Demonstration of Spider‐Eyes‐Like Intelligent Antennas for Dynamically Perceiving Incoming Waves

Wang, Zhedong; Qian, Chao; Cai, Tong; Tian, Longwei; Fan, Zhixiang; Liu, Jian; Shen, Yichen; Li, Jing; Jin, Jian‐Ming; Li, Er‐Ping; Zheng, Bin; Chen, Hongsheng

doi:10.1002/aisy.202100066

Cited by 22 publications

(14 citation statements)

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“…A rabbit plays freely in front of the neuro-metamaterials under the illumination of a transverse electric plane wave, where the electric field is along the z axis. Meanwhile, three detectors (small monopole antennas) are connected to a series of miscellaneous components to perceive the EM strength (the amplitude of the electric field) at the output plane 37 ; see Methods and Supplementary Note 4 . Note that here all the electronic components are used only to illustrate the perception results for users utilizing microwave frequencies, whereas in visible frequencies the results can be seen with the naked eye.…”

Section: Resultsmentioning

confidence: 99%

“…A high-directivity lens antenna centered at the neuro- metamaterials was used as the excitation source. Three monopole probes, which we built ourselves, were connected to one RF switch (HMC641ALC4), collecting the amplitude signals from the three ports at microseconds 37 . The received signal was amplified by a broadband amplifier and down-converted by 6 GHz.…”

Section: Methodsmentioning

confidence: 99%

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Dynamic recognition and mirage using neuro-metamaterials

et al. 2022

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Breakthroughs in the field of object recognition facilitate ubiquitous applications in the modern world, ranging from security and surveillance equipment to accessibility devices for the visually impaired. Recently-emerged optical computing provides a fundamentally new computing modality to accelerate its solution with photons; however, it still necessitates digital processing for in situ application, inextricably tied to Moore’s law. Here, from an entirely optical perspective, we introduce the concept of neuro-metamaterials that can be applied to realize a dynamic object- recognition system. The neuro-metamaterials are fabricated from inhomogeneous metamaterials or transmission metasurfaces, and optimized using, such as topology optimization and deep learning. We demonstrate the concept in experiments where living rabbits play freely in front of the neuro-metamaterials, which enable to perceive in light speed the rabbits’ representative postures. Furthermore, we show how this capability enables a new physical mechanism for creating dynamic optical mirages, through which a sequence of rabbit movements is converted into a holographic video of a different animal. Our work provides deep insight into how metamaterials could facilitate a myriad of in situ applications, such as illusive cloaking and speed-of-light information display, processing, and encryption, possibly ushering in an “Optical Internet of Things” era.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Dynamic recognition and mirage using neuro-metamaterials

et al. 2022

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“…As schematically illustrated in Figure a, we guided the intelligent metasurfaces to generate illusive scattered waves, causing an observer to mistake them for another object, for example, a crocodile. To build a set of intelligent EM system, we made an intelligent EM detector composed of an 8‐port metasurface array for the simultaneous attainment of frequency, direction‐of‐arrival and polarization, covering the entire X‐band [ 40 ] (Supplementary Note 8). In conjunction with this EM detector, we can output the metasurface pattern in real time for an arbitrary illusive scattering requirement.…”

Section: Optical Illusion Experiments For In Situ Applicationmentioning

confidence: 99%

In Situ Customized Illusion Enabled by Global Metasurface Reconstruction

Jia

Qian

Fan

et al. 2022

Adv Funct Materials

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Optical illusion has always attracted extensive attention, as it provides a superior self‐protection ability for both natural animals and human beings. A decade ago, this motivated the study and application of transformation optics, which provides a universal tool to manipulate light for invisibility cloaking and optical illusion. However, mainstream transformation‐optics‐based optical illusions are inherently hindered by the extreme requirements of metamaterial compositions in practice and unfavorably limited by the very large computational cost caused by their bulky state. To overcome these grand challenges, a novel and intelligent optical illusion supported by form‐free metasurfaces via a deep learning architecture is reported, which can not only render a similar illusion effect but also greatly reduces the parameter space in physics. Illustrative examples of conformal metasurfaces are presented, with a high‐fidelity inverse design from either the near‐ or far‐field in the simulation and experiment. Furthermore, a full set of intelligent systems is developed to benchmark the real‐world optical illusion applicability. The work brings the available illusion strategies closer to a wide range of in situ practical‐oriented applications and lays a foundation for the next generation of intelligent metamaterials.

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“…As an example, the spider-eye-like antenna demonstrated in Ref. [181] is supplemented by a generalised regression neural network [202] to analyze the incoming waves (see Fig. 7(a)).…”

Section: Perspective and Outlookmentioning

confidence: 99%

“…ANN in this case explicitly imitates the work of a biological neural network, realizing a system similar to a vision system of a spider. (Adopted from Ref [181]…”

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confidence: 99%

Intelligent metaphotonics empowered by machine learning

Krasikov,

Tranter,

Bogdanov

et al. 2021

Preprint

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In the recent years, we observe a dramatic boost of research in photonics empowered by the concepts of machine learning and artificial intelligence. The corresponding photonic systems, to which this new methodology is applied, can range from traditional optical waveguides to nanoantennas and metasurfaces, and these novel approaches underpin the fundamental principles of light-matter interaction developed for a smart design of intelligent photonic devices. Concepts and approaches of artificial intelligence and machine learning penetrate rapidly into the fundamental physics of light, and they provide effective tools for the study of the field of metaphotonics driven by opticallyinduced electric and magnetic resonances. Here, we introduce this new field with its application to metaphotonics and also present a summary of the basic concepts of machine learning with some specific examples developed and demonstrated for metasystems and metasurfaces.

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Demonstration of Spider‐Eyes‐Like Intelligent Antennas for Dynamically Perceiving Incoming Waves

Cited by 22 publications

References 50 publications

Dynamic recognition and mirage using neuro-metamaterials

Dynamic recognition and mirage using neuro-metamaterials

In Situ Customized Illusion Enabled by Global Metasurface Reconstruction

Intelligent metaphotonics empowered by machine learning

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