Improving Efficiency in Near-State and State-Optimal Self-Stabilising Leader Election Population Protocols

Abstract

We investigate leader election problem via ranking within self-stabilising population protocols. In this scenario, the agent's state space comprises n rank states and x extra states. The initial configuration of n agents consists of arbitrary arrangements of rank and extra states, with the objective of self-ranking. Specifically, each agent is tasked with stabilising in a unique rank state silently, implying that after stabilisation, each agent remains in its designated state indefinitely. In this paper, we present several new self-stabilising ranking protocols, greatly enriching our comprehension of these intricate problems. All protocols ensure self-stabilisation time with high probability (whp), defined as 1-n-η, for a constant η>0. We delve into three scenarios, from which we derive stable (always correct), either state-optimal or almost state-optimal, silent ranking protocols that self-stabilise within a time frame of o(n2) whp, including: - Utilising a novel concept of an agent trap, we derive a state-optimal ranking protocol that achieves self-stabilisation in time O(min(kn3/2,n22 n)), for any k-distant starting configuration. - Furthermore, we show that the incorporation of a single extra state (x=1) ensures a ranking protocol that self-stabilises in time O(n7/42 n)=o(n2), regardless of the initial configuration. - Lastly, we show that extra x=O( n) states admit self-stabilising ranking with the best currently known stabilisation time O(n n), when whp and x=O( n) guarantees are imposed.

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