English

Destructive Error Interference in Product-Formula Lattice Simulation

Quantum Physics 2020-06-05 v1

Abstract

Quantum computers can efficiently simulate the dynamics of quantum systems. In this paper, we study the cost of digitally simulating the dynamics of several physically relevant systems using the first-order product formula algorithm. We show that the errors from different Trotterization steps in the algorithm can interfere destructively, yielding a much smaller error than previously estimated. In particular, we prove that the total error in simulating a nearest-neighbor interacting system of nn sites for time tt using the first-order product formula with rr time slices is O(nt/r+nt3/r2)O({nt}/{r}+{nt^3}/{r^2}) when nt2/rnt^2/r is less than a small constant. Given an error tolerance ϵ\epsilon, the error bound yields an estimate of max{O(n2t/ϵ),O(n2t3/2/ϵ1/2)}\max\{O({n^2t}/{\epsilon}),O({n^2 t^{3/2}}/{\epsilon^{1/2}})\} for the total gate count of the simulation. The estimate is tighter than previous bounds and matches the empirical performance observed in Childs et al. [PNAS 115, 9456-9461 (2018)]. We also provide numerical evidence for potential improvements and conjecture an even tighter estimate for the gate count.

Keywords

Cite

@article{arxiv.1912.11047,
  title  = {Destructive Error Interference in Product-Formula Lattice Simulation},
  author = {Minh C. Tran and Su-Kuan Chu and Yuan Su and Andrew M. Childs and Alexey V. Gorshkov},
  journal= {arXiv preprint arXiv:1912.11047},
  year   = {2020}
}

Comments

9 pages, 2 figures

R2 v1 2026-06-23T12:55:03.008Z