New List Decoding Algorithms for Reed-Solomon and BCH Codes

Abstract

In this paper we devise a rational curve fitting algorithm and apply it to the list decoding of Reed-Solomon and BCH codes. The proposed list decoding algorithms exhibit the following significant properties. 1 The algorithm corrects up to n(1-1-D) errors for a (generalized) (n, k, d=n-k+1) Reed-Solomon code, which matches the Johnson bound, where D dn denotes the normalized minimum distance. In comparison with the Guruswami-Sudan algorithm, which exhibits the same list correction capability, the former requires multiplicity, which dictates the algorithmic complexity, O(n(1-1-D)), whereas the latter requires multiplicity O(n2(1-D)). With the up-to-date most efficient implementation, the former has complexity O(n6(1-1-D)7/2), whereas the latter has complexity O(n10(1-D)4). 2. With the multiplicity set to one, the derivative list correction capability precisely sits in between the conventional hard-decision decoding and the optimal list decoding. Moreover, the number of candidate codewords is upper bounded by a constant for a fixed code rate and thus, the derivative algorithm exhibits quadratic complexity O(n2). 3. By utilizing the unique properties of the Berlekamp algorithm, the algorithm corrects up to n2(1-1-2D) errors for a narrow-sense (n, k, d) binary BCH code, which matches the Johnson bound for binary codes. The algorithmic complexity is O(n6(1-1-2D)7).

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