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Main Authors: Wang, Yakun, Han, Pengyu, Liu, Zeyi, He, Xiao, Cai, Dongming, Zhao, Hongshuo
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.22028
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author Wang, Yakun
Han, Pengyu
Liu, Zeyi
He, Xiao
Cai, Dongming
Zhao, Hongshuo
author_facet Wang, Yakun
Han, Pengyu
Liu, Zeyi
He, Xiao
Cai, Dongming
Zhao, Hongshuo
contents In modern industrial systems, machinery frequently operates under dynamic environments with continuously varying loads and speeds. Consequently, deep learning-based fault diagnosis models often suffer from severe performance degradation under unseen operating conditions due to complex data distribution shifts. Since existing methods predominantly rely on static offline training, they lack the capability to dynamically adapt to these continuous variations. To address this issue, an integrated framework combining offline domain generalization (DG) and online test-time adaptation (OTTA) is proposed. Initially, a model with preliminary generalization capability is obtained offline by extracting domain-invariant features via adversarial learning. During the online phase, a dual-memory replay mechanism is developed. By selectively storing high-confidence online pseudo-labeled samples and replaying them with historical offline data, the model facilitates adaptation to changing data distributions and helps reduce forgetting of previously learned knowledge Experiments on a real-world motor dataset show that the proposed approach achieves competitive performance under the considered unseen operating conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2605_22028
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Replay-guided Test-time Adaptation for Fault Diagnosis Under Unseen Operating Conditions
Wang, Yakun
Han, Pengyu
Liu, Zeyi
He, Xiao
Cai, Dongming
Zhao, Hongshuo
Signal Processing
In modern industrial systems, machinery frequently operates under dynamic environments with continuously varying loads and speeds. Consequently, deep learning-based fault diagnosis models often suffer from severe performance degradation under unseen operating conditions due to complex data distribution shifts. Since existing methods predominantly rely on static offline training, they lack the capability to dynamically adapt to these continuous variations. To address this issue, an integrated framework combining offline domain generalization (DG) and online test-time adaptation (OTTA) is proposed. Initially, a model with preliminary generalization capability is obtained offline by extracting domain-invariant features via adversarial learning. During the online phase, a dual-memory replay mechanism is developed. By selectively storing high-confidence online pseudo-labeled samples and replaying them with historical offline data, the model facilitates adaptation to changing data distributions and helps reduce forgetting of previously learned knowledge Experiments on a real-world motor dataset show that the proposed approach achieves competitive performance under the considered unseen operating conditions.
title Replay-guided Test-time Adaptation for Fault Diagnosis Under Unseen Operating Conditions
topic Signal Processing
url https://arxiv.org/abs/2605.22028