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RESEARCH PRODUCT

The Calderon problem in transversally anisotropic geometries

Yaroslav KurylevMikko SaloMatti LassasDavid Dos Santos Ferreira

subject

Mathematics - Differential GeometryGeodesicGeneral MathematicsBoundary (topology)Conformal map01 natural sciencessymbols.namesakeMathematics - Analysis of PDEsFOS: Mathematics[MATH.MATH-AP]Mathematics [math]/Analysis of PDEs [math.AP]0101 mathematicsMathematicsCalderón problemRiemannian manifoldApplied Mathematicsta111010102 general mathematicsMathematical analysiscomplex geometrical optics solutionInverse problemRiemannian manifold010101 applied mathematicsboundary control methodFourier transformDifferential Geometry (math.DG)Transversal (combinatorics)Metric (mathematics)symbolsinverse boundary value problemAnalysis of PDEs (math.AP)

description

We consider the anisotropic Calderon problem of recovering a conductivity matrix or a Riemannian metric from electrical boundary measurements in three and higher dimensions. In the earlier work \cite{DKSaU}, it was shown that a metric in a fixed conformal class is uniquely determined by boundary measurements under two conditions: (1) the metric is conformally transversally anisotropic (CTA), and (2) the transversal manifold is simple. In this paper we will consider geometries satisfying (1) but not (2). The first main result states that the boundary measurements uniquely determine a mixed Fourier transform / attenuated geodesic ray transform (or integral against a more general semiclassical limit measure) of an unknown coefficient. In particular, one obtains uniqueness results whenever the geodesic ray transform on the transversal manifold is injective. The second result shows that the boundary measurements in an infinite cylinder uniquely determine the transversal metric. The first result is proved by using complex geometrical optics solutions involving Gaussian beam quasimodes, and the second result follows from a connection between the Calderon problem and Gel'fand's inverse problem for the wave equation and the boundary control method.

yearjournalcountryeditionlanguage
2016-01-01
https://dx.doi.org/10.48550/arxiv.1305.1273