Noise robust classification of carbide tool wear in machining mild steel using texture extraction based transfer learning approach for predictive maintenance

Ravi Sekhar; Sharnil Pandya; Pritesh Shah; Hemant Ghayvat; Deepak Sharma; Matthias Renz; Deep Shah; Adeeth Jagdale; Devansh Hukmani; Santosh Saxena; Neeraj Kumar

doi:10.1016/j.rico.2024.100491

Noise robust classification of carbide tool wear in machining mild steel using texture extraction based transfer learning approach for predictive maintenance

Ravi Sekhar, Sharnil Pandya, Pritesh Shah^*, Hemant Ghayvat, Deepak Sharma, Matthias Renz, Deep Shah, Adeeth Jagdale, Devansh Hukmani, Santosh Saxena, Neeraj Kumar

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

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Abstract

Acoustics based smart condition monitoring is a viable alternative to mechanical vibrations or image-capture based predictive maintenance methods. In this study, a texture analysis based transfer learning methodology was applied to classify tool wear based on the noise generated during mild steel machining. The machining acoustics were converted to spectrogram images and transfer learning was applied for their classification into high/medium/low tool wear using four pre-trained deep learning models (SqueezeNet, ResNet50, InceptionV3, GoogLeNet). Moreover, three optimizers (RMSPROP, ADAM, SGDM) were applied to each of the deep learning models to enhance classification accuracies. Primary results indicate that the InceptionV3-RMSPROP obtained the highest testing accuracy of 87.50%, followed by the SqueezeNet-RMSPROP and ResNet50-SGDM at 75.00% and 62.50% respectively. However, SqueezeNet-RMSPROP was determined to be more desirable from a practical machining quality and safety perspective, owing to its greater recall value for the highest tool wear class. The proposed acoustics-texture extraction-transfer learning approach is especially suitable for cost effective tool wear condition monitoring involving limited datasets.

Original language	English
Article number	100491
Number of pages	26
Journal	Results in Control and Optimization
Volume	17
Early online date	19 Nov 2024
DOIs	https://doi.org/10.1016/j.rico.2024.100491
Publication status	Published - 1 Dec 2024
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

Keywords

Acoustics
Deep learning
Predictive maintenance
Smart manufacturing
Sound classification
Texture extraction
Tool condition monitoring
Transfer learning

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10.1016/j.rico.2024.100491Licence: CC BY-NC-ND

1-s2.0-S2666720724001218-mainFinal published version, 3.6 MBLicence: CC BY-NC-ND

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Sekhar, R., Pandya, S., Shah, P., Ghayvat, H., Sharma, D., Renz, M., Shah, D., Jagdale, A., Hukmani, D., Saxena, S., & Kumar, N. (2024). Noise robust classification of carbide tool wear in machining mild steel using texture extraction based transfer learning approach for predictive maintenance. Results in Control and Optimization, 17, Article 100491. https://doi.org/10.1016/j.rico.2024.100491

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title = "Noise robust classification of carbide tool wear in machining mild steel using texture extraction based transfer learning approach for predictive maintenance",

abstract = "Acoustics based smart condition monitoring is a viable alternative to mechanical vibrations or image-capture based predictive maintenance methods. In this study, a texture analysis based transfer learning methodology was applied to classify tool wear based on the noise generated during mild steel machining. The machining acoustics were converted to spectrogram images and transfer learning was applied for their classification into high/medium/low tool wear using four pre-trained deep learning models (SqueezeNet, ResNet50, InceptionV3, GoogLeNet). Moreover, three optimizers (RMSPROP, ADAM, SGDM) were applied to each of the deep learning models to enhance classification accuracies. Primary results indicate that the InceptionV3-RMSPROP obtained the highest testing accuracy of 87.50\%, followed by the SqueezeNet-RMSPROP and ResNet50-SGDM at 75.00\% and 62.50\% respectively. However, SqueezeNet-RMSPROP was determined to be more desirable from a practical machining quality and safety perspective, owing to its greater recall value for the highest tool wear class. The proposed acoustics-texture extraction-transfer learning approach is especially suitable for cost effective tool wear condition monitoring involving limited datasets.",

keywords = "Acoustics, Deep learning, Predictive maintenance, Smart manufacturing, Sound classification, Texture extraction, Tool condition monitoring, Transfer learning",

author = "Ravi Sekhar and Sharnil Pandya and Pritesh Shah and Hemant Ghayvat and Deepak Sharma and Matthias Renz and Deep Shah and Adeeth Jagdale and Devansh Hukmani and Santosh Saxena and Neeraj Kumar",

