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Inverse problems for fractional equations with a minimal number of measurements

Yi‐Hsuan Lin, Hongyu Liu

2023Communications on Analysis and Computation16 citationsDOIOpen Access PDF

Abstract

In this paper, we study several inverse problems associated with a fractional differential equation of the following form: \begin{document}$ (-\Delta)^s u(x)+\sum\limits_{k = 0}^N a^{(k)}(x) [u(x)]^k = 0, \ \ 0<s<1, \ N\in\mathbb{N}\cup\{0\}\cup\{\infty\}, $\end{document} which is given in a bounded domain $ \Omega\subset\mathbb{R}^n $, $ n\geq 1 $. For any finite $ N $, we show that $ a^{(k)}(x) $, $ k = 0, 1, \ldots, N $, can be uniquely determined by $ N+1 $ different pairs of Cauchy data in $ \Omega_e: = \mathbb{R}^n\backslash\overline{\Omega} $. If $ N = \infty $, the uniqueness result is established by using infinitely many pairs of Cauchy data. The results are highly intriguing in that it generally does not hold true in the local case, namely $ s = 1 $, even for the simplest case when $ N = 0 $, a fortiori $ N\geq 1 $. The nonlocality plays a key role in establishing the uniqueness result, and we do not utilize any linearization techniques. We also establish several other unique determination results by making use of a minimal number of measurements. Moreover, in the process we derive a novel comparison principle for nonlinear fractional differential equations as a significant byproduct.

Topics & Concepts

UniquenessBounded functionOmegaCauchy distributionMathematicsDomain (mathematical analysis)CombinatoricsInverseMathematical analysisPhysicsGeometryQuantum mechanicsNumerical methods in inverse problemsAdvanced Mathematical Modeling in EngineeringDifferential Equations and Boundary Problems
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