Direct Synthesis of Metasurfaces for Efficient Space- to Surface-Wave Conversion and Beamforming

IF 4.6 1区 计算机科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Transactions on Antennas and Propagation Pub Date : 2024-09-11 DOI:10.1109/TAP.2024.3454826
Talha Arshed;Stefano Maci;Enrica Martini
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Abstract

This article presents an accurate analytical-based approach for the synthesis of modulated metasurfaces (MTSs) that efficiently convert an arbitrary impinging field into a surface wave (SW) with a given wavenumber and convert a given SW into an arbitrary amplitude-phase shaped aperture leaky wave (LW) that produces a desired radiation pattern. The considered MTSs consist of dense metallic claddings printed over a dielectric slab, which are modeled through homogenized penetrable impedance boundary conditions (PIBCs). The desired conversion is obtained through a proper locally periodic modulation of the PIBC, whose profile is designed through an effective systematic procedure based on analytical formulas. These latter are derived from the Floquet-wave (FW) expansion of fields and currents over the sinusoidally modulated impedance surface that locally matches the actual structure. This approach provides an accurate control of both the amplitude and phase of the aperture field, which allows for high conversion efficiencies and a general radiation pattern. Another advantage of the proposed analytically driven procedure is that it leads to impedance profiles with smooth spatial variations, which can be easily implemented through subwavelength patches of variable size. The effectiveness of the procedure is demonstrated by designing MTSs that couple SWs and space waves (SPWs) in different scenarios. Moreover, MTSs are designed, which first convert the impinging signal into an SW and then convert it back to an SPW with prescribed characteristics. This latter example can find application in future smart radio environments (SREs), making it a valid alternative to reflecting intelligent surfaces (RISs).
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直接合成元表面以实现高效的空间波到表面波转换和波束成形
本文介绍了一种基于精确分析的方法,用于合成调制元表面(MTS),它能有效地将任意入射场转换成具有给定波数的表面波(SW),并将给定的 SW 转换成任意振幅相位的孔径泄漏波(LW),从而产生所需的辐射模式。所考虑的 MTS 由印制在介质板上的致密金属包层组成,通过均匀化可穿透阻抗边界条件 (PIBC) 进行建模。通过对 PIBC 进行适当的局部周期性调制,可以获得所需的转换。后者由正弦调制阻抗面上的场和电流的 Floquet-wave (FW) 扩展推导得出,与实际结构局部匹配。这种方法可精确控制孔径场的振幅和相位,从而实现高转换效率和一般辐射模式。建议的分析驱动程序的另一个优点是,它能产生具有平滑空间变化的阻抗剖面,可以通过尺寸可变的亚波长贴片轻松实现。通过设计在不同情况下耦合 SW 波和空间波 (SPW) 的 MTS,证明了该程序的有效性。此外,还设计了 MTS,首先将冲击信号转换为 SW,然后再将其转换回具有规定特性的 SPW。后一个例子可应用于未来的智能无线电环境(SRE),使其成为反射智能表面(RIS)的有效替代品。
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来源期刊
CiteScore
10.40
自引率
28.10%
发文量
968
审稿时长
4.7 months
期刊介绍: IEEE Transactions on Antennas and Propagation includes theoretical and experimental advances in antennas, including design and development, and in the propagation of electromagnetic waves, including scattering, diffraction, and interaction with continuous media; and applications pertaining to antennas and propagation, such as remote sensing, applied optics, and millimeter and submillimeter wave techniques
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Table of Contents IEEE Transactions on Antennas and Propagation Publication Information IEEE Transactions on Antennas and Propagation Information for Authors Institutional Listings Table of Contents
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