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通过物联网和人工智能驱动技术赋能垂直农场:全面综述

Empowering vertical farming through IoT and AI-Driven technologies: A comprehensive review.

作者信息

Rathor Ajit Singh, Choudhury Sushabhan, Sharma Abhinav, Nautiyal Pankaj, Shah Gautam

机构信息

Department of Electrical & Electronics Engineering, University of Petroleum & Energy Studies, Dehradun, Uttarakhand, India.

Krishi Vigyan Kendra (ICAR-CSSRI), Hardoi, Uttar Pradesh, India.

出版信息

Heliyon. 2024 Jul 23;10(15):e34998. doi: 10.1016/j.heliyon.2024.e34998. eCollection 2024 Aug 15.

DOI:10.1016/j.heliyon.2024.e34998
PMID:39157372
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11328057/
Abstract

The substantial increase in the human population dramatically strains food supplies. Farmers need healthy soil and natural minerals for traditional farming, and production takes a little longer time. The soil-free farming method known as vertical farming (VF) requires a small land and consumes a very small amount of water than conventional soil-dependent farming techniques. With modern technologies like hydroponics, aeroponics, and aquaponics, the notion of the VF appears to have a promising future in urban areas where farming land is very expensive and scarce. VF faces difficulty in the simultaneous monitoring of multiple indicators, nutrition advice, and plant diagnosis systems. However, these issues can be resolved by implementing current technical advancements like artificial intelligence (AI)-based control techniques such as machine learning (ML), deep learning (DL), the internet of things (IoT), image processing as well as computer vision. This article presents a thorough analysis of ML and IoT applications in VF system. The areas on which the attention is concentrated include disease detection, crop yield prediction, nutrition, and irrigation control management. In order to predict crop yield and crop diseases, the computer vision technique is investigated in view of the classification of distinct collections of crop images. This article also illustrates ML and IoT-based VF systems that can raise product quality and production over the long term. Assessment and evaluation of the knowledge-based VF system have also been outlined in the article with the potential outcomes, advantages, and limitations of ML and IoT in the VF system.

摘要

人口的大幅增长给粮食供应带来了巨大压力。农民进行传统农业生产需要肥沃的土壤和天然矿物质,而且生产所需时间较长。被称为垂直农场(VF)的无土栽培方法所需土地面积小,与传统的依赖土壤的耕作技术相比,耗水量也非常少。借助水培、气培和鱼菜共生等现代技术,垂直农场的理念在城市地区似乎有着广阔的前景,因为城市地区的耕地非常昂贵且稀缺。垂直农场在同时监测多个指标、提供营养建议和植物诊断系统方面面临困难。然而,通过应用当前的技术进步,如基于人工智能(AI)的控制技术,如机器学习(ML)、深度学习(DL)、物联网(IoT)、图像处理以及计算机视觉,可以解决这些问题。本文对机器学习和物联网在垂直农场系统中的应用进行了全面分析。重点关注的领域包括疾病检测、作物产量预测、营养和灌溉控制管理。为了预测作物产量和作物病害,针对不同作物图像集的分类对计算机视觉技术进行了研究。本文还阐述了基于机器学习和物联网的垂直农场系统,这些系统从长远来看可以提高产品质量和产量。文章还概述了基于知识的垂直农场系统的评估,以及机器学习和物联网在垂直农场系统中的潜在成果、优势和局限性。

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