Wide bandwidth microstrip antenna with defected patch surface for low cross polarization applications

Ghosh, Abhijyoti; Chattopadhyay, Sudipta; Singh, L. Lolit Kumar; Basu, Banani

doi:10.1002/mmce.21127

Cited by 15 publications

(6 citation statements)

References 23 publications

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“…4.0 mm. The reason for the increase of f 1 is similar to the case for parameter G V , that is, it can also be derived from (10) to (12) that the increase of G U leads to a decrease of C V when other parameters in Table 1 are fixed, while C 1 , C P1 , and L 1 are almost kept unchanged, thus C m is decreased. From (26), the resultant upward frequency shifts for f 1 is observed.…”

Section: P a Ram Etr Ic S Tudy And A Naly S I Ssupporting

confidence: 58%

“…Many researchers have devoted to broaden the bandwidth, and some techniques have been proposed and applied, including substrate with low permittivity (e.g., air substrate) and increasing the substrate thickness; incorporating coplanar parasitic elements 1,2 or stacked structures; 3,4 specific feeding techniques, such as L-shaped probe feed, 5 T-shaped probe feed, 6 and crossshaped probe; 7 cutting slots in the patch, such as U-slot, 8,9 E-shaped slot, 10 V-slot, 11 and other shapes of slots. [12][13][14][15] However, microstrip antennas with low permittivity substrate have the disadvantage of large volume, which limits its application in some space limited cases. Increasing the substrate thickness has the limitation of further increase in bandwidth due to the inductance from the fed probe.…”

Section: Introductionmentioning

confidence: 99%

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Design and analysis of wideband U-slot patch antenna with U-shaped parasitic elements

Liu

Су

et al. 2017

Int J RF Microw Comput Aided Eng

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A single layer single probe‐fed wideband microstrip antenna is presented and investigated. By cutting a U‐slot in the rectangular patch, and by incorporating two identical U‐shaped parasitic patches around both the radiating edges and the nonradiating edges of the rectangular patch, three resonant frequencies are excited to form the wideband performance. Details of the antenna design is presented. The measured and simulated results are in good agreement, the measured impedance bandwidth is 1.44 GHz (4.82‐6.26 GHz), or 26.2% centered at 5.5 GHz, which covers WLAN 5.2 GHz ( 5.15‐5.35 GHz), WLAN 5.8 GHz ( 5.725‐5.825 GHz), and WIMAX 5.5 GHz ( 5.25‐5.85 GHz) bands. The measured peak gains at the three resonant frequencies are 7.73 dB, 7.01 dB, and 4.55 dB, respectively. An equivalent circuit model which is based on the transmission line theory, the asymmetric coupled microstrip lines theory, and the π‐network theory is established. This equivalent circuit model is used to give an insight into the wideband mechanism of the proposed antenna, and is also used to explain why the three resonant frequencies shift at the variations of different parameters from a physical point of view. The error analysis is given to demonstrate the validity of the equivalent circuit model.

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Section: P a Ram Etr Ic S Tudy And A Naly S I Ssupporting

confidence: 58%

Section: Introductionmentioning

confidence: 99%

Design and analysis of wideband U-slot patch antenna with U-shaped parasitic elements

Liu

Су

et al. 2017

Int J RF Microw Comput Aided Eng

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“…In addition, the size of the aperture type unit cell used to develop the proposed superstrate is nearly 27% compact than the reference [23] unit cell which significantly reduces the overall structure. The proposed work uses the DPS for the narrowband application but it is also effective for the wideband cross-polarization reduction without affecting the gain of the antenna, as reported in [24]. The width of a rectangular patch antenna is shorted to the ground using a shorting-pin and an optimized thin slot is incorporated near to the shorting-pin, resulting in co-cross-polarization isolation of more than 30 dB in the elevation plane.…”

Section: Introductionmentioning

confidence: 99%

Low Cross-Polarization Improved-Gain Rectangular Patch Antenna

2019

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In this paper, a low cross-polarization improved-gain rectangular patch antenna is presented. A patch-ground shorting pin with defected patch structure (DPS) is introduced to suppress the cross-polarization level. A High Reflective Frequency Selective Surface (HRFSS) superstrate is designed and placed over the proposed antenna at an optimized position to intensify the gain. To characterize the unit-cell of the superstrate, its transmission characteristics are extracted and discussed. Integration of the superstrate achieves a beam contraction resulting in a gain enhancement to 10.65 dBi. The proposed antenna has perfect broadside radiation with a cross-polarization level of below −30 dB in the entire half power beamwidth. The prototype of the antenna exhibits good agreement between experimental and simulated results.

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“…However, dielectric antennas are also facing the problem of impedance bandwidth, especially in high dielectric constant material antennas. For resolving this issue, many researches have been made in recent years, for example, a meander line structure in, a ladder structure in and other structures in …”

Section: Introductionmentioning

confidence: 99%

“…For resolving this issue, many researches have been made in recent years, for example, a meander line structure in, 8,9 a ladder structure in 10,11 and other structures in. 12,13 In this article, a novel AiP system based on LTCC technology for 2.4 GHz applications is designed. Double fractal antennas structure is designed in antenna part for realizing miniaturization, air cavities are designed for realizing broadband and a packaging cavity for integrated with components and IC chips.…”

Section: Introductionmentioning

confidence: 99%

Novel double fractal patches structure Antenna-in-Package based on LTCC technology for 2.4 GHz applications

Kuang

Dong

Nie

et al. 2018

Int J RF Microw Comput Aided Eng

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A novel Antenna‐in‐Package with small size and low profile is designed based on Low Temperature Co‐fired Ceramic technology. In order to realize miniaturization and broadband in antenna part, a novel structure using double fractal antennas and air cavities is applied. A packaging cavity is designed for integrated with usable components and IC chips. The antenna operates at a center frequency of 2.4 GHz and the bandwidth is about 200 MHz. Its maximum gain is 5.6 dBi, and radiation efficiency is above 90% across the frequency passband. By adjusting the dimension parameters, a tradeoff between height and area can be made with its performance parameters constant, therefore the proposed Antenna‐in‐Package can easily adapt to different processes and performance.

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Wide bandwidth microstrip antenna with defected patch surface for low cross polarization applications

Cited by 15 publications

References 23 publications

Design and analysis of wideband U-slot patch antenna with U-shaped parasitic elements

Design and analysis of wideband U-slot patch antenna with U-shaped parasitic elements

Low Cross-Polarization Improved-Gain Rectangular Patch Antenna

Novel double fractal patches structure Antenna-in-Package based on LTCC technology for 2.4 GHz applications

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