Kirigami-Inspired Linearly Polarized Reconfigurable 3-D Frequency-Selective Surface With Controllable Resonant Behavior

A linearly polarized reconfigurable 3-D frequency-selective surface (FSS) with controllable resonant behavior is proposed in this article. The reconfigurable performance relies on a kirigami-inspired deployable structure composed of crisscross substrates with mutually inverted notches. Four identica...

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Bibliographic Details
Published inIEEE transactions on microwave theory and techniques Vol. 72; no. 9; pp. 5193 - 5203
Main Authors Zhao, Li-Wei, Wu, Ya Fei, Fan, Yuhan, Guo, Yongxin
Format Journal Article
LanguageEnglish
Published New York IEEE 01.09.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Bandwidth
Controllability
Couplings
Current distribution
Frequency selective surfaces
Frequency stability
Frequency tuning
Frequency variation
kirigami-inspired periodic structure
Linear polarization
Notches
Optical ring resonators
Parallelograms
Periodic structures
Position measurement
reconfigurable frequency-selective surface (FSS)
Reconfiguration
Resonant frequencies
Resonant frequency
Substrates
Tuning
Unit cell
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Summary:A linearly polarized reconfigurable 3-D frequency-selective surface (FSS) with controllable resonant behavior is proposed in this article. The reconfigurable performance relies on a kirigami-inspired deployable structure composed of crisscross substrates with mutually inverted notches. Four identical asymmetric double-split ring resonators are, respectively, positioned on the four faces of the 3-D unit cell with a parallelogram cross section. Under the normal incidence, two resonant frequencies can be seen in the transmission coefficient. At each resonant frequency, there exist two different reconfiguration mechanisms that have inverse impacts on the shift direction of the resonant frequency in the process of deploying. The type and the dominance degree of the reconfiguration mechanism that has the dominant impact can be adjusted by changing the position of the splits, which implies controllability of the shift speed and direction of the resonant frequencies when the deploying angle changes. Finally, a reconfigurable FSS with stable center frequency is proposed through the two resonant frequencies being engineered to shift at a similar speed but in opposite directions with the deploying angle. The simulation results illustrate that the proposed FSS can achieve a continuously reconfigurable bandwidth in the range of 4.8% and 30.3% and a center frequency variation of less than 2.0%, while the same level of center frequency stability is also verified by measurement results.
ISSN:0018-9480
1557-9670
DOI:10.1109/TMTT.2024.3377528