Extracting Shallow-Water Bathymetry from Lidar Point Clouds Using Pulse Attribute Data: Merging Density-Based and Machine Learning Approaches

IF 2 4区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS Marine Geodesy Pub Date : 2021-05-05 DOI:10.1080/01490419.2021.1925790

K. Lowell, B. Calder

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引用次数: 7

Abstract

Abstract To automate extraction of bathymetric soundings from lidar point clouds, two machine learning (ML 1 ) techniques were combined with a more conventional density-based algorithm. The study area was four data “tiles” near the Florida Keys. The density-based algorithm determined the most likely depth (MLD) for a grid of “estimation nodes” (ENs). Unsupervised k-means clustering determined which EN’s MLD depth and associated soundings represented ocean depth rather than ocean surface or noise to produce a preliminary classification. An extreme gradient boosting (XGB) model was fitted to pulse return metadata – e.g. return intensity, incidence angle – to produce a final Bathy/NotBathy classification. Compared to an operationally produced reference classification, the XGB model increased global accuracy and decreased the false negative rate (FNR) – i.e. undetected bathymetry – that are most important for nautical navigation for all but one tile. Agreement between the final XGB and operational reference classifications ranged from 0.84 to 0.999. Imbalance between Bathy and NotBathy was addressed using a probability decision threshold that equalizes the FNR and the true positive rate (TPR). Two methods are presented for visually evaluating differences between the two classifications spatially and in feature-space.

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利用脉冲属性数据从激光雷达点云提取浅水测深:融合基于密度的方法和机器学习方法

为了从激光雷达点云中自动提取测深数据，将两种机器学习(ML 1)技术与更传统的基于密度的算法相结合。研究区域是佛罗里达群岛附近的四个数据“瓦片”。基于密度的算法确定“估计节点”(ENs)网格的最可能深度(MLD)。无监督k-means聚类确定哪些EN的MLD深度和相关的测深代表海洋深度，而不是海洋表面或噪声，从而产生初步分类。将极端梯度增强(XGB)模型拟合到脉冲返回元数据(例如返回强度，入射角)中，以产生最终的bath / notbath分类。与操作生成的参考分类相比，XGB模型提高了全局精度，降低了误报率(FNR)，即未检测到的水深测量，这对除一个瓦片外的所有瓦片的航海导航都是最重要的。最终的XGB和操作参考分类之间的一致性范围从0.84到0.999。使用概率决策阈值来平衡FNR和真阳性率(TPR)，解决了bath和notbath之间的不平衡。提出了两种方法来直观地评价两种分类在空间和特征空间上的差异。

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来源期刊

Marine Geodesy 地学-地球化学与地球物理

CiteScore

4.10

自引率

6.20%

发文量

审稿时长

>12 weeks

期刊介绍： The aim of Marine Geodesy is to stimulate progress in ocean surveys, mapping, and remote sensing by promoting problem-oriented research in the marine and coastal environment. The journal will consider articles on the following topics: topography and mapping; satellite altimetry; bathymetry; positioning; precise navigation; boundary demarcation and determination; tsunamis; plate/tectonics; geoid determination; hydrographic and oceanographic observations; acoustics and space instrumentation; ground truth; system calibration and validation; geographic information systems.