English

Decentralized No-Regret Frequency-Time Scheduling for FMCW Radar Interference Avoidance

Systems and Control 2026-01-01 v1 Systems and Control Signal Processing

Abstract

Automotive FMCW radars are indispensable to modern ADAS and autonomous-driving systems, but their increasing density has intensified the risk of mutual interference. Existing mitigation techniques, including reactive receiver-side suppression, proactive waveform design, and cooperative scheduling, often face limitations in scalability, reliance on side-channel communication, or degradation of range-Doppler resolution. Building on our earlier work on decentralized Frequency-Domain No-Regret hopping, this paper introduces a unified time-frequency game-theoretic framework that enables radars to adapt across both spectral and temporal resources. We formulate the interference-avoidance problem as a repeated anti-coordination game, in which each radar autonomously updates a mixed strategy over frequency subbands and chirp-level time offsets using regret-minimization dynamics. We show that the proposed Time-Frequency No-Regret Hopping algorithm achieves vanishing external and swap regret, and that the induced empirical play converges to an ε\varepsilon-coarse correlated equilibrium or a correlated equilibrium. Theoretical analysis provides regret bounds in the joint domain, revealing how temporal adaptation implicitly regularizes frequency selection and enhances robustness against asynchronous interference. Numerical experiments with multi-radar scenarios demonstrate substantial improvements in SINR, collision rate, and range-Doppler quality compared with time-frequency random hopping and centralized Nash-based benchmarks.

Keywords

Cite

@article{arxiv.2512.24619,
  title  = {Decentralized No-Regret Frequency-Time Scheduling for FMCW Radar Interference Avoidance},
  author = {Yunian Pan and Jun Li and Lifan Xu and Shunqiao Sun and Quanyan Zhu},
  journal= {arXiv preprint arXiv:2512.24619},
  year   = {2026}
}
R2 v1 2026-07-01T08:46:32.367Z