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Main Authors: Wang, Ziqi, Zhao, Hailiang, Yang, Yuhao, Hu, Daojiang, Bao, Cheng, Liu, Mingyi, Di, Kai, Dustdar, Schahram, Wang, Zhongjie, Deng, Shuiguang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.01320
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author Wang, Ziqi
Zhao, Hailiang
Yang, Yuhao
Hu, Daojiang
Bao, Cheng
Liu, Mingyi
Di, Kai
Dustdar, Schahram
Wang, Zhongjie
Deng, Shuiguang
author_facet Wang, Ziqi
Zhao, Hailiang
Yang, Yuhao
Hu, Daojiang
Bao, Cheng
Liu, Mingyi
Di, Kai
Dustdar, Schahram
Wang, Zhongjie
Deng, Shuiguang
contents Accurate and timely prediction of tool conditions is critical for intelligent manufacturing systems, where unplanned tool failures can lead to quality degradation and production downtime. In modern industrial environments, predictive maintenance is increasingly implemented as an intelligent service that integrates sensing, analysis, and decision support across production processes. To meet the demand for reliable and service-oriented operation, we present OmniFuser, a multimodal learning framework for predictive maintenance of milling tools that leverages both visual and sensor data. It performs parallel feature extraction from high-resolution tool images and cutting-force signals, capturing complementary spatiotemporal patterns across modalities. To effectively integrate heterogeneous features, OmniFuser employs a contamination-free cross-modal fusion mechanism that disentangles shared and modality-specific components, allowing for efficient cross-modal interaction. Furthermore, a recursive refinement pathway functions as an anchor mechanism, consistently retaining residual information to stabilize fusion dynamics. The learned representations can be encapsulated as reusable maintenance service modules, supporting both tool-state classification (e.g., Sharp, Used, Dulled) and multi-step force signal forecasting. Experiments on real-world milling datasets demonstrate that OmniFuser consistently outperforms state-of-the-art baselines, providing a dependable foundation for building intelligent industrial maintenance services.
format Preprint
id arxiv_https___arxiv_org_abs_2511_01320
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle OmniFuser: Adaptive Multimodal Fusion for Service-Oriented Predictive Maintenance
Wang, Ziqi
Zhao, Hailiang
Yang, Yuhao
Hu, Daojiang
Bao, Cheng
Liu, Mingyi
Di, Kai
Dustdar, Schahram
Wang, Zhongjie
Deng, Shuiguang
Artificial Intelligence
Accurate and timely prediction of tool conditions is critical for intelligent manufacturing systems, where unplanned tool failures can lead to quality degradation and production downtime. In modern industrial environments, predictive maintenance is increasingly implemented as an intelligent service that integrates sensing, analysis, and decision support across production processes. To meet the demand for reliable and service-oriented operation, we present OmniFuser, a multimodal learning framework for predictive maintenance of milling tools that leverages both visual and sensor data. It performs parallel feature extraction from high-resolution tool images and cutting-force signals, capturing complementary spatiotemporal patterns across modalities. To effectively integrate heterogeneous features, OmniFuser employs a contamination-free cross-modal fusion mechanism that disentangles shared and modality-specific components, allowing for efficient cross-modal interaction. Furthermore, a recursive refinement pathway functions as an anchor mechanism, consistently retaining residual information to stabilize fusion dynamics. The learned representations can be encapsulated as reusable maintenance service modules, supporting both tool-state classification (e.g., Sharp, Used, Dulled) and multi-step force signal forecasting. Experiments on real-world milling datasets demonstrate that OmniFuser consistently outperforms state-of-the-art baselines, providing a dependable foundation for building intelligent industrial maintenance services.
title OmniFuser: Adaptive Multimodal Fusion for Service-Oriented Predictive Maintenance
topic Artificial Intelligence
url https://arxiv.org/abs/2511.01320