Formalizing building-up constructions of self-dual codes through isotropic lines in Lean

Jae-Hyun Baek, Jon-Lark Kim · Apr 9, 2026 · Citations: 0

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Abstract

The purpose of this paper is two-fold. First we show that Kim's building-up construction of binary self-dual codes is equivalent to Chinburg-Zhang's Hilbert symbol construction. Second we introduce a $q$-ary version of Chinburg-Zhang's construction in order to construct $q$-ary self-dual codes efficiently. For the latter, we study self-dual codes over split finite fields $\F_q$ with $q \equiv 1 \pmod{4}$ through three complementary viewpoints: the building-up construction, the binary arithmetic reduction of Chinburg--Zhang, and the hyperbolic geometry of the Euclidean plane. The condition that $-1$ be a square is the common algebraic input linking these viewpoints: in the binary case it underlies the Lagrangian reduction picture, while in the split $q$-ary case it produces the isotropic line governing the correction terms in the extension formulas. As an application of our efficient form of generator matrices, we construct optimal self-dual codes from the split boxed construction, including self-dual $[6,3,4]$ and $[8,4,4]$ codes over $\GF{5}$, MDS self-dual $[8,4,5]$ and $[10,5,6]$ codes over $\GF{13}$, and a self-dual $[12,6,6]$ code over $\GF{13}$. These structural statements are accompanied by a Lean~4 formalization of the algebraic core.

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