English

Edge-isoperimetric problem for Cayley graphs and generalized Takagi function

Combinatorics 2012-03-02 v2

Abstract

Let GG be a finite abelian abelian group of exponent m2m\ge 2. For subsets A,SGA,S\subset G, denote by S(A)\partial_S(A) the number of edges from AA to its complement GAG\setminus A in the directed Cayley graph, induced by SS on GG. We show that if SS generates GG, and AA is non-empty, then S(A)emAlnGA. \partial_S(A) \ge \frac{e}m\,|A|\ln\frac{|G|}{|A|}. Here the coefficient e=2.718...e=2.718... is best possible and cannot be replaced with a number larger than ee. For homocyclic groups GG of exponent mm, we find an explicit closed-form expression for S(A)\partial_S(A) in the case where SS is a "standard" generating subset of GG, and AA is an initial segment of GG with respect to the lexicographic order, induced by SS on GG. Namely, we show that in this situation S(A)=Gωm(A/G), \partial_S(A) = |G|\,\omega_m(|A|/|G|), where ω2\omega_2 is the Takagi function, and ωm\omega_m for m3m\ge 3 is an appropriate generalization thereof. This particular case is of special interest, since for m{2,3,4}m\in\{2,3,4\} it is known to yield the smallest possible value of S(A)\partial_S(A), over all sets AGA\subset G of given size. We give this classical result a new proof, somewhat different from the standard one. We also give a new, short proof of the Boros-Pales inequality ω2(x+y2)ω2(x)+ω2(y)2+12yx,\omega_2(\frac{x+y}2) \le \frac{\omega_2(x) + \omega_2(y)}2 + \frac12\,|y-x|, establish an extremal characterization of the Takagi function as the (pointwise) maximal function, satisfying this inequality and the boundary condition max{ω2(0),ω2(1)}0\max\{\omega_2(0),\omega_2(1)\}\le 0, and obtain similar results for the 3-adic analog ω3\omega_3 of the Takagi function.

Keywords

Cite

@article{arxiv.1202.2566,
  title  = {Edge-isoperimetric problem for Cayley graphs and generalized Takagi function},
  author = {Vsevolod F. Lev},
  journal= {arXiv preprint arXiv:1202.2566},
  year   = {2012}
}

Comments

Minor corrections as compared to the original version. 27 pages, 3 figures

R2 v1 2026-06-21T20:18:17.656Z