Impact-Detection Algorithm That Uses Point Clouds as Topographic Inputs for 3D Rockfall Simulations

Numerous 3D rockfall simulation models use coarse gridded digital terrain model (DTM raster) as their topography input. Artificial surface roughness is often added to overcome the loss of details that occurs during the gridding process. Together with the use of sensitive energy damping parameters, they provide great freedom to the user at the expense of the objectivity of the method. To quantify and limit the range of such artificial values, we developed an impact-detection algorithm that can be used to extract the perceived surface roughness from detailed terrain samples in relation to the size of the impacting rocks. The algorithm can also be combined with a rebound model to perform rockfall simulations directly on detailed 3D point clouds. The abilities of the algorithm are demonstrated by objectively extracting different perceived surface roughnesses from detailed terrain samples and by simulating rockfalls on detailed terrain models as proof of concept. The results produced are also compared to that of rockfall simulation software CRSP 4, RocFall 8 and Rockyfor3D 5.2.15 as validation. Although differences were observed, the validation shows that the algorithm can produce similar results. With the presented approach not being limited to coarse terrain models, the need for adding artificial terrain roughness or for adjusting sensitive damping parameters on a per-site basis is reduced, thereby limiting the related biases and subjectivity.

[1]  Frédéric Berger,et al.  Stem breakage of trees and energy dissipation during rockfall impacts. , 2006, Tree physiology.

[2]  Tom Edwards,et al.  A 4D Filtering and Calibration Technique for Small-Scale Point Cloud Change Detection with a Terrestrial Laser Scanner , 2015, Remote. Sens..

[3]  C. Derek Martin,et al.  RockFall analyst: A GIS extension for three-dimensional and spatially distributed rockfall hazard modeling , 2007, Comput. Geosci..

[4]  P. Grussenmeyer,et al.  Surveying and modeling of rock discontinuities by terrestrial laser scanning and photogrammetry: Semi-automatic approaches for linear outcrop inspection , 2014 .

[5]  P. Asteriou,et al.  Effect of impact velocity, block mass and hardness on the coefficients of restitution for rockfall analysis , 2018, International Journal of Rock Mechanics and Mining Sciences.

[6]  D. J. Hutchinson,et al.  Evaluating roadside rockmasses for rockfall hazards using LiDAR data: optimizing data collection and processing protocols , 2010, Natural Hazards.

[7]  Roberto Tomás,et al.  Characterization of rock slopes through slope mass rating using 3D point clouds , 2016 .

[8]  P. Asteriou,et al.  Geotechnical and kinematic parameters affecting the coefficients of restitution for rock fall analysis , 2012 .

[9]  Q. Fang,et al.  Numerical simulation of rockfall trajectory with consideration of arbitrary shapes of falling rocks and terrain , 2020 .

[10]  M. Jaboyedoff,et al.  Quantifying 40 years of rockfall activity in Yosemite Valley with historical Structure-from-Motion photogrammetry and terrestrial laser scanning , 2020 .

[11]  O. Hungr,et al.  Pierre3D: a 3D stochastic rockfall simulator based on random ground roughness and hyperbolic restitution factors , 2015 .

[12]  Sophia E. Demmel,et al.  Reconstruction of four-dimensional rockfall trajectories using remote sensing and rock-based accelerometers and gyroscopes , 2019, Earth Surface Dynamics.

[13]  F. Bourrier,et al.  Improving three-dimensional rockfall trajectory simulation codes for assessing the efficiency of protective embankments , 2013 .

[14]  C. Thorne,et al.  Quantitative analysis of land surface topography , 1987 .

[15]  T. Pfeiffer,et al.  Computer Simulation of Rockfalls , 1989 .

[16]  Anna Giacomini,et al.  Statistical evaluation of rockfall energy ranges for different geological settings of New South Wales, Australia , 2013 .

[17]  K. Thoeni,et al.  A rapid approach to estimate the rockfall energies and distances at the base of rock cliffs , 2016 .

[18]  F. Nicot,et al.  Toward a Generic Computational Approach for Flexible Rockfall Barrier Modeling , 2019, Rock Mechanics and Rock Engineering.

[19]  O. Buzzi,et al.  In situ rockfall testing in New South Wales, Australia , 2012 .

[20]  F. Berger,et al.  Real-size experiments and 3-D simulation of rockfall on forested and non-forested slopes , 2006 .

[21]  Dimitri Lague,et al.  3D Terrestrial LiDAR data classification of complex natural scenes using a multi-scale dimensionality criterion: applications in geomorphology , 2011, ArXiv.

[22]  Z. Ji,et al.  Laboratory study on the influencing factors and their control for the coefficient of restitution during rockfall impacts , 2019, Landslides.

[23]  P. Asteriou Effect of Impact Angle and Rotational Motion of Spherical Blocks on the Coefficients of Restitution for Rockfalls , 2018, Geotechnical and Geological Engineering.

[24]  Yang Ye,et al.  An Experimental and Theoretical Study of the Normal Coefficient of Restitution for Marble Spheres , 2019, Rock Mechanics and Rock Engineering.

[25]  L. Ravanel,et al.  Assessing rockfall susceptibility in steep and overhanging slopes using three-dimensional analysis of failure mechanisms , 2018, Landslides.

[26]  M. Jaboyedoff,et al.  Terrestrial laser scanning of rock slope instabilities , 2014 .

[27]  F. Berger,et al.  Mechanisms, effects and management implications of rockfall in forests , 2005 .

[28]  Franck Bourrier,et al.  Introducing Meta-models for a More Efficient Hazard Mitigation Strategy with Rockfall Protection Barriers , 2018, Rock Mechanics and Rock Engineering.

[29]  Sophia E. Demmel,et al.  Modelling rockfall impact with scarring in compactable soils , 2019, Landslides.

[30]  O. Buzzi,et al.  Laboratory Investigation on High Values of Restitution Coefficients , 2011, Rock Mechanics and Rock Engineering.

[31]  J D Higgins,et al.  ROCKFALL HAZARD ANALYSIS USING THE COLORADO ROCKFALL SIMULATION PROGRAM , 1990 .

[32]  Wei Jiang,et al.  Effects of the impact angle on the coefficient of restitution in rockfall analysis based on a medium-scale laboratory test , 2018, Natural Hazards and Earth System Sciences.

[33]  R. Metzger,et al.  New insight techniques to analyze rock-slope relief using DEM and 3D-imaging cloud points: COLTOP-3D software , 2007 .

[34]  O. Hungr,et al.  Rockfall rebound: comparison of detailed field experiments and alternative modelling approaches , 2012 .

[35]  Giovanni B. Crosta,et al.  Engineering Geology for Society and Territory - Volume 2: Landslide Processes , 2015 .