Synchronization with Guaranteed Clock Continuity using Pulse-Coupled Oscillators

TL;DR

This paper introduces a pulse-coupled oscillator approach to achieve clock synchronization with guaranteed continuity, avoiding abrupt changes and ensuring reliable timing in network systems.

Contribution

It presents two general methods for continuous phase evolution in pulse-coupled oscillators and proves their convergence to synchronization.

Findings

Proposed methods ensure clock continuity in oscillator networks.

Mathematical proof of convergence to synchronized state.

Simulation results support the theoretical findings.

Abstract

Clock synchronization is a widely discussed topic in the engineering literature. Ensuring that individual clocks are closely aligned is important in network systems, since the correct timing of various events in a network is usually necessary for proper system implementation. However, many existing clock synchronization algorithms update clock values abruptly, resulting in discontinuous clocks which have been shown to lead to undesirable behavior. In this paper, we propose using the pulse-coupled oscillator model to guarantee clock continuity, demonstrating two general methods for achieving continuous phase evolution in any pulse-coupled oscillator network. We provide rigorous mathematical proof that the pulse-coupled oscillator algorithm is able to converge to the synchronized state when the phase continuity methods are applied. We provide simulation results supporting these proofs. We further investigate the convergence behavior of other pulse-coupled oscillator synchronization algorithms using the proposed methods.