Towards Optimal Depth Reductions for Syntactically Multilinear Circuits

Abstract

We show that any n-variate polynomial computable by a syntactically multilinear circuit of size poly(n) can be computed by a depth-4 syntactically multilinear () circuit of size at most (O(n n)). For degree d = ω(n/ n), this improves upon the upper bound of (O(d n)) obtained by Tavenas~T15 for general circuits, and is known to be asymptotically optimal in the exponent when d < nε for a small enough constant ε. Our upper bound matches the lower bound of ((n n)) proved by Raz and Yehudayoff~RY09, and thus cannot be improved further in the exponent. Our results hold over all fields and also generalize to circuits of small individual degree. More generally, we show that an n-variate polynomial computable by a syntactically multilinear circuit of size poly(n) can be computed by a syntactically multilinear circuit of product-depth of size at most (O( · (n/ n)1/ · n)). It follows from the lower bounds of Raz and Yehudayoff (CC 2009) that in general, for constant , the exponent in this upper bound is tight and cannot be improved to o((n/ n)1/· n).