Antenna systems for IoT applications: a review

In smart homes, industrial automation, healthcare, agriculture, and environmental monitoring, IoT antenna systems improve communication efficiency and dependability. IoT antenna systems affect network performance and connection by affecting gain, directivity, bandwidth, efficiency, and impedance mat...

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Published in:DISCOVER SUSTAINABILITY
Main Authors: Khan, Sunawar; Mazhar, Tehseen; Shahzad, Tariq; Bibi, Afsha; Ahmad, Wasim; Khan, Muhammad Amir; Saeed, Mamoon M.; Hamam, Habib
Format: Review
Language:English
Published: SPRINGERNATURE 2024
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001356201200005
author Khan
Sunawar; Mazhar
Tehseen; Shahzad
Tariq; Bibi
Afsha; Ahmad
Wasim; Khan
Muhammad Amir; Saeed
Mamoon M.; Hamam
Habib
spellingShingle Khan
Sunawar; Mazhar
Tehseen; Shahzad
Tariq; Bibi
Afsha; Ahmad
Wasim; Khan
Muhammad Amir; Saeed
Mamoon M.; Hamam
Habib
Antenna systems for IoT applications: a review
Science & Technology - Other Topics; Environmental Sciences & Ecology
author_facet Khan
Sunawar; Mazhar
Tehseen; Shahzad
Tariq; Bibi
Afsha; Ahmad
Wasim; Khan
Muhammad Amir; Saeed
Mamoon M.; Hamam
Habib
author_sort Khan
spelling Khan, Sunawar; Mazhar, Tehseen; Shahzad, Tariq; Bibi, Afsha; Ahmad, Wasim; Khan, Muhammad Amir; Saeed, Mamoon M.; Hamam, Habib
Antenna systems for IoT applications: a review
DISCOVER SUSTAINABILITY
English
Review
In smart homes, industrial automation, healthcare, agriculture, and environmental monitoring, IoT antenna systems improve communication efficiency and dependability. IoT antenna systems affect network performance and connection by affecting gain, directivity, bandwidth, efficiency, and impedance matching. Dipole, patch, spiral, metamaterial-based, and other antenna types are tested in IoT settings to identify their applicability, benefits, and downsides. Current antenna technology has challenges with frequency, bandwidth, size, weight, material choices, and energy efficiency, requiring new solutions. According to the study, interference control, power consumption, and dynamic IoT adaptation research are inadequate. Metamaterials, nanomaterials, and 3D printing may circumvent these antenna design limitations. AI and machine learning can improve antenna design real-time optimization and performance in complex settings. The paper explores how standards and regulatory frameworks affect IoT antenna system development to ensure future designs meet a fast-growing market. For the growing range of IoT applications, this research suggests more flexible and reconfigurable antennas that can function across numerous frequency bands. The report emphasizes antenna material and design innovation to improve durability, cut costs, and scale manufacturing. This research tackles these key elements to enable the next generation of antenna systems to meet IoT technology's expanding needs and increase networked devices' functionality, efficiency, and integration across industries. This comprehensive approach helps identify current trends and concerns and prepares for future IoT antenna system advancements, enabling smarter, more connected, and more efficient technologies.
SPRINGERNATURE

2662-9984
2024
5
1
10.1007/s43621-024-00638-z
Science & Technology - Other Topics; Environmental Sciences & Ecology

WOS:001356201200005
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001356201200005
title Antenna systems for IoT applications: a review
title_short Antenna systems for IoT applications: a review
title_full Antenna systems for IoT applications: a review
title_fullStr Antenna systems for IoT applications: a review
title_full_unstemmed Antenna systems for IoT applications: a review
title_sort Antenna systems for IoT applications: a review
container_title DISCOVER SUSTAINABILITY
language English
format Review
description In smart homes, industrial automation, healthcare, agriculture, and environmental monitoring, IoT antenna systems improve communication efficiency and dependability. IoT antenna systems affect network performance and connection by affecting gain, directivity, bandwidth, efficiency, and impedance matching. Dipole, patch, spiral, metamaterial-based, and other antenna types are tested in IoT settings to identify their applicability, benefits, and downsides. Current antenna technology has challenges with frequency, bandwidth, size, weight, material choices, and energy efficiency, requiring new solutions. According to the study, interference control, power consumption, and dynamic IoT adaptation research are inadequate. Metamaterials, nanomaterials, and 3D printing may circumvent these antenna design limitations. AI and machine learning can improve antenna design real-time optimization and performance in complex settings. The paper explores how standards and regulatory frameworks affect IoT antenna system development to ensure future designs meet a fast-growing market. For the growing range of IoT applications, this research suggests more flexible and reconfigurable antennas that can function across numerous frequency bands. The report emphasizes antenna material and design innovation to improve durability, cut costs, and scale manufacturing. This research tackles these key elements to enable the next generation of antenna systems to meet IoT technology's expanding needs and increase networked devices' functionality, efficiency, and integration across industries. This comprehensive approach helps identify current trends and concerns and prepares for future IoT antenna system advancements, enabling smarter, more connected, and more efficient technologies.
publisher SPRINGERNATURE
issn
2662-9984
publishDate 2024
container_volume 5
container_issue 1
doi_str_mv 10.1007/s43621-024-00638-z
topic Science & Technology - Other Topics; Environmental Sciences & Ecology
topic_facet Science & Technology - Other Topics; Environmental Sciences & Ecology
accesstype
id WOS:001356201200005
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001356201200005
record_format wos
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