Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors

Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors

A microstrip-to-slot line-fed miniaturized Vivaldi antenna using semicircular patch embedment is proposed in this study. The conventional Vivaldi antenna has ultrawide bandwidth, but suffers from low gain in the low-frequency band. The proposed antenna topology incorporates the embedment of semicirc...

Full description

Bibliographic Details
Main Authors: Jungwoo Seo, Jae Hee Kim, Jungsuek Oh
Format: Article
Language:English
Published: MDPI AG 2020-10-01
Series:Sensors
Subjects:
miniaturization methods
ultrawideband antennas
Vivaldi antennas
Online Access:https://www.mdpi.com/1424-8220/20/21/5988
id doaj-9793e61d6b1047fd8cd1bc065567306e
record_format Article
spelling doaj-9793e61d6b1047fd8cd1bc065567306e2020-11-25T03:41:09ZengMDPI AGSensors1424-82202020-10-01205988598810.3390/s20215988Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar SensorsJungwoo Seo0Jae Hee Kim1Jungsuek Oh2Institute of New Media and Communications, Seoul National University, Seoul 08826, KoreaSchool of Electrical, Electronics and Communication Engineering, Korea University of Technology and Education, Cheonan 31253, KoreaInstitute of New Media and Communications, Seoul National University, Seoul 08826, KoreaA microstrip-to-slot line-fed miniaturized Vivaldi antenna using semicircular patch embedment is proposed in this study. The conventional Vivaldi antenna has ultrawide bandwidth, but suffers from low gain in the low-frequency band. The proposed antenna topology incorporates the embedment of semicircular patch elements into the side edge of the antenna. This enables the phases of electric fields at both ends of the antenna to be out of phase. Since the distance between the two ends are λ<sub>L</sub>/2 where λ<sub>L</sub> is the wavelength at a low operating frequency, this antenna topology can achieve the constructive addition of electrical fields at the radiating end, leading to gain enhancement at the chosen low frequency. In comparison with the conventional Vivaldi antenna, the proposed antenna has a wider bandwidth from 2.84 to 9.83 GHz. Moreover, the simulated result shows a gain enhancement of 5 dB at low frequency. This cannot be realized by the conventional low-band impedance matching techniques only relying on slotted topologies. The measured results of this proposed antenna with a size of 45 × 40 × 0.8 mm<sup>3</sup> are in good agreement with the simulated results.https://www.mdpi.com/1424-8220/20/21/5988miniaturization methodsultrawideband antennasVivaldi antennas
collection DOAJ
language English
format Article
sources DOAJ
author Jungwoo Seo
Jae Hee Kim
Jungsuek Oh
spellingShingle Jungwoo Seo
Jae Hee Kim
Jungsuek Oh
Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors
Sensors
miniaturization methods
ultrawideband antennas
Vivaldi antennas
author_facet Jungwoo Seo
Jae Hee Kim
Jungsuek Oh
author_sort Jungwoo Seo
title Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors
title_short Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors
title_full Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors
title_fullStr Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors
title_full_unstemmed Semicircular Patch-Embedded Vivaldi Antenna for Miniaturized UWB Radar Sensors
title_sort semicircular patch-embedded vivaldi antenna for miniaturized uwb radar sensors
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2020-10-01
description A microstrip-to-slot line-fed miniaturized Vivaldi antenna using semicircular patch embedment is proposed in this study. The conventional Vivaldi antenna has ultrawide bandwidth, but suffers from low gain in the low-frequency band. The proposed antenna topology incorporates the embedment of semicircular patch elements into the side edge of the antenna. This enables the phases of electric fields at both ends of the antenna to be out of phase. Since the distance between the two ends are λ<sub>L</sub>/2 where λ<sub>L</sub> is the wavelength at a low operating frequency, this antenna topology can achieve the constructive addition of electrical fields at the radiating end, leading to gain enhancement at the chosen low frequency. In comparison with the conventional Vivaldi antenna, the proposed antenna has a wider bandwidth from 2.84 to 9.83 GHz. Moreover, the simulated result shows a gain enhancement of 5 dB at low frequency. This cannot be realized by the conventional low-band impedance matching techniques only relying on slotted topologies. The measured results of this proposed antenna with a size of 45 × 40 × 0.8 mm<sup>3</sup> are in good agreement with the simulated results.
topic miniaturization methods
ultrawideband antennas
Vivaldi antennas
url https://www.mdpi.com/1424-8220/20/21/5988
work_keys_str_mv AT jungwooseo semicircularpatchembeddedvivaldiantennaforminiaturizeduwbradarsensors
AT jaeheekim semicircularpatchembeddedvivaldiantennaforminiaturizeduwbradarsensors
AT jungsuekoh semicircularpatchembeddedvivaldiantennaforminiaturizeduwbradarsensors
_version_ 1724531271334363136

Similar Items