Even Sets and Dual Projective Geometric Codes: A Tale of Cylinders

Abstract

In this paper, we prove that the smallest even sets in PG(n,q), i.e. sets that intersect every line in an even number of points, are cylinders with a hyperoval as base. This fits into a more general study of dual projective geometric codes. Let q be a prime power, and define Ck(n,q) as the kernel of the k-space vs. point incidence matrix of PG(n,q), seen as a matrix over the prime order subfield of Fq. Determining the minimum weight of this linear code is still an open problem in general, but has been reduced to the case k=1. There is a known construction that constructs small weight codewords of C1(n,q) from minimum weight codewords of C1(2,q). We call such codewords cylinder codewords. We pose the conjecture that all minimum weight codewords of C1(n,q) are cylinder codewords. This conjecture is known to be true if q is prime. We take three steps towards proving that the conjecture is true in general: (1) We prove that the conjecture is true if q is even. This is equivalent to our classification of the smallest even sets. (2) We prove that the minimum weight of C1(n,q) is qn-2 times the minimum weight of C1(2,q), which matches the weight of cylinder codewords. Thus, we completely reduce the problem of determining the minimum weight of C1(n,q) to the case n=2. (3) We prove that if the conjecture is true for n=3, it is true in general.