Automated identification of earthen berms in Western US rangelands from LiDAR-based digital elevation models

IF 2.8 3区 地球科学 Q2 GEOGRAPHY, PHYSICAL
Haiqing Xu, Mary H. Nichols, Dana Lapides, Octavia Crompton
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引用次数: 0

Abstract

Earthworks such as earthen berms have been constructed across the western US since the late 1800s to mitigate erosion in landscapes where water is both the dominant driver of erosion and the limiting resource for biota. Berms alter hydrologic, geomorphic and ecologic processes by intercepting runoff and altering patterns of water availability in the landscape. Understanding site-specific changes in process dynamics requires accurate mapping of berm locations and knowledge of their condition. This paper presents an automated, object-based framework for identifying earthen berms from 1 m LiDAR-derived digital elevation models in the western US rangelands. Geomorphon, a computer vision tool, was used to classify landforms and identify berm-like landforms, including summits and ridges. Ten geomorphic and geometric attributes associated with each potential berm object were used to develop a machine-learning model for distinguishing berms from natural summits and ridges. The model was trained and applied to independent test sites to identify and map berms. The mapped berms were compared with manually identified reference berms for accuracy assessment. The identification results achieved 79% to 87% recall, 82% to 92% precision and 81% to 89% F-measure. We also explored the influence of training sample selection on model performance and conducted an analysis of attribute relative importance. The automated framework has the potential to be scaled up to larger areas in semi-arid environments.

自 19 世纪晚期以来,美国西部地区一直在修建土护堤等土方工程,以减轻地貌侵蚀,因为水既是侵蚀的主要驱动力,也是限制生物群落的资源。护堤通过拦截径流和改变景观中的水供应模式来改变水文、地貌和生态过程。要了解特定地点的过程动态变化,需要准确绘制护堤位置图并了解其状况。本文介绍了一种基于对象的自动框架,用于从美国西部牧场 1 米激光雷达数字高程模型中识别土质护堤。计算机视觉工具 Geomorphon 被用来对地貌进行分类,并识别类似护堤的地貌,包括山顶和山脊。与每个潜在护堤对象相关的十个地貌和几何属性被用来开发一个机器学习模型,用于区分护堤与自然山顶和山脊。该模型经过训练后应用于独立的测试地点,以识别和绘制护堤图。将绘制的护堤与人工识别的参考护堤进行比较,以评估准确性。识别结果的召回率为 79% 至 87%,精确率为 82% 至 92%,F-measure 为 81% 至 89%。我们还探讨了训练样本选择对模型性能的影响,并对属性相对重要性进行了分析。该自动化框架有可能扩大到半干旱环境中的更大区域。
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来源期刊
Earth Surface Processes and Landforms
Earth Surface Processes and Landforms 地学-地球科学综合
CiteScore
6.40
自引率
12.10%
发文量
215
审稿时长
4 months
期刊介绍: Earth Surface Processes and Landforms is an interdisciplinary international journal concerned with: the interactions between surface processes and landforms and landscapes; that lead to physical, chemical and biological changes; and which in turn create; current landscapes and the geological record of past landscapes. Its focus is core to both physical geographical and geological communities, and also the wider geosciences
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