Centimetric Accuracy in Snow Depth Using Unmanned Aerial System Photogrammetry and a MultiStation

Avanzi, Francesco; Bianchi, Alberto; Cina, Alberto; Michele, Carlo De; Maschio, Paolo Felice; Pagliari, Diana; Passoni, D.; Pinto, Livio; Piras, Marco; Rossi, Lorenzo

doi:10.3390/rs10050765

Cited by 60 publications

(68 citation statements)

References 62 publications

(88 reference statements)

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“…In addition, airborne laser scanning (ALS) and terrestrial laser scanning (TLS) technologies have been applied as the preferred methods to obtain HS data [3,[26][27][28][29][30][31][32][33]. Moreover, tachymetry [28], ground-penetrating radar (GPR) [34,35], and time-lapse photography [36,37] have been used.The use of unmanned aerial system (UAS) technology in snow and avalanche studies has been recently reported in the literature [10,19,33,35,[38][39][40][41][42][43][44]. While the first studies on the use of a UAS in HS mapping investigated its potential and limitations by using manual HS probing for accuracy assessment, more recent studies have used time series of a UAS and compared it with other techniques, such as airborne sensors, including the ADS100 [45], TLS [33,44], and tri-stereoscopic Pléiades satellite images [46].…”

mentioning

confidence: 99%

“…Moreover, tachymetry [28], ground-penetrating radar (GPR) [34,35], and time-lapse photography [36,37] have been used.The use of unmanned aerial system (UAS) technology in snow and avalanche studies has been recently reported in the literature [10,19,33,35,[38][39][40][41][42][43][44]. While the first studies on the use of a UAS in HS mapping investigated its potential and limitations by using manual HS probing for accuracy assessment, more recent studies have used time series of a UAS and compared it with other techniques, such as airborne sensors, including the ADS100 [45], TLS [33,44], and tri-stereoscopic Pléiades satellite images [46]. Also, different camera sensors that record data in various parts of the electromagnetic spectrum, such as visible (350-680 nm) and near infrared (NIR) (in different ranges (>700 and >830 nm)), have been evaluated [10,43,44].…”

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confidence: 99%

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Monitoring of Snow Cover Ablation Using Very High Spatial Resolution Remote Sensing Datasets

Eker

Bühler²,

Schlögl³

et al. 2019

Remote Sensing

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This study tested the potential of a short time series of very high spatial resolution (cm to dm) remote sensing datasets obtained from unmanned aerial system (UAS)-based photogrammetry and terrestrial laser scanning (TLS) to monitor snow cover ablation in the upper Dischma valley (Davos, Switzerland). Five flight missions (for UAS) and five scans (for TLS) were carried out simultaneously: Four during the snow-covered period (9, 10, 11, and 27 May 2016) and one during the snow-free period (24 June 2016 for UAS and 31 May 2016 for TLS). The changes in both the areal extent of the snow cover and the snow depth (HS) were assessed together in the same case study. The areal extent of the snow cover was estimated from both UAS- and TLS-based orthophotos by classifying pixels as snow-covered and snow-free based on a threshold value applied to the blue band information of the orthophotos. Also, the usage possibility of TLS-based orthophotos for mapping snow cover was investigated in this study. The UAS-based orthophotos provided higher overall classification accuracy (97%) than the TLS-based orthophotos (86%) and allowed for mapping snow cover in larger areas than the ones from TLS scans by preventing the occurrence of gaps in the orthophotos. The UAS-based HS were evaluated and compared to TLS-based HS. Initially, the CANUPO (CAractérisation de NUages de POints) binary classification method, a proposed approach for improving the quality of models to obtain more accurate HS values, was applied to the TLS 3D raw point clouds. In this study, the use of additional artificial ground control points (GCPs) was also proposed to improve the quality of UAS-based digital elevation models (DEMs). The UAS-based HS values were mapped with an error of around 0.1 m during the time series. Most pixels representing change in the HS derived from the UAS data were consistent with the TLS data. The time series used in this study allowed for testing of the significance of the data acquisition interval in the monitoring of snow ablation. Accordingly, this study concluded that both the UAS- and TLS-based high-resolution DSMs were biased in detecting change in HS, particularly for short time spans, such as a few days, where only a few centimeters in HS change occur. On the other hand, UAS proved to be a valuable tool for monitoring snow ablation if longer time intervals are chosen.

