Monitoring snow depth change across a range of landscapes with ephemeral snowpacks using structure from motion applied to lightweight unmanned aerial vehicle videos

Fernandes, Richard; Prévost, C; Canisius, Francis; Leblanc, Sylvain G.; Maloley, Matt; Oakes, S; Holman, Kiyomi; Knudby, Anders

doi:10.5194/tc-12-3535-2018

Cited by 35 publications

(44 citation statements)

References 34 publications

(76 reference statements)

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“…Snow is challenging for building products from Structure from Motion (SfM) algorithms because of the high reflectance of homogenous surfaces and lack of contrast. True to photogrammetric theory, limited variation in surface features could hinder SfM software in identifying tie points to match between images, leading to increased inaccuracy or failure to utilize images within an orthomosaic [94]. Because of this, Bühler et al [34] suggested fresh snow to be less suitable than older, weathered snow for reliable photogrammetry.…”

Section: Uavs For Snow Researchmentioning

confidence: 99%

Applications of Unmanned Aerial Vehicles in Cryosphere: Latest Advances and Prospects

2020

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Owing to usual logistic hardships related to field-based cryospheric research, remote sensing has played a significant role in understanding the frozen components of the Earth system. Conventional spaceborne or airborne remote sensing platforms have their own merits and limitations. Unmanned aerial vehicles (UAVs) have emerged as a viable and inexpensive option for studying the cryospheric components at unprecedented spatiotemporal resolutions. UAVs are adaptable to various cryospheric research needs in terms of providing flexibility with data acquisition windows, revisits, data/sensor types (multispectral, hyperspectral, microwave, thermal/night imaging, Light Detection and Ranging (LiDAR), and photogrammetric stereos), viewing angles, flying altitudes, and overlap dimensions. Thus, UAVs have the potential to act as a bridging remote sensing platform between spatially discrete in situ observations and spatially continuous but coarser and costlier spaceborne or conventional airborne remote sensing. In recent years, a number of studies using UAVs for cryospheric research have been published. However, a holistic review discussing the methodological advancements, hardware and software improvements, results, and future prospects of such cryospheric studies is completely missing. In the present scenario of rapidly changing global and regional climate, studying cryospheric changes using UAVs is bound to gain further momentum and future studies will benefit from a balanced review on this topic. Our review covers the most recent applications of UAVs within glaciology, snow, permafrost, and polar research to support the continued development of high-resolution investigations of cryosphere. We also analyze the UAV and sensor hardware, and data acquisition and processing software in terms of popularity for cryospheric applications and revisit the existing UAV flying regulations in cold regions of the world. The recent usage of UAVs outlined in 103 case studies provide expertise that future investigators should base decisions on.

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Section: Uavs For Snow Researchmentioning

confidence: 99%

Applications of Unmanned Aerial Vehicles in Cryosphere: Latest Advances and Prospects

2020

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“…In general, the precision of the SFM DEMs is related to flying height, distance to GCP, and image overlap (Goetz et al, 2018;James, Robson, Smith, et al, 2017), as well as field site conditions (Bühler, Adams, Bösch, et al, 2016;Nolan et al, 2015). That is, errors in the computed snow depths can also vary temporally due to different snow-cover conditions (Adams et al, 2018;Bühler, Adams, Bösch, et al, 2016;Fernandes et al, 2018;Harder et al, 2016). The precision for most of the study area was less than 4 cm (at 1σ).…”

Section: Water Resources Researchmentioning

confidence: 99%

“…Adding oblique imagery instead of using only nadir viewing angles or including more images (e.g., higher image overlap) can improve the quality of SFM reconstruction without having to rely solely on GCPs for mitigating SFM reconstruction errors (James & Robson, 2014;James, Robson, d'Oleire-Oltmanns, et al, 2017). Additionally, the density of the GCP network can be further reduced with the use of RTK or post-processing kinematic solutions for correction of the UAVs onboard GNSS for higher-quality camera location estimates (Fernandes et al, 2018;James, Robson, d'Oleire-Oltmanns, et al, 2017). Therefore, by surveying with a strong image network, using high-quality geotagging and ground control (e.g., RTK/PKK GNSS measurements), large-scale SFM snow depth mapping is likely more feasible.…”

Section: Reducing Sfm Snow Depth Uncertaintiesmentioning

confidence: 99%

“…The quality of the SFM‐derived elevation models for snow depth mapping generally depends on field site conditions, survey design, and the SFM software. These aspects can include the snowpack conditions (e.g., the presence of fresh snow or ice; Gindraux et al, ; Fernandes et al, ; Bühler et al, ; Cimoli et al, ; Vander Jagt et al, ; de Michele et al, ), terrain conditions (e.g., hilly or flat; Cimoli et al, ; Avanzi et al, ), lighting conditions (i.e., presence of shadows; e.g., zenith angle of the sun and cloud coverage; Goetz et al, ; Nolan et al, ; Cimoli et al, ; Harder et al, ; Bühler, Adams, Stoffel, et al, ; Gindraux et al, ), characteristics of the UAV survey (e.g., flying height, image overlap, and distribution of ground control; Goetz et al, ; James et al, ; Tonkin et al, ; Gindraux et al, ), and the SFM software processing (e.g., settings for sparse and dense point cloud quality; Cimoli et al, ; Hendrickx et al, ; Gindraux et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Quantifying Uncertainties in Snow Depth Mapping From Structure From Motion Photogrammetry in an Alpine Area

