ARC: Alignment-based RPM Estimation with Curvature-adaptive Tracking

TL;DR

ARC introduces a unified, curvature-informed probabilistic tracking method for more robust and interpretable rotational speed estimation in noisy and non-stationary conditions.

Contribution

It unifies heterogeneous estimators into a shared RPM grid and incorporates a state-dependent prior based on local curvature for improved tracking.

Findings

Stable and physically plausible RPM trajectories achieved.

Enhanced robustness against noise and interference demonstrated.

Uncertainty-aware propagation improves tracking over fixed-variance methods.

Abstract

Tacho-less rotational speed estimation is critical for vibration-based prognostics and health management (PHM) of rotating machinery, yet traditional methods--such as time-domain periodicity, cepstrum, and harmonic comb matching--struggle under noise, non-stationarity, and inharmonic interference. Probabilistic tracking offers a principled way to fuse multiple estimators, but a major challenge is that heterogeneous estimators produce evidence on incompatible axes and scales. We address this with ARC (Alignment-based RPM Estimation with Curvature-adaptive Tracking) by unifying the observation representation. Each estimator outputs a one-dimensional evidence curve on its native axis, which is mapped onto a shared RPM grid and converted into a comparable grid-based log-likelihood via robust standardization and a Gibbs-form energy shaping. Standard recursive filtering with fixed-variance motion priors can fail under multi-modal or ambiguous evidence. To overcome this, ARC introduces a curvature-informed, state-dependent motion prior, where the transition variance is derived from the local discrete Hessian of the previous log-posterior. This design enforces smooth tracking around confident modes while preserving competing hypotheses, such as octave alternatives. Experiments on synthetic stress tests and real vibration-table data demonstrate stable, physically plausible trajectories with interpretable uncertainty, and ablations confirm that these gains arise from uncertainty-aware temporal propagation rather than per-frame peak selection or ad hoc rules.