English

Byzantine Fault Tolerant Distributed Quickest Change Detection

Probability 2014-12-30 v2 Information Theory Systems and Control math.IT Optimization and Control

Abstract

We introduce and solve the problem of Byzantine fault tolerant distributed quickest change detection in both continuous and discrete time setups. In this problem, multiple sensors sequentially observe random signals from the environment and send their observations to a control center that will determine whether there is a change in the statistical behavior of the observations. We assume that the signals are independent and identically distributed across sensors. An unknown subset of sensors are compromised and will send arbitrarily modified and even artificially generated signals to the control center. It is shown that the performance of the the so-called CUSUM statistic, which is optimal when all sensors are honest, will be significantly degraded in the presence of even a single dishonest sensor. In particular, instead of in a logarithmically the detection delay grows linearly with the average run length (ARL) to false alarm. To mitigate such a performance degradation, we propose a fully distributed low complexity detection scheme. We show that the proposed scheme can recover the log scaling. We also propose a centralized group-wise scheme that can further reduce the detection delay.

Keywords

Cite

@article{arxiv.1306.2086,
  title  = {Byzantine Fault Tolerant Distributed Quickest Change Detection},
  author = {Erhan Bayraktar and Lifeng Lai},
  journal= {arXiv preprint arXiv:1306.2086},
  year   = {2014}
}

Comments

Final version. To appear in the SIAM Journal on Control and Optimization. Keywords: (Non-Bayesian) quickest change detection, Byzantine fault tolerance, distributed sensor network, robust optimal stopping in continuous and discrete time

R2 v1 2026-06-22T00:30:49.381Z