Global registration of large collections of range images with an improved Optimization-on-a-Manifold approach

Bonarrigo, Francesco; Signoroni, Alberto

doi:10.1016/j.imavis.2014.02.012

Cited by 4 publications

(2 citation statements)

References 40 publications

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“…Then we fixed by hand the failed alignments that occurred during the process by running again the pipeline with user-selected control points for the critical point clouds. Finally, we refined the result in a global fashion by leveraging on an optimization-on-a-manifold framework [8] . Eventually, the final set of point clouds is properly aligned, thus constituting the ground truth for different kinds of tests on 3D object registration or for training/fine-tuning models to cope with small-scale 3D objects and dense acquisitions.…”

Section: Experimental Design Materials and Methodsmentioning

confidence: 99%

DenseMatch: a dataset for real-time 3D reconstruction

2021

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We provide a database aimed at real-time quantitative analysis of 3D reconstruction and alignment methods, containing 3140 point clouds from 10 subjects/objects. These scenes are acquired with a high-resolution 3D scanner. It contains depth maps that produce point clouds with more than 500k points on average. This dataset is useful to develop new models and alignment strategies to automatically reconstruct 3D scenes from data acquired with optical scanners or benchmarking purposes.

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Section: Experimental Design Materials and Methodsmentioning

confidence: 99%

DenseMatch: a dataset for real-time 3D reconstruction

2021

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“…In contrast, lightweight configurations can be achieved by integrating a limited number of sensors, although this approach necessitates multiple scanner placements around the patient’s arm to capture the complete anatomy [ 15 ]. This technique is more flexible and adaptable to different patients’ needs but requires accurate registration of the acquired multiple views into a common reference frame, which is conventionally composed of two alignment steps [ 16 , 17 ]: a local coarse alignment and a global fine registration. The first step is based on manually identifying common landmarks on different scans.…”

Section: Introductionmentioning

confidence: 99%

Automatic Multiview Alignment of RGB-D Range Maps of Upper Limb Anatomy

Di Angelo,

Di Stefano,

Guardiani

et al. 2023

Sensors

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Digital representations of anatomical parts are crucial for various biomedical applications. This paper presents an automatic alignment procedure for creating accurate 3D models of upper limb anatomy using a low-cost handheld 3D scanner. The goal is to overcome the challenges associated with forearm 3D scanning, such as needing multiple views, stability requirements, and optical undercuts. While bulky and expensive multi-camera systems have been used in previous research, this study explores the feasibility of using multiple consumer RGB-D sensors for scanning human anatomies. The proposed scanner comprises three Intel® RealSenseTM D415 depth cameras assembled on a lightweight circular jig, enabling simultaneous acquisition from three viewpoints. To achieve automatic alignment, the paper introduces a procedure that extracts common key points between acquisitions deriving from different scanner poses. Relevant hand key points are detected using a neural network, which works on the RGB images captured by the depth cameras. A set of forearm key points is meanwhile identified by processing the acquired data through a specifically developed algorithm that seeks the forearm’s skeleton line. The alignment process involves automatic, rough 3D alignment and fine registration using an iterative-closest-point (ICP) algorithm expressly developed for this application. The proposed method was tested on forearm scans and compared the results obtained by a manual coarse alignment followed by an ICP algorithm for fine registration using commercial software. Deviations below 5 mm, with a mean value of 1.5 mm, were found. The obtained results are critically discussed and compared with the available implementations of published methods. The results demonstrate significant improvements to the state of the art and the potential of the proposed approach to accelerate the acquisition process and automatically register point clouds from different scanner poses without the intervention of skilled operators. This study contributes to developing effective upper limb rehabilitation frameworks and personalized biomedical applications by addressing these critical challenges.

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