Gradient Clock Synchronization with Practically Constant Local Skew
Abstract
Gradient Clock Synchronization (GCS) is the task of minimizing the \emph{local skew,} i.e., the clock offset between neighboring clocks, in a larger network. While asymptotically optimal bounds are known, from a practical perspective they have crucial shortcomings: - Local skew bounds are determined by upper bounds on offset estimation that need to be guaranteed throughout the entire lifetime of the system. - Worst-case frequency deviations of local oscillators from their nominal rate are assumed, yet frequencies tend to be much more stable in the (relevant) short term. State-of-the-art deployed synchronization methods adapt to the true offset measurement and frequency errors, but achieve no non-trivial guarantees on the local skew. In this work, we provide a refined model and novel analysis of existing techniques for solving GCS in this model. By requiring only \emph{stability} of measurement and frequency errors, we can circumvent existing lower bounds, leading to dramatic improvements under very general conditions. For example, if links exhibit a uniform worst-case estimation error of and a \emph{change} in estimation errors of on relevant time scales, we bound the local skew by for networks of diameter , effectively ``breaking'' the established lower bound, which holds when . Similarly, we show how to limit the influence of local oscillators on to scale with the \emph{change} of frequency of an individual oscillator on relevant time scales. Moreover, we show how to ensure self-stabilization in this challenging setting. Last, but not least, we extend all of our results to the scenario of external synchronization, at the cost of a limited increase in stabilization time.
Keywords
Cite
@article{arxiv.2511.01420,
title = {Gradient Clock Synchronization with Practically Constant Local Skew},
author = {Christoph Lenzen},
journal= {arXiv preprint arXiv:2511.01420},
year = {2026}
}
Comments
39 pages, no figures, shorter conference version accepted at PODC 2026