Spherical Conformal Parameterization of Genus-0 Point Clouds for Meshing

Choi, Gilwoo; Ho, Kin Tat; Lui, Lok Ming

doi:10.1137/15m1037561

Cited by 36 publications

(23 citation statements)

References 51 publications

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“…x ideal (λ) = (xc + a cos λ, yc + b sin λ) , (6) where −π ≤ λ ≤ π. For the boundary represented by the C ∞ function, we use x c = y c = 0.9, a = 0.04, b = 0.05, A = 0.09, and σ 1 = 0.1.…”

Section: Convergence Of Geometric Modelsmentioning

confidence: 99%

“…Fourth, in order to reduce time-to-discovery, we want our methods to be (provably) computationally efficient and scalable with regards to the number of points needed to discretize the problem, regardless of the order of the RBF-FD method used. Our focus in this work is not on generating a suitable parametrization for an arbitrary point cloud, which is a problem that has been tackled by others (e.g., [6]). We restrict ourselves to irregular domains with boundaries that are easily parameterizable, of genus-0, and at least homeomorphic to the sphere S d−1 ⊂ R d .…”

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confidence: 99%

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Robust Node Generation for Mesh-free Discretizations on Irregular Domains and Surfaces

Shankar

Kirby²,

Fogelson³

2018

SIAM J. Sci. Comput.

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We present a new algorithm for the automatic one-shot generation of scattered node sets on irregular 2D and 3D domains using Poisson disk sampling coupled to novel parameter-free, high-order parametric Spherical Radial Basis Function (SBF)-based geometric modeling of irregular domain boundaries. Our algorithm also automatically modifies the scattered node sets locally for time-varying embedded boundaries in the domain interior. We derive complexity estimates for our node generator in 2D and 3D that establish its scalability, and verify these estimates with timing experiments. We explore the influence of Poisson disk sampling parameters on both quasi-uniformity in the node sets and errors in an RBF-FD discretization of the heat equation. In all cases, our framework requires only a small number of "seed" nodes on domain boundaries. The entire framework exhibits O(N ) complexity in both 2D and 3D.

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Section: Convergence Of Geometric Modelsmentioning

confidence: 99%

mentioning

confidence: 99%

Robust Node Generation for Mesh-free Discretizations on Irregular Domains and Surfaces

Shankar

Kirby²,

Fogelson³

2018

SIAM J. Sci. Comput.

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“…Area information has also been utilized in the computation of optimal mass transport maps [21,22,50] and density-equalizing maps [10,16,17]. More recently, quasi-conformal mappings have become increasingly popular for the development of non-rigid image registration [31,47] and surface mapping methods [12,13,19,32,37], with applications to geometry processing [7,11,14], biological shape analysis [8,15] and medical visualization [9,18]. Specifically, quasi-conformal theory allows one to ensure the bijectivity and reduce the local geometric distortion of the mappings.…”

Section: Introductionmentioning

confidence: 99%

A unifying framework for $n$-dimensional quasi-conformal mappings

Zhang,

Choi,

Zhang

et al. 2021

Preprint

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With the advancement of computer technology, there is a surge of interest in effective mapping methods for objects in higher-dimensional spaces. To establish a one-to-one correspondence between objects, higher-dimensional quasi-conformal theory can be utilized for ensuring the bijectivity of the mappings. In addition, it is often desirable for the mappings to satisfy certain prescribed geometric constraints and possess low distortion in conformality or volume. In this work, we develop a unifying framework for computing n-dimensional quasi-conformal mappings. More specifically, we propose a variational model that integrates quasi-conformal distortion, volumetric distortion, landmark correspondence, intensity mismatch and volume prior information to handle a large variety of deformation problems. We further prove the existence of a minimizer for the proposed model and devise efficient numerical methods to solve the optimization problem. We demonstrate the effectiveness of the proposed framework using various experiments in two-and three-dimensions, with applications to medical image registration, adaptive remeshing and shape modeling.

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“…Existing conformal parameterization methods for simply-connected open surfaces include least-squares conformal map (LSCM) [46], discrete natural conformal parameterization (DNCP) [22], angle-based flattening (ABF) [67,68,79], holomorphic 1-form [29], discrete Yamabe flow [51,70], discrete Ricci flow [35,74,83], fast disk conformal map [17], boundary first flattening [64], linear disk conformal map [12], conformal energy minimization [76], parallelizable global conformal parameterization (PGCP) [10,11] and spherical cap conformal map [65]. For simply-connected closed surfaces, existing spherical conformal parameterization methods include harmonic energy minimization [28,42] and its linearizations [2,9,16,30] and parallelizable global conformal parameterization (PGCP) [10]. While many surfaces in real applications may be multiply-connected, the conformal mapping of multiply-connected surfaces is less studied.…”

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confidence: 99%

Parallelizable global quasi-conformal parameterization of multiply-connected surfaces via partial welding

Zhu¹,

Choi²,

Lui³

2021

Preprint

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Conformal and quasi-conformal mappings have widespread applications in imaging science, computer vision and computer graphics, such as surface registration, segmentation, remeshing, and texture map compression. While various conformal and quasi-conformal parameterization methods for simplyconnected surfaces have been proposed, efficient parameterization algorithms for multiply-connected surfaces are less explored. In this paper, we propose a novel parallelizable algorithm for computing the global conformal and quasi-conformal parameterization of multiply-connected surfaces onto a 2D circular domain using variants of the partial welding method and the Koebe's iteration. The main idea is to first partition a multiply-connected surface into several subdomains and compute the free-boundary conformal or quasi-conformal parameterizations of them respectively, and then apply a variant of the partial welding algorithm to reconstruct the global mapping. We apply the Koebe's iteration together with the geodesic algorithm to the boundary points and welding paths before and after the global welding to transform all the boundaries to circles conformally. After getting all the updated boundary conditions, we obtain the global parameterization of the multiply-connected surface by solving the Laplace equation for each subdomain. Using this divide-and-conquer approach, the global conformal and quasi-conformal parameterization of surfaces can be efficiently computed. Experimental results are presented to demonstrate the effectiveness of our proposed algorithm. More broadly, the proposed shift in perspective from solving a global quasi-conformal mapping problem to solving multiple local mapping problems paves a new way for computational quasi-conformal geometry.

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Spherical Conformal Parameterization of Genus-0 Point Clouds for Meshing

Cited by 36 publications

References 51 publications

Robust Node Generation for Mesh-free Discretizations on Irregular Domains and Surfaces

Robust Node Generation for Mesh-free Discretizations on Irregular Domains and Surfaces

A unifying framework for $n$-dimensional quasi-conformal mappings

Parallelizable global quasi-conformal parameterization of multiply-connected surfaces via partial welding

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