Journal of South China University of Technology(Natural Science) >
Study on Third-Order Wide Band Miniaturized Element Frequency Selective Surface with an Ultra Wide Stopband
Received date: 2021-12-06
Online published: 2022-05-09
Supported by
the National Natural Science Foundation of China(62003262);the Natural Science Foundation of Shaanxi Province(2019JQ-341)
In view of the problems of large area, narrow bandwidth, low stopband rejection and narrow stopband of frequency selective surface unit, this paper proposed a novel third-order ultra wide stopband miniaturized frequency selective surface element based on three symmetrical interdigital microstrip metal layer, square metal layer coupled loop and four dielectric layer. The symmetrical interdigital structures is equivalent to capacitance, the square coupling rings is equivalent to inductor, and the dielectric layer is equivalent to short lines. The hybrid parameter equivalent circuit with lumped and distributed parameters was obtained. According to the circuit theory, the frequency response characteristics of the third-order Chebyshev band pass filter and the frequency characteristics of the ultra wide band stopband were calculated. The third-order frequency selective surface was designed by combining the circuit theory calculation with the electromagnetic simulation software HFSS. The results of the theoretical calculation are in agreement with those of the electromagnetic simulation software HFSS, and has a frequency response characteristic curve of third-order band-pass filter and ultra wide stopband. The size of the ultra wide stopband mi-niaturized frequency selective surface element is 6 mm×6 mm, and the thickness is 7 mm. A 41×41 third-order wide band miniaturized element frequency selective surface was machined and tested. The measured center frequency is 2.48 GHz, the relative bandwidth is 11.2%, the in-band insertion loss is less than 0.5 dB, the return loss is greater than 18 dB, the stopband exceeds 55 GHz, and the rejection in the stopband is greater than 25 dB in the frequency range from 2.8 GHz to 55 GHz. It has good frequency stability in the angle of incidence from 0° to 70°. The experimental results are in good agreement with the simulation results, indicating that the design method and the structure of the three-order frequency selective surface adopted in this paper are correct.
ZHENG Guangming, ZHANG Yandong, LONG Yifei . Study on Third-Order Wide Band Miniaturized Element Frequency Selective Surface with an Ultra Wide Stopband[J]. Journal of South China University of Technology(Natural Science), 2022 , 50(10) : 80 -86 . DOI: 10.12141/j.issn.1000-565X.210774
| 1 | MUNK B A. Frequency selective surfaces:Theory and design [M].New York:Wiley-Interscience,2000. |
| 2 | MONACELLI B, PRYOR J B, MUNK B A,et al .Infrared frequency selective surface based on circuit-analog square loop design [J].IEEE Transactions Antennas Propagation,2005,53(2):745-752. |
| 3 | BOSSARD J A .The design and fabrication of planar multiband metallo dielectric frequency selective surfaces for infrared applications [J].IEEE Transactions Antennas Propagation,2006,54(4):1265-1276. |
| 4 | KIANI G I, OLSSON L G, KARLSSON A,et al .Transmission of infrared and visible wavelengths through energy-saving glass due to etching of frequency-selective surfaces [J].IET Microwave Antennas Propagation,2010,4(7):955-961. |
| 5 | SAEIDI C, WEIDE D V .Nanoparticle array based optical frequency selective surfaces:Theory and design [J].Optic Express,2013,21(13):16170-16180. |
| 6 | BEHDAB N .A second-order band-pass frequency selective surface using non-resonant sub-wavelength periodic structures [J].Microwave Optical Technology Letter,2008,50(6):1639-1643. |
| 7 | MONORCHIO A, MANARA G, LANUZZA L .Synthesis of artificial magnetic conductors by using multilayered frequency selective surfaces [J].IEEE Antennas Wireless Propagation Letter,2005,1(1):196-199. |
| 8 | HIRANANDANI M A, YAKOVLEY A B, KISHK A A .Artificial magnetic conductors realized by frequency selective surfaces on a grounded dielectric slab for antenna applications [J].IEEE Antennas and Propagation,2006,53(5):487-493. |
| 9 | JOUMAYLY M A, BEHDAD N .Wideband planar microwave lenses using sub-wavelength spatial phase shifters [J].IEEE Transactions on Antennas and Propagation,2011,59(12):4542-4552. |
| 10 | LI M, JOUMAYLY M A, BEHDAD N .Broadband true-time-delay microwave lenses based on miniaturized element frequency selective surfaces [J].IEEE Transactions on Antennas and Propagation,2013,61(3):1166-1179. |
