A Review of Metasurfaces for Microwave Energy Transmission and Harvesting in Wireless Powered Networks

Eteng, Akaa Agbaeze; Goh, Hui Hwang; Rahim, Sharul Kamal Abdul; Alomainy, Akram

doi:10.1109/access.2021.3058151

Cited by 36 publications

(10 citation statements)

References 139 publications

(159 reference statements)

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“…The metasurface is efficient over a broad input power range when various diodes are used. According to recent research achievements, Metamaterial will play an essential role in ambient RF energy harvesting and wireless power transmission in near future with greater progress in miniaturization, higher efficiencies, lower sensitivity thresholds and other exciting features [215]. 4.…”

Section: Metamaterials Arraymentioning

confidence: 99%

A Review on Antenna Technologies for Ambient RF Energy Harvesting and Wireless Power Transfer: Designs, Challenges and Applications

et al. 2022

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Radio frequency energy harvesting (RFEH) and wireless power transmission (WPT) are two emerging alternative energy technologies that have the potential to offer wireless energy delivery in the future. One of the key components of RFEH or WPT system is the receiving antenna. The receiving antenna's performance has a considerable impact on the power delivery capability of an RFEH or WPT system. This paper provides a well-rounded review of recent advancements of receiving antennas for RFEH and WPT. Antennas discussed in this paper are categorized as low-profile antennas, multi-band antennas, circularly polarized antennas, and array antennas. A number of contemporary antennas from each category are presented, compared, and discussed with particular emphasis on design approach and performance. Current design and fabrication challenges, future development, open research issues of the antennas and visions for RFEH and WPT are also discussed in this review.

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Section: Metamaterials Arraymentioning

confidence: 99%

A Review on Antenna Technologies for Ambient RF Energy Harvesting and Wireless Power Transfer: Designs, Challenges and Applications

et al. 2022

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“…Microwave wireless energy transfer systems have overcome the limitations of batteries and transmission lines and are now prevalent in many fields including biomedical, aerospace, and radar communication. Additionally, they are minimally affected by environmental factors and terrain, promising a wide range of future applications [ 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 ]. The main microwave frequency in the Chinese environment is 2.45 GHz, but the energy density is mostly in the region of weak energy density, and the value of the input power that can be received is less than 0 dBm.…”

Section: Introductionmentioning

confidence: 99%

Novel Ge-Based Plasma TFET with High Rectification Efficiency for 2.45 GHz Microwave Wireless Weak Energy Transmission

Liu,

Bi,

Song

2024

Micromachines

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The enhancement of rectification efficiency in 2.45 GHz microwave wireless weak energy transmission systems is centred on rectifier device selection. The overall rectification efficiency of traditional rectifier devices is low in weak energy density situations, failing to fulfil the commercial requirements of this region. The subthreshold swing of the emerging device TFET exceeds 60 mV/dec, which has the advantages of a large open-state current and a small off-state current in the corresponding region of the weak energy density. In view of this, this paper designs a double-gate plasma rectifier TFET with an embedded n+ heavily doped layer on the basis of a PNPN-structured TFET, where the device is simulated with the MixedMode module of Silvaco TCAD 2018, the rectification efficiency at −10 dBm is 44.12%, which is 10.61% higher than that of the PNPN-TFET, and the efficiency in the weak energy density region is generally 10% or more than that of commercial HSMS devices, showing obvious rectification advantages.

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“…The low efficiency of wireless power transfer (WPT) systems compared to the wired ones inevitably limits their wider incorporation in modern telecommunication applications. It is proved, however, that a relatively high efficiency can be achieved by means magnetic resonance coupling (Kurs, 2007; Sun et al , 2018; Shaw and Mitra, 2019; Lee and Yoon, 2020; Eteng et al , 2021; Huang et al , 2021). Moreover, extra efficiency and operational distance improvement may be further obtained via resonant-type metamaterials and metasurfaces, which can confine magnetic fields into the region between transmitting and the receiving part of the WPT system (Wang et al , 2020; Lu et al , 2021; Shi et al , 2021; Aboualalaa et al , 2022; Shan et al , 2022; Xue et al , 2022; Zhou et al , 2022; Zheng et al , 2022).…”

Section: Introductionmentioning

confidence: 99%

Enhanced WPT structures via EC-SRR-based metasurfaces

Karatzidis

Zygiridis

Kantartzis

2023

COMPEL

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Purpose The purpose of this paper is to present a family of robust metasurface-oriented wireless power transfer systems with improved efficiency and size compactness. The effect of geometric and structural features on the overall efficiency and miniaturisation is elaborately studied, while the presence of substrate losses is, also, considered. Moreover, to further enhance the performance, possible means for reducing the operating frequency, without comprising the unit-cell size, are proposed. Design/methodology/approach The key element of the design technique is the edge-coupled split-ring resonators patterned in various metasurface configurations and optimally placed to increase the total efficiency. To this goal, a rigorous three-dimensional algorithm, launching a new high-order prism macroelement, is developed in this paper for the fast evaluation of the required quantities. The featured scheme can host diverse approximation orders, while it is drastically more economical than existing methods. Hence, the demanding wireless power transfer systems are precisely modelled via reduced degrees of freedom, without the need to conduct large-scale simulations. Findings Numerical results, compared with measured data from fabricated prototypes, validate the design methodology and prove its competence to provide enhanced metasurface wireless power transfer systems. An assortment of optimized 3 x 3 and 5 x 5 metamaterial setups is investigated, and interesting deductions, regarding the impact of the inter-element gaps, the distance between the transmitting and receiving components and the substrate losses, are derived. Also, the proposed vector macroelement technique overwhelms typical implementations in terms of computational burden, particularly when combined with the relevant commercial software packages. Originality/value Systematic design of advanced real-world wireless power transfer structures through optimally selected metasurfaces with fully controllable electromagnetic properties is presented. The analysis is performed by means of a rapid prism macroelement methodology, which leads to very confined meshes, accurate results and significantly reduced overhead. The selected metamaterial resonators are found to be very flexible and reconfigurable, even in the case of large substrate conductivity losses, whereas their contribution to the system’s total efficiency is decisive.

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A Review of Metasurfaces for Microwave Energy Transmission and Harvesting in Wireless Powered Networks

Cited by 36 publications

References 139 publications

A Review on Antenna Technologies for Ambient RF Energy Harvesting and Wireless Power Transfer: Designs, Challenges and Applications

A Review on Antenna Technologies for Ambient RF Energy Harvesting and Wireless Power Transfer: Designs, Challenges and Applications

Novel Ge-Based Plasma TFET with High Rectification Efficiency for 2.45 GHz Microwave Wireless Weak Energy Transmission

Enhanced WPT structures via EC-SRR-based metasurfaces

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