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EMBEDDING OF METRIC GRAPHS ON HYPERBOLIC SURFACES

Part of: Graph theory Low-dimensional topology

Published online by Cambridge University Press:  13 February 2019

BIDYUT SANKI Open the ORCID record for BIDYUT SANKI [Opens in a new window]
BIDYUT SANKI*
Affiliation:
Department of Mathematics and Statistics, Indian Institute of Technology, Kanpur, UP – 208016, India email bidyut.iitk7@gmail.com
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Abstract

An embedding of a metric graph $(G,d)$ on a closed hyperbolic surface is essential if each complementary region has a negative Euler characteristic. We show, by construction, that given any metric graph, its metric can be rescaled so that it admits an essential and isometric embedding on a closed hyperbolic surface. The essential genus $g_{e}(G)$ of $(G,d)$ is the lowest genus of a surface on which such an embedding is possible. We establish a formula to compute $g_{e}(G)$ and show that, for every integer $g\geq g_{e}(G)$, there is an embedding of $(G,d)$ (possibly after a rescaling of $d$) on a surface of genus $g$. Next, we study minimal embeddings where each complementary region has Euler characteristic $-1$. The maximum essential genus $g_{e}^{\max }(G)$ of $(G,d)$ is the largest genus of a surface on which the graph is minimally embedded. We describe a method for an essential embedding of $(G,d)$, where $g_{e}(G)$ and $g_{e}^{\max }(G)$ are realised.

Keywords

hyperbolic surfacefat graphgirthBetti numberBetti deficiency

MSC classification

Primary: 57M15: Relations with graph theory
Secondary: 05C10: Planar graphs; geometric and topological aspects of graph theory
Type
Research Article
Information
Bulletin of the Australian Mathematical Society , Volume 99 , Issue 3 , June 2019 , pp. 508 - 520
Copyright
© 2019 Australian Mathematical Publishing Association Inc. 

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Footnotes

The author has been supported by a Post Doctoral Fellowship funded by a J. C. Bose fellowship of Professor Mahan Mj.

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