Quantum spectral method for gradient and Hessian estimation
Abstract
Gradient descent is one of the most basic algorithms for solving continuous optimization problems. In [Jordan, PRL, 95(5):050501, 2005], Jordan proposed the first quantum algorithm for estimating gradients of functions close to linear, with exponential speedup in the black-box model. This quantum algorithm was greatly enhanced and developed by [Gily\'en, Arunachalam, and Wiebe, SODA, pp. 1425-1444, 2019], providing a quantum algorithm with optimal query complexity (d/) for a class of smooth functions of d variables, where is the accuracy. This is quadratically faster than classical algorithms for the same problem. In this work, we continue this research by proposing a new quantum algorithm for another class of functions, namely, analytic functions f(x) which are well-defined over the complex field. Given phase oracles to query the real and imaginary parts of f(x) respectively, we propose a quantum algorithm that returns an -approximation of its gradient with query complexity O(1/). As an extension, we also propose two quantum algorithms for Hessian estimation, aiming to improve quantum analogs of Newton's method. The two algorithms have query complexity O(d/) and O(d1.5/), respectively, under different assumptions. Moreover, if the Hessian is promised to be s-sparse, we then have two new quantum algorithms with query complexity O(s/) and O(sd/), respectively. We also prove a lower bound of (d) for Hessian estimation in the general case.
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