Smart Metasurface for Active and Passive Cooperative Manipulation of Electromagnetic Waves

Jiang, Lixin; Li, Yongfeng; Zheng, Lin; Yuan, Qi; Zhu, Zhibiao; Wan, Weipeng; Wang, He; Pang, Yongqiang; Wang, Jiafu; Wang, Weiyu; Cui, Tiejun; Qu, Shaobo

doi:10.1021/acsami.2c15768

Cited by 15 publications

(6 citation statements)

References 37 publications

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“…shape, edge, and surface of an object to minimize reflections back to the radar, is one of the scattering methods [3]. Nonabsorptive metasurfaces (MSs) offer another approach by eliminating scattering between elements through equivalent amplitude and out-of-phase scattered waves [4][5][6][7][8]. On the other hand, radar absorbing materials are employed to absorb electromagnetic (EM) energy and convert it into heat, thereby reducing the RCS.…”

Section: Introductionmentioning

confidence: 99%

An efficient parameter-retrieval-based surrogate-assisted optimization of on-platform honeycomb absorbing structures

Yang,

Yu,

Cui

2024

J. Phys. D: Appl. Phys.

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An electromagnetic (EM) parameter-retrieval-based surrogate-assisted optimization (PSAO) algorithm is presented to reduce radar cross section (RCS) by optimizing the on-platform honeycomb absorbing structures. To facilitate the optimization process, the honeycomb structure is transformed to an anisotropic homogeneous slab, and the effective parameters of the slab are extracted by the retrieval algorithm. A multi-fidelity model is employed to reduce the computing-time consumption, in which a Gaussian process (GP) regression model is used as the substitute for the coarse model. The GP model establishes a relationship between the geometry of the honeycomb structure and the RCS response of the target coated with the equivalent slab. Finally, the optimization result of the fine model is achievedthrough a space mapping strategy. The accuracy of the parameter extraction algorithm is verified by analyzing the honeycomb absorbing structure. Subsequently, the proposed optimization method is applied to a metal plate and a metal cylinder, resulting in a 10dB reduction of RCS in broadband and wide-angle scenarios. This demonstrates the applicability of the proposed PSAO algorithm to both planar and conformal on-platform honeycomb absorbing structures. Furthermore, an NACA0015 oil is analyzed, showing an average RCS reduction of 10 dB and a minimum RCS reduction of 5dB in the X-band. These results indicate that the PSAO approach can effectively apply tocomplicated targets. Additionally, the proposed method exhibits significant advantages in terms of computational accuracy and efficiency compared to the traditional genetic algorithm.

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Section: Introductionmentioning

confidence: 99%

An efficient parameter-retrieval-based surrogate-assisted optimization of on-platform honeycomb absorbing structures

Yang,

Yu,

Cui

2024

J. Phys. D: Appl. Phys.

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“…Metasurfaces, a kind of two-dimensional artificially structured materials, − are engineered to obtain properties that have not yet been found in nature and have emerged as promising candidates for electromagnetic wave manipulations. − Owing to the unprecedented opportunities to manipulate electromagnetic characteristics, a variety of metasurfaces with different functions have been investigated and realized, such as absorber, , polarization converter, , OAM generation, − and wireless power transfer . However, the functionalities of these metasurfaces rely on the variations of the physical structures of meta-atoms, which are typically fixed once designed or fabricated.…”

Section: Introductionmentioning

confidence: 99%

Single-Layer Programmable Metasurface for Manipulating Both Linearly and Circularly Polarized Electromagnetic Waves

Tian,

Shi,

et al. 2024

ACS Appl. Opt. Mater.

