On monotone circuits with local oracles and clique lower bounds

Abstract

We investigate monotone circuits with local oracles [K., 2016], i.e., circuits containing additional inputs yi = yi(x) that can perform unstructured computations on the input string x. Let μ ∈ [0,1] be the locality of the circuit, a parameter that bounds the combined strength of the oracle functions yi(x), and Un,k, Vn,k ⊂eq \0,1\m be the set of k-cliques and the set of complete (k-1)-partite graphs, respectively (similarly to [Razborov, 1985]). Our results can be informally stated as follows. 1. For an appropriate extension of depth-2 monotone circuits with local oracles, we show that the size of the smallest circuits separating Un,3 (triangles) and Vn,3 (complete bipartite graphs) undergoes two phase transitions according to μ. 2. For 5 ≤ k(n) ≤ n1/4, arbitrary depth, and μ ≤ 1/50, we prove that the monotone circuit size complexity of separating the sets Un,k and Vn,k is n(k), under a certain restrictive assumption on the local oracle gates. The second result, which concerns monotone circuits with restricted oracles, extends and provides a matching upper bound for the exponential lower bounds on the monotone circuit size complexity of k-clique obtained by Alon and Boppana (1987).