Genetically Designed Wire Bundle Superscatterers

Konstantin Grotov; Dmytro Vovchuk; Sergei Kosulnikov; Ilya Gorbenko; Leon Shaposhnikov; Konstantin Ladutenko; Pavel Belov; Pavel Ginzburg

doi:10.1109/TAP.2022.3177531

Genetically Designed Wire Bundle Superscatterers

Konstantin Grotov, Dmytro Vovchuk, Sergei Kosulnikov, Ilya Gorbenko, Leon Shaposhnikov, Konstantin Ladutenko, Pavel Belov, Pavel Ginzburg

School of Electrical Engineering

Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

Experimental demonstration of superdirectivity and superscattering phenomena is among the long-standing challenges in electromagnetic theory. Efficient computational algorithms can contribute to this endeavor by suggesting new designs bypassing commonly accepted limitations. Here, we demonstrate a rectangular wire bundle superscatterer designed using a stochastic optimization algorithm. The structure encompassing wires of different lengths demonstrates superior scattering capabilities, bypassing the single channel dipole limit by an order of magnitude. The subwavelength wire bundle supports several resonant higher-order multipoles, which constructively contribute to the scattering, as we demonstrate experimentally. A new generation of genetically designed superscatterers may be used in a range of wireless applications, including point-to-point communications, smart beacons, and radar targets.

Original language	English
Pages (from-to)	9621-9629
Number of pages	9
Journal	IEEE Transactions on Antennas and Propagation
Volume	70
Issue number	10
DOIs	https://doi.org/10.1109/TAP.2022.3177531
State	Published - 1 Oct 2022

Keywords

Genetic algorithm
scattering limit
superscattering
wire bundle

All Science Journal Classification (ASJC) codes

Electrical and Electronic Engineering

Access to Document

10.1109/TAP.2022.3177531

Cite this

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title = "Genetically Designed Wire Bundle Superscatterers",

abstract = "Experimental demonstration of superdirectivity and superscattering phenomena is among the long-standing challenges in electromagnetic theory. Efficient computational algorithms can contribute to this endeavor by suggesting new designs bypassing commonly accepted limitations. Here, we demonstrate a rectangular wire bundle superscatterer designed using a stochastic optimization algorithm. The structure encompassing wires of different lengths demonstrates superior scattering capabilities, bypassing the single channel dipole limit by an order of magnitude. The subwavelength wire bundle supports several resonant higher-order multipoles, which constructively contribute to the scattering, as we demonstrate experimentally. A new generation of genetically designed superscatterers may be used in a range of wireless applications, including point-to-point communications, smart beacons, and radar targets.",

keywords = "Genetic algorithm, scattering limit, superscattering, wire bundle",

author = "Konstantin Grotov and Dmytro Vovchuk and Sergei Kosulnikov and Ilya Gorbenko and Leon Shaposhnikov and Konstantin Ladutenko and Pavel Belov and Pavel Ginzburg",

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AU - Grotov, Konstantin

AU - Vovchuk, Dmytro

AU - Kosulnikov, Sergei

AU - Gorbenko, Ilya

AU - Shaposhnikov, Leon

AU - Ladutenko, Konstantin

AU - Belov, Pavel

AU - Ginzburg, Pavel

PY - 2022/10/1

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N2 - Experimental demonstration of superdirectivity and superscattering phenomena is among the long-standing challenges in electromagnetic theory. Efficient computational algorithms can contribute to this endeavor by suggesting new designs bypassing commonly accepted limitations. Here, we demonstrate a rectangular wire bundle superscatterer designed using a stochastic optimization algorithm. The structure encompassing wires of different lengths demonstrates superior scattering capabilities, bypassing the single channel dipole limit by an order of magnitude. The subwavelength wire bundle supports several resonant higher-order multipoles, which constructively contribute to the scattering, as we demonstrate experimentally. A new generation of genetically designed superscatterers may be used in a range of wireless applications, including point-to-point communications, smart beacons, and radar targets.

AB - Experimental demonstration of superdirectivity and superscattering phenomena is among the long-standing challenges in electromagnetic theory. Efficient computational algorithms can contribute to this endeavor by suggesting new designs bypassing commonly accepted limitations. Here, we demonstrate a rectangular wire bundle superscatterer designed using a stochastic optimization algorithm. The structure encompassing wires of different lengths demonstrates superior scattering capabilities, bypassing the single channel dipole limit by an order of magnitude. The subwavelength wire bundle supports several resonant higher-order multipoles, which constructively contribute to the scattering, as we demonstrate experimentally. A new generation of genetically designed superscatterers may be used in a range of wireless applications, including point-to-point communications, smart beacons, and radar targets.

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JO - IEEE Transactions on Antennas and Propagation

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Genetically Designed Wire Bundle Superscatterers

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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