English

Quantifying nonlocality: how outperforming local quantum codes is expensive

Quantum Physics 2022-08-17 v1 Information Theory math.IT

Abstract

Quantum low-density parity-check (LDPC) codes are a promising avenue to reduce the cost of constructing scalable quantum circuits. However, it is unclear how to implement these codes in practice. Seminal results of Bravyi & Terhal, and Bravyi, Poulin & Terhal have shown that quantum LDPC codes implemented through local interactions obey restrictions on their dimension kk and distance dd. Here we address the complementary question of how many long-range interactions are required to implement a quantum LDPC code with parameters kk and dd. In particular, in 2D we show that a quantum LDPC with distance n1/2+ϵn^{1/2 + \epsilon} code requires Ω(n1/2+ϵ)\Omega(n^{1/2 + \epsilon}) interactions of length Ω~(nϵ)\widetilde{\Omega}(n^{\epsilon}). Further a code satisfying knk \propto n with distance dnαd \propto n^\alpha requires Ω~(n)\widetilde{\Omega}(n) interactions of length Ω~(nα/2)\widetilde{\Omega}(n^{\alpha/2}). Our results are derived using bounds on quantum codes from graph metrics. As an application of these results, we consider a model called a stacked architecture, which has previously been considered as a potential way to implement quantum LDPC codes. In this model, although most interactions are local, a few of them are allowed to be very long. We prove that limited long-range connectivity implies quantitative bounds on the distance and code dimension.

Keywords

Cite

@article{arxiv.2109.10982,
  title  = {Quantifying nonlocality: how outperforming local quantum codes is expensive},
  author = {Nouédyn Baspin and Anirudh Krishna},
  journal= {arXiv preprint arXiv:2109.10982},
  year   = {2022}
}
R2 v1 2026-06-24T06:13:58.655Z