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A Hybrid Deep Learning Framework for Fault Diagnosis in Milling Machines

Muhammad Siddique, Wasim Zaman, Muhammad Umar, Jae‐Young Kim, Jong-Myon Kim, Jong-Myon Kim, Jong-Myon Kim

2025Sensors25 citationsDOIOpen Access PDF

Abstract

This paper presents a hybrid fault-diagnosis framework for milling cutting tools designed to address three persistent challenges in industrial monitoring: noisy vibration signals, limited fault labels, and variability across operating conditions. The framework begins by removing baseline drift from raw signals to improve the signal-to-noise ratio. Logarithmic continuous wavelet scalograms are then constructed to provide precise time-frequency localization and reveal fault-related harmonics. To enhance feature clarity, a Canny edge operator is applied, suppressing minor artifacts and reducing intra-class variation so that key diagnostic structures are emphasized. Feature representation is obtained through a dual-branch encoder, where one pathway captures localized patterns while the other preserves long-range dependencies, resulting in compact and discriminative fault descriptors. These descriptors are integrated by an ensemble decision mechanism that assigns validation-guided weights to individual learners, ensuring reliable fault identification, improved robustness under noise, and stable performance across diverse operating conditions. Experimental validation on real-world cutting tool data demonstrates an accuracy of 99.78%, strong resilience to environmental noise, and consistent diagnostic performance under variable conditions. The framework remains lightweight, scalable, and readily deployable, providing a practical solution for high-precision tool fault diagnosis in data-constrained industrial environments.

Topics & Concepts

Discriminative modelRobustness (evolution)Artificial intelligenceComputer scienceWaveletFault (geology)Pattern recognition (psychology)Feature (linguistics)EngineeringFeature extractionFault detection and isolationRepresentation (politics)Enhanced Data Rates for GSM EvolutionData miningMachine learningFeature learningDeep learningWavelet transformArtificial neural networkOperator (biology)Feature selectionKey (lock)Variable (mathematics)Control engineeringTroubleshootingAdvanced machining processes and optimizationIndustrial Vision Systems and Defect DetectionWelding Techniques and Residual Stresses
A Hybrid Deep Learning Framework for Fault Diagnosis in Milling Machines | Litcius