Roundness and positioning deviation prediction in single point incremental forming using deep learning approaches

This article proposes a deep learning technique for the prevision of the geometric accuracy in single point incremental forming. Moreover, predicting geometric accuracy is one of the most crucial measures of part quality. Accordingly, roundness and positioning deviation are two indicators for measur...

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Veröffentlicht in:Advances in mechanical engineering Jg. 11; H. 7; S. 168781401986446
Hauptverfasser: Akrichi, Sofien, Abbassi, Amira, Abid, Sabeur, Ben yahia, Noureddine
Format: Journal Article
Sprache:Englisch
Veröffentlicht: London, England SAGE Publications 01.07.2019
Sage Publications Ltd
SAGE Publishing
Schlagworte:
Accuracy
Artificial intelligence
Back propagation networks
Belief networks
Deep learning
Depth indicators
Deviation
Feed rate
Forming techniques
Geometric accuracy
Machine learning
Model accuracy
Neural networks
Performance prediction
Process parameters
Roundness
deep learning
stack autoencoder
supervised learning
Single point incremental forming
deep belief network
geometric tolerancing
unsupervised learning
ISSN:1687-8132, 1687-8140, 1687-8140
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Zusammenfassung:This article proposes a deep learning technique for the prevision of the geometric accuracy in single point incremental forming. Moreover, predicting geometric accuracy is one of the most crucial measures of part quality. Accordingly, roundness and positioning deviation are two indicators for measuring geometric accuracy and presenting two output variables. Two types of artificial intelligence learning approaches, that is, shallow learning and deep learning, are investigated and compared for forecasting geometrical accuracy in the single point incremental forming process. Therefore, the back-propagation neural network with one hidden layer is selected as the representative for shallow learning and deep belief network and stack autoencoder are chosen as the representatives for deep learning. Accurate prediction is closely related to the feature learning of single point incremental forming process parameters. The following six parameters were considered as input variables: sheet thickness, tool path direction, step depth, speed rate, feed rate, and wall angle. The results of these studies indicate that deep learning could be a powerful tool in the current search for geometric accuracy prediction in single point incremental forming. Otherwise, the deep learning approach shows the best performance prediction with shallow learning. In addition, the deep belief network model achieves superior performance accuracy for the prediction of roundness and position deviation in comparison with the stack autoencoder approach.
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ISSN:1687-8132
1687-8140
1687-8140
DOI:10.1177/1687814019864465