Stable Leader Election in Population Protocols Requires Linear Time

February 14, 2015 Β· Declared Dead Β· πŸ› Distributed computing

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Authors David Doty, David Soloveichik arXiv ID 1502.04246 Category cs.DC: Distributed Computing Cross-listed cs.CC, q-bio.MN Citations 117 Venue Distributed computing Last Checked 4 months ago
Abstract
A population protocol *stably elects a leader* if, for all $n$, starting from an initial configuration with $n$ agents each in an identical state, with probability 1 it reaches a configuration $\mathbf{y}$ that is correct (exactly one agent is in a special leader state $\ell$) and stable (every configuration reachable from $\mathbf{y}$ also has a single agent in state $\ell$). We show that any population protocol that stably elects a leader requires $Ξ©(n)$ expected "parallel time" --- $Ξ©(n^2)$ expected total pairwise interactions --- to reach such a stable configuration. Our result also informs the understanding of the time complexity of chemical self-organization by showing an essential difficulty in generating exact quantities of molecular species quickly.
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