Euler Transformation of Polyhedral Complexes
Abstract
We propose an Euler transformation that transforms a given -dimensional cell complex for into a new -complex in which every vertex is part of a uniform even number of edges. Hence every vertex in the graph that is the -skeleton of has an even degree, which makes 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 -complexes in () under mild assumptions (that no two adjacent edges of a -cell in are boundary edges), we show that the Euler transformed -complex has a geometric realization in , and that each vertex in its -skeleton has degree . We bound the numbers of vertices, edges, and -cells in as small scalar multiples of the corresponding numbers in . We prove corresponding results for -complexes in under an additional assumption that the degree of a vertex in each -cell containing it is . In this setting, every vertex in is shown to have a degree of . We also present bounds on parameters measuring geometric quality (aspect ratios, minimum edge length, and maximum angle) of in terms of the corresponding parameters of (for ). Finally, we illustrate a direct application of the proposed Euler transformation in additive manufacturing.
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