| 11 | LI M, BEHDAD N. Wide band true-time-delay microwave lenses based on metallo dielectric and all-dielectric low pass frequency selective surfaces [J].IEEE Transactions on Antennas and Propagation,2013,61(8):4109-4119. |
| 12 | ABADI S M A M H, BEHDAD N .Design of wideband,FSS-based multibeam antennas using the effective medium approach [J].IEEE Transactions on Antennas and Propagation,2014,62(11):5557-5564. |
| 13 | ENCINAR J A. Design of two-layer printed reflect arrays using patches of variable size [J].IEEE Transactions on Antennas and Propagation,2001,49(10):1403-1410. |
| 14 | ABADI S M A M H, GHAEMI K .Ultra-wide band,true-time-delay reflectarray antennas using ground plane backed,miniaturized-element frequency selective surfaces [J].IEEE Transactions on Antennas and Propagation,2015,63(2):534-542. |
| 15 | ABADI S M A M H, LI M, BEHDAD N .Harmonic-suppressed miniaturized-element frequency selective surfaces with higher order bandpass responses [J].IEEE Transactions on Antennas and Propagation,2014,62(5):2562-2571. |
| 16 | SUNG G, SOWERBY K W, NEVE M J,et al .A frequency selective wall for interference reduction in wireless indoor environments [J].IEEE Antennas Propagation Magazine,2006,48(5):29-37. |
| 17 | KIANI G, FORD K L, OLSSON L G .Switchable frequency selective surface for reconfigurable electromagnetic architecture of buildings [J].IEEE Transactions on Antennas and Propagation,2010,58(2):581-584. |
| 18 | BEHDAD N, AL-JOUMAYLY M, SALEHI M .A low-profile third-order band pass frequency selective surface [J].IEEE Transactions on Antennas and Propagation,2009,57(2):460-466. |
| 19 | ABADI S M A M H, BEHDAD N .Inductively-coupled miniaturized-element frequency selective surfaces with narrow band,high-order bandpass responses [J].IEEE Transactions on Antennas and Propagation,2015,63(11):4766-4774. |
| 20 | ABADI S M A M H, LI M, BEHDAD N .Harmonic-suppressed miniaturized-element frequency sele-ctive surfaces with higher order bandpass responses [J].IEEE Transactions on Antennas and Propagation,2014,62(5):2562-2571. |
| 21 | LI M, BEHDAD N .A third-order bandpass frequency selective surface with a tunable transmission null [J].IEEE Transactions on Antennas and Propagation,2012,60(4):2109-2113. |
| 22 | BEHDAD N, AL-JOUMAYLY M, SALEHI M .A low-profile third-order bandpass frequency selective surface [J].IEEE Transactions on Antennas and Propagation,2009,57(2):460-466. |
| 23 | HUSSEIN M, ZHOU J, HUANG Y,et al .A Low-profile miniaturized second-order bandpass frequency selective surface [J].IEEE Antennas and Wireless Propagation Letters,2017,16(10):2791-2794. |
| 24 | 郑光明,王雪纯,汪岩 .小型化宽阻带多层宽带频率选择表面研究 [J].华中科技大学学报(自然科学版),2020,48(8):57-60. |
| 24 | ZHENG Guang-ming, WANG Xue-chun, WANG Yan .Study on miniaturized ultra wide stopband multilayer broadband frequency [J].Journal of Huazhong University of Science and Technology(Natural Science Edition),2020,48(8):57-60. |
| 25 | LUO G Q, HOMG W, LAI Q H,et al .Design and experimental verification of compact frequency selective surface with quasi-elliptic bandpass response [J].IEEE Transactions Microwave Theory Techniques,2007,55(12):2481-2487. |
| 26 | ZHOU H .Narrowband frequency selective surface based on substrate integrated waveguide technology [J].Progress Electromagnetic Research Letter,2011,22(3):19-28. |
| 27 | XU G, ELEFTHERIADES G V, HUM S V .Generalized synthesis technique for high-order low-profile dual-band frequency selective surfaces [J].IEEE Transactions on Antennas and Propagation,2018,66(11):6033-6042. |
| 28 | 郑光明,张兵兵,汪岩,等 .宽阻带二阶带通频率选择表面研究 [J].华中科技大学学报(自然科学版),2021,49(8):70-74. |
| 28 | ZHENG Guangming, ZHANG Bingbing, WANG Yan,et al .Study on wide stopband second-order bandpass frequency selective surface [J].Journal of Huazhong University of Science and Technology(Natural Science Edition),2021,49(8):70-74. |
| 29 | ZHENG G M, LIN W G .An ultra-wide stopband micro strip bandpass filter [J].Microwave and Optical Technology Letters,2010,52(10):2218-2221. |
| 30 | ZHENG G M, LIN W G .Study of an ultra-wide stopband mirostrip bandpass filter with half asymmetric stepped impedance open stub resonators [J].Microwave and Optical Technology Letters,2010,52(4):845-847. |
| 31 | TANG C, HSU Y .A microstrip bandpass filter with ultra-wide stopband [J].IEEE Transactions on Microwave Theory and Techniques,2008,56(6):1468-1472. |
| 32 | MATTHAEI G L, YOUNG L, JONES E M .Design of microwave filters,impedance matching networks,and coupling structures [M].Norwood,MA:Artech House,1980. |
| 33 | LUUKKONEN O .Simple and accurate analytical model of planar grids and high-impedance surfaces comprising metal strips or patches [J].IEEE Transactions on Antennas and Propagation,2008,56(6):1624-1632. |
/
| 〈 |
|
〉 |