Quantum-inspired algorithms for multivariate analysis: from interpolation to partial differential equations
Abstract
In this work we study the encoding of smooth, differentiable multivariate functions in quantum registers, using quantum computers or tensor-network representations. We show that a large family of distributions can be encoded as low-entanglement states of the quantum register. These states can be efficiently created in a quantum computer, but they are also efficiently stored, manipulated and probed using Matrix-Product States techniques. Inspired by this idea, we present eight quantum-inspired numerical analysis algorithms, that include Fourier sampling, interpolation, differentiation and integration of partial derivative equations. These algorithms combine classical ideas -- finite-differences, spectral methods -- with the efficient encoding of quantum registers, and well known algorithms, such as the Quantum Fourier Transform. {When these heuristic methods work}, they provide an exponential speed-up over other classical algorithms, such as Monte Carlo integration, finite-difference and fast Fourier transforms (FFT). But even when they don't, some of these algorithms can be translated back to a quantum computer to implement a similar task.
Cite
@article{arxiv.1909.06619,
title = {Quantum-inspired algorithms for multivariate analysis: from interpolation to partial differential equations},
author = {Juan José García-Ripoll},
journal= {arXiv preprint arXiv:1909.06619},
year = {2021}
}
Comments
Revised version (v4), accepted for publication