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Corrected quantum walk for optimal Hamiltonian simulation

Quantum Physics 2017-02-15 v3

Abstract

We describe a method to simulate Hamiltonian evolution on a quantum computer by repeatedly using a superposition of steps of a quantum walk, then applying a correction to the weightings for the numbers of steps of the quantum walk. This correction enables us to obtain complexity which is the same as the lower bound up to double-logarithmic factors for all parameter regimes. The scaling of the query complexity is O(τloglogτlogloglogτ+log(1/ϵ))O\left( \tau \frac{\log\log\tau}{\log\log\log\tau} + \log(1/\epsilon) \right) where τ:=tHmaxd\tau := t\|H\|_{\max}d, for ϵ\epsilon the allowable error, tt the time, Hmax\|H\|_{\max} the max-norm of the Hamiltonian, and dd the sparseness. This technique should also be useful for improving the scaling of the Taylor series approach to simulation, which is relevant to applications such as quantum chemistry.

Keywords

Cite

@article{arxiv.1606.03443,
  title  = {Corrected quantum walk for optimal Hamiltonian simulation},
  author = {Dominic W. Berry and Leonardo Novo},
  journal= {arXiv preprint arXiv:1606.03443},
  year   = {2017}
}

Comments

18 pages, published version

R2 v1 2026-06-22T14:22:48.756Z