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A near-optimal direct-sum theorem for communication complexity

Information Theory 2020-09-04 v3 math.IT

Abstract

We show a near optimal direct-sum theorem for the two-party randomized communication complexity. Let fX×Y×Zf\subseteq X \times Y\times Z be a relation, ε>0\varepsilon> 0 and kk be an integer. We show, Rεpub(fk)log(Rεpub(fk))Ω(kRεpub(f)),\mathrm{R}^{\mathrm{pub}}_\varepsilon(f^k) \cdot \log(\mathrm{R}^{\mathrm{pub}}_\varepsilon(f^k)) \ge \Omega(k \cdot \mathrm{R}^{\mathrm{pub}}_\varepsilon(f)) \enspace, where fk=f××ff^k= f \times \ldots \times f (kk-times) and Rεpub()\mathrm{R}^{\mathrm{pub}}_\varepsilon(\cdot) represents the public-coin randomized communication complexity with worst-case error ε\varepsilon. Given a protocol P\mathcal{P} for fkf^k with communication cost ckc \cdot k and worst-case error ε\varepsilon, we exhibit a protocol Q\mathcal{Q} for ff with external-information-cost O(c)O(c) and worst-error ε\varepsilon. We then use a message compression protocol due to Barak, Braverman, Chen and Rao [2013] for simulating Q\mathcal{Q} with communication O(clog(ck))O(c \cdot \log(c\cdot k)) to arrive at our result. To show this reduction we show some new chain-rules for capacity, the maximum information that can be transmitted by a communication channel. We use the powerful concept of Nash-Equilibrium in game-theory, and its existence in suitably defined games, to arrive at the chain-rules for capacity. These chain-rules are of independent interest.

Keywords

Cite

@article{arxiv.2008.07188,
  title  = {A near-optimal direct-sum theorem for communication complexity},
  author = {Rahul Jain},
  journal= {arXiv preprint arXiv:2008.07188},
  year   = {2020}
}

Comments

Withdrawing due to an incorrigible error

R2 v1 2026-06-23T17:54:04.611Z