6533b859fe1ef96bd12b7919

RESEARCH PRODUCT

Partial data inverse problems and simultaneous recovery of boundary and coefficients for semilinear elliptic equations

Matti LassasMikko SaloYi-hsuan LinTony Liimatainen

subject

inverse obstacle problemGeneral MathematicsMathematics::Analysis of PDEsInverseBoundary (topology)Schiffer's problemCalderon problempartial data01 natural sciencesDomain (mathematical analysis)inversio-ongelmatsymbols.namesakeMathematics - Analysis of PDEsLinearizationTaylor series111 MathematicsFOS: MathematicsSchiffer’s problemBoundary value problem0101 mathematicsMathematicsosittaisdifferentiaaliyhtälötCalderón problem010102 general mathematicsMathematical analysisInverse problemElliptic curvesymbolssimultaneous recoveryAnalysis of PDEs (math.AP)

description

We study various partial data inverse boundary value problems for the semilinear elliptic equation $\Delta u+ a(x,u)=0$ in a domain in $\mathbb R^n$ by using the higher order linearization technique introduced in [LLS 19, FO19]. We show that the Dirichlet-to-Neumann map of the above equation determines the Taylor series of $a(x,z)$ at $z=0$ under general assumptions on $a(x,z)$. The determination of the Taylor series can be done in parallel with the detection of an unknown cavity inside the domain or an unknown part of the boundary of the domain. The method relies on the solution of the linearized partial data Calder\'on problem [FKSU09], and implies the solution of partial data problems for certain semilinear equations $\Delta u+ a(x,u) = 0$ also proved in [KU19]. The results that we prove are in contrast to the analogous inverse problems for the linear Schr\"odinger equation. There recovering an unknown cavity (or part of the boundary) and the potential simultaneously are long-standing open problems, and the solution to the Calder\'on problem with partial data is known only in special cases when $n \geq 3$.

yearjournalcountryeditionlanguage
2021-01-01
https://dx.doi.org/10.48550/arxiv.1905.02764