Edge Computing in IoT–Enabled Honeybee Monitoring for the Detection of Varroa Destructor

IF 1.6 4区计算机科学 Q3 AUTOMATION & CONTROL SYSTEMS

International Journal of Applied Mathematics and Computer Science Pub Date : 2022-09-01 DOI:10.34768/amcs-2022-0026

Anna Wachowicz, Jakub Pytlik, Bożena Małysiak-Mrozek, Krzysztof Tokarz, Dariusz Mrozek

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引用次数: 2

Abstract

Abstract Among many important functions, bees play a key role in food production. Unfortunately, worldwide bee populations have been decreasing since 2007. One reason for the decrease of adult worker bees is varroosis, a parasitic disease caused by the Varroa destructor (V. destructor) mite. Varroosis can be quickly eliminated from beehives once detected. However, this requires them to be monitored continuously during periods of bee activity to ensure that V. destructor mites are detected before they spread and infest the entire beehive. To this end, the use of Internet of things (IoT) devices can significantly increase detection speed. Comprehensive solutions are required that can cover entire apiaries and prevent the disease from spreading between hives and apiaries. In this paper, we present a solution for global monitoring of apiaries and the detection of V. destructor mites in beehives. Our solution captures and processes video streams from camera-based IoT devices, analyzes those streams using edge computing, and constructs a global collection of cases within the cloud. We have designed an IoT device that monitors bees and detects V. destructor infestation via video stream analysis on a GPU-accelerated Nvidia Jetson Nano. Experimental results show that the detection process can be run in real time while maintaining similar efficacy to alternative approaches.

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边缘计算在基于物联网的蜜蜂监测中用于瓦螨的检测

在众多重要功能中，蜜蜂在食物生产中起着关键作用。不幸的是，自2007年以来，全球蜜蜂数量一直在减少。工蜂成虫数量减少的一个原因是瓦螨病，一种由瓦螨引起的寄生虫病。一旦发现蜂箱内的静脉曲张病可以迅速消除。然而，这需要在蜜蜂活动期间对它们进行持续监测，以确保在它们扩散和感染整个蜂巢之前发现它们。为此，使用物联网(IoT)设备可以显著提高检测速度。需要全面的解决方案，以覆盖整个蜂房，并防止疾病在蜂箱和蜂房之间传播。在本文中，我们提出了一种解决方案，用于全球监测蜂房和检测蜂箱中的破坏螨。我们的解决方案捕获和处理来自基于摄像头的物联网设备的视频流，使用边缘计算分析这些视频流，并在云中构建一个全球案例集合。我们设计了一个物联网设备，通过gpu加速的Nvidia Jetson Nano上的视频流分析来监测蜜蜂和检测V. destructor侵扰。实验结果表明，该方法可以实时进行检测，同时保持与其他方法相似的有效性。

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来源期刊

International Journal of Applied Mathematics and Computer Science 工程技术-计算机：人工智能

CiteScore

4.10

自引率

21.10%

发文量

审稿时长

4.2 months

期刊介绍： The International Journal of Applied Mathematics and Computer Science is a quarterly published in Poland since 1991 by the University of Zielona Góra in partnership with De Gruyter Poland (Sciendo) and Lubuskie Scientific Society, under the auspices of the Committee on Automatic Control and Robotics of the Polish Academy of Sciences. The journal strives to meet the demand for the presentation of interdisciplinary research in various fields related to control theory, applied mathematics, scientific computing and computer science. In particular, it publishes high quality original research results in the following areas: -modern control theory and practice- artificial intelligence methods and their applications- applied mathematics and mathematical optimisation techniques- mathematical methods in engineering, computer science, and biology.