Near-optimal small-depth lower bounds for small distance connectivity

Abstract

We show that any depth-d circuit for determining whether an n-node graph has an s-to-t path of length at most k must have size n(k1/d/d). The previous best circuit size lower bounds for this problem were nk(-O(d)) (due to Beame, Impagliazzo, and Pitassi [BIP98]) and n(( k)/d) (following from a recent formula size lower bound of Rossman [Ros14]). Our lower bound is quite close to optimal, since a simple construction gives depth-d circuits of size nO(k2/d) for this problem (and strengthening our bound even to nk(1/d) would require proving that undirected connectivity is not in NC1.) Our proof is by reduction to a new lower bound on the size of small-depth circuits computing a skewed variant of the "Sipser functions" that have played an important role in classical circuit lower bounds [Sip83, Yao85, Hs86]. A key ingredient in our proof of the required lower bound for these Sipser-like functions is the use of random projections, an extension of random restrictions which were recently employed in [RST15]. Random projections allow us to obtain sharper quantitative bounds while employing simpler arguments, both conceptually and technically, than in the previous works [Ajt89, BPU92, BIP98, Ros14].