Polynomial Identity Testing and Reconstruction for Depth-4 Powering Circuits of High Degree

Abstract

We study deterministic polynomial identity testing (PIT) and reconstruction algorithms for depth-4 arithmetic circuits of the form \[ [r]\![d]\![s]\![δ]. \] This model generalizes Waring decompositions and diagonal circuits, and captures sums of powers of low-degree sparse polynomials. Specifically, each circuit computes a sum of r terms, where each term is a d-th power of an s-sparse polynomial of degree δ. This model also includes algebraic representations that arise in tensor decomposition and moment-based learning tasks such as mixture models and subspace learning. We give deterministic worst-case algorithms for PIT and reconstruction in this model. Our PIT construction applies when d>r2 and yields explicit hitting sets of size O(r4 s4 n2 d δ3). The reconstruction algorithm runs in time poly(n,s,d) under the condition d=(r4δ), and in particular it tolerates polynomially large top fan-in r and bottom degree δ. Both results hold over fields of characteristic zero and over fields of sufficiently large characteristic. These algorithms provide the first polynomial-time deterministic solutions for depth-4 powering circuits with unbounded top fan-in. In particular, the reconstruction result improves upon previous work which required non-degeneracy or average-case assumptions. The PIT construction relies on the ABC theorem for function fields (Mason-Stothers theorem), which ensures linear independence of high-degree powers of sparse polynomials after a suitable projection. The reconstruction algorithm combines this with Wronskian-based differential operators, structural properties of their kernels, and a robust version of the Klivans-Spielman hitting set.