Advances in List Decoding of Polynomial Codes

TL;DR

This paper surveys recent advances in list decoding of polynomial codes, especially Reed-Solomon Codes, highlighting new algorithms that decode beyond traditional limits efficiently and with optimal list sizes.

Contribution

It provides a comprehensive overview of the latest methods enabling efficient list decoding of polynomial codes up to capacity with optimal performance.

Findings

Efficient list decoding algorithms up to information-theoretic capacity.

Optimal list-size achieved in polynomial-time algorithms.

Development of nearly-linear and sublinear time decoding methods.

Abstract

Error-correcting codes are a method for representing data, so that one can recover the original information even if some parts of it were corrupted. The basic idea, which dates back to the revolutionary work of Shannon and Hamming about a century ago, is to encode the data into a redundant form, so that the original information can be decoded from the redundant encoding even in the presence of some noise or corruption. One prominent family of error-correcting codes are Reed-Solomon Codes which encode the data using evaluations of low-degree polynomials. Nearly six decades after they were introduced, Reed-Solomon Codes, as well as some related families of polynomial-based codes, continue to be widely studied, both from a theoretical perspective and from the point of view of applications. Besides their obvious use in communication, error-correcting codes such as Reed-Solomon Codes are also useful for various applications in theoretical computer science. These applications often require the ability to cope with many errors, much more than what is possible information-theoretically. List-decodable codes are a special class of error-correcting codes that enable correction from more errors than is traditionally possible by allowing a small list of candidate decodings. These codes have turned out to be extremely useful in various applications across theoretical computer science and coding theory. In recent years, there have been significant advances in list decoding of Reed-Solomon Codes and related families of polynomial-based codes. This includes efficient list decoding of such codes up to the information-theoretic capacity, with optimal list-size, and using fast nearly-linear time, and even sublinear-time, algorithms. In this book, we survey these developments.