Trigonometry in Galois fields

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The expander mixing lemma states that, for any two subsets S,T of a d-regular expander graph G, the number of edges between S and T is approximately what you would expect in a random d-regular graph, i.e. d|S||T|/n.

Statement

Let G=(V,E) be a d-regular graph with normalized second-largest eigenvalue λ (in absolute value) of the adjacency matrix. Then for any two subsets S,TV, let E(S,T) denote the number of edges between S and T. If the two sets are not disjoint, edges in their intersection are counted twice, that is, E(S,T)=2|E(G[ST])|+E(ST,T)+E(S,TS). We have

|E(S,T)d|S||T|n|dλ|S||T|.

For a proof, see references.

Converse

Recently, Bilu and Linial showed that the converse holds as well: if a graph satisfies the conclusion of the expander mixing lemma, that is, for any two subsets S,TV,

|E(S,T)d|S||T|n|dλ|S||T|

then its second-largest eigenvalue is O(dλ(1+log(1/λ))).

References

  • Notes proving the expander mixing lemma. [1]
  • Expander mixing lemma converse. [2]

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