Electromagnetic Band Gap and Artificial Magnetic Conductor and Their Application to the Patch Antenna

被引:0
作者
Zhou, Hongyuan [1 ]
Liu, Leilei [1 ]
Xu, Feng [1 ]
机构
[1] Nanjing Univ Posts & Telecommun, Sch Elect Sci & Engn, Nanjing, Jiangsu, Peoples R China
来源
PROCEEDINGS OF 2014 3RD ASIA-PACIFIC CONFERENCE ON ANTENNAS AND PROPAGATION (APCAP 2014) | 2014年
关键词
electromagnetic bandgap(EBG); artificial magnetic conductor; patch antenna; SUBSTRATE;
D O I
暂无
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
In this letter, the microstrip antenna with square patch array on the front surface and two-dimensional photonic band gap (PBG) on the ground has been proposed. The ground etching structure can suppress the resonance of the harmonic frequencies effectively of the antenna while the square patch array can increase the gain comparing with the normal microstrip patch antenna. The simulation and measurement results of this novel antenna are illustrated. The comparison of radiation patterns between this novel antenna, the microstrip antenna only with ground etching structure and the normal microstrip antenna is also presented.
引用
收藏
页码:236 / 239
页数:4
相关论文
共 50 条
[31]   Comparative investigation of reflection and band gap properties of finite periodic wideband artificial magnetic conductor surfaces for microwave circuits applications in X-band [J].
Malekpoor, Hossein .
INTERNATIONAL JOURNAL OF RF AND MICROWAVE COMPUTER-AIDED ENGINEERING, 2019, 29 (10)
[32]   Metamaterial superstrate and electromagnetic band-gap substrate for high directive antenna [J].
Xu, Huiliang ;
Zhao, Zeyu ;
Lv, Yueguang ;
Du, Chunlei ;
Luo, Xiangang .
INTERNATIONAL JOURNAL OF INFRARED AND MILLIMETER WAVES, 2008, 29 (05) :493-498
[33]   Metamaterial Superstrate and Electromagnetic Band-Gap Substrate for High Directive Antenna [J].
Huiliang Xu ;
Zeyu Zhao ;
Yueguang Lv ;
Chunlei Du ;
Xiangang Luo .
International Journal of Infrared and Millimeter Waves, 2008, 29 :493-498
[34]   Design of a textile antenna with artificial magnetic conductor for wearable applications [J].
Mersani, Ameni ;
Lotfi, Osman ;
Ribero, Jean-Marc .
MICROWAVE AND OPTICAL TECHNOLOGY LETTERS, 2018, 60 (06) :1343-1349
[35]   A Study on Electromagnetic Band Gap on Aperture Coupled Microstrip Antenna [J].
Alias, H. ;
Ali, M. T. ;
Ya'acob, N. ;
Ramli, N. ;
Sulaiman, M. A. ;
Kayat, S. Muhamud .
2012 IEEE ASIA-PACIFIC CONFERENCE ON APPLIED ELECTROMAGNETICS (APACE), 2012, :318-321
[36]   Analysis of adaptive antenna using electromagnetic band gap structure [J].
Talleb, H ;
Lautru, D ;
Hanna, VF .
MICROWAVE AND OPTICAL TECHNOLOGY LETTERS, 2006, 48 (02) :226-229
[37]   Microstrip Patch Antennas on Tunable Electromagnetic Band-Gap Substrates [J].
Liang, Jing ;
Yang, H. Y. David .
IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION, 2009, 57 (06) :1612-1617
[38]   A Dual-Band High-Gain Subwavelength Cavity Antenna with Artificial Magnetic Conductor Metamaterial Microstructures [J].
Lu, Guang ;
Yan, Fabao ;
Zhang, Kaiyuan ;
Zhao, Yunpeng ;
Zhang, Lei ;
Shang, Ziqian ;
Diao, Chao ;
Zhou, Xiachen .
MICROMACHINES, 2022, 13 (01)
[39]   A compact multiband frequency reconfigurable antenna integrated with sextuple band artificial magnetic conductor for heterogeneous wireless applications [J].
Rajavel, Vellaichamy ;
Ghoshal, Dibyendu .
FREQUENZ, 2025, 79 (3-4) :143-166
[40]   Enhancement of off-body communications with a low-SAR, high-gain multiband patch antenna designed with a quad-band artificial magnetic conductor [J].
Rajavel, Vellaichamy ;
Ghoshal, Dibyendu .
INTERNATIONAL JOURNAL OF MICROWAVE AND WIRELESS TECHNOLOGIES, 2024, 16 (02) :318-338
12345