A Method for Reconstruction of Size Distributions from 3D Drone Image Analysis: A Case Study

This paper describes a novel procedure to assess fragmentation from automatic analysis of 3D photogrammetric models with a commercial software. The muckpiles from 12 blasts were photographed with a conventional drone to build 3D photogrammetric models; the flights were made with a relatively constan...

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Bibliographic Details
Published in:Rock mechanics and rock engineering 2024-05, Vol.57 (5), p.4033-4050
Main Authors: Segarra, Pablo, Sanchidrián, José A., Pötsch, Markus, Iglesias, Luis, Gómez, Santiago, Gaich, Andreas, Bernardini, Maurizio
Format: Article
Language:English
Subjects:
Blasting
Civil Engineering
Earth and Environmental Science
Earth Sciences
Errors
Fragmentation
Geophysics/Geodesy
Image analysis
Image processing
Image reconstruction
Original Paper
Photogrammetry
Software
Three dimensional models
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Summary:This paper describes a novel procedure to assess fragmentation from automatic analysis of 3D photogrammetric models with a commercial software. The muckpiles from 12 blasts were photographed with a conventional drone to build 3D photogrammetric models; the flights were made with a relatively constant ground sampling distance (GSD) of 6.2 sd 0.92 mm (mean and standard deviation, respectively). A comparison with already published mass-based size distributions from 11 of these blasts, shows a good performance of automatic 3D-fragmentation measurements in the coarse range ( P  ≥ 60%), while deviations between mass-based and 3D model fragmentation analysis grow towards the central-fines range. As a solution, the Swebrec function is fitted to the reliable part of the size distributions, well above the GSD, and then is extended towards the fines, down to a percentage passing of 5–10%. The suitable fitting range is obtained iteratively from the mass-based fragmentation data; the lower fragment size considered is independent of the model’s resolution (i.e. GSD) with mean of 357 mm (equivalent to a passing in the range 66–86%, and well above the GSD of our models). The resulting distributions match properly mass-based size distributions with relative errors in percentile sizes of 15.5 sd 3.4%, and they can be represented with the simplest form of the fragmentation-energy-fan. As a guideline for reconstruction of size distributions and fines assessment when mass-based data is not available, the lower-fitting limit of 357 mm yields reasonable results (mean errors in pass in the range 5–36%) for the present case. The errors are limited enough to keep a sound description of the variation of fragmentation with change in blast design. Highlights 3D photogrammetric models are obtained from UAV flights over the muckpiles to assess fragmentation from blasting with a commercial software. The coarse fraction is reasonably well estimated through automatic analysis of 3D muckpile models. To correct deviations in the central-fines range, the Swebrec function is fitted to the coarse range (passings generally above 70%) and extrapolated to passing of 5–10%. The smaller fragment size considered for the fit is estimated for each blast from sieving data and it is independent of the model’s resolution; the mean of these sizes (357 mm) procures a proper fines assessment for the present case. The reconstructed image-based size distributions match properly mass-based size distributions an
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-024-03765-1