Multipole engineering for enhanced backscattering modulation

D. Dobrykh, D. Shakirova, S. Krasikov, A. Mikhailovskaya, I. Yusupov, A. Slobozhanyuk, K. Ladutenko, D. Filonov, A. Bogdanov, P. Ginzburg
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引用次数: 11

Abstract

An efficient modulation of backscattered energy is one of the key requirements for enabling efficient wireless communication channels. Typical architectures, being based on either electronically or mechanically modulated reflectors, cannot be downscaled to subwavelengths dimensions by design. Here we show that integrating high-index dielectric materials with tunable subwavelength resonators allows achieving an efficient backscattering modulation, keeping a footprint of an entire structure small. An interference between high-order Mie resonances leads to either enhancement or suppression of the backscattering, depending on a control parameter. In particular, a ceramic core-shell, driven by an electronically tunable split ring resonator was shown to provide a backscattering modulation depth as high as tens of the geometrical cross-section of the structure. The design was optimized towards maximizing reading range of radio frequency identification (RFID) tags and shown to outperform existing commercial solutions by orders of magnitude in terms of the modulation efficiency. The proposed concept of multipole engineering allows one to design a new generation of miniature beacons and modulators for wireless communication needs and other relevant applications.
增强后向散射调制的多极工程
有效调制后向散射能量是实现高效无线通信信道的关键要求之一。基于电子或机械调制反射器的典型结构,无法通过设计缩小到亚波长尺寸。在这里,我们展示了将高折射率介电材料与可调谐亚波长谐振器集成可以实现有效的后向散射调制,保持整个结构的占地面积小。高阶Mie共振之间的干扰会导致后向散射的增强或抑制,这取决于控制参数。特别是,由电子可调谐劈裂环谐振器驱动的陶瓷核壳可以提供高达结构几何截面数十倍的后向散射调制深度。该设计旨在最大化射频识别(RFID)标签的读取范围,并在调制效率方面优于现有商业解决方案的数量级。提出的多极工程概念允许人们设计新一代微型信标和调制器,以满足无线通信需求和其他相关应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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