English

Euler Transformation of Polyhedral Complexes

Computational Geometry 2021-04-28 v3

Abstract

We propose an Euler transformation that transforms a given dd-dimensional cell complex KK for d=2,3d=2,3 into a new dd-complex K^\hat{K} in which every vertex is part of a uniform even number of edges. Hence every vertex in the graph G^\hat{G} that is the 11-skeleton of K^\hat{K} has an even degree, which makes G^\hat{G} Eulerian, i.e., it is guaranteed to contain an Eulerian tour. Meshes whose edges admit Eulerian tours are crucial in coverage problems arising in several applications including 3D printing and robotics. For 22-complexes in R2\mathbb{R}^2 (d=2d=2) under mild assumptions (that no two adjacent edges of a 22-cell in KK are boundary edges), we show that the Euler transformed 22-complex K^\hat{K} has a geometric realization in R2\mathbb{R}^2, and that each vertex in its 11-skeleton has degree 44. We bound the numbers of vertices, edges, and 22-cells in K^\hat{K} as small scalar multiples of the corresponding numbers in KK. We prove corresponding results for 33-complexes in R3\mathbb{R}^3 under an additional assumption that the degree of a vertex in each 33-cell containing it is 33. In this setting, every vertex in G^\hat{G} is shown to have a degree of 66. We also present bounds on parameters measuring geometric quality (aspect ratios, minimum edge length, and maximum angle) of K^\hat{K} in terms of the corresponding parameters of KK (for d=2,3d=2, 3). Finally, we illustrate a direct application of the proposed Euler transformation in additive manufacturing.

Keywords

Cite

@article{arxiv.1812.02412,
  title  = {Euler Transformation of Polyhedral Complexes},
  author = {Prashant Gupta and Bala Krishnamoorthy},
  journal= {arXiv preprint arXiv:1812.02412},
  year   = {2021}
}

Comments

Modifications to Section 5.1 and minor improvements in other places; to appear in IJCGA

R2 v1 2026-06-23T06:33:48.546Z