Sage Journals: Discover world-class research

Abstract

Predictive maintenance for machines typically involves model-based condition monitoring systems. However, many state-of-the-art methods are not designed to work under varying production plans or machine operating conditions. Contextual data, such as machine parameters, input material details, and environmental factors, can provide valuable insights into the effectiveness of existing models in changing environments. However, research in this area is limited. This article takes a broad view on adaptive ensemble learning for machine health prognosis from context information-based fitness estimation. Prognostic models are leveraged to increase accuracy under varying operating conditions by using spatial proximity computations between new contextual data features and data from their training phases. Several experiments aim to answer open research questions from previous work. In particular, this study extends the base algorithm from a single one to a set of five common regression algorithms and two classification algorithms and the demonstration domain from turbofans to a simplified synthetic and a milling scenario. In addition, the effect of the available time horizon for online prediction of the context information is evaluated. The results show that the adaptive ensemble method consistently improves degradation percentage estimation accuracy over both single models and conventional averaging ensembles. For classification tasks with highly imbalanced data, such as the milling scenario, the method offers marginal gains, indicating limited benefit from cross-validation weighting in such cases.

Keywords

prognostics & health management smart manufacturing machine learning intelligent maintenance systems co-learning and self-learning condition monitoring

Get full access to this article

View all access options for this article.

References

Leohold

Freitag

Adaptive ensemble learning for machine tool prognostics from meta-feature-based context information. IFAC-PapersOnLine 2024; 58: 252–257.

Maierhofer

Trojahn

Ryll

Dynamic scheduling and preventive maintenance in small-batch production: a flexible control approach for maximising machine reliability and minimising delays. Appl Sci 2025; 15: 4287.

Latil

Houé Ngouna

Medjaher

, et al. Vibration-based data-driven fault diagnosis of rotating machines operating under varying working conditions. Int J Progn Health Manag 2025; 16. https://papers.phmsociety.org/index.php/ijphm/issue/view/73

Jombo

Zhang

Acoustic-based machine condition monitoring—methods and challenges. Eng 2023; 4: 47–79.

Huang

Fey

, et al. Prior knowledge-embedded machine learning-driven cutting force monitoring in machinery industry. In: 2022 International Conference on Electrical, Computer and Energy Technologies (ICECET), Prague, Czech Republic, 20–22 July 2022, pp.1–6. New York, NY: IEEE.

Ahmed Murtaza

Saher

Hamza Zafar

, et al. Paradigm shift for predictive maintenance and condition monitoring from Industry 4.0 to Industry 5.0: a systematic review, challenges and case study. Results Eng 2024; 24: 102935.

Leohold

Engbers

Freitag

Prognostic methods for predictive maintenance: a generalized topology. IFAC-PapersOnLine 2021; 54: 629–634.

Braghirolli

Mendes

Engbers

, et al. Improving production and maintenance planning with meta-learning-based failure prediction. J Manuf Syst 2024; 75: 42–55.

Hosseinli

Ooijevaar

Gryllias

Context-aware machine learning for estimating the remaining useful life of bearings under varying speed operating conditions. Annu Conf PHM Society 2023; 15. https://papers.phmsociety.org/index.php/phmconf/issue/view/63

10.

Liu

Zhang

Zheng

, et al. Online industrial fault prognosis in dynamic environments via task-free continual learning. Neurocomputing 2024; 598: 127930.

11.

Feng

Predictive maintenance decision making based on reinforcement learning in multistage production systems. IEEE Access 2022; 10: 18910–18921.

12.

Wang

Zhu

Zhao

Dynamic predictive maintenance strategy for system remaining useful life prediction via deep learning ensemble method. Reliabil Eng Syst Saf 2024; 245: 110012.

13.

K-L

Zhang

Jiang

, et al. Foundations and innovations in data fusion and ensemble learning for effective consensus. Mathematics 2025; 13: 587.

14.

Mahajan

Uddin

Hajati

, et al. Ensemble learning for disease prediction: a review. Healthcare 2023; 11: 1808.

15.

Alharthi

Medjek

Djenouri

Ensemble learning approaches for multi-class intrusion detection systems for the internet of vehicles (IoV): a comprehensive survey. Future Internet 2025; 17: 317.

16.

Abimannan

El-Alfy

E-SM

Chang

Y-S

, et al. Ensemble multifeatured deep learning models and applications: a survey. IEEE Access 2023; 11: 107194–107217.

17.

de Carvalho

HDP

de Oliveira

JFL

Fagundes

RAdA.

Dynamic selection of ensemble-based regression models: systematic literature review. Expert Syst Appl 2025; 290: 128429.

18.

Wang

, et al. An ensembled remaining useful life prediction method with data fusion and stage division. Reliabil Eng Syst Saf 2024; 242: 109804.

19.

Mahalanobis

PC.

On the generalized distance in statistics. Sankhyā 2018; 80: S1-S7.

20.

Saxena

Celaya

Balaban

, et al. Metrics for evaluating performance of prognostic techniques. In: 2008 International Conference on Prognostics and Health Management, Denver, CO, USA, 6–9 October 2008, pp. 1–17. New York, NY: IEEE.

21.

Christ

Braun

Neuffer

, et al. Time series FeatuRe extraction on basis of scalable hypothesis tests (tsfresh – a python package). Neurocomputing 2018; 307: 72–77.

22.

Ester

Kriegel

H-P

Sander

, et al. A density-based algorithm for discovering clusters in large spatial databases with noise. In: Proceedings of the Second International Conference on Knowledge Discovery and Data Mining, 1996, pp. 226–231. AAAI Press.

23.

Pedregosa

Varoquaux

Gramfort

, et al. Scikit-learn: machine learning in python. J Mach Learn Res 2011; 12: 2825–2830.

24.

Saxena

Goebel

Simon

, et al. Damage propagation modeling for aircraft engine run-to-failure simulation. In: 2008 International Conference on Prognostics and Health Management, Denver, CO, USA, 6–9 October 2008, pp.1–9. New York, NY: IEEE.

25.

Tnani

M-A

Feil

Diepold

Smart data collection system for brownfield CNC milling machines: a new benchmark dataset for data-driven machine monitoring. Procedia CIRP 2022; 107: 131–136.

Leveraging context information for machine health prognosis with meta-feature-based fitness estimation

Abstract

Keywords

Get full access to this article

References