@inproceedings{0bccd250b78f4f8191c034a6c5e9e702,
title = "Every list-decodable code for high noise has abundant near-optimal rate puncturings",
abstract = "We show that any q-ary code with suficiently good distance can be randomly punctured to obtain, with high probability, a code that is list decodable up to radius 1 - 1=q ε with near-optimal rate and list sizes. Our results imply that {"}most{"} Reed-Solomon codes are list decodable beyond the Johnson bound, settling the longstanding open question of whether any Reed Solomon codes meet this criterion. More precisely, we show that a Reed- Solomon code with random evaluation points is, with high probability, list decodable up to radius 1 ε with list sizes O(1/ε) and rate {\~Ω}(ε). As a second corollary of our argument, we obtain improved bounds on the list decodability of random linear codes over large fields. Our approach exploits techniques from high dimensional probability. Previous work used similar tools to obtain bounds on the list decodability of random linear codes, but the bounds did not scale with the size of the alphabet. In this paper, we use a chaining argument to deal with large alphabet sizes.",
keywords = "List decoding, Random linear codes, Reed-Solomon codes",
author = "Atri Rudra and Mary Wootters",
year = "2014",
doi = "10.1145/2591796.2591797",
language = "English",
isbn = "9781450327107",
series = "Proceedings of the Annual ACM Symposium on Theory of Computing",
publisher = "Association for Computing Machinery",
pages = "764--773",
booktitle = "STOC 2014 - Proceedings of the 2014 ACM Symposium on Theory of Computing",
address = "United States",
note = "4th Annual ACM Symposium on Theory of Computing, STOC 2014 ; Conference date: 31-05-2014 Through 03-06-2014",
}