Smaller Depth-2 Linear Circuits for Disjointness Matrices

Abstract

We prove two new upper bounds for depth-2 linear circuits computing the Nth disjointness matrix D N. First, we obtain a circuit of size O(21.24485N) over \0,1\. Second, we obtain a circuit of degree O(20.3199N) over \0, 1\. These improve the previous bounds of Alman and Li, namely size O(21.249424N) and degree O(2N/3). Our starting point is the rebalancing framework developed in a line of works by Jukna and Sergeev, Alman, Sergeev, and Alman-Guan-Padaki, culminating in Alman and Li. We sharpen that framework in two ways. First, we replace the earlier "wild" rebalancing process by a tame, discretized process whose geometric-average behavior is governed by the quenched top Lyapunov exponent of a random matrix product. This allows us to invoke the convex-optimization upper bound of Gharavi and Anantharam. Second, for the degree bound we work explicitly with a cost landscape on the (p,q)-plane and show that different circuit families are dominant on different regions, so that the global maximum remains below 0.3199.

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