Hybrid Second Order Method for Orthogonal Projection onto Parametric Curve in n-Dimensional Euclidean Space

Liang, Juan; Hou, Linke; Li, Xiaowu; Pan, Feng; Cheng, Taixia; Wang, Lin

doi:10.3390/math6120306

Cited by 4 publications

(1 citation statement)

References 44 publications

(133 reference statements)

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“…Hartmann [2] proposed a first-order tangent line method to calculate point orthogonal projection onto parametric curve and surface. For a few cases of non-convergence and as supplement and perfection of the first-order tangent line method [2], Liang et al [3] and Li et al [4] presented hybrid second-order method for orthogonal projection onto parametric curve and surface, respectively. Hu et al [5] proposed a second-order geometric iterative algorithm with curvature information to approximate the orthogonal projection point of the given point on parametric curves and surfaces.…”

Section: Introductionmentioning

confidence: 99%

Point Orthogonal Projection onto a Spatial Algebraic Curve

Cheng

et al. 2020

Mathematics

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Point orthogonal projection onto a spatial algebraic curve plays an important role in computer graphics, computer-aided geometric design, etc. We propose an algorithm for point orthogonal projection onto a spatial algebraic curve based on Newton’s steepest gradient descent method and geometric correction method. The purpose of Algorithm 1 in the first step of Algorithm 4 is to let the initial iteration point fall on the spatial algebraic curve completely and successfully. On the basis of ensuring that the iteration point fallen on the spatial algebraic curve, the purpose of the intermediate for loop body including Step 2 and Step 3 is to let the iteration point gradually approach the orthogonal projection point (the closest point) such that the distance between them is very small. Algorithm 3 in the fourth step plays an important double acceleration and orthogonalization role. Numerical example shows that our algorithm is very robust and efficient which it achieves the expected and ideal result.

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Section: Introductionmentioning

confidence: 99%

Point Orthogonal Projection onto a Spatial Algebraic Curve

Cheng

et al. 2020

Mathematics

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Approximation of curve-based sleeve functions in high dimensions

Beinert

2023

Adv Comput Math

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Sleeve functions are generalizations of the well-established ridge functions that play a major role in the theory of partial differential equation, medical imaging, statistics, and neural networks. Where ridge functions are non-linear, univariate functions of the distance to hyperplanes, sleeve functions are based on the squared distance to lower-dimensional manifolds. The present work is a first step to study general sleeve functions by starting with sleeve functions based on finite-length curves. To capture these curve-based sleeve functions, we propose and study a two-step method, where first the outer univariate function—the profile—is recovered, and second, the underlying curve is represented by a polygonal chain. Introducing a concept of well-separation, we ensure that the proposed method always terminates and approximates the true sleeve function with a certain quality. Investigating the local geometry, we study an inexact version of our method and show its success under certain conditions.

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A Geometric Strategy Algorithm for Orthogonal Projection onto a Parametric Surface

Pan

et al. 2019

J. Comput. Sci. Technol.

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Hybrid Second Order Method for Orthogonal Projection onto Parametric Curve in n-Dimensional Euclidean Space

Cited by 4 publications

References 44 publications

Point Orthogonal Projection onto a Spatial Algebraic Curve

Point Orthogonal Projection onto a Spatial Algebraic Curve

Approximation of curve-based sleeve functions in high dimensions

A Geometric Strategy Algorithm for Orthogonal Projection onto a Parametric Surface

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