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Sekhar, R, Pandya, S, Shah, P, Ghayvat, H, Sharma, D, Renz, M, Shah, D, Jagdale, A, Hukmani, D, Saxena, S & Kumar, N 2024, 'Noise robust classification of carbide tool wear in machining mild steel using texture extraction based transfer learning approach for predictive maintenance', Results in Control and Optimization, vol. 17, 100491. https://doi.org/10.1016/j.rico.2024.100491

TY - JOUR

T1 - Noise robust classification of carbide tool wear in machining mild steel using texture extraction based transfer learning approach for predictive maintenance

AU - Sekhar, Ravi

AU - Pandya, Sharnil

AU - Shah, Pritesh

AU - Ghayvat, Hemant

AU - Sharma, Deepak

AU - Renz, Matthias

AU - Shah, Deep

AU - Jagdale, Adeeth

AU - Hukmani, Devansh

AU - Saxena, Santosh

AU - Kumar, Neeraj

PY - 2024/12/1

Y1 - 2024/12/1

N2 - Acoustics based smart condition monitoring is a viable alternative to mechanical vibrations or image-capture based predictive maintenance methods. In this study, a texture analysis based transfer learning methodology was applied to classify tool wear based on the noise generated during mild steel machining. The machining acoustics were converted to spectrogram images and transfer learning was applied for their classification into high/medium/low tool wear using four pre-trained deep learning models (SqueezeNet, ResNet50, InceptionV3, GoogLeNet). Moreover, three optimizers (RMSPROP, ADAM, SGDM) were applied to each of the deep learning models to enhance classification accuracies. Primary results indicate that the InceptionV3-RMSPROP obtained the highest testing accuracy of 87.50%, followed by the SqueezeNet-RMSPROP and ResNet50-SGDM at 75.00% and 62.50% respectively. However, SqueezeNet-RMSPROP was determined to be more desirable from a practical machining quality and safety perspective, owing to its greater recall value for the highest tool wear class. The proposed acoustics-texture extraction-transfer learning approach is especially suitable for cost effective tool wear condition monitoring involving limited datasets.

AB - Acoustics based smart condition monitoring is a viable alternative to mechanical vibrations or image-capture based predictive maintenance methods. In this study, a texture analysis based transfer learning methodology was applied to classify tool wear based on the noise generated during mild steel machining. The machining acoustics were converted to spectrogram images and transfer learning was applied for their classification into high/medium/low tool wear using four pre-trained deep learning models (SqueezeNet, ResNet50, InceptionV3, GoogLeNet). Moreover, three optimizers (RMSPROP, ADAM, SGDM) were applied to each of the deep learning models to enhance classification accuracies. Primary results indicate that the InceptionV3-RMSPROP obtained the highest testing accuracy of 87.50%, followed by the SqueezeNet-RMSPROP and ResNet50-SGDM at 75.00% and 62.50% respectively. However, SqueezeNet-RMSPROP was determined to be more desirable from a practical machining quality and safety perspective, owing to its greater recall value for the highest tool wear class. The proposed acoustics-texture extraction-transfer learning approach is especially suitable for cost effective tool wear condition monitoring involving limited datasets.

KW - Acoustics

KW - Deep learning

KW - Predictive maintenance

KW - Smart manufacturing

KW - Sound classification

KW - Texture extraction

KW - Tool condition monitoring

KW - Transfer learning

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DO - 10.1016/j.rico.2024.100491

M3 - Article

AN - SCOPUS:85209385038

SN - 2666-7207

VL - 17

JO - Results in Control and Optimization

JF - Results in Control and Optimization

M1 - 100491

ER -

Noise robust classification of carbide tool wear in machining mild steel using texture extraction based transfer learning approach for predictive maintenance

Abstract

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Keywords

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