Minimal Permutation-Invariant Qudit Codes from Edge-Colorings of Complete Graphs

Abstract

We study permutation-invariant quantum codes in the symmetric subspace Symn(Cq) of n qudits of local dimension q. For every integer q≥ 2, we construct a permutation-invariant code with parameters ((4,q,2))q. Thus four physical qudits suffice to encode one logical qudit with distance two in the symmetric sector for every local dimension. We also show, using linear-programming constraints for permutation-invariant quantum codes, that no permutation-invariant code of dimension q and distance at least 2 exists in Symn(Cq) for n≤ 3. Hence four qudits are necessary and sufficient. The construction has a simple representation-theoretic and combinatorial description. In the irreducible SU(q)-module Sym4(Cq), the distance-two Knill-Laflamme conditions split into root and Cartan parts. By restricting supports to the even-entry occupation layer, all root-error conditions vanish automatically. The remaining Cartan conditions reduce to linear balancing constraints on packets of occupation vectors. These packets admit a natural graph-theoretic interpretation in terms of the vertices and edges of the complete graph Kq: for odd q, they are organized by the midpoint rule, while for even q, they are organized by a decomposition of Kq into perfect matchings. In this way, the existence of minimal ((4,q,2))q permutation-invariant codes is reduced to a parity-dependent edge-coloring problem on Kq.