English

Quantum sketching protocols for Hamming distance and beyond

Quantum Physics 2022-08-30 v4

Abstract

In this work we use the concept of quantum fingerprinting to develop a quantum communication protocol in the simultaneous message passing model that calculates the Hamming distance between two nn-bit strings up to relative error ϵ\epsilon. The number of qubits communicated by the protocol is polynomial in logn\log{n} and 1/ϵ1/\epsilon, while any classical protocol must communicate Ω(n)\Omega(\sqrt{n}) bits. Motivated by the relationship between Hamming distance and vertex distance in hypercubes, we apply the protocol to approximately calculate distances between vertices in graphs that can be embedded into a hypercube such that all distances are preserved up to a constant factor. Such graphs are known as 1\ell_1-graphs. This class includes all trees, median graphs, Johnson graphs and Hamming graphs. Our protocol is efficient for 1\ell_1-graphs with low diameter, and we show that its dependence on the diameter is essentially optimal. Finally, we show that our protocol can be used to approximately compute 1\ell_1-distances between vectors efficiently.

Keywords

Cite

@article{arxiv.1810.12808,
  title  = {Quantum sketching protocols for Hamming distance and beyond},
  author = {João F. Doriguello and Ashley Montanaro},
  journal= {arXiv preprint arXiv:1810.12808},
  year   = {2022}
}

Comments

11 pages; v3: epsilon dependence was improved and typos corrected; v4: appendix on $\ell_1$-graphs characterisation deleted due to a mistake and references added

R2 v1 2026-06-23T04:57:52.724Z