Intelligent metasurface imager and recognizer

Li, Lianlin; Shuang, Ya; Ma, Qian; Li, Haoyang; Zhao, Hanting; Wei, Menglin; Liu, Che; Hao, Chenglong; Qiu, Cheng‐Wei; Cui, Tie Jun

doi:10.1038/s41377-019-0209-z

Cited by 276 publications

(207 citation statements)

References 49 publications

(50 reference statements)

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“…AI systems, in combination with sensors, cameras and other data collection devices, have been developed to monitor the health and wellbeing of individuals [70,87]. Machine learning techniques can be used to improve the cost and efficiency of fall detection devices [99], and detect changes in sleep, mood, heartbeat, respiration, and other vital signs [118,129]. Wearable devices, or 'smart textiles, enabled by AI, can detect changes in the human body and report findings to health care providers [129].…”

Section: Ai In the Society Dimension Of Smart Citiesmentioning

confidence: 99%

Contributions and Risks of Artificial Intelligence (AI) in Building Smarter Cities: Insights from a Systematic Review of the Literature

et al. 2020

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Artificial intelligence (AI) is one of the most disruptive technologies of our time. Interest in the use of AI for urban innovation continues to grow. Particularly, the rise of smart cities—urban locations that are enabled by community, technology, and policy to deliver productivity, innovation, livability, wellbeing, sustainability, accessibility, good governance, and good planning—has increased the demand for AI-enabled innovations. There is, nevertheless, no scholarly work that provides a comprehensive review on the topic. This paper generates insights into how AI can contribute to the development of smarter cities. A systematic review of the literature is selected as the methodologic approach. Results are categorized under the main smart city development dimensions, i.e., economy, society, environment, and governance. The findings of the systematic review containing 93 articles disclose that: (a) AI in the context of smart cities is an emerging field of research and practice. (b) The central focus of the literature is on AI technologies, algorithms, and their current and prospective applications. (c) AI applications in the context of smart cities mainly concentrate on business efficiency, data analytics, education, energy, environmental sustainability, health, land use, security, transport, and urban management areas. (d) There is limited scholarly research investigating the risks of wider AI utilization. (e) Upcoming disruptions of AI in cities and societies have not been adequately examined. Current and potential contributions of AI to the development of smarter cities are outlined in this paper to inform scholars of prospective areas for further research.

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Section: Ai In the Society Dimension Of Smart Citiesmentioning

confidence: 99%

Contributions and Risks of Artificial Intelligence (AI) in Building Smarter Cities: Insights from a Systematic Review of the Literature

et al. 2020

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“…[6,7] However, in most of these strategies, the metasurfaces are designed for a specific application and their scattering program remains unchanged after being fabricated. Digital metasurfaces accompanied by reprogrammable functionalities furnish a wider range of wave-matter functionalities which renders them especially appealing in the applications of imaging, [8] smart surfaces, [9] and dynamical THz wavefront manipulation. [10] All the above mentioned digital programmable architectures are spacecoding metasurfaces wherein the coding sequences are generally fixed in time and are controlled through a computerprogrammed biasing networks only to switch the functionalities whenever needed.…”

Section: Introductionmentioning

confidence: 99%

Full Manipulation of the Power Intensity Pattern in a Large Space‐Time Digital Metasurface: From Arbitrary Multibeam Generation to Harmonic Beam Steering Scheme

Shabanpour

2020

Annalen der Physik

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Beyond the scope of space-coding metasurfaces, space-time digital metasurfaces can substantially expand the application scope of digital metamaterials. In this paper, by adopting a superposition operation of terms with unequal coefficients, Huygens' principle, and a proper time-varying biasing mechanism, some useful closed-form formulas in the class of large digital metasurfaces are presented for predicting the absolute directivity of scatted beams. Moreover, in the harmonic beam steering scheme, by applying several suitable assumptions, two separate expressions are derived for calculating the exact total radiated power at harmonic frequencies and total radiated power for scattered beams located at the end-fire direction. Despite the simplifying assumptions applied, it is proved that the provided formulas can still be a good and fast estimate for developing a large digital metasurface with a predetermined power intensity pattern. The effect of quantization level and metasurface dimensions as well as the limitation on the maximum scan angle in harmonic beam steering are addressed. Several demonstrative examples numerically demonstrated through MATLAB software and the good agreement between simulations and theoretical predictions are observed. The author believes that the proposed straightforward approach discloses a new opportunity for various applications such as multiple-target radar systems and communication.

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“…One possible approach to achieve the required spatial phasers is the artificial surfaces, [ 20,21 ] or metasurfaces, which comprise periodic or quasi‐periodic arrays of subwavelength elements. They can alter the amplitude, phase, and polarization responses of the incident waves, and thus offer ideal toolkit to realize numerous functions, such as polarization conversion, [ 22 ] subwavelength imaging, [ 23 ] and hologram generation. [ 24,25 ] Since the advent of artificial surfaces, a series of metasurface‐based signal processing devices, such as integrator, [ 26 ] equation solver, [ 27 ] and spatial filter, [ 28 ] have been implemented in spatial domain and considered as promising candidates for future optical analogue computing systems.…”

Section: Introductionmentioning

confidence: 99%

Metasurface‐Based Spatial Phasers for Analogue Signal Processing

Chen

Cheng

Xia

et al. 2020

Advanced Optical Materials

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A dispersive delay structure, or phaser, is an integral part of analogue signal processor. A phaser is a circuit, whose group delay can be engineered to obtain the desired response as a function of frequency. Traditionally, phasers have been implemented in circuits or waveguide structures, but they can never deal with electromagnetic waves in free space due to limitation of natural materials. To resolve this drawback, a novel metasurface‐based structure, spatial phaser, for analogue signal processing in the spatial domain is proposed. A general design theory is put forward to realize the spatial phaser for manipulating the dispersive delay of electromagnetic waves. To demonstrate this method, three spatial phasers with different group‐delay responses are elaborately devised and a prototype that exhibits a positive‐triangular group delay from 8 to 10 GHz is fabricated. The experimental and simulation results show good agreement. This work will facilitate the development of real‐time analogue signal processing in spatial domain for applications in radars, electronic countermeasures, and other related areas.

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Intelligent metasurface imager and recognizer

Cited by 276 publications

References 49 publications

Contributions and Risks of Artificial Intelligence (AI) in Building Smarter Cities: Insights from a Systematic Review of the Literature

Contributions and Risks of Artificial Intelligence (AI) in Building Smarter Cities: Insights from a Systematic Review of the Literature

Full Manipulation of the Power Intensity Pattern in a Large Space‐Time Digital Metasurface: From Arbitrary Multibeam Generation to Harmonic Beam Steering Scheme

Metasurface‐Based Spatial Phasers for Analogue Signal Processing

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