3-Designs from GL2(Fq)-Invariant Subspaces of Fq[X,Y]k

Abstract

We present a uniform framework for constructing 3-designs from GL2( Fq)-invariant subspaces of Fq[X,Y]k, the space of homogeneous polynomials of degree k. Given such a subspace W, we associate a PGL2( Fq)-invariant family of k-subsets of P1( Fq). Whenever this family is nonempty, it forms a 3-(q+1,k,λ) design. Via the Cayley transform, the construction is reformulated on the unit circle Uq+1⊂eq Fq2×, where the block conditions become explicit linear relations among elementary symmetric polynomials. This reformulation unifies several previously disparate constructions and simplifies a number of delicate ad hoc computations. When k q, the evaluation map on P1( Fq) identifies W with a subcode CW of the projective Reed--Solomon code. We show that the associated block family is nonempty if and only if d(CW)=q+1-k. Under this condition, the supports of minimum-weight codewords in CW, as well as the supports of suitable fixed-weight codewords in the dual code CW, yield further 3-designs. Applying this framework to the Lucas subspaces, which form a distinguished family of invariant subspaces, we obtain explicit block descriptions, classify the cases in which the defining conditions reduce to a single equation, and establish several emptiness and nonemptiness results. In particular, for q=pe and k=pm+1, we show that the associated block family is nonempty if and only if m e, in which case it yields the Steiner system S(3,pm+1,q+1). Finally, in the ternary case p=3 and k=7, we use the weight distribution of the ternary Melas code to determine the design parameters left undetermined by Xu et al.