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Quantum Entanglement Halves the Oblivious Update Bandwidth

Quantum Physics 2026-05-20 v1 Information Theory math.IT

Abstract

We consider (n,k)(n,k) MDS-coded distributed storage over Fq\mathbb{F}_q with per-node storage α\alpha symbols. For the oblivious update problem, where a single message symbol changes and neither helpers nor the stale node know which, the classical lower bound is αklog2q\alpha k \log_2 q bits. We prove that when the kk contacted helpers share prior quantum entanglement, the update bandwidth is α/2klog2q\lceil \alpha/2 \rceil \cdot k \log_2 q bits-equivalent, a factor approaching 2 reduction. For α=2\alpha = 2, a [[k,k2]]q[[k, k-2]]_q CSS code achieves bandwidth klog2qk \log_2 q with one qudit per helper. For general α\alpha, a [[α/2k,α/2kα]]q[[\lceil \alpha/2 \rceil k, \lceil \alpha/2 \rceil k - \alpha]]_q CSS code achieves the bound with α/2\lceil \alpha/2 \rceil qudits per helper. The matching converse uses the superdense coding bound: the stale node holds all transmitted qudits and hence the entangled partners, so each helper's channel supports at most D2D^2 distinguishable signals for dimension DD. The result holds for all (n,k)(n,k) pairs with sufficiently large prime qq.

Keywords

Cite

@article{arxiv.2605.19248,
  title  = {Quantum Entanglement Halves the Oblivious Update Bandwidth},
  author = {Sagar Dubey},
  journal= {arXiv preprint arXiv:2605.19248},
  year   = {2026}
}