Goetz

Brenning

2019

Water Resources Research

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Mapping snow conditions in alpine areas is crucial for monitoring local hydrology to support water resource management decisions. Recently, the use of structure‐from‐motion multiview stereo 3‐D reconstruction (or SFM photogrammetry) to derive high‐resolution digital elevation models (DEMs) has become popular for mapping snow depth in alpine areas. In this study, methods for communicating spatial uncertainties in snow depth calculated from SFM‐derived DEMs are presented using a case study in the French Alps. A spatially varying snow depth precision estimate was determined using an error propagation model based on the precision of the acquired SFM DEMs, which was obtained from repeated unmanned aerial vehicle flights. Spatially varying snow depth detection limits were determined using Student's t distribution. It was found that snow depths as shallow as 1 to 5 cm could be detected with high confidence for most of the study area. Areas of high uncertainties were generally related to where the extent of the ground control coverage did not match in the snow‐on and snow‐off surveys and in areas with higher surface roughness. A map of the snow depth detection threshold was found to be useful for identifying areas with high uncertainties and potential biases in the SFM snow depths, such as errors due to changes in topography between DEM acquisition dates and poor SFM reconstruction.

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“…The primary drawbacks of UAS SfM as compared to lidar for mapping snow depth are that the DSM needs to be georeferenced using ground control points (GCPs) with known coordinates and may require significant manual steps (Tonkin et al, 2016;Meyer and Skiles, 2019), although new 85 techniques are emerging that may reduce field data collection time (Gabrlik et al, 2019;Meyer and Skiles, 2019). Dense canopy or vegetation can reduce performance when snow compresses the vegetation relative to the snow-off imagery or when above-canopy vegetation is falsely interpreted to be the snow surface (Bühler et al, 2017;Cimoli et al, 2017;De Michele et al, 2016;Fernandes et al, 2018;Harder et al, 2016;Nolan et al, 2015). Canopy effects impact SfM snow mapping capability in regions where shallow snowpacks are masked by dense forest canopies like the northeastern United 90…”

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confidence: 99%

Shallow snow depth mapping with unmanned aerial systems lidar observations: A case study in Durham, New Hampshire, United States

Jacobs

Hunsaker

Sullivan

et al. 2020

Preprint

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Shallow snowpack conditions, which occur throughout the year in many regions as well as during accumulation and ablation periods in all regions, are important in water resources, agriculture, ecosystems, and winter recreation.Terrestrial and airborne (manned and unmanned) laser scanning and structure from motion (SfM) techniques have emerged as viable methods to map snow depths. Lidar on an unmanned aerial vehicle is also a potential method to observe field and 15 slope scale variations of shallow snowpacks. This paper describes an unmanned aerial lidar system, which uses commercially available components, for snow depth mapping on the landscape scale. The system was assessed in a mixed deciduous and coniferous forest and open field for a shallow snowpack (< 20 cm). The lidar ground point clouds yielded an average of 90 and 364 points/m 2 in the forest and field, respectively. Comparisons of snow probe and lidar mean snow depths in the field, at 0.4 m resolution, had a mean absolute difference of 0.96 cm and a root mean squared difference of 1.22 20 cm. In the forest, the in situ mean snow depth was nearly twice that from the lidar from mean absolute difference of 9.6 cm and root mean squared difference of 10.5 cm. These differences in forests are likely due, in part, to limitations of sampling using a snow probe. At 1 m resolution, the field snow depth precision was consistently less than 1 cm. The forest and heavily vegetated areas had modestly reduced performance with typical values within 4 cm precision. Performance depends on both the point cloud density, which can be increased or decreased by changing the flight plan, and the within cell variability that 25 depends on site surface conditions.

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Monitoring snow depth change across a range of landscapes with ephemeral snowpacks using structure from motion applied to lightweight unmanned aerial vehicle videos

Cited by 35 publications

References 34 publications

Applications of Unmanned Aerial Vehicles in Cryosphere: Latest Advances and Prospects

Applications of Unmanned Aerial Vehicles in Cryosphere: Latest Advances and Prospects

Quantifying Uncertainties in Snow Depth Mapping From Structure From Motion Photogrammetry in an Alpine Area

Shallow snow depth mapping with unmanned aerial systems lidar observations: A case study in Durham, New Hampshire, United States

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