Erasure List-Decodable Codes from Random and Algebraic Geometry Codes
Abstract
Erasure list decoding was introduced to correct a larger number of erasures with output of a list of possible candidates. In the present paper, we consider both random linear codes and algebraic geometry codes for list decoding erasure errors. The contributions of this paper are two-fold. Firstly, we show that, for arbitrary and ( and are independent), with high probability a random linear code is an erasure list decodable code with constant list size that can correct a fraction of erasures, i.e., a random linear code achieves the information-theoretic optimal trade-off between information rate and fraction of erasure errors. Secondly, we show that algebraic geometry codes are good erasure list-decodable codes. Precisely speaking, for any and , a -ary algebraic geometry code of rate from the Garcia-Stichtenoth tower can correct fraction of erasure errors with list size . This improves the Johnson bound applied to algebraic geometry codes. Furthermore, list decoding of these algebraic geometry codes can be implemented in polynomial time.
Cite
@article{arxiv.1401.2716,
title = {Erasure List-Decodable Codes from Random and Algebraic Geometry Codes},
author = {Yang Ding and Lingfei Jin and Chaoping Xing},
journal= {arXiv preprint arXiv:1401.2716},
year = {2014}
}