A comparison of hole-filling methods in 3D

Tejado, Inés; Salamanca, Santiago; Merchán, Pilar; Adán, Antonio

doi:10.1515/amcs-2016-0063

Cited by 25 publications

(14 citation statements)

References 57 publications

(63 reference statements)

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“…At the moment there is no general approach to solve this problem. Existing methods can be divided into three categories [5]: methods based on polygonal representation (restores arbitrary holes and irregular data can be used, but requires significant computational resources and user involvement in processing), methods based on parametric representation (does not require user involvement in the formation of the model but allows you to repair only small holes, requires holes to be regular and it does not work well with highly curved surfaces), methods based on signed distance functions and voluminous performances (restores arbitrary holes, irregular data can be used, restores large holes and does not require user input but requires significant computational resources and high resolution input). Professional software packages (RapidForm XOR, RapidForm XOR, etc.)…”

Section: Methods Of Inverse Distancesmentioning

confidence: 99%

Reconstruction of the Sculpture Surface in the Process of Optical 3D Scanning

Shchegoleva

Parfenov

Smolina

2020

Wseas Transactions on Computers

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Currently, 3D scanning technology is used for high-precision measurements and fixing the geometric shape of various objects. However, when creating a computer 3D-model as a result of processing the array of data obtained from the scanning process, may contain errors. Errors may related to the features of the studied object (material, weight, size, location), functional properties of the software used or they may be the low qualification of the software engineer involved in processing 3D scan data. The task of this work was a finding the technical solutions, which allows one to reconstruct the objects surface, recorded using 3D scanning in the process of creating their computer 3D models. We proposed to use the inverse distance method, which is used in biometry to improve the quality of reconstruction of the 3D surface of a human face. Experiments have shown that the result of the reconstruction makes it possible to increase the accuracy of creating 3D models by recovering gaps in the surface of an object that were made during the 3D scanning process. The proposed approach allows one to construct a 3D surface without solving the triangulation problem, which leads to a reduction in computational costs.

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Section: Methods Of Inverse Distancesmentioning

confidence: 99%

Reconstruction of the Sculpture Surface in the Process of Optical 3D Scanning

Shchegoleva

Parfenov

Smolina

2020

Wseas Transactions on Computers

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“…According to the work from Ju et al [16], the hole-filling methods based on a triangular mesh can be classified into two groups: surface-based methods and volume-based methods. In most cases, the former operates directly on the given mesh and follows the same stages: hole detection, initial filling and refinement [4]. The latter converts the input mesh into a signed distance function over a volumetric grid to fill holes and then extracts a completed mesh from a zero-level set of the distance function [17].…”

Section: Hole-fillingmentioning

confidence: 99%

“…The main advantage of volume-based methods is its robustness in resolving geometric errors, and the drawback is the loss of geometric detail. For more works, please refer to these two survey papers [3,4]. Based on the above analysis, fast hole-filling, especially for different sizes of holes, is still a challenge.…”

Section: Hole-fillingmentioning

confidence: 99%

“…Although many hole-filling techniques have been proposed in the last two decades [3,4], most of them are originally designed to handle one or fewer types of holes. For example, to repair the mesh holes generated by the Poisson surface reconstruction algorithm towards 3D printing, Sheng et al proposed an iterative postprocessing algorithm for partial differential equation (PDE) patch generation based on biharmonic-like four-order PDEs [5].…”

Section: Introductionmentioning

confidence: 99%

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A Fast Hole-Filling Method for Triangular Mesh in Additive Repair

et al. 2020

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In the triangular meshes obtained in additive repair, it is a challenge to find one single hole-filling method to close all holes and make the filling patches assort with surrounding meshes well with low time complexity, which is mainly caused by the shape complexity and size difference of the various holes, especially in the fields of intelligent manufacturing, 3D measurement, and reverse engineering. Therefore, it is reasonable to adopt different algorithms to fill different types of holes. In this research, a fast hole-filling method for triangular mesh is proposed based on the hole size. First, a group of basic concepts is defined to make them uniform throughout the whole text, followed by the descriptions of hole detection and boundary cleaning. Second, three different algorithms are developed to fill the small-sized, middle-sized, and large-sized holes classified by hole size respectively, which can fill all the detected holes in a fast and proper manner. Finally, two experiments are carried out to verify the efficiency, robustness, and ability to recover the shape of our method. Compared to two state-of-the-art hole-filling methods in the first experiment, the quantitative evaluation results demonstrate that our proposed method is much faster than them with the ability to guarantee the regularity of most filling triangles. The second experiment proves that our method can produce satisfactory filling results by making the filling patches be compatible with surrounding meshes well.

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“…The fastgrowing neuroscientific evidence relevant to AC and related processes has been reviewed by Thielen et al (2019). As regards artificial vision, some computational models embody AC processes (Follman et al, 2018;Oliver et al, 2016;Zhu et al, 2017), while occasional references to AC are found in the broader literature on object recovery from images with missing regions, not necessarily due to occlusion (Ehsani et al, 2017;Guo et al, 2018;Han et al, 2017;Harary et al, 2014;Hueting et al, 2017;Li & Malik, 2016;Mavridis et al, 2015;Oliver et al, 2017;P erez et al, 2016;Shao et al, 2014).…”

mentioning

confidence: 99%

Amodal Completion Revisited

Gerbino

2020

i-Perception

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Amodal completion (AC) is analyzed, by looking at its historical roots and persisting conceptual difficulties. Looking at the origin of the concept, it becomes clear that it is not equivalent to perception of occluded parts. The role of fragment incompleteness is discussed, to clarify that it cannot be taken as a necessary factor for eliciting AC. The standard view of AC, depicted as a set of processes that extrapolate from veridically represented image fragments, is evaluated and rejected on the basis of evidence that AC modifies also modal parts. The theoretical importance of AC phenomena and their potential to reveal the inner forces of perceptual organization are emphasized, with specific reference to the minimum principle. Instances in which AC might be expected but does not occur are examined, to define the limits of such an integrative process.

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A comparison of hole-filling methods in 3D

Cited by 25 publications

References 57 publications

Reconstruction of the Sculpture Surface in the Process of Optical 3D Scanning

Reconstruction of the Sculpture Surface in the Process of Optical 3D Scanning

A Fast Hole-Filling Method for Triangular Mesh in Additive Repair

Amodal Completion Revisited

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