使用机器学习为物联网设备收集热电能:综述

IF 8.4 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Tereza Kucova, Michal Prauzek, Jaromir Konecny, Darius Andriukaitis, Mindaugas Zilys, Radek Martinek
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引用次数: 2

摘要

尽量减少电池使用、解决可持续性问题和减少定期维护的举措,推动了使用替代电源为物联网(IoT)网络中部署的设备供电的挑战。作为第五代(5G)和5G网络之外的关键支柱,物联网预计到2025年将达到420亿台设备。热电发电机(TEG)是一种固态能量采集器,可可靠且可再生地将热能转换为电能。这些设备能够回收损失的热能,在极端环境中产生能量,在偏远地区发电,并为微型传感器供电。运用最新技术,作者对机器学习(ML)方法与TEG供电的物联网设备相结合,用于管理和预测可用能源进行了全面的综述。总结了TEG驱动的物联网设备的应用领域,这些设备利用环境、生物结构、机器和其他技术中的温差作为热源。在详细研究TEG供电设备的技术现状的基础上,作者调查了该技术的研究挑战、应用算法和应用领域。该研究的目的是设计基于ML方法的新能源预测和能源管理系统,创建更好地估计输入能源的监督算法,并开发提供自适应和动态操作的无监督和半监督方法。综述结果表明,TEG具有可扩展性、在普遍存在的温差场景中的可用性和较长的使用寿命,是一种适合低功耗应用的能量收集技术。然而,TEG也具有低能效(约10%),并且需要相对恒定的热源。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Thermoelectric energy harvesting for internet of things devices using machine learning: A review

Thermoelectric energy harvesting for internet of things devices using machine learning: A review

Initiatives to minimise battery use, address sustainability, and reduce regular maintenance have driven the challenge to use alternative power sources to supply energy to devices deployed in Internet of Things (IoT) networks. As a key pillar of fifth generation (5G) and beyond 5G networks,IoT is estimated to reach 42 billion devices by the year 2025. Thermoelectric generators (TEGs) are solid state energy harvesters which reliably and renewably convert thermal energy into electrical energy. These devices are able to recover lost thermal energy, produce energy in extreme environments, generate electric power in remote areas, and power micro-sensors. Applying the state of the art, the authorspresent a comprehensive review of machine learning (ML) approaches applied in combination with TEG-powered IoT devices to manage and predict available energy. The application areas of TEG-driven IoT devices that exploit as a heat source the temperature differences found in the environment, biological structures, machines, and other technologies are summarised. Based on detailed research of the state of the art in TEG-powered devices, the authors investigated the research challenges, applied algorithms and application areas of this technology. The aims of the research were to devise new energy prediction and energy management systems based on ML methods, create supervised algorithms which better estimate incoming energy, and develop unsupervised and semi-supervised approaches which provide adaptive and dynamic operation. The review results indicate that TEGs are a suitable energy harvesting technology for low-power applications through their scalability, usability in ubiquitous temperature difference scenarios, and long operating lifetime. However, TEGs also have low energy efficiency (around 10%) and require a relatively constant heat source.

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来源期刊
CAAI Transactions on Intelligence Technology
CAAI Transactions on Intelligence Technology COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-
CiteScore
11.00
自引率
3.90%
发文量
134
审稿时长
35 weeks
期刊介绍: CAAI Transactions on Intelligence Technology is a leading venue for original research on the theoretical and experimental aspects of artificial intelligence technology. We are a fully open access journal co-published by the Institution of Engineering and Technology (IET) and the Chinese Association for Artificial Intelligence (CAAI) providing research which is openly accessible to read and share worldwide.
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