Distribution of particles which produces a "smart" material

Abstract

If Aq(β, α, k) is the scattering amplitude, corresponding to a potential q∈ L2(D), where D⊂3 is a bounded domain, and eikα · x is the incident plane wave, then we call the radiation pattern the function A(β):=Aq(β, α, k), where the unit vector α, the incident direction, is fixed, and k>0, the wavenumber, is fixed. It is shown that any function f(β)∈ L2(S2), where S2 is the unit sphere in 3, can be approximated with any desired accuracy by a radiation pattern: ||f(β)-A(β)||L2(S2)<ε, where ε>0 is an arbitrary small fixed number. The potential q, corresponding to A(β), depends on f and ε, and can be calculated analytically. There is a one-to-one correspondence between the above potential and the density of the number of small acoustically soft particles Dm⊂ D, 1≤ m≤ M, distributed in an a priori given bounded domain D⊂3. The geometrical shape of a small particle Dm is arbitrary, the boundary Sm of Dm is Lipschitz uniformly with respect to m. The wave number k and the direction α of the incident upon D plane wave are fixed.It is shown that a suitable distribution of the above particles in D can produce the scattering amplitude A(α',α), α',α∈ S2, at a fixed k>0, arbitrarily close in the norm of L2(S2× S2) to an arbitrary given scattering amplitude f(α',α), corresponding to a real-valued potential q∈ L2(D).

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