Quantum simulation of a noisy classical nonlinear dynamics

Abstract

We present an end-to-end quantum algorithm for simulating nonlinear dynamics described by a system of stochastic dissipative differential equations with a quadratic nonlinearity. The stochastic part of the system is modeled by a Gaussian noise in the equation of motion and in the initial conditions. Our algorithm can approximate the expected value of any correlation function that depends on O(1) variables with rigorous bounds on the approximation error. The runtime scales polynomially with N, t, J, and λ1-1, where N is the total number of variables, t is the evolution time, J is the nonlinearity strength, and λ1 is the smallest dissipation rate. However, the runtime scales exponentially with a parameter quantifying inverse relative error in the initial conditions. To the best of our knowledge, this is the first rigorous quantum algorithm capable of simulating strongly nonlinear systems with J λ1 at the cost poly-logarithmic in N and polynomial in t. The considered simulation problem is shown to be BQP-complete, providing a strong evidence for a quantum advantage. We benchmark the quantum algorithm via numerical experiments by simulating a vortex flow in the 2D Navier Stokes equation.