Approximating the Determinant of Well-Conditioned Matrices by Shallow Circuits

Abstract

The determinant can be computed by classical circuits of depth O(2 n), and therefore it can also be computed in classical space O(2 n). Recent progress by Ta-Shma [Ta13] implies a method to approximate the determinant of Hermitian matrices with condition number in quantum space O( n + ). However, it is not known how to perform the task in less than O(2 n) space using classical resources only. In this work, we show that the condition number of a matrix implies an upper bound on the depth complexity (and therefore also on the space complexity) for this task: the determinant of Hermitian matrices with condition number can be approximated to inverse polynomial relative error with classical circuits of depth O( n · ), and in particular one can approximate the determinant for sufficiently well-conditioned matrices in depth O( n). Our algorithm combines Barvinok's recent complex-analytic approach for approximating combinatorial counting problems [Bar16] with the Valiant-Berkowitz-Skyum-Rackoff depth-reduction theorem for low-degree arithmetic circuits [Val83].