Key points are not available for this paper at this time.
We study the problem of identity testing for multilinear ΣΠΣΠ (k) circuits, i. e. , multilinear depth-4 circuits with fan-in k at the top + gate. We give the first polynomial-time deterministic identity testing algorithm for such circuits when k=O (1). Our results also hold in the black-box setting. The running time of our algorithm is ({ns) ^{O ({k³}) }}, where n is the number of variables, s is the size of the circuit and k is the fan-in of the top gate. The importance of this model arises from 11, where it was shown that derandomizing black-box polynomial identity testing for general depth-4 circuits implies a derandomization of polynomial identity testing (PIT) for general arithmetic circuits. Prior to our work, the best PIT algorithm for multilinear ΣΠΣΠ (k) circuits 31 ran in quasi-polynomial-time, with the running time being n^{{ O ({k⁶ (k) { ²}s}) }}. We obtain our results by showing a strong structural result for multilinear ΣΠΣΠ (k) circuits that compute the zero polynomial. We show that under some mild technical conditions, any gate of such a circuit must compute a sparse polynomial. We then show how to combine the structure theorem with a result by Klivans and Spielman 33, on the identity testing for sparse polynomials, to yield the full result.
Saraf et al. (Mon,) studied this question.