A Novel Triple Band Pass Frequency Selective Surface for the Proliferation the Performance of WiMax and WLAN 2.5/3.5/5.5 GHz

被引：0

作者：

Garg, Monika ^{[1
]}

Chahar, Rekha ^{[1
]}

Yadav, Sanjeev ^{[1
]}

机构：

[1] Govt Women Engn Coll Ajmer, Ajmer, India

来源：

OPTICAL AND WIRELESS TECHNOLOGIES, OWT 2017 | 2018年 / 472卷

关键词：

Three elements; Triple-band-pass frequency selective surface (FSS); WiMax and WLAN 2.5; 3.5; and 5.5 GHz band; RING;

D O I：

10.1007/978-981-10-7395-3_47

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

Among the upcoming wireless technologies, WiMax and WLAN provide soaring speed communication with full coverage. However due to assured factors like path loss, interference, and coverage area led to signal degradation. WiMax and WLAN have used different range of bands. But these bands suffer large path loss, so a band-pass frequency selective surface has been projected in this paper which led to escalation in the transmission of WiMax signal to reduce the effect of path loss. In the proposed design, a single-sided FR-4 substrate is inbuilt with the square and three elements that led to triple-band characteristics at 2.5, 3.5, and 5.5 GHz. The dielectric constant of substrate is 4.4, and dimension of substrate is 0.166 lambda x 0.166 lambda. Further, this paper has been realized with simulated results in CST Microwave Studio.

引用

页码：421 / 428

页数：8

共 40 条

[21] 2.5D Inductive Intertwined Frequency Selective Surface For Pass-Band Applications
Vasquez-Peralvo, Juan A.
Merlano Duncan, Juan Carlos
Gonzalez-Rios, Jorge Luis
Chatzinotas, Symeon
2023 INTERNATIONAL WORKSHOP ON ANTENNA TECHNOLOGY, IWAT, 2023,
[22] Novel Planar Band Pass Lump-Loaded Frequency Selective Surface
Liu, H.
Ford, K. L.
Langley, R. J.
2008 IEEE MIT-S INTERNATIONAL MICROWAVE WORKSHOP SERIES ON ART OF MINIATURIZING RF AND MICROWAVE PASSIVE COMPONENTS, 2008, : 87 - 89
[23] A Novel Third-Order Band-Pass Frequency Selective Surface for Ku Band Applications
Yang, Chenchen
Hussain, Tauseef
Li, Huangyan
Cao, Qunsheng
Wang, Yi
2016 IEEE INTERNATIONAL WORKSHOP ON ELECTROMAGNETICS: APPLICATIONS AND STUDENT INNOVATION COMPETITION (IWEM), 2016,
[24] Design of triple-band-pass frequency selective structure based on spoof surface plasmon polariton
Wang, Chao
Li, Yongfeng
Han, Yajuan
Feng, Maochang
Wang, Jiafu
Ma, Hua
Zhang, Jieqiu
Qu, Shaobo
AIP ADVANCES, 2018, 8 (09):
[25] 2.5D Inductive Intertwined Frequency Selective Surface for Band-Pass and High Miniaturization Applications
Vasquez-Peralvo, Juan Andres
Lasheras, Rocio Chueca
Duncan, Juan Carlos Merlano
Zhang, Shuai
Pechac, Pavel
Kabourek, Vaclav
Chatzinotas, Symeon
IEEE ACCESS, 2025, 13 : 22156 - 22165
[26] A Novel Millimeter Wave Band-pass Frequency Selective Surface Transparent to Infrared Wave
Zong, Zhiyuan
Wu, Wen
Shi, Lingfei
Fang, Dagang
2010 ASIA-PACIFIC INTERNATIONAL SYMPOSIUM ON ELECTROMAGNETIC COMPATIBILITY & TECHNICAL EXHIBITION ON EMC RF/MICROWAVE MEASUREMENTS & INSTRUMENTATION, 2010, : 162 - 165
[27] Design and characteristic analysis of uniplanar multiband frequency selective surface for GSM, LTE, WLAN, ISM, WiMAX and X-band applications
Kundu, Surajit
MICROWAVE AND OPTICAL TECHNOLOGY LETTERS, 2023, 65 (10) : 2721 - 2724
[28] A Triple Band Frequency Selective Surface Design for GSM Systems by Utilizing a Novel Synthetic Resonator
Kartal, M.
Golezani, J. J.
Doken, B.
IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION, 2017, 65 (05) : 2724 - 2727
[29] Dual Band/Wide Band Polarization Insensitive Modified Four-Legged Element Frequency Selective Surface for 2.4 GHz Bluetooth, 2.4/5.8 GHz WLAN Applications
Jain, Vandana
Yadav, Sanjeev
Peswani, Bhavana
Jain, Manish
Dadhich, Ajay
PROCEEDINGS OF FIRST INTERNATIONAL CONFERENCE ON INFORMATION AND COMMUNICATION TECHNOLOGY FOR INTELLIGENT SYSTEMS: VOL 1, 2016, 50 : 83 - 89
[30] Triple Bandstop 2.5D Frequency Selective Surface for Sub-6 GHz 5G Communication
Katoch, Kanishka
Jaglan, Naveen
Kanaujia, Binod Kumar
Chen, Pai-Yen
Kishk, Ahmed A.
IEEE TRANSACTIONS ON ELECTROMAGNETIC COMPATIBILITY, 2024, 66 (05) : 1420 - 1429

← 1 2 3 4 →