Reconstructing Reed-Solomon Codes from Multiple Noisy Channel Outputs

Abstract

The sequence reconstruction problem, introduced by Levenshtein in 2001, considers a communication setting in which a sender transmits a codeword and the receiver observes K independent noisy versions of this codeword. In this work, we study the problem of efficient reconstruction when each of the K outputs is corrupted by a q-ary discrete memoryless symmetric (DMS) substitution channel with substitution probability p. Focusing on Reed-Solomon (RS) codes, we adapt the Koetter-Vardy soft-decision decoding algorithm to obtain an efficient reconstruction algorithm. For sufficiently large blocklength and alphabet size, we derive an explicit rate threshold, depending only on (p, K), such that the transmitted codeword can be reconstructed with arbitrarily small probability of error whenever the code rate R lies below this threshold.