Multi‐temporal 3D point cloud‐based quantification and analysis of geomorphological activity at an alpine rock glacier using airborne and terrestrial LiDAR

Zahs, Vivien; Hämmerle, Martin; Anders, Katharina; Hecht, Stefan; Sailer, Rudolf; Rutzinger, Martin; Williams, Jack G.; Höfle, Bernhard

doi:10.1002/ppp.2004

Cited by 17 publications

(14 citation statements)

References 52 publications

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“…The RMSE and the mean error ranged from 0.19 to 0.23 m, and from 0.13 to 0.16 m, respectively, being the slope and the undergrowth vegetation the most important factors influencing DTM accuracy. In [6], as part of a multitemporal study of an alpine rock glacier, the signed discrepancy for stable areas yielded a standard deviation of 0.23 m for a time span of 5 years. LiDAR precision is also evaluated for physical features, as for example in [7], where the LiDAR error for dimensional features of a bridge and several fence posts reach up to 23.5%.…”

Section: Introductionmentioning

confidence: 99%

A New Method for Positional Accuracy Control for Non-Normal Errors Applied to Airborne Laser Scanner Data

et al. 2019

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A new statistical method for the quality control of the positional accuracy, useful in a wide range of data sets, is proposed and its use is illustrated through its application to airborne laser scanner (ALS) data. The quality control method is based on the use of a multinomial distribution that categorizes cases of errors according to metric tolerances. The use of the multinomial distribution is a very novel and powerful approach to the problem of evaluating positional accuracy, since it allows for eliminating the need for a parametric model for positional errors. Three different study cases based on ALS data (infrastructure, urban, and natural cases) that contain non-normal errors were used. Three positional accuracy controls with different tolerances were developed. In two of the control cases, the tolerances were defined by a Gaussian model, and in the third control case, the tolerances were defined from the quantiles of the observed error distribution. The analysis of the test results based on the type I and type II errors show that the method is able to control the positional accuracy of freely distributed data.

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Section: Introductionmentioning

confidence: 99%

A New Method for Positional Accuracy Control for Non-Normal Errors Applied to Airborne Laser Scanner Data

et al. 2019

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“…Disaggregating the changes related to this deformation represents a valuable step in interpreting how rock glaciers move, as well as what drives this movement. Approaches to support these interpretations based on in situ monitoring, such as the distribution of electrical resistivity tomography values (Zahs et al, 2019) or ground temperature records from boreholes (Kenner et al, 2017) are also of value. To distinguish changes at the surface, which are assumed to be in the order of a few centimeters within timescales of few weeks, 3D topographic data at high spatial resolution are required.…”

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confidence: 99%

“…These can be obtained using lidar systems (e.g. Bollmann et al, 2012;Micheletti et al, 2016;Zahs et al, 2019), which provide highaccuracy and high-precision 3D measurements of a surface at centimeter-scale point spacing (generally equating to spatial resolution).…”

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confidence: 99%

“…While Zahs et al (2019) have applied this approach to existing datasets of the rock glacier Äußeres Hochebenkar, the processes that cause the observed changes may induce movement along different predominant directions. Examining change in multiple directions may therefore be required in order to distinguish these processes.…”

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confidence: 99%

“…Repeated data acquisitions using lidar have seen increasing use in order to detect and quantify rock glacier surface change (Bollmann et al, 2012;Bollmann et al, 2015;Micheletti et al, 2016;Klug et al, 2017;Zahs et al, 2019). To date, most studies have used monitoring intervals of one year or longer.…”

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Disaggregating surface change mechanisms of a rock glacier using terrestrial laser scanning point clouds acquired at different time scales

Ulrich¹,

Williams²,

Zahs³

et al. 2020

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Abstract. Topographic change at a given location usually results from multiple processes operating over different timescales. However, interpretations of surface change are often based upon single values of movement, measured over a specified time period and in a single direction. This work presents a method to help separate surface change mechanisms related to the deformation of an active rock glacier, drawing on terrestrial lidar monitoring at sub-monthly intervals. We derive 3D topographic changes across the Äußeres Hochebenkar rock glacier in the Ötztal Alps. These are presented as the relative contribution of surface change during a three-week period of snow-free conditions (2018) to the annual surface change (2017–2018). They are also separated according to the direction perpendicular to the local rock glacier surface (using point cloud distance computation) and the direction of rock glacier flow, indicated by movement of individual boulders. In a 1500 m2 sample area in the lower tongue section of the rock glacier, the contribution of the three-week period to the annual change perpendicular to the surface is 20 %, as compared to 6 % in the direction of rock glacier flow. This shows that different directions of surface change are dominant at different times of the year. Our results demonstrate the benefit of more frequent lidar monitoring and, critically, the requirement of novel approaches to detecting change, as a step towards interpreting the mechanisms that underlie the surface change of rock glaciers.

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Kinematics of an Alpine rock glacier from multi-temporal UAV surveys and GNSS data

et al. 2022

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Multi‐temporal 3D point cloud‐based quantification and analysis of geomorphological activity at an alpine rock glacier using airborne and terrestrial LiDAR

Cited by 17 publications

References 52 publications

A New Method for Positional Accuracy Control for Non-Normal Errors Applied to Airborne Laser Scanner Data

A New Method for Positional Accuracy Control for Non-Normal Errors Applied to Airborne Laser Scanner Data

Disaggregating surface change mechanisms of a rock glacier using terrestrial laser scanning point clouds acquired at different time scales

Kinematics of an Alpine rock glacier from multi-temporal UAV surveys and GNSS data

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