English

Interactive Error Correcting Codes Over Binary Erasure Channels Resilient to $>\frac12$ Adversarial Corruption

Data Structures and Algorithms 2021-11-09 v1 Information Theory math.IT

Abstract

An error correcting code (ECC\mathsf{ECC}) allows a sender to send a message to a receiver such that even if a constant fraction of the communicated bits are corrupted, the receiver can still learn the message correctly. Due to their importance and fundamental nature, ECC\mathsf{ECC}s have been extensively studied, one of the main goals being to maximize the fraction of errors that the ECC\mathsf{ECC} is resilient to. For adversarial erasure errors (over a binary channel) the maximal error resilience of an ECC\mathsf{ECC} is 12\frac12 of the communicated bits. In this work, we break this 12\frac12 barrier by introducing the notion of an interactive error correcting code (iECC\mathsf{iECC}) and constructing an iECC\mathsf{iECC} that is resilient to adversarial erasure of 35\frac35 of the total communicated bits. We emphasize that the adversary can corrupt both the sending party and the receiving party, and that both parties' rounds contribute to the adversary's budget. We also prove an impossibility (upper) bound of 23\frac23 on the maximal resilience of any binary iECC\mathsf{iECC} to adversarial erasures. In the bit flip setting, we prove an impossibility bound of 27\frac27.

Keywords

Cite

@article{arxiv.2111.04181,
  title  = {Interactive Error Correcting Codes Over Binary Erasure Channels Resilient to $>\frac12$ Adversarial Corruption},
  author = {Meghal Gupta and Yael Tauman Kalai and Rachel Zhang},
  journal= {arXiv preprint arXiv:2111.04181},
  year   = {2021}
}
R2 v1 2026-06-24T07:29:41.361Z