A hierarchical method and workflow for the semi-automated mapping of valley bottom geomorphic units using publicly available remote sensing datasets

IF 2.8 3区 地球科学 Q2 GEOGRAPHY, PHYSICAL Earth Surface Processes and Landforms Pub Date : 2024-07-04 DOI:10.1002/esp.5920
Nuosha Zhang, Kirstie Fryirs
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Abstract

Geomorphic units (GUs) are the landforms that make up the valley bottom and are produced by fluvial processes that determine river structure and function. Mapping of GUs can be used to interpret river type and behaviour and to analyse river condition and recovery processes. The advancement of remote sensing technologies and big-data acquisition are enabling the development and operationalisation of tools to semi-automate the mapping of assemblages of GUs across large spatial areas. In this study, we develop a hierarchical method that combines a landscape classification approach (Geomorphons) with supervised classification using light detection and ranging data (LiDAR) and satellite images to semi-automate the mapping of GUs across valley bottoms. We have also produced a new method for identifying and mapping pools in the absence of bathymetry data. We applied our method on 78 river sections in coastal catchments of NSW, Australia. We were able to identify 20 refined GU types and four further sub-types of bank-attached bars. Our method produced GU maps that are consistent with desktop manual delineation from aerial images and digital elevation models. Our hierarchical method offers GU maps with varying accuracy and resolution, accommodating a user's decisions regarding amount of effort invested relative to map quality and accuracy required. Initial runs produce maps with 12 preliminary GUs with 61%–75% consistency when compared to desktop manual mapping. With additional effort and manual corrections, a higher level of GU identification is possible (i.e. refined GU mapping increases the consistency to 70%–81%). The delineation of more intricate sub-types of GU or sub-units on compound GUs, which is essential for interpretation of river behaviour, condition, and recovery, still requires on-site field verification to achieve the best results.

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利用公开遥感数据集进行谷底地貌单元半自动绘图的分层方法和工作流程
地貌单元(GUs)是构成河谷底部的地貌,由决定河流结构和功能的河流过程产生。绘制地貌单元图可用来解释河流类型和行为,分析河流状况和恢复过程。遥感技术和大数据采集技术的进步使得开发和操作半自动化绘制大面积 GUs 组合图的工具成为可能。在本研究中,我们开发了一种分层方法,将景观分类方法(地貌)与利用光探测与测距数据(LiDAR)和卫星图像进行的监督分类相结合,对谷底的 GU 进行半自动化测绘。我们还提出了一种在没有水深测量数据的情况下识别和绘制水池的新方法。我们在澳大利亚新南威尔士州沿海集水区的 78 个河段上应用了我们的方法。我们能够识别出 20 种细化的 GU 类型和另外四种附岸条石子类型。我们的方法绘制出的 GU 图与通过航空图像和数字高程模型进行的桌面人工划界一致。我们的分层方法提供了不同精度和分辨率的 GU 地图,可满足用户对地图质量和精度要求的精力投入。与桌面人工制图相比,最初运行产生的 12 幅初步 GU 地图的一致性为 61%-75%。如果投入更多精力并进行人工修正,就有可能实现更高级别的 GU 识别(即精细 GU 测绘将一致性提高到 70%-81%)。划定更复杂的 GU 子类型或复合 GU 上的子单元,对于解释河流行为、状况和恢复至关重要,但仍需要进行现场实地验证,以获得最佳结果。
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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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