On Slepian--Wolf Theorem with Interaction
Abstract
In this paper we study interactive "one-shot" analogues of the classical Slepian-Wolf theorem. Alice receives a value of a random variable , Bob receives a value of another random variable that is jointly distributed with . Alice's goal is to transmit to Bob (with some error probability ). Instead of one-way transmission, which is studied in the classical coding theory, we allow them to interact. They may also use shared randomness. We show, that Alice can transmit to Bob in expected number of bits. Moreover, we show that every one-round protocol with information complexity can be compressed to the (many-round) protocol with expected communication about bits. This improves a result by Braverman and Rao \cite{braverman2011information}, where they had . Further, we show how to solve this problem (transmitting ) using bits and rounds on average. This improves a result of~\cite{brody2013towards}, where they had bits and 10 rounds on average. In the end of the paper we discuss how many bits Alice and Bob may need to communicate on average besides . The main question is whether the upper bounds mentioned above are tight. We provide an example of , such that transmission of from Alice to Bob with error probability requires bits on average.
Cite
@article{arxiv.1506.00617,
title = {On Slepian--Wolf Theorem with Interaction},
author = {Alexander Kozachinskiy},
journal= {arXiv preprint arXiv:1506.00617},
year = {2015}
}