Higher Dimensional Discrete Cheeger Inequalities
Abstract
For graphs there exists a strong connection between spectral and combinatorial expansion properties. This is expressed, e.g., by the discrete Cheeger inequality, the lower bound of which states that , where is the second smallest eigenvalue of the Laplacian of a graph and is the Cheeger constant measuring the edge expansion of . We are interested in generalizations of expansion properties to finite simplicial complexes of higher dimension (or uniform hypergraphs). Whereas higher dimensional Laplacians were introduced already in 1945 by Eckmann, the generalization of edge expansion to simplicial complexes is not straightforward. Recently, a topologically motivated notion analogous to edge expansion that is based on -cohomology was introduced by Gromov and independently by Linial, Meshulam and Wallach. It is known that for this generalization there is no higher dimensional analogue of the lower bound of the Cheeger inequality. A different, combinatorially motivated generalization of the Cheeger constant, denoted by , was studied by Parzanchevski, Rosenthal and Tessler. They showed that indeed , where is the smallest non-trivial eigenvalue of the (-dimensional upper) Laplacian, for the case of -dimensional simplicial complexes with complete -skeleton. Whether this inequality also holds for -dimensional complexes with non-complete -skeleton has been an open question. We give two proofs of the inequality for arbitrary complexes. The proofs differ strongly in the methods and structures employed, and each allows for a different kind of additional strengthening of the original result.
Keywords
Cite
@article{arxiv.1401.2290,
title = {Higher Dimensional Discrete Cheeger Inequalities},
author = {Anna Gundert and May Szedlák},
journal= {arXiv preprint arXiv:1401.2290},
year = {2015}
}
Comments
14 pages, 2 figures