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confidence: 99%

mentioning

confidence: 99%

Monitoring of Snow Cover Ablation Using Very High Spatial Resolution Remote Sensing Datasets

Eker

Bühler²,

Schlögl³

et al. 2019

Remote Sensing

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“…Like lidar and digital photogrammetry methods, SFM‐derived snow depth maps are computed by differencing two coregistered elevation models acquired for snow‐covered (snow‐on) and snow‐free (snow‐off) conditions. Reported snow depth root mean squared errors (RMSEs) using UAVs in alpine areas typically range between 7 and 30 cm (Adams et al, ; Avanzi et al, ; Bühler et al, ; de Michele et al, ; Harder et al, ; Vander Jagt et al, ).…”

Section: Introductionmentioning

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%

“…An additional challenge unique to mapping snow depth using elevation differencing is accounting for changes in the surface topography beneath the snow cover that may occur overtime. For example, seasonal erosion of the surface (Avanzi et al, 2018;Bernard et al, 2017), frost heave (Nolan et al, 2015), vegetation compression (Nolan et al, 2015), and permafrost creep (Goetz et al, 2019) can cause errors in the computed snow depths. In the case of monitoring snow accumulation on glaciers, glacier surface lowering due to ice or snow melt and ice flow can also lead to errors (Gindraux et al, 2017).…”

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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Quantifying snow water equivalent using terrestrial ground penetrating radar and unmanned aerial vehicle photogrammetry

Yildiz

Akyürek

Binley

2021

Hydrological Processes

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This study demonstrates the potential value of a combined unmanned aerial vehicle (UAV) Photogrammetry and ground penetrating radar (GPR) approach to map snow water equivalent (SWE) over large scales. SWE estimation requires two different physical parameters (snow depth and density), which are currently difficult to measure with the spatial and temporal resolution desired for basin-wide studies. UAV photogrammetry can provide very high-resolution spatially continuous snow depths (SD) at the basin scale, but does not measure snow densities. GPR allows nondestructive quantitative snow investigation if the radar velocity is known. Using photogrammetric snow depths and GPR two-way travel times (TWT) of reflections at the snowground interface, radar velocities in snowpack can be determined. Snow density (RSN) is then estimated from the radar propagation velocity (which is related to electrical permittivity of snow) via empirical formulas. A Phantom-4 Pro UAV and a MALA GX450 HDR model GPR mounted on a ski mobile were used to determine snow parameters. A snow-free digital surface model (DSM) was obtained from the photogrammetric survey conducted in September 2017. Then, another survey in synchronization with a GPR survey was conducted in February 2019 whilst the snowpack was approximately at its maximum thickness. Spatially continuous snow depths were calculated by subtracting the snow-free DSM from the snow-covered DSM.Radar velocities in the snowpack along GPR survey lines were computed by using UAV-based snow depths and GPR reflections to obtain snow densities and SWEs.The root mean square error of the obtained SWEs (384 mm average) is 63 mm, indicating good agreement with independent SWE observations and the error lies within acceptable uncertainty limits.digital surface model, digital terrain model, ground penetrating radar, photogrammetry, snow density, snow tube, snow water equivalent, unmanned aerial vehicle | INTRODUCTIONSnow water equivalent (SWE) is the product of snow depth and bulk density (relative to water) and is commonly reported in units of mm. It is a key variable that characterizes the hydrological significance of the snow cover. SWE information is needed to calibrate hydrological models, estimate snowmelt runoff in drainage basins, and improve decision making concerning water supply, hydroelectric power and flood forecasting. SWE is also useful to studies related to snow climatology, ecological function, and avalanche forecasting. SWE can

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Centimetric Accuracy in Snow Depth Using Unmanned Aerial System Photogrammetry and a MultiStation

Cited by 60 publications

References 62 publications

Monitoring of Snow Cover Ablation Using Very High Spatial Resolution Remote Sensing Datasets

Monitoring of Snow Cover Ablation Using Very High Spatial Resolution Remote Sensing Datasets

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

Quantifying snow water equivalent using terrestrial ground penetrating radar and unmanned aerial vehicle photogrammetry

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