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Abstract

With the evolution of the Internet of Things, stretchable antennas are playing an increasingly important role in wearable devices and flexible electronics. Typical drawbacks of current stretchable antennas are complex manufacturing processes, inadequate ventilation, and limited flexibility, which negatively impact their comfort and practicality. In this study, an all-knitted stretchable dipole antenna was designed and fabricated. This antenna was breathable and flexible like regular knitted fabric and had a simple manufacturing process. In addition, the effects of two yarn alignment types, namely antenna arms aligned in the course (AaC) and wale (AaW) directions, on antenna electromagnetic properties under tensile stress were investigated. Under unstretched conditions, both antenna AaC and AaW exhibited S₁₁ of less than –10 dB at the operating frequency of 915 MHz, demonstrating good impedance matching performance and omnidirectional radiation characteristics. When stretched along the arm length direction, the frequency variations and strain of antenna AaC and AaW displayed strong linear relationships. Specifically, antenna AaC exhibited a higher sensitivity to the resonant frequency variation induced by strain when compared to antenna AaW. The results suggest that the antenna AaC are a more desirable option to be used as a sensor for human body movement monitoring. This study provides the theoretical basis and experimental foundation for the design and large-scale production of stretchable antennas utilizing textile materials.

Keywords

Smart textiles textile antenna dipole antenna electromagnetic properties tensile properties

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References

Bandara

TMWJ

Hansadi

JMC

Bella

A review of textile dye-sensitized solar cells for wearable electronics. Ionics 2022; 28: 2563–2583.

Liu

Wang

et al. An ultralight self-powered fire alarm e-textile based on conductive aerogel fiber with repeatable temperature monitoring performance used in firefighting clothing. ACS Nano 2022; 16: 2953–2967.

Yan

Noel

Loke

et al. Single fibre enables acoustic fabrics via nanometre-scale vibrations. Nature 2022; 603: 616–623.

Lin

Kim

H-J

Achavananthadith

et al. Digitally-embroidered liquid metal electronic textiles for wearable wireless systems. Nature Commun 2022; 13: 2190.

Ojuroye

Torah

Beeby

Modified PDMS packaging of sensory e-textile circuit microsystems for improved robustness with washing. Microsyst Technol 2022; 28: 1467–1484.

Lou

Eshetu

Yuan

et al. Regulation of the fabric wet adhesion property through structural design of desirable scale: a theoretical suggestion. Text Res J 2023; 93: 2126–2137.

Zheng

Shen

et al. Vapor phase polymerized conducting polymer/MXene textiles for wearable electronics. Nanoscale 2021; 13: 1832–1841.

Zheng

Wang

Nie

et al. Elastic polyaniline nanoarrays/MXene textiles for all-solid-state supercapacitors and anisotropic strain sensors. Compos Part A Appl Sci Manuf 2022; 158: 106985.

Dou

Zeng

Cheng

et al. Weft-knitted spacer fabric for highly stretchable-compressible strain sensor, supercapacitor, and joule heater. Nanomaterials 2022; 12: 3684.

10.

Fan

Meng

et al. Machine-knitted washable sensor array textile for precise epidermal physiological signal monitoring. Sci Adv 2020; 6: 2840.

11.

Kang

T-K.

Highly stretchable non-volatile nylon thread memory. Sci Rep 2016; 6: 24406.

12.

Kim

Cho

Won

D-J

et al. Textile-type triboelectric nanogenerator using Teflon wrapping wires as wearable power source. Micro Nano Syst Lett 2022; 10: 8.

13.

Chen

Y-T

Hsiao

Y-C

et al. Mycena chlorophos-inspired autoluminescent triboelectric fiber for wearable energy harvesting, self-powered sensing, and as human-device interfaces. Nano Energ 2022; 94: 106944.

14.

Tajin

MAS

Levitt

Liu

et al. On the effect of sweat on sheet resistance of knitted conductive yarns in wearable antenna design. IEEE Antennas Wirel Propagat Lett 2020; 19: 542–546.

15.

Kirtania

Elger

Hasan

et al. Flexible antennas: a review. Micromachines 2020; 11: 847.

16.

Ali

Sovuthy

Imran

et al. Recent advances of wearable antennas in materials, fabrication methods, designs, and their applications: state-of-the-art. Micromachines 2020; 11: 888.

17.

Zhu

Cheng

Recent development of flexible and stretchable antennas for bio-integrated electronics. Sensors 2018; 18: 4364.

18.

Aquino

Guerra

Holanda

et al. An evaluation and characterization study of knitted fabrics for use as telecommunication device substrate. J Mater Res Technol 2021; 12: 2076–2084.

19.

Nikbakhtnasrabadi

El Matbouly

Ntagios

et al. Textile-based stretchable microstrip antenna with intrinsic strain sensing. ACS Appl Electron Mater 2021; 3: 2233–2246.

20.

Virkki

Björninen

Kellomäki

et al. Reliability of washable wearable screen printed UHF RFID tags. Microelectron Reliab 2014; 54: 840–846.

21.

Patron

Mongan

Kurzweg

et al. On the use of knitted antennas and inductively coupled RFID tags for wearable applications. IEEE Trans Biomed Circ Syst 2016; 10: 1047–1057.

22.

Liu

Levitt

Kara

et al. An improved design of wearable strain sensor based on knitted RFID technology. In: 2016 IEEE conference on antenna measurements & applications (CAMA), Syracuse, NY, USA, 2016.

23.

Tajin

MAS

Bshara

Liu

et al. Efficiency measurement of the flexible on-body antenna at varying levels of stretch in a reverberation chamber. IET Microw Antennas Propagat 2020; 14: 154–158.

24.

Kuang

Yao

Luan

et al. Effects of weaving structures and parameters on the radiation properties of three-dimensional fabric integrated microstrip antennas. Text Res J 2018; 88: 2182–2189.

25.

Seager

Zhang

Chauraya

et al. Effect of the fabrication parameters on the performance of embroidered antennas. IET Microw Antennas Propagat 2013; 7: 1174–1181.

All-knitted stretchable dipole antenna: design,fabrication,and effects of yarn alignments on antenna electromagnetic and tensile properties

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