Cyclic Projective Orbits on Rational Normal Curves and MDS Codes
Abstract
Let \(A\) be a cyclic operator on an \(r\)-dimensional vector space over a field \(k\), and let \(z\) be a cyclic vector. Their Krylov code has parity-check matrix \((z,Az,…,An-1z)\). For \(r 3\) and \(n r+3\), we prove that an MDS orbit segment lies on a rational normal curve precisely when the projective pair \((A,[z])\) is conjugate to one arising from the \((r-1)\)-st symmetric-power action of \(PGL2\). Over finite fields, for companion operators, this gives a complete classification of the generalized Reed--Solomon locus into split semisimple, two nonsplit semisimple, and unipotent families. Over an algebraically closed field \(k\), the Zariski closure \(r,k\) of the semisimple GRS coefficient locus is an irreducible rational surface, generically parameterized two-to-one by a two-dimensional torus of geometric-progression root sets; reversal is the generic ambiguity. The affine quotient of the parameter torus by reversal is the normalization of \(r,k D(a0)\), its nonzero-constant-term open part. The codimension in the space of monic degree-\(r\) polynomials is \(r-2\). Frobenius descent gives an exact formula for the number of GRS polynomials over \( Fq\). A canonical remainder parity-check matrix defines the MDS locus by a principal open condition. For fixed \(r3\) and \(n r+3\), the proportion of all monic degree-\(r\) polynomials over \( Fq\) whose companion codes are MDS and non-GRS tends to one as \(q∞\) through prime powers.
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