English

Quantum Resources Required to Block-Encode a Matrix of Classical Data

Quantum Physics 2023-04-17 v1

Abstract

We provide modular circuit-level implementations and resource estimates for several methods of block-encoding a dense N×NN\times N matrix of classical data to precision ϵ\epsilon; the minimal-depth method achieves a TT-depth of O(log(N/ϵ)),\mathcal{O}{(\log (N/\epsilon))}, while the minimal-count method achieves a TT-count of O(Nlog(1/ϵ))\mathcal{O}{(N\log(1/\epsilon))}. We examine resource tradeoffs between the different approaches, and we explore implementations of two separate models of quantum random access memory (QRAM). As part of this analysis, we provide a novel state preparation routine with TT-depth O(log(N/ϵ))\mathcal{O}{(\log (N/\epsilon))}, improving on previous constructions with scaling O(log2(N/ϵ))\mathcal{O}{(\log^2 (N/\epsilon))}. Our results go beyond simple query complexity and provide a clear picture into the resource costs when large amounts of classical data are assumed to be accessible to quantum algorithms.

Keywords

Cite

@article{arxiv.2206.03505,
  title  = {Quantum Resources Required to Block-Encode a Matrix of Classical Data},
  author = {B. David Clader and Alexander M. Dalzell and Nikitas Stamatopoulos and Grant Salton and Mario Berta and William J. Zeng},
  journal= {arXiv preprint arXiv:2206.03505},
  year   = {2023}
}
R2 v1 2026-06-24T11:42:36.227Z