Quantum Codes from r-Nearly Self-Orthogonal Linear Codes via Jordan Canonical Form over Fq2

Abstract

We introduce a Jordan-canonical-form framework for constructing q-ary quantum stabilizer codes from arbitrary classical linear codes over q2. The framework does not require the classical linear code C to satisfy the dual-containing condition (i.e., self-orthogonality). Given a classical code C=[n,k,d]q2 with parity-check matrix H, we measure the obstruction to Hermitian self-orthogonality by the rank r=(n-k)-_q2(Ch C). The ingredient code C is r-nearly dual containing, or, equivalently, Ch is r-nearly self-orthogonal, by which we mean that r=(HH)=_q2(Ch)-_q2(Ch C). By systematically reducing the rank of the Hermitian inner-product matrix A=HH through rank-one perturbations along the Jordan basis W=P-1 of the decomposition A=PJAP-1, we construct an explicit Hermitian self-orthogonal code Cso=[n+r,n-k]q2. A sufficient distance-preservation criterion guarantees that the resulting q-ary quantum code has parameters [[n+r,2k-n+r,≥ d]]q. Applying this construction to classical codes produces several record quantum codes that improve or supplement the best-known parameters in Grassl's tables.

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