English

Constructing expander graphs by 2-lifts and discrepancy vs. spectral gap

Combinatorics 2007-05-23 v3

Abstract

We present a new explicit construction for expander graphs with nearly optimal spectral gap. The construction is based on a series of 2-lift operations. Let GG be a graph on nn vertices. A 2-lift of GG is a graph HH on 2n2n vertices, with a covering map π:HG\pi:H \to G. It is not hard to see that all eigenvalues of GG are also eigenvalues of HH. In addition, HH has nn ``new'' eigenvalues. We conjecture that every dd-regular graph has a 2-lift such that all new eigenvalues are in the range [2d1,2d1][-2\sqrt{d-1},2\sqrt{d-1}] (If true, this is tight, e.g. by the Alon-Boppana bound). Here we show that every graph of maximal degree dd has a 2-lift such that all ``new'' eigenvalues are in the range [cdlog3d,cdlog3d][-c \sqrt{d \log^3d}, c \sqrt{d \log^3d}] for some constant cc. This leads to a polynomial time algorithm for constructing arbitrarily large dd-regular graphs, with second eigenvalue O(dlog3d)O(\sqrt{d \log^3 d}). The proof uses the following lemma: Let AA be a real symmetric matrix such that the l1l_1 norm of each row in AA is at most dd. Let α=maxx,y{0,1}n,supp(x)supp(y)=xAyxy\alpha = \max_{x,y \in \{0,1\}^n, supp(x)\cap supp(y)=\emptyset} \frac {|xAy|} {||x||||y||}. Then the spectral radius of AA is at most cαlog(d/α)c \alpha \log(d/\alpha), for some universal constant cc. An interesting consequence of this lemma is a converse to the Expander Mixing Lemma.

Keywords

Cite

@article{arxiv.math/0312022,
  title  = {Constructing expander graphs by 2-lifts and discrepancy vs. spectral gap},
  author = {Yonatan Bilu and Nathan Linial},
  journal= {arXiv preprint arXiv:math/0312022},
  year   = {2007}
}

Comments

29 pages, 1 figure