Improved List-Decodability of Reed--Solomon Codes via Tree Packings

Abstract

This paper shows that there exist Reed--Solomon (RS) codes, over exponentially large finite fields in the code length, that are combinatorially list-decodable well beyond the Johnson radius, in fact almost achieving the list-decoding capacity. In particular, we show that for any ε∈ (0,1] there exist RS codes with rate (ε(1/ε)+1) that are list-decodable from radius of 1-ε. We generalize this result to list-recovery, showing that there exist (1 - ε, , O(/ε))-list-recoverable RS codes with rate ( ε ((1/ε)+1) ). Along the way we use our techniques to give a new proof of a result of Blackburn on optimal linear perfect hash matrices, and strengthen it to obtain a construction of strongly perfect hash matrices. To derive the results in this paper we show a surprising connection of the above problems to graph theory, and in particular to the tree packing theorem of Nash-Williams and Tutte. We also state a new conjecture that generalizes the tree-packing theorem to hypergraphs, and show that if this conjecture holds, then there would exist RS codes that are optimally (non-asymptotically) list-decodable.