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Main Authors: Coltraro, Franco, Amorós, Jaume, Alberich-Carramiñana, Maria, Torras, Carme
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.17257
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author Coltraro, Franco
Amorós, Jaume
Alberich-Carramiñana, Maria
Torras, Carme
author_facet Coltraro, Franco
Amorós, Jaume
Alberich-Carramiñana, Maria
Torras, Carme
contents In this work, we study the perception problem for sampled surfaces (possibly with boundary) using tools from computational topology, specifically, how to identify their underlying topology starting from point-cloud samples in space, such as those obtained with 3D scanners. We present a reconstruction algorithm based on a careful topological study of the point sample that allows us to obtain a cellular decomposition of it using a Morse function. No triangulation or local implicit equations are used as intermediate steps, avoiding in this way reconstruction-induced artifices. The algorithm can be run without any prior knowledge of the surface topology, density or regularity of the point-sample. The results consist of a piece-wise decomposition of the given surface as a union of Morse cells (i.e. topological disks), suitable for tasks such as mesh-independent reparametrization or noise-filtering, and a small-rank cellular complex determining the topology of the surface. The algorithm, which we test with several real and synthetic surfaces, can be applied to smooth surfaces with or without boundary, embedded in an ambient space of any dimension.
format Preprint
id arxiv_https___arxiv_org_abs_2405_17257
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Topological reconstruction of sampled surfaces via Morse theory
Coltraro, Franco
Amorós, Jaume
Alberich-Carramiñana, Maria
Torras, Carme
Computational Geometry
Computer Vision and Pattern Recognition
Algebraic Topology
In this work, we study the perception problem for sampled surfaces (possibly with boundary) using tools from computational topology, specifically, how to identify their underlying topology starting from point-cloud samples in space, such as those obtained with 3D scanners. We present a reconstruction algorithm based on a careful topological study of the point sample that allows us to obtain a cellular decomposition of it using a Morse function. No triangulation or local implicit equations are used as intermediate steps, avoiding in this way reconstruction-induced artifices. The algorithm can be run without any prior knowledge of the surface topology, density or regularity of the point-sample. The results consist of a piece-wise decomposition of the given surface as a union of Morse cells (i.e. topological disks), suitable for tasks such as mesh-independent reparametrization or noise-filtering, and a small-rank cellular complex determining the topology of the surface. The algorithm, which we test with several real and synthetic surfaces, can be applied to smooth surfaces with or without boundary, embedded in an ambient space of any dimension.
title Topological reconstruction of sampled surfaces via Morse theory
topic Computational Geometry
Computer Vision and Pattern Recognition
Algebraic Topology
url https://arxiv.org/abs/2405.17257