An Efficient Decomposition of the Carleman Linearized Burgers' Equation

Abstract

Herein, we present a polylogarithmic decomposition method to load the matrix from the linearized 1-dimensional Burgers' equation onto a quantum computer. First, we use the Carleman linearization method to map the nonlinear Burgers' equation into an infinite linear system of equations, which is subsequently truncated to order α. This new finite linear system is then embedded into a larger system of equations with the key property that its matrix can be decomposed into a linear combination of O( nt + α2 nx) terms for nt time steps and nx spatial grid points. While the terms in this linear combination are not unitary, each can be implemented using a simple block encoding procedure. A numerical simulation is performed by combining our approach with the variational quantuam linear solver demonstrating that accurate solutions are possible. Finally, a resource estimate shows that the upper bound of the Clifford and T gate counts scale like O(α( nx)2) and O(( nx)2), respectively. This is therefore the first explicit polylogarithmic data loading method with respect to nx and nt for a Carleman linearized system.