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用于气候适应型农业的设备端人工智能,通过智能农业设备上的轻量级模型进行智能作物产量预测。

On-device AI for climate-resilient farming with intelligent crop yield prediction using lightweight models on smart agricultural devices.

作者信息

Dhanaraj Rajesh Kumar, Maragatharajan M, Sureshkumar Aanjankumar, Balakannan S P

机构信息

Symbiosis Institute of Computer Studies and Research (SICSR), Symbiosis International (Deemed University), Pune, India.

School of Computing Science and Engineering, VIT Bhopal University, Bhopal-Indore Highway, Kothrikalan, Sehore, Madhya Pradesh, 466114, India.

出版信息

Sci Rep. 2025 Aug 25;15(1):31195. doi: 10.1038/s41598-025-16014-4.

DOI:10.1038/s41598-025-16014-4
PMID:40854942
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12378187/
Abstract

In Recent time, with the utilization of Artificial Intelligence (AI), AI applications have proliferated across various domains where agricultural consumer electronics are no exception. These innovations have significantly enhanced the intelligence of agricultural processes, leading to increased efficiency and sustainability. This study introduces an intelligent crop yield prediction system that utilizes Random Forest (RF) classifier to optimize the usage of water based on environmental factors. By integrating lightweight machine learning with consumer electronics such as sensors connected inside the smart display devices, this work is aimed to amplify water management and promote sustainable farming practices. While focusing on the sustainable agriculture, the water usage efficiency in irrigation should be enhanced by predicting optimal watering schedules and it will reduce the environmental impact and support the climate resilient farming. The proposed lightweight model has been trained on real-time agricultural data with minimum memory resource in sustainability prediction and the model has achieved 90.1% accuracy in the detection of crop yield suitable for the farmland as well as outperformed the existing methods including AI-enabled IoT model with mobile sensors and deep learning architectures (89%), LoRa-based systems (87.2%), and adaptive AI with self-learning techniques (88%). The deployment of computationally efficient machine learning models like random forest algorithms will emphasis on real time decision making without depending on the cloud computing. The performance evaluation and effectiveness of the proposed method are estimated using the important parameter called prediction accuracy. The main goal of this parameter is to access how the AI model accurately predicts the irrigation needs based on the sensor data.

摘要

近年来,随着人工智能(AI)的应用,AI应用已在各个领域激增,农业消费电子产品也不例外。这些创新显著提高了农业生产过程的智能化水平,从而提高了效率并增强了可持续性。本研究介绍了一种智能作物产量预测系统,该系统利用随机森林(RF)分类器根据环境因素优化水资源利用。通过将轻量级机器学习与智能显示设备内部连接的传感器等消费电子产品相结合,这项工作旨在加强水资源管理并推广可持续农业实践。在关注可持续农业的同时,应通过预测最佳灌溉时间表来提高灌溉用水效率,这将减少对环境的影响并支持气候适应型农业。所提出的轻量级模型已在可持续性预测中使用最少内存资源的实时农业数据进行训练,该模型在检测适合农田的作物产量方面达到了90.1%的准确率,并且优于现有方法,包括带有移动传感器的人工智能物联网模型和深度学习架构(89%)、基于LoRa的系统(87.2%)以及具有自学习技术的自适应人工智能(88%)。像随机森林算法这样的计算高效的机器学习模型的部署将强调实时决策,而不依赖云计算。使用称为预测准确率的重要参数来评估所提出方法的性能和有效性。该参数的主要目标是评估AI模型如何根据传感器数据准确预测灌溉需求。

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2
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3
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Plant Methods. 2024 Jul 14;20(1):104. doi: 10.1186/s13007-024-01228-w.
4
Machine learning-based optimal crop selection system in smart agriculture.智能农业中基于机器学习的最优作物选择系统
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5
Enriching IoT Modules with Edge AI Functionality to Detect Water Misuse Events in a Decentralized Manner.利用边缘人工智能功能丰富物联网模块,以去中心化的方式检测用水滥用事件。
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6
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