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深度学习在可控环境农业中的应用:综述最新进展、挑战与展望。

Deep Learning in Controlled Environment Agriculture: A Review of Recent Advancements, Challenges and Prospects.

机构信息

Department of Biological and Agricultural Engineering, Texas A&M AgriLife Research, Texas A&M University System, Dallas, TX 75252, USA.

出版信息

Sensors (Basel). 2022 Oct 19;22(20):7965. doi: 10.3390/s22207965.

DOI:10.3390/s22207965
PMID:36298316
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9612366/
Abstract

Controlled environment agriculture (CEA) is an unconventional production system that is resource efficient, uses less space, and produces higher yields. Deep learning (DL) has recently been introduced in CEA for different applications including crop monitoring, detecting biotic and abiotic stresses, irrigation, microclimate prediction, energy efficient controls, and crop growth prediction. However, no review study assess DL's state of the art to solve diverse problems in CEA. To fill this gap, we systematically reviewed DL methods applied to CEA. The review framework was established by following a series of inclusion and exclusion criteria. After extensive screening, we reviewed a total of 72 studies to extract the useful information. The key contributions of this article are the following: an overview of DL applications in different CEA facilities, including greenhouse, plant factory, and vertical farm, is presented. We found that majority of the studies are focused on DL applications in greenhouses (82%), with the primary application as yield estimation (31%) and growth monitoring (21%). We also analyzed commonly used DL models, evaluation parameters, and optimizers in CEA production. From the analysis, we found that convolutional neural network (CNN) is the most widely used DL model (79%), Adaptive Moment Estimation (Adam) is the widely used optimizer (53%), and accuracy is the widely used evaluation parameter (21%). Interestingly, all studies focused on DL for the microclimate of CEA used RMSE as a model evaluation parameter. In the end, we also discussed the current challenges and future research directions in this domain.

摘要

可控环境农业(CEA)是一种非传统的生产系统,它具有资源效率高、占地面积小、产量高的特点。深度学习(DL)最近在 CEA 中被引入,用于不同的应用,包括作物监测、检测生物和非生物胁迫、灌溉、微气候预测、节能控制和作物生长预测。然而,没有综述研究评估 DL 在解决 CEA 中多样化问题方面的最新技术。为了填补这一空白,我们系统地回顾了应用于 CEA 的 DL 方法。综述框架是通过遵循一系列包括和排除标准来建立的。经过广泛的筛选,我们共回顾了 72 项研究,以提取有用的信息。本文的主要贡献如下:概述了 DL 在不同 CEA 设施中的应用,包括温室、植物工厂和垂直农场。我们发现,大多数研究都集中在温室中的 DL 应用(82%),主要应用是产量估计(31%)和生长监测(21%)。我们还分析了 CEA 生产中常用的 DL 模型、评估参数和优化器。从分析中发现,卷积神经网络(CNN)是最广泛使用的 DL 模型(79%),自适应矩估计(Adam)是最广泛使用的优化器(53%),准确率是最广泛使用的评估参数(21%)。有趣的是,所有关注 CEA 微气候的研究都将 RMSE 作为模型评估参数。最后,我们还讨论了该领域当前的挑战和未来的研究方向。

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