To Fill or Not to Fill: Sensitivity Analysis of the Influence of Resolution and Hole Filling on Point Cloud Surface Modeling and Individual Rockfall Event Detection

Olsen, Michael J.; Wartman, Joseph; McAlister, Martha; Mahmoudabadi, Hamid; O'Banion, Matt; Dunham, Lisa; Cunningham, Keith

doi:10.3390/rs70912103

Cited by 31 publications

(36 citation statements)

References 47 publications

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“…Multi-temporal TLS scans have been used to identify and characterize patterns of precursor rockfall activity [1][2][3]; and to detect and analyze millimeter-scale pre-failure deformation in rock slopes [4,5]. TLS systems have also been used for rock bridge characterization [6], assessing cliff-talus interactions [7], and most commonly; the development of remotely sensed rockfall databases [8][9][10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

“…Recent work by Olsen et al [10] raises a key issue with many of these analyses. At many study sites, complex slope geometry results in occlusions (i.e., holes) in the point cloud captured by the TLS system.…”

Section: Introductionmentioning

confidence: 99%

“…For accurate volume calculations, the triangulated surface mesh must be watertight, free of intersecting triangles and have consistent normal vector orientation. As noted by Olsen et al [10], ensuring that each mesh is topologically correct can require significant manual editing which is time-consuming and subjective. Therefore there is a need to evaluate automated surface reconstruction algorithms and their influence on resulting volumetric analyses, in order to improve methods used to monitor and quantify geomorphological processes.…”

Section: Introductionmentioning

confidence: 99%

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Surface Reconstruction for Three-Dimensional Rockfall Volumetric Analysis

Bonneau

DiFrancesco

Hutchinson

2019

IJGI

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Laser scanning is routinely being used for the characterization and management of rockfall hazards. A key component of many studies is the ability to use the high-resolution topographic datasets for detailed volume estimates. 2.5-Dimensional (2.5D) approaches exist to estimate the volume of rockfall events; however these approaches require rasterization of the point cloud. These 2.5D volume estimates are therefore sensitive to picking an appropriate cell size to preserve resolution while minimizing interpolation, especially for lower volume rockfall events. To overcome the limitations of working with 2.5D raster datasets, surface reconstruction methods originating from the field of computational geometry can be implemented to assess the volume of rockfalls in 3D. In this technical note, the authors address the methods and implications of how the surface of 3D rockfall objects, derived from sequential terrestrial laser scans (TLS), are reconstructed for volumetric analysis. The Power Crust, Convex Hull and Alpha-shape algorithms are implemented to reconstruct a synthetic rockfall object generated in Houdini, a procedural modeling and animation software package. The reconstruction algorithms are also implemented for a selection of three rockfall cases studies which occurred in the White Canyon, British Columbia, Canada. The authors find that there is a trade-off between accurate surface topology reconstruction and ensuring the mesh is watertight manifold; which is required for accurate volumetric estimates. Power Crust is shown to be the most robust algorithm, however, the iterative Alpha-shape approach introduced in the study is also shown to find a balance between hole-filling and loss of detail.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Surface Reconstruction for Three-Dimensional Rockfall Volumetric Analysis

Bonneau

DiFrancesco

Hutchinson

2019

IJGI

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“…The work presented in this Special Issue by Olsen et al [16] utilized a 2.5D connected component algorithm for isolating individual failure clusters and for calculating the volume of each individual rockfall. Compared to other processing techniques using the original 3D point clouds (e.g., noise reduction and feature extraction, clustering of individual failures, automatic volume calculation have already been proposed [32,37]), Olsen and colleagues proposed an original technique for filling data gaps due to topographic obstructions on the interpolated mesh.…”

Section: Rock Slope Monitoring and Automatic Rockfall Extractionmentioning

confidence: 99%

“…Several submissions were related to the development of specific methods for data treatment, examples including the pre-processing of High Dynamic Range (HDR) imagery, the automatic extraction of rockfalls from multi-temporal LiDAR datasets and the treatment of massive amounts of geometrical data for carrying out efficient 4D monitoring. Several other contributions deal with the investigation of a given physical phenomena including slow-moving lava flows coming from recent volcanic eruptions [12], shear displacements due to historical earthquakes [13] and mass movements both on mountainous areas [14] and rocky cliffs [15,16]. A short review of each topic of investigation addressed in this Special Issue, including an overall context and main findings, is given below.…”

Section: Introductionmentioning

confidence: 99%

“Use of 3D Point Clouds in Geohazards” Special Issue: Current Challenges and Future Trends

2016

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Effects of sampling interval on the frequency - magnitude relationship of rockfalls detected from terrestrial laser scanning using semi-automated methods

et al. 2017

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Using change detection and semi-automated identification methods, it is possible to extract detailed rockfall information from terrestrial laser scanning data to build a database of events, which can be used in the development of the frequency-magnitude relationship for a slope. In this study, we have applied these methods to the White Canyon, a hazardous slope that presents rockfall hazards to the CN Rail line in British Columbia, to build a database of rockfalls including their locations, volumes, and block shapes. We identified over 1900 rockfall events during a 15-month period, ranging in volume from 0.01 to 45 m 3. The frequency of these events changed throughout the year, with the highest periods of activity occurring over the winter months. We investigated how the sampling interval, or duration between scans, can affect how the rockfalls are identified, and therefore the frequency-magnitude relationship for the slope using datasets with fewer scans. We show that as the duration between scans becomes larger, fewer rockfalls are detected, as multiple events that have occurred in the same location cluster together into a single event. The results of this study can be used to assist the railways in planning the appropriate number and duration between future scans, in order to capture frequency-magnitude data for the slope with a desired level of detail.

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To Fill or Not to Fill: Sensitivity Analysis of the Influence of Resolution and Hole Filling on Point Cloud Surface Modeling and Individual Rockfall Event Detection

Cited by 31 publications

References 47 publications

Surface Reconstruction for Three-Dimensional Rockfall Volumetric Analysis

Surface Reconstruction for Three-Dimensional Rockfall Volumetric Analysis

“Use of 3D Point Clouds in Geohazards” Special Issue: Current Challenges and Future Trends

Effects of sampling interval on the frequency - magnitude relationship of rockfalls detected from terrestrial laser scanning using semi-automated methods

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