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Quantum Query Complexity of the Hyperoctahedral Group

Combinatorics 2026-04-16 v1

Abstract

We determine the quantum query complexity of oracle identification on the hyperoctahedral group BN={±1}NSNB_N = \{\pm 1\}^N \rtimes S_N with respect to the natural representation: QLV(BN)=2(N1)Q_{LV}(B_N) = 2(N-1) for all N2N \ge 2. This is twice the symmetric-group value QLV(SN)=N1Q_{LV}(S_N) = N-1; the doubling arises from an ε\varepsilon-parity obstruction that restricts the bottleneck representation sgn(σ)\operatorname{sgn}(\sigma) to even tensor powers. The proof combines a reduction to SNS_N Kronecker products via Rademacher moment polynomials with the bipartition distance formula dT(((N),),(α,β))=2(Nα1)βd_T(((N),\varnothing),(\alpha,\beta)) = 2(N-\alpha_1)-|\beta| in the tensor product graph. A closed-form generating function yields the first-appearance multiplicity (2N3)!!(2N-3)!!. We also show Qdecomp(φ)2Qsigned(φ)Q_{\mathrm{decomp}}(\varphi) \le 2\,Q_{\mathrm{signed}}(\varphi), with equality on B2B_2, and conjecture a link between the adversary bound and the graph eccentricity.

Keywords

Cite

@article{arxiv.2604.13554,
  title  = {Quantum Query Complexity of the Hyperoctahedral Group},
  author = {Ji Ho Bae},
  journal= {arXiv preprint arXiv:2604.13554},
  year   = {2026}
}

Comments

33 pages

R2 v1 2026-07-01T12:10:14.697Z