Spatially continuous snow depth mapping by aeroplane photogrammetry for annual peak of winter from 2017 to 2021 in open areas

IF 4.4 2区 地球科学 Q1 GEOGRAPHY, PHYSICAL Cryosphere Pub Date : 2023-08-22 DOI:10.5194/tc-17-3383-2023
Leon J. Bührle, M. Marty, Lucie A. Eberhard, A. Stoffel, Elisabeth D. Hafner, Y. Bühler
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Abstract

Abstract. Information on snow depth and its spatial distribution is important for numerous applications, including natural hazard management, snow water equivalent estimation for hydropower, the study of the distribution and evolution of flora and fauna, and the validation of snow hydrological models. Due to its heterogeneity and complexity, specific remote sensing tools are required to accurately map the snow depth distribution in Alpine terrain. To cover large areas (>100 km2), airborne laser scanning (ALS) or aerial photogrammetry with large-format cameras is needed. While both systems require piloted aircraft for data acquisition, ALS is typically more expensive than photogrammetry but yields better results in forested terrain. While photogrammetry is slightly cheaper, it is limited due to its dependency on favourable acquisition conditions (weather, light conditions). In this study, we present photogrammetrically processed high-spatial-resolution (0.5 m) annual snow depth maps, recorded during the peak of winter over a 5-year period under different acquisition conditions over a study area around Davos, Switzerland. Compared to previously carried out studies, using the Vexcel UltraCam Eagle Mark 3 (M3) sensor improves the average ground sampling distance to 0.1 m at similar flight altitudes above ground. This allows for very detailed snow depth maps in open areas, calculated by subtracting a snow-off digital terrain model (DTM, acquired with ALS) from the snow-on digital surface models (DSMs) processed from the airborne imagery. Despite challenging acquisition conditions during the recording of the UltraCam images (clouds, shaded areas and fresh snow), 99 % of unforested areas were successfully photogrammetrically reconstructed. We applied masks (high vegetation, settlements, water, glaciers) to increase the reliability of the snow depth calculations. An extensive accuracy assessment was carried out using check points, the comparison to DSMs derived from unpiloted aerial systems and the comparison of snow-free DSM pixels to the ALS DTM. The results show a root mean square error of approximately 0.25 m for the UltraCam X and 0.15 m for the successor, the UltraCam Eagle M3. We developed a consistent and reliable photogrammetric workflow for accurate snow depth distribution mapping over large regions, capable of analysing snow distribution in complex terrain. This enables more detailed investigations on seasonal snow dynamics and can be used for numerous applications related to snow depth distribution, as well as serving as a ground reference for new modelling approaches and satellite-based snow depth mapping.
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开放地区2017 - 2021年冬季年高峰的飞机摄影测量空间连续雪深制图
摘要雪深及其空间分布信息在许多应用中都很重要,包括自然灾害管理、水电站雪水当量估计、动植物分布和进化研究以及雪水文模型的验证。由于其异质性和复杂性,需要特定的遥感工具来准确绘制Alpineterrain的雪深分布图。覆盖大面积(>100 km2)、机载激光扫描(ALS)或具有大格式相机的航空摄影测量。虽然这两个系统都需要有人驾驶的飞机进行数据采集,但ALS通常比摄影测量更昂贵,但在森林地形中效果更好。虽然摄影测量有点小,但由于它依赖于有利的获取条件(天气、光照条件),所以它是有限的。在这项研究中,我们提出了经过摄影测量处理的高空间分辨率(0.5 m) 在瑞士达沃斯周围的一个研究区域,在不同的采集条件下,在5年的冬季高峰期记录的年度积雪深度图。与之前进行的研究相比,使用VexcelUltraCam Eagle Mark 3(M3)传感器将平均地面采样距离提高到0.1 m,在地面以上类似的飞行高度。这允许在开阔地区绘制非常详细的雪深图,通过从航空图像处理的数字地面上的雪模型(DSM)中减去数字地形模型外的雪(DTM,用ALS获取)来计算。UltraCam图像记录过程中极具挑战性的采集条件(云层、阴影区域和新鲜雪),99 % 成功地对未受挤压的区域进行了摄影测量重建。我们应用了遮罩(高植被、定居点、水、冰川)来提高现在深度计算的可靠性。使用检查点进行了广泛的精度评估,与无人驾驶航空系统得出的DSM进行了比较,并将无雪DSM像素与ALS DTM进行了比较。结果显示均方根误差约为0.25 m用于UltraCam X和0.15 m代表继任者UltraCam Eagle M3。我们开发了一个一致可靠的摄影测量工作流程,用于大面积精确的积雪深度分布测绘,能够分析复杂地形中的积雪分布。这使得能够对季节性雪动力学进行更详细的研究,并可用于与雪深度分布相关的许多应用,以及作为新建模方法和基于卫星的雪深度测绘的地面参考。
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来源期刊
Cryosphere
Cryosphere GEOGRAPHY, PHYSICAL-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
8.70
自引率
17.30%
发文量
240
审稿时长
4-8 weeks
期刊介绍: The Cryosphere (TC) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies. The main subject areas are the following: ice sheets and glaciers; planetary ice bodies; permafrost and seasonally frozen ground; seasonal snow cover; sea ice; river and lake ice; remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.
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