Extraction of discontinuity sets of rocky slopes using iPhone-12 derived 3DPC and comparison to TLS and SfM datasets

Riquelme, Adrián; Tomás, Roberto; Cano, Miguel; Pastor, José Luis; Bordehore, Luis Jordá

doi:10.1088/1755-1315/833/1/012056

Cited by 18 publications

(14 citation statements)

References 24 publications

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“…Imaging of a site for photogrammetry models can be done relatively quickly (minutes per impact), but the post-field production and analysis of models (hours to tens of hours) lengthens the overall method time. Smartphones cameras, and the Light Detection and Ranging (LiDAR) capability of new generation iPhones or hand-held scanners, are increasingly able to generate 3D SfM models approaching the precision of those using digital cameras and SfM software, or those derived from terrestrial laser scanning (TLS) 36,37 . The LiDAR sensors in iPhones were developed to enhance photographs, and not to produce surface coordinates like traditional TLS.…”

Section: Discussionmentioning

confidence: 99%

Measuring crater volumes from bullet impacts: implications for field methods and cratering mechanics

Campbell

Blenkinsop

Gilbert

et al. 2022

Preprint

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Bullet impacts are a ubiquitous form of damage to the built environment resulting from armed conflicts. Bullet impacts into stone buildings result in surficial cratering, fracturing, and changes to material properties, such as permeability and surface hardness. Controlled experiments into two different sedimentary stones were conducted to characterise surface damage and to investigate the relationship between the impact energy (a function of engagement distance) and crater volumes. Simplified geometries of crater volume using only depth and diameter measurements showed that the volume of a simple cone provides the best approximation (within 5%) to crater volume measured from photogrammetry models. This result suggests a quick and efficient method of estimating crater volumes during field assessments of damage. Over the engagement distances studied (100 – 400 m), there is little consistent effect on crater volume, but different target materials result in an order of magnitude variation in measured crater volumes. Bullet impacts in the experiments are similar in appearance to damage caused by hypervelocity experiments, but crater excavation is driven by momentum transfer to the target rather than a hemispherical shock wave. Target material plays the dominant role in controlling damage, not projectile energy as predicted by some impact scaling relationships.

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Section: Discussionmentioning

confidence: 99%

Measuring crater volumes from bullet impacts: implications for field methods and cratering mechanics

Campbell

Blenkinsop

Gilbert

et al. 2022

Preprint

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“…While typically performed from a tripod, handheld full-size and smartphone-based models exist. These can generally attain 1 cm accuracy, however their smaller range may present issues for AEC applications, with the Apple Lidar having a maximum range of 5 m [37,38].…”

Section: Reality Capture To Digitized Demolition Sitesmentioning

confidence: 99%

Automating building element detection for deconstruction planning and material reuse: A case study

Gordon

Batallé

Wolf

et al. 2023

Automation in Construction

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“…There is growing attention in extracting information regarding discontinuities from the remote sensing derived datasets. These techniques could help to characterize discontinuities from close or far ranges of surfaces [2,3,4].…”

Section: Introductionmentioning

confidence: 99%

“…A camera is used in the SfM technique. Discontinuity sets could be extracted and analyzed by 3D point clouds provided by SfM and LiDAR by Discontinuity Set Extractor software (DSE) [4,10]. Companies are more encouraged now to develop devices with powerful processors and highresolution cameras since the use of smartphones is growing.…”

Section: Introductionmentioning

confidence: 99%

Method to obtain 3D point clouds of tunnels using smartphone LiDAR and comparison to photogrammetry

Torkan

Janiszewski

Uotinen

et al. 2023

IOP Conf. Ser.: Earth Environ. Sci.

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Remote sensing methods, for example, photogrammetry and laser scanning can be employed to scan rock masses by digitizing underground spaces or slopes. To reconstruct a 3D model by photogrammetry, plenty of photos should be captured. This process is time-consuming and can be dangerous when the rock mass is unstable. Therefore, rapid capturing methods are needed to reduce the acquisition time. This can be achieved with LiDAR scanners that capture a 3D point cloud with a high-speed pulsed laser beam. However, the cost of laser scanners is high, which limits their usability. Apple’s iPhone 12 Pro Max smartphone is equipped with a LiDAR sensor and is much cheaper than conventional laser scanners. Several mobile applications for 3D models using the smartphone Lidar have been developed, making the scanning process easy. Therefore, smartphones can be used for rapid scanning of unstable surfaces of tunnels and slopes. In this study, 3D point clouds (3DPC) of a tunnel wall of the Underground Research Laboratory of Aalto University (URLA) are obtained by a high-resolution digital camera and smartphone LiDAR. The models are analyzed and compared. The results show the quality of the smartphone LiDAR sensor is adequate for generating 3D models of underground spaces.

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Extraction of discontinuity sets of rocky slopes using iPhone-12 derived 3DPC and comparison to TLS and SfM datasets

Cited by 18 publications

References 24 publications

Measuring crater volumes from bullet impacts: implications for field methods and cratering mechanics

Measuring crater volumes from bullet impacts: implications for field methods and cratering mechanics

Automating building element detection for deconstruction planning and material reuse: A case study

Method to obtain 3D point clouds of tunnels using smartphone LiDAR and comparison to photogrammetry

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