of a radiating solution of the Helmholtz equation from the far-field pattern. Isakov [16] showed that the stability of this inverse problem increases as the frequency increases in the sense that the stability estimate changes from a logarithmic type to a Hölder type. We prove in this work that the instability changes from an exponential type to a Hölder type as the frequency increases. This result is inspired by our recent work [25].


Keywordspartial differential equationsinverse problemsimagingelectrical impedance tomographyscattering (physics)

Free keywordsinverse problems; instability; Calderón's problem; electrical impedance tomography; depth-dependent instability of exponential-type; Helmholtz equation; scattering theory; Rellich lemma; increasing stability phenomena; 35J15; 35R25; 35R30


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Ministry reportingYes

VIRTA submission year2022

JUFO rating2


Last updated on 2024-12-10 at 14:45