Dequantization and Hardness of Spectral Sum Estimation

Abstract

We give new dequantization and hardness results for estimating spectral sums of matrices, such as the log-determinant. Recent quantum algorithms have demonstrated that the logarithm of the determinant of sparse, well-conditioned, positive matrices can be approximated to -relative accuracy in time polylogarithmic in the dimension N, specifically in time poly(log(N), s, , 1/), where s is the sparsity and the condition number of the input matrix. We provide a simple dequantization of these techniques that preserves the polylogarithmic dependence on the dimension. Our classical algorithm runs in time polylog(N)· sO( /) which constitutes an exponential improvement over previous classical algorithms in certain parameter regimes. We complement our classical upper bound with DQC1-completeness results for estimating specific spectral sums such as the trace of the inverse and the trace of matrix powers for log-local Hamiltonians, with parameter scalings analogous to those of known quantum algorithms. Assuming BPP⊂neqDQC1, this rules out classical algorithms with the same scalings. It also resolves a main open problem of Cade and Montanaro (TQC 2018) concerning the complexity of Schatten-p norm estimation. We further analyze a block-encoding input model, where instead of a classical description of a sparse matrix, we are given a block-encoding of it. We show DQC1-completeness in a very general way in this model for estimating tr[f(A)] whenever f and f-1 are sufficiently smooth. We conclude our work with BQP-hardness and PP-completeness results for high-accuracy log-determinant estimation.