面向回归无监督域自适应的不确定性引导对齐

Uncertainty-guided alignment for unsupervised domain adaptation in regression

Reliability Engineering and System Safety · 2025
被引 1
ABS 3

中文导读

提出不确定性引导对齐方法,在无监督域自适应回归中利用预测不确定性指导特征对齐,提升跨工况预测可靠性,在电池荷电状态预测等任务中优于现有方法。

Abstract

In prognostics and health management systems, models must reliably predict asset health conditions across varying operating conditions, equipment manufacturers, or degradation patterns. However, obtaining labeled data for every new operational context is often impractical, particularly for run-to-failure trajectories. This work addresses this challenge through Unsupervised Domain Adaptation for Regression, which enables adaptation from a labeled source domain to an unlabeled target domain. Traditional feature alignment methods (such as adversarial or moment matching) underperform in PHM regression tasks due to the inherent correlation among learned features, leading to unreliable prognostic predictions when operating conditions change. This work proposes Uncertainty-Guided Alignment (UGA), a novel method that explicitly integrates predictive uncertainty into the feature alignment process. UGA employs Evidential Deep Learning to predict both target values and their associated uncertainties, using this uncertainty information to guide domain alignment and regularize the embedding space. This directly addresses key PHM requirements: (1) quantifying confidence in predictions when deployed in new operational conditions, (2) enabling reliable cross-operational context deployment. The approach is validated on two computer vision benchmarks and a real-world PHM case study of battery state-of-charge prediction, where domains are defined by different manufacturers (LG, Panasonic) and operating temperatures (-20 ∘ C to 25 ∘ C). Across 52 transfer tasks, UGA outperforms existing state-of-the-art methods on average. Our approach not only improves adaptation performance but also provides well-calibrated uncertainty estimates. The code is available in https://github.com/ismailnejjar/UGA .

预测与健康管理无监督域自适应不确定性量化回归分析电池健康状态预测