English

Permutation-invariant codes: a numerical study and qudit constructions

Quantum Physics 2026-03-12 v1 Information Theory math.IT

Abstract

We investigate Permutation-Invariant (PI) quantum error-correcting codes encoding a logical qudit of dimension dL\mathrm{d}_\mathrm{L} in PI states using physical qudits of dimension dP\mathrm{d}_\mathrm{P}. We extend the Knill--Laflamme (KL) conditions for d1d-1 deletion errors from qubits to qudits and investigate numerically both qubit (dL=dP=2\mathrm{d}_\mathrm{L} = \mathrm{d}_\mathrm{P} = 2) and qudit (dL>2\mathrm{d}_\mathrm{L} > 2 or dP>2\mathrm{d}_\mathrm{P} > 2) PI codes. We analyze the scaling of the block length nn in terms of the code distance dd, and compare to existing families of PI codes due to Ouyang, Aydin--Alekseyev--Barg (AAB) and Pollatsek--Ruskai (PR). Our three main findings are: (i) We conjecture that qubit PI codes correcting up to d1d-1 deletion errors have block length n(d)(3d2+1)/4n(d) \geq (3d^2 + 1) / 4, which implies an upper bound d12n3/3d \leq \sqrt{12n-3}/3 on their code distance, and that PR codes can saturate this bound. (ii) For qudit PI codes encoding a single qudit we numerically observe that increasing dP\mathrm{d}_\mathrm{P} results in nn monotonically decreasing and approaching the quantum Singleton bound n(d)2d1n(d) \geq 2d-1. (iii) We propose a semi-analytic extension of the qubit AAB construction to qudits that finds explicit solutions by solving a linear program. Our results therefore provide key insights into lower bounds on the block length scaling of both qubit and qudit PI codes, and demonstrate the benefit of increased physical local dimension in the context of PI codes.

Keywords

Cite

@article{arxiv.2603.10981,
  title  = {Permutation-invariant codes: a numerical study and qudit constructions},
  author = {Liam J. Bond and Jiří Minář and Māris Ozols and Arghavan Safavi-Naini and Vladyslav Visnevskyi},
  journal= {arXiv preprint arXiv:2603.10981},
  year   = {2026}
}
R2 v1 2026-07-01T11:15:02.224Z