Elastic Calder\'on Problem via Resonant Hard Inclusions: Linearisation of the N-D Map and Density Reconstruction

Abstract

We study an elastic Calderon-type inverse problem: recover the mass density (x) in a bounded domain ⊂R3 from the Neumann-to-Dirichlet map associated with the isotropic Lam\'e system Lλ,μu+ω2(x)u=0. We introduce a constructive strategy that embeds a subwavelength periodic array of resonant high-density (hard) inclusions to create an effective medium with a uniform negative density shift. Specifically, we place a periodic cluster of inclusions of size a and density 1 a-2 strictly inside . For frequencies ω tuned to an eigenvalue of the elastic Newton (Kelvin) operator of a single inclusion, we show that as a0 and the number of inclusions M∞, the Neumann-to-Dirichlet map D converges to an effective map P corresponding to a background density shift -P2, with the operator norm estimate \|D-P\| CaαP6 for some α>0 determined by the geometric scaling. Around this negative background we derive a first-order linearization of P in terms of and the Newton volume potential for the shifted Lam\'e operator. Testing the linearized relation with complex geometric optics solutions yields an explicit reconstruction formula for the Fourier transform of , and hence a global density recovery scheme. The results provide a metamaterial-inspired analytic framework for inverse coefficient problems in linear elasticity and a concrete paradigm for leveraging nanoscale resonators in reconstruction algorithms.