Mapping fault geomorphology with drone-based lidar

Guy Salomon, Theron Finley, Edwin Nissen, Roger Stephen, Brian Menounos
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Abstract

The advent of sub-meter resolution topographic surveying has revolutionized active fault mapping. Light detection and ranging (lidar) collected using crewed airborne laser scanning (ALS) can provide ground coverage of entire fault systems but is expensive, while Structure-from-Motion (SfM) photogrammetry from uncrewed aerial vehicles (UAVs) is popular for mapping smaller sites but cannot image beneath vegetation. Here, we present a new UAV laser scanning (ULS) system which overcomes these limitations to survey fault-related topography cost-effectively, at desirable spatial resolutions, and even beneath dense vegetation. In describing our system, data acquisition and processing workflows, we provide a practical guide for other researchers interested in developing their own ULS capabilities. We showcase ULS data collected over faults from a variety of terrain and vegetation types across the Canadian Cordillera and compare them to conventional ALS and SfM data. Due to the lower, slower UAV flights, ULS offers improved ground return density (~260 points/m2 for the capture of a paleoseismic trenching site and ~10–72 points/m2 for larger, multi-kilometer fault surveys) over conventional ALS (~3–9 points/m2) as well as better vegetation penetration than both ALS and SfM. The resulting ~20–50 cm-resolution ULS terrain models reveal fine-scale tectonic landforms that would otherwise be challenging to image.
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利用无人机激光雷达绘制断层地貌图
亚米级分辨率地形测量技术的出现彻底改变了主动断层测绘。利用机载激光扫描(ALS)采集的光探测和测距(lidar)可以提供整个断层系统的地面覆盖范围,但价格昂贵;而利用无人驾驶飞行器(UAV)进行的运动结构(SfM)摄影测量法在绘制较小地点的地图时很受欢迎,但无法对植被下的地形进行成像。在此,我们介绍一种新型无人飞行器激光扫描(ULS)系统,该系统克服了这些限制,能以理想的空间分辨率,甚至在茂密的植被下,经济高效地勘测与断层有关的地形。通过介绍我们的系统、数据采集和处理工作流程,我们为其他有兴趣开发自己的 ULS 功能的研究人员提供了实用指南。我们展示了在加拿大科迪勒拉山系各种地形和植被类型的断层上采集的 ULS 数据,并将其与传统的 ALS 和 SfM 数据进行了比较。由于无人机飞行速度较低、较慢,与传统的 ALS(约 3-9 个点/平方米)相比,ULS 提供了更高的地面回波密度(捕捉古地震坑道现场约 260 个点/平方米,大型、多公里断层勘测约 10-72 个点/平方米),以及比 ALS 和 SfM 更好的植被穿透性。由此产生的 ~20-50 厘米分辨率的 ULS 地形模型揭示了细尺度的构造地貌,否则很难对其进行成像。
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