On Factoring Quantum-Plane Skew Polynomials over Q(ω)(t)

Abstract

We study algorithms for factorization in the quantum plane of (dilation) skew polynomials over a function field of a cyclotomic field: \[ R=K(t)[x;σ], K=Q(ω), σ(t)=ωt, \] where ω∈C is a primitive m-th root of unity. We start with the established approach through central elements and factor the central left multiples, staying in characteristic zero, to obtain a partial decomposition. A two-level modular approach is proposed: specialize a central parameter to good algebraic values, study the resulting cyclic algebras over number fields, and then reduce further at good inert primes so that fast finite-field skew-factorization algorithms apply. A prototype SageMath implementation is provided to experiment with the algorithms. We then look at the effect of extending the field of constants from Q(ω) to Q, an algebraic closure of Q, and factoring over Q(t)[x;σ]. In this case we show factorization is decidable in the exact algebraic model based on finite extensions.

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