Rapid 3D lidar change detection for geohazard identification using GPU-based alignment and M3C2 algorithms

IF 3 3区工程技术 Q2 ENGINEERING, GEOLOGICAL

Canadian Geotechnical Journal Pub Date : 2023-10-04 DOI:10.1139/cgj-2023-0073

Luke Morgan Weidner, Alex Ferrier, Megan van Veen, Matthew J Lato

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引用次数: 0

Abstract

Topographic change detection is increasingly being used to identify and monitor landslides and other geohazards in support of risk-informed decision making. Expanding change detection from site-specific to regional scales enables increasingly proactive asset management and contributes to improving the resilience of infrastructure to extreme events. It is widely known that change detection precision can be improved by applying three-dimensional (3D) algorithms, such as iterative closest point (ICP) and M3C2, directly to raw point clouds. However, this also increases the computational requirements compared to alternatives such as digital elevation model (DEM) differencing (DoD). This study presents a novel graphics processing unit (GPU) based implementation of the ICP-M3C2 workflow to address this limitation. In the proposed algorithm, point cloud data segments are automatically queued and served to the working GPU, which efficiently performs point cloud processing operations, while the central processing unit (CPU) performs data management operations in parallel. The developed method is estimated to be up to 54 times faster than CPU-based versions of the same algorithm. In this paper, we present how the workflow has been applied to six regional-scale landslide identification and monitoring case studies, in which landslides are causing the disruption of pipelines, highways, and rail corridors. Overall, in 2021 and 2022, over 17,500 linear kms of change detection were processed using the demonstrated method.

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基于gpu对齐和M3C2算法的快速三维激光雷达变化检测地质灾害识别

地形变化探测越来越多地被用于识别和监测滑坡和其他地质灾害，以支持风险知情的决策。将变化检测从特定地点扩展到区域尺度，使资产管理更加主动，并有助于提高基础设施对极端事件的适应能力。众所周知，将迭代最近点(ICP)和M3C2等三维(3D)算法直接应用于原始点云可以提高变化检测精度。然而，与数字高程模型(DEM)差分(DoD)等替代方案相比，这也增加了计算需求。本研究提出了一种新颖的图形处理单元(GPU)基于实现的ICP-M3C2工作流来解决这一限制。在该算法中，点云数据段自动排队并提供给工作GPU, GPU高效地执行点云处理操作，而中央处理器(CPU)并行执行数据管理操作。据估计，开发的方法比基于cpu的相同算法快54倍。在本文中，我们介绍了如何将工作流程应用于六个区域尺度的滑坡识别和监测案例研究，其中滑坡导致管道，高速公路和铁路走廊的中断。总体而言，在2021年和2022年，使用所演示的方法处理了超过17,500线性公里的变化检测。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Canadian Geotechnical Journal 地学-地球科学综合

CiteScore

7.20

自引率

5.60%

发文量

163

审稿时长

7.5 months

期刊介绍： The Canadian Geotechnical Journal features articles, notes, reviews, and discussions related to new developments in geotechnical and geoenvironmental engineering, and applied sciences. The topics of papers written by researchers and engineers/scientists active in industry include soil and rock mechanics, material properties and fundamental behaviour, site characterization, foundations, excavations, tunnels, dams and embankments, slopes, landslides, geological and rock engineering, ground improvement, hydrogeology and contaminant hydrogeology, geochemistry, waste management, geosynthetics, offshore engineering, ice, frozen ground and northern engineering, risk and reliability applications, and physical and numerical modelling. Contributions that have practical relevance are preferred, including case records. Purely theoretical contributions are not generally published unless they are on a topic of special interest (like unsaturated soil mechanics or cold regions geotechnics) or they have direct practical value.