Characterizations of Flexible Wearable Antenna based on Rubber Substrate

Dar, Saadat Hanif; Ahmed, Jameel; Raees, Muhammad

doi:10.14569/ijacsa.2016.071124

Cited by 10 publications

(4 citation statements)

References 12 publications

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“…One of the impacts of bending on an antenna's performance is the reflection or scattering of waves and resultant impedance mismatch. While an impedance miss-match should occur when a flexible antenna is bent and crumpled, this simultaneously leads to a change in signal strength which often decreases [223], although sometimes increases, after bending the antenna. In order to analyse the effects of bending on impedance mismatch or reflection coefficient (S 11 ), the average of S 11 is evaluated from a flat case to a bend level up to 6mm for different ranges of frequencies.…”

Section: Effect Of Bending On Reflection Co-efficient (S11)mentioning

confidence: 99%

Bending Analysis of Polymer-Based Flexible Antennas for Wearable, General IoT Applications: A Review

et al. 2021

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Flexible substrates have become essential in order to provide increased flexibility in wearable sensors, including polymers, plastic, paper, textiles and fabrics. This study is to comprehensively summarize the bending capabilities of flexible polymer substrate for general Internet of Things (IoTs) applications. The basic premise is to investigate the flexibility and bending ability of polymer materials as well as their tendency to withstand deformation. We start by providing a chronological order of flexible materials which have been used during the last few decades. In the future, the IoT is expected to support a diverse set of technologies to enable new applications through wireless connectivity. For wearable IoTs, flexibility and bending capabilities of materials are required. This paper provides an overview of some abundantly used polymer substrates and compares their physical, electrical and mechanical properties. It also studies the bending effects on the radiation performance of antenna designs that use polymer substrates. Moreover, we explore a selection of flexible materials for flexible antennas in IoT applications, namely Polyimides (PI), Polyethylene Terephthalate (PET), Polydimethylsiloxane (PDMS), Polytetrafluoroethylene (PTFE), Rogers RT/Duroid and Liquid Crystal Polymer (LCP). The study includes a complete analysis of bending and folding effects on the radiation characteristics such as S-parameters, resonant frequency deviation and the impedance mismatch with feedline of the flexible polymer substrate microstrip antennas. These flexible polymer substrates are useful for future wearable devices and general IoT applications.

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Section: Effect Of Bending On Reflection Co-efficient (S11)mentioning

confidence: 99%

Bending Analysis of Polymer-Based Flexible Antennas for Wearable, General IoT Applications: A Review

et al. 2021

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“…Saadat Hanif Dar et al [20] proposed a patch antenna using rubber substrate. The design performance of the antenna on human body was also investigated.…”

Section: Study Of Bending Conditions In Antenna Designmentioning

confidence: 99%

Design Issues of Flexible Antenna -A Review

Pandimadevi¹

2019

IJATCSE

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Recent years has been observed increasing attention from both academic and scientific communities in the field of flexible technology. Flexible antennas have found their importance, when conventional antenna performance is very low because of its peripheral environment. This survey reviews the development of flexible antennas, their design, substrate material used and addresses various bending conditions tested on the antenna finds many applications in military, satellite, medical and defense fields. The antenna should get adjustable to any kind of surfaces. The careful study had been done using current researches going on in the field of flexible antenna technology. Such antennas have merits of compactness, light weight, low profile, cheap and easy to fabricate. Even though there are more survey papers on flexible antenna is available, they are restricted only to particular issues only. So, in this review, a comprehensive survey has been provided which deals with all the issues and challenges of flexible antenna. Thus this review will find out the perfect solution of designing and bending issues of flexible antenna. All the designs presented are of the recent development in flexible technology.

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“…Designing such an effective and compact wearable antenna is challenging due to the low-size antenna structure, which offers a small current path and impedance mismatch at lower frequencies. Keeping the main characteristics in mind, many investigators chose the microstrip patch antenna in combination with fractal technology to produce the desired characteristics such as flexibility [7], compact [8], multi-band, and broadband characteristics [9][10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

A fully flexible, high gain saw-tooth-shaped boundary fractal wearable patch antenna for WBAN applications

Mallavarapu

Anjaneyulu

2022

Int. J. Microw. Wireless Technol.

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A flexible and high gain saw-tooth-shaped boundary fractal wearable antenna is anticipated for WBAN applications. A square shape is converted to the saw-tooth-shaped boundary by sequentially rotating the square at an angle of 45° and overlaid on one another and repeated the same for three iterations. The geometry is built on a flexible jeans substrate, and the total size of the anticipated antenna is 0.583λ × 0.583λ × 0.02λ at 2.4 GHz. A prototype has been made to test its suitability for wearable applications' gain, bandwidth, and efficiency. The results revealed that the proposed antenna provides an impedance bandwidth of 4.2% and a peak gain of 5.76 dBi at the 2.45 GHz ISM band. The anticipated antenna is wrapped around foam cylinders of radii 70 and 50 mm to test the stability and deformability of its performance. The full ground plane isolates the antenna from the human body contributing to the lower SAR values. The simulated maximum achieved specific absorption rate (SAR) of 0.3025 and 1.16 W/kg for 10 and 1 g of average tissue for the input power of 100 mW, respectively, found within the standards as per FCC. The peak gain, compact size, and SAR permanence made the anticipated antenna a worthy candidate for wearable on/off body applications.

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Characterizations of Flexible Wearable Antenna based on Rubber Substrate

Cited by 10 publications

References 12 publications

Bending Analysis of Polymer-Based Flexible Antennas for Wearable, General IoT Applications: A Review

Bending Analysis of Polymer-Based Flexible Antennas for Wearable, General IoT Applications: A Review

Design Issues of Flexible Antenna -A Review

A fully flexible, high gain saw-tooth-shaped boundary fractal wearable patch antenna for WBAN applications

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