• Title/Summary/Keyword: High-gain antenna

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Design of Cavity-Backed High Gain Dual Band Microstrip Antenna Using Frequency Selective Surface (FSS 구조를 이용한 Cavity-Backed 고이득 이중 대역 마이크로스트립 안테나 설계)

  • Kim, Byoung-Chul;Choo, Ho-Sung;Park, Ik-Mo
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.21 no.2
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    • pp.152-163
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    • 2010
  • In this paper, a cavity-backed high gain dual band microstrip antenna with Frequency Selective Surface space(FSS) for WLAN is proposed. The proposed antenna that operates in IEEE 802.11a/b bands with similar radiation pattern and gain is fabricated on RO4003 substrate with a dielectric constant of 3.38. The size of the antenna is $71.5{\times}42.0{\times}6.6\;mm^3$, and the FSS size is $120.0{\times}120.02\;mm^3$. The ground plane size including cavity is $150.0{\times}145.0\;mm^3$. The antenna is fed by coaxial cable. The simulated bandwidths of the antenna are 2.369~2.517 GHz and 5.608~5.833 GHz for VSWR<2. The gains are 11.23 dBi and 12.60 dBi, respectively, for the lower and upper bands.

Design and analyes of reconfigurable inset-fed microstrip patch antennas for wireless sensor Networks (무선 센서 네트워크용 주파수 조정이 가능한 마이크로 스트립 패치 안테나 설계 및 해석)

  • Phan, Duy Thach;Chung, Gwiy-Sang
    • Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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    • 2009.11a
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    • pp.129-129
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    • 2009
  • In this paper, a tunable microstrip patch antenna designed using RF MEMS switches is reported. The design and simulation antenna were performed using high frequency structure simulator (HFSS). The antenna was designed in ISM Band and operates simultaneously at 2.4 GHz and 5.7 GHz with a -10 dB return-loss bandwidth of 20 MHz and 180 MHz, respect-tively. To obtain high efficiency and improve integrated ability, the High Resistivity Silicon (HRS) wafer was used for the antenna. The antenna achieved high gain with 8 dB at 5.7 GHzand 1.5 dB at 2.4 GHz. The RF MEMS DC contact switches was simulated and analysis by ANSYS software.

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Design of a 4×4 Phased Array Antenna with High Sidelobe Charactericstic for Millimeter-Wave Band 5G Dedicated Network Services (밀리미터파 대역 5G 특화망 서비스를 위한 고부엽 특성의 4×4 위상배열안테나 설계)

  • Myeong-Jun Oh;Jung-Ick Moon;Jung-Nam Lee;Young-Bae Jung
    • Journal of IKEEE
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    • v.28 no.3
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    • pp.303-309
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    • 2024
  • This paper proposes a high-gain phased array antenna that can provide private network communication services for large office spaces, factories, and other large-scale facilities, specifically designed for millimeter-wave band 5G (5th generation) networks. The proposed antenna features a 4×4 array structure with eight sub-arrays, each consisting of a 1×2 series array. To achieve high side-lobe characteristics, an offset array structure is applied by shifting even-numbered rows by one unit, combined with power tapering to adjust the size of individual radiating elements. This design achieves a high side-lobe level (SLL) of 22.3 dB and a high gain of 18.1 dBi. Additionally, the antenna provides gain characteristics of at least 15.2 dBi and 17.4 dBi within the intended beam steering range of ±45° in the azimuth direction and ±10° in the elevation direction, ensuring smooth communication services over a wide service area.

The design of Horn array antenna for 28GHz millimeter wave band (28GHz 밀리미터파대역 혼 어레이 안테나 설계)

  • Jin, Duck-Ho;Lee, Je-Ho
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.26 no.11
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    • pp.1672-1678
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    • 2022
  • In this paper, the relay antenna was designed in consideration of the performance of the 28GHz band 5G mobile communication relay horn antenna, such as radiation pattern and return loss. A horn array for 5G mobile communication repeater was designed by arranging the antenna elements in phase, and the performance was analyzed. Unlike conventional WCDMA (3G) and LTE (4G), in millimeter wave band communication, high path loss occurs between transmission and reception. In the design of a 5G millimeter wave horn antenna, antenna performance such as isolation and gain between antenna elements as well as gain and bandwidth of the antenna must be additionally considered. The antenna gain of the single horn antenna (1×1) and the array horn antenna (2×4) in the 28GHz band is about 10.44d Bi and 19.58dBi, respectively, and the return loss is designed to be less than -18dB. It has proven its validity and has been shown to be suitable for application to 5G mobile communication relay system.

A High Gain Corrugated Horn Antenna with Dielectric Lens (유전체 렌즈가 삽입된 고이득 Corrugated 혼 안테나)

  • Lee, Hojoo;Choi, Jaehoon
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.27 no.5
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    • pp.486-489
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    • 2016
  • A horn antenna with corrugation structure and a PTFE(Polytetrafluoroethylene) teflon(relative permittivity=2.1) dielectric lens for good impedance matching characteristic and high gain performance is proposed in this paper. The proposed antenna shows measured return loss below -25 dB over the operating X band(8~12 GHz), the peak gain of 22.3 dBi at the center frequency(10 GHz) and has overall size of $110mm{\times}110mm{\times}135mm$. Considering the performance of the proposed antenna, it is suitable for being inserted in a radar level transmitters, particularly for gas tanks on vessels or off-shore plants containing gas with very low reflectivity and relative permittivity such as LNG or LPG.

