# A New Approach to Multi-Party Peer-to-Peer Communication Complexity

**Authors:** Adi Ros\'en, Florent Urrutia

arXiv: 1901.01178 · 2020-10-01

## TL;DR

This paper introduces new models and measures for multi-party peer-to-peer communication complexity, proving tight lower bounds for Disjointness and parity functions, advancing understanding in natural peer-to-peer settings.

## Contribution

It presents the first tight lower bounds for multi-party peer-to-peer communication complexity, improving upon previous models and results.

## Key findings

- Proves a tight  lower bound of  on Disjointness complexity.
- Establishes a tight  lower bound for parity function.
- Shows an  lower bound on random bits for private computation.

## Abstract

We introduce new models and new information theoretic measures for the study of communication complexity in the natural peer-to-peer, multi-party, number-in-hand setting. We prove a number of properties of our new models and measures, and then, in order to exemplify their effectiveness, we use them to prove two lower bounds. The more elaborate one is a tight lower bound of $\Omega(kn)$ on the multi-party peer-to-peer randomized communication complexity of the $k$-player, $n$-bit Disjointness function. The other one is a tight lower bound of $\Omega(kn)$ on the multi-party peer-to-peer randomized communication complexity of the $k$-player, $n$-bit bitwise parity function. Both lower bounds hold when ${n=\Omega(k)}$. The lower bound for Disjointness improves over the lower bound that can be inferred from the result of Braverman et al.~(FOCS 2013), which was proved in the coordinator model and can yield a lower bound of $\Omega(kn/\log k)$ in the peer-to-peer model.   To the best of our knowledge, our lower bounds are the first tight (non-trivial)lower bounds on communication complexity in the natural {\em peer-to-peer} multi-party setting.   In addition to the above results for communication complexity, we also prove, using the same tools, an $\Omega(n)$ lower bound on the number of random bits necessary for the (information theoretic) private computation of the $k$-player, $n$-bit Disjointness function .

## Full text

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## References

49 references — full list in the complete paper: https://tomesphere.com/paper/1901.01178/full.md

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Source: https://tomesphere.com/paper/1901.01178