Generative and self‐supervised ensemble modeling for multivariate tool wear monitoring

Joanes Agung', Oroko; James, Kimotho; Samuel, Kabini; Evan, Murimi

doi:10.1002/eng2.12788

Engineering Reports

2023

DOI: 10.1002/eng2.12788

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Generative and self‐supervised ensemble modeling for multivariate tool wear monitoring

Oroko Joanes Agung',

Kimotho James,

Kabini Samuel

et al.

Abstract: Development of an effective tool wear monitor requires maximum utilization of information from associated data, especially in machine learning based modeling. However, vastly varied annotated training data is required, which is not only expensive but impractical to obtain. In the present work, a contiguous approach of artificial data generation followed up by self‐supervised pre‐training before supervised model fine tuning and final stacked generalized ensembling, has been adopted to develop an effective tool … Show more

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A Review of Physics-Based, Data-Driven, and Hybrid Models for Tool Wear Monitoring

Zhang,

Jiang,

Gao

et al. 2024

Machines

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Tool wear is an inevitable phenomenon in the machining process. By monitoring the wear state of a tool, the machining system can give early warning and make advance decisions, which effectively ensures improved machining quality and production efficiency. In the past two decades, scholars have conducted extensive research on tool wear monitoring (TWM) and obtained a series of remarkable research achievements. However, physics-based models have difficulty predicting tool wear accurately. Meanwhile, the diversity of actual machining environments further limits the application of physical models. Data-driven models can establish the deep mapping relationship between signals and tool wear, but they only fit trained data well. They still have difficulty adapting to complex machining conditions. In this paper, physics-based and data-driven TWM models are first reviewed in detail, including the factors that affect tool wear, typical data-based models, and methods for extracting and selecting features. Then, tracking research hotspots, emerging physics–data fusion models are systematically summarized.

show abstract

A Review of Physics-Based, Data-Driven, and Hybrid Models for Tool Wear Monitoring

Zhang,

Jiang,

Gao

et al. 2024

Machines

View full text Add to dashboard Cite

show abstract

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Generative and self‐supervised ensemble modeling for multivariate tool wear monitoring

Cited by 1 publication

References 60 publications

A Review of Physics-Based, Data-Driven, and Hybrid Models for Tool Wear Monitoring

A Review of Physics-Based, Data-Driven, and Hybrid Models for Tool Wear Monitoring

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