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Programmable metasurfaces provide an innovative scenario to carry out promising control of electromagnetic waves. However, most works focus on the manipulation of only linearly polarized (LP) or circularly polarized (CP) waves, and multilayer configurations are typically desired due to the existence of direct current biasing networks. Here, a general strategy for designing programmable metasurfaces for the manipulation of both LP and CP waves is proposed and verified. As a result, the real-time programmable manipulation of quad-LP (x-polarized, y-polarized, upolarized, v-polarized) and dual-CP (right-hand, left-hand) waves could be achieved. Moreover, by placing both the direct current biasing network and the finely designed isolation circuit on top of the metasurface, only a single dielectric layer is required for such a programmable metasurface. As an example, a single-layer programmable metasurface consisting of 16 × 16 meta-atoms is designed, fabricated, and measured. The PIN diodes incorporated into each meta-atom are used as active components to provide a 1-bit reflective phase control. By shifting the working states of each PIN diode in the meta-atom, wide-angle beam scanning can be obtained. Both the simulated and measured results verify the capacity of the proposed strategy and demonstrate that the designed single-layer programmable metasurface exhibits stable beam scanning for both LP and CP waves, enabling promising applications in future wireless communications.

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“…[28][29][30][31] Due to these compelling features, metasurfaces have been widely introduced to explore the integrated control of radiated waves and reflected waves. In most radiation-reflection-integrated designs, metasurfaces are tactfully spliced, embedded, or stacked to traditional antennas, [32][33][34][35][36][37][38][39][40][41] where metasurfaces control reflected waves, and antennas control radiated waves. In addition, several other designs directly excite metasurface sub-arrays or each meta-element of metasurfaces to radiate EM waves by common feeding technics in antenna designs, [42][43][44][45][46] such as coaxial probe and gap coupling.…”

Section: Introductionmentioning

confidence: 99%

“…These designs all ingeniously combine design concepts of metasurfaces and antennas, realizing the integration of different radiation functions (high-gain radiation, [34,35] beam scanning, [39] polarization reconfiguration, [44] etc.) and reflection functions (radar-cross-section reduction, [32][33][34][35][36]38,[42][43][44][45] polarization conversion, [37,40,41] reflection field shaping, [39] etc.) on the same aperture.…”

Section: Introductionmentioning

confidence: 99%

Integrated Control of Radiations and In‐Band Co‐Polarized Reflections by a Single Programmable Metasurface

Tian

et al. 2023

Adv Funct Materials

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Integrated control of radiated and reflected electromagnetic (EM) waves is of great importance in information science and engineering, which are mostly achieved by elaborately integrating metasurfaces and antennas. However, most of the radiation‐reflection‐integrated designs remain difficulties to modulate the radiated waves directly without cascading additional radio‐frequency (RF) modules. More importantly, the completely independent control of radiated waves and in‐band co‐polarized reflected waves has rarely been achieved. Herein, direct, dynamic and integrated control of radiated waves and in‐band co‐polarized reflected waves is realized merely by a single programmable metasurface. The radiation‐reflection‐integrated programmable metasurface (RRIPM) can dynamically choose to radiate EM waves only or reflect incident EM waves only, and even dynamically modulate the radiation phases and reflection phases, thus realizing arbitrary radiation functions and in‐band co‐polarized reflection functions without crosstalk. To illustrate the capabilities of RRIPM, an ultra‐compact and broadband RRIPM prototype is designed and fabricated, and this is used for the radiation and reflection of multiple beams with arbitrary energy distributions, low‐gain‐fluctuation reflection‐beam scanning, and low‐side‐lobe‐level broadside radiation.

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Smart Metasurface for Active and Passive Cooperative Manipulation of Electromagnetic Waves

Cited by 15 publications

References 37 publications

An efficient parameter-retrieval-based surrogate-assisted optimization of on-platform honeycomb absorbing structures

An efficient parameter-retrieval-based surrogate-assisted optimization of on-platform honeycomb absorbing structures

Single-Layer Programmable Metasurface for Manipulating Both Linearly and Circularly Polarized Electromagnetic Waves

Integrated Control of Radiations and In‐Band Co‐Polarized Reflections by a Single Programmable Metasurface

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