利用物联网和人工智能技术监测边坡移动和土壤水文行为:系统性综述

Md Jobair Bin Alam, Luis Salgado Manzano, Rahul Debnath, A. Ahmed
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引用次数: 0

摘要

山体滑坡或斜坡崩塌对人类生命和基础设施构成重大威胁。斜坡的稳定性受各种水文过程控制,如降雨渗透、土壤水动态和非饱和土壤行为。因此,土壤水文监测和斜坡位移跟踪对于通过向相关部门发出预警来降低此类风险至关重要。在这种情况下,对关键土壤水文参数和斜坡移动的监测已经取得了进展,以确保在潜在的斜坡崩塌危险升级为灾难之前将其识别出来并加以缓解。随着物联网 (IoT)、人工智能和高速互联网的出现,利用这些技术远程监测土壤水文参数和边坡运动的潜力正变得越来越重要。本文概述了使用物联网和人工智能技术的现有水文监测系统,包括土壤采样、部署现场传感器(如电容、热耗散、时域反射仪(TDR))、地球物理应用等。此外,我们还回顾并比较了传统的斜坡移动探测系统,包括地面激光扫描仪、伸长计、张力计、倾角仪、全球定位系统、合成孔径雷达 (SAR)、激光雷达和无人机 (UAV) 等复杂应用的地形测量。最后,这项跨学科研究从岩土工程和计算机科学的角度,对监测滑坡和斜坡崩塌的不同方法和解决方案,以及未来研究可能面临的主要挑战和前景进行了全面的最新评述。
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Monitoring Slope Movement and Soil Hydrologic Behavior Using IoT and AI Technologies: A Systematic Review
Landslides or slope failure pose a significant risk to human lives and infrastructures. The stability of slopes is controlled by various hydrological processes such as rainfall infiltration, soil water dynamics, and unsaturated soil behavior. Accordingly, soil hydrological monitoring and tracking the displacement of slopes become crucial to mitigate such risks by issuing early warnings to the respective authorities. In this context, there have been advancements in monitoring critical soil hydrological parameters and slope movement to ensure potential causative slope failure hazards are identified and mitigated before they escalate into disasters. With the advent of the Internet of Things (IoT), artificial intelligence, and high-speed internet, the potential to use such technologies for remotely monitoring soil hydrological parameters and slope movement is becoming increasingly important. This paper provides an overview of existing hydrological monitoring systems using IoT and AI technologies, including soil sampling, deploying on-site sensors such as capacitance, thermal dissipation, Time-Domain Reflectometers (TDRs), geophysical applications, etc. In addition, we review and compare the traditional slope movement detection systems, including topographic surveys for sophisticated applications such as terrestrial laser scanners, extensometers, tensiometers, inclinometers, GPS, synthetic aperture radar (SAR), LiDAR, and Unmanned Aerial Vehicles (UAVs). Finally, this interdisciplinary research from both Geotechnical Engineering and Computer Science perspectives provides a comprehensive state-of-the-art review of the different methodologies and solutions for monitoring landslides and slope failures, along with key challenges and prospects for potential future study.
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