Antenna Design with Vertically Structured Radiator for Increasing Bandwidth and Gain of the Mobile Phone Internal Antenna (휴대폰 내장 안테나의 대역폭과 이득 향상을 위한 수직 방사체를 가진 안테나 설계)

  • Lee, Jae-Ho;Lee, Kyung-Sub;Choi, Deuk-Su
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.22 no.9
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    • pp.881-887
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    • 2011
  • In this paper, we proposed vertically structured radiator for increasing bandwidth and gain of mobile phone internal antenna. The proposed antenna has vertically structured radiator instead of planar structured radiator to improve the antenna characteristics for GSM850/900 and DCS1800/PCS1900 bands. The antenna improve bandwidth of low band with 28 % than planar structured radiator. and also, improve bandwidth of high band with 14 %, efficiency 31.80~86.36 %, average gain -4.956~-0.617 dBi on the GSM850/900 and DCS1800/PCS1900 bands. These results are good performance among the small antenna with vertically structured radiator for increasing bandwidth and gain.

Fabrication of a Subminiature 3 Dimensional Antenna for the Mobile Phone Handset (이동 통신 단말기용 초소형 3차원 안테나 제작)

  • Hong, Min-Gi;Son, Tae-Ho
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.19 no.12
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    • pp.1455-1461
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    • 2008
  • We implemented a subminiature internal antenna that is around 1 cc volume for the mobile phone. The fundamental type of studied antenna is IFA(Inverted F Antenna), and this antenna is designed to be improved efficiency and gain due to minimum current cancellation by the avoidance of multiple bending pattern. For the implementation of multiple band, helix is applied to compensate for short antenna length for low frequency band, and a 3 dimensional pattern is used for high frequency band. We made two kinds of 3D structure antenna. One is a 1 cc volume antenna for GSM/DCS band on the bare board set, and the other is a 1.5 cc volume for the GSM/USPCS mobile phone set. Measurements showed good gain performance that average gain of two antenna on each band are $-3.46{\sim}-0.45\;dBi$ and $-4.80{\sim}-3.29\;dBi$ respectively.

Long Reading Range Yagi-Uda UHF RFID Tag Antennas with Small Back-Lobe (후엽이 작은 장거리 인식용 Yagi-Uda UHF RFID 태그 안테나 설계)

  • Lee, Kyoung-Hwan;Chung, You-Chung
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.18 no.11
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    • pp.1211-1216
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    • 2007
  • Yagi-Uda UHF RFID(Radio Frequency Identification) tag antennas with long reading range have been designed. According to ISO-18000, EIRP(Effective Isotropic Radiation Power) of reader and reader antenna is limited as 36 dBm. Therefore, the gain of a tag antenna should be high enough to extend the reading range. Yagi-Uda antenna has been applied to a UHF RFID tag antenna, and high gain and long reading range have been achieved. Three different of Yagi-Uda UHF antennas have been optimized to achieve the small size with low back-lobe patterns. The sizes, reading ranges and return loss of Yagi-Uda tag antennas are compared and measured.

Dual-Fed Small Repeater Antenna with High Isolation (높은 격리 특성을 갖는 이중 급전 방식 초소형 중계기용 안테나)

  • Seong, Cheol-Min;Jang, Jae-Su;Ha, Jae-Kwon;Park, Dong-Chul
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.23 no.6
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    • pp.661-668
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    • 2012
  • In this paper, a dual-fed small ICS repeater antenna with high isolation is designed, fabricated, and measured. Bandwidth and gain are optimized by changing the stub lengths near main patch and power divider, and also by changing the size of parasitic patch. To improve the isolation characteristic of the antenna, a dual-feeding method is applied in designing the antenna. The fabricated antenna has a VSWR less than 2, a gain over 7 dBi, and an isolation between the donor and the server antennas less than -65 dB from 1,920~2,170 MHz for 3G mobile communication.

Design of Wideband Circular polarized Patch Antenna for 1.6GHz band (1.6GHz대역용 광대역 원편파 패치 안테나 설계)

  • Kim, GunKyun;Rhee, Seung-Yeop;Yeo, Junho;Lee, Jong-Ig;Kang, NyoungHak
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • 2017.05a
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    • pp.61-62
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    • 2017
  • In this study, a circular polarization patch antenna operates at the wide bandwidth of 1.5GHz~1.7GHz was designed. To obtain the wide bandwidth and high gain, the high air substrate was applied. The impedance bandwidth is improved by adjusting the sizes of patch, the distance between main patch and ground plate, the length of internal slots, the position of feeding point, the length of external stub, etc. The antenna is designed by simulation for an operation in the frequency range of 1.5GHz~1.7GHz band, and the antenna characteristics such as return loss, gain, radiation patterns are examined.

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