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Towards Optimal Depth Reductions for Syntactically Multilinear Circuits

Computational Complexity 2019-02-20 v1

Abstract

We show that any nn-variate polynomial computable by a syntactically multilinear circuit of size poly(n)\operatorname{poly}(n) can be computed by a depth-44 syntactically multilinear (ΣΠΣΠ\Sigma\Pi\Sigma\Pi) circuit of size at most exp(O(nlogn))\exp\left({O\left(\sqrt{n\log n}\right)}\right). For degree d=ω(n/logn)d = \omega(n/\log n), this improves upon the upper bound of exp(O(dlogn))\exp\left({O(\sqrt{d}\log n)}\right) obtained by Tavenas~\cite{T15} for general circuits, and is known to be asymptotically optimal in the exponent when d<nϵd < n^{\epsilon} for a small enough constant ϵ\epsilon. Our upper bound matches the lower bound of exp(Ω(nlogn))\exp\left({\Omega\left(\sqrt{n\log n}\right)}\right) proved by Raz and Yehudayoff~\cite{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 nn-variate polynomial computable by a syntactically multilinear circuit of size poly(n)\operatorname{poly}(n) can be computed by a syntactically multilinear circuit of product-depth Δ\Delta of size at most exp(O(Δ(n/logn)1/Δlogn))\exp\left(O\left(\Delta \cdot (n/\log n)^{1/\Delta} \cdot \log n\right)\right). It follows from the lower bounds of Raz and Yehudayoff (CC 2009) that in general, for constant Δ\Delta, the exponent in this upper bound is tight and cannot be improved to o((n/logn)1/Δlogn)o\left(\left(n/\log n\right)^{1/\Delta}\cdot \log n\right).

Cite

@article{arxiv.1902.07063,
  title  = {Towards Optimal Depth Reductions for Syntactically Multilinear Circuits},
  author = {Mrinal Kumar and Rafael Oliveira and Ramprasad Saptharishi},
  journal= {arXiv preprint arXiv:1902.07063},
  year   = {2019}
}
R2 v1 2026-06-23T07:44:51.550Z