利用 ParaCRN-AMResNet 预测刀具磨损:混合深度学习方法

Machines Pub Date : 2024-05-15 DOI:10.3390/machines12050341
Lian Guo, Yongguo Wang
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摘要

在制造业,刀具磨损严重影响产品质量和生产效率。虽然传统的序列深度学习模型可以处理时间序列任务,但它们忽视了时间序列数据中复杂的时间关系,往往导致连续预测中的误差累积,从而降低了对刀具磨损的预测精度。为了解决这些局限性,我们引入了具有注意力调节残差学习的并行卷积和递归神经网络(ParaCRN-AMResNet)模型。与传统的深度学习模型相比,ParaCRN-AMResNet 通过其创新的并行架构,显著提高了从时间序列数据中提取特征的效率和精度。该模型巧妙地结合了扩张卷积神经网络和双向门控递归单元,有效地解决了距离依赖问题,丰富了特征提取的数量和维度。ParaCRN-AMResNet 的优势在于它能够捕捉时间序列数据的复杂动态,显著提高了模型的准确性和泛化能力。该模型的功效通过全面的铣削实验和振动信号分析得到了验证,展示了 ParaCRN-AMResNet 的卓越性能。在评估指标中,该模型的 MAE 为 2.6015,MSE 为 15.1921,R2 为 0.9897,MAPE 为 2.7997%,充分证明了其在精确预测刀具磨损方面的效率和准确性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Predicting Tool Wear with ParaCRN-AMResNet: A Hybrid Deep Learning Approach
In the manufacturing sector, tool wear substantially affects product quality and production efficiency. While traditional sequential deep learning models can handle time-series tasks, their neglect of complex temporal relationships in time-series data often leads to errors accumulating in continuous predictions, which reduces their forecasting accuracy for tool wear. For addressing these limitations, the parallel convolutional and recurrent neural networks with attention-modulated residual learning (ParaCRN-AMResNet) model is introduced. Compared with conventional deep learning models, ParaCRN-AMResNet markedly enhances the efficiency and precision of feature extraction from time-series data through its innovative parallel architecture. The model adeptly combines dilated convolution neural network and bidirectional gated recurrent units, effectively addressing distance dependencies and enriching the quantity and dimensions of extracted features. The strength of ParaCRN-AMResNet lies in its refined ability to capture the complex dynamics of time-series data, significantly boosting the model’s accuracy and generalization capability. The model’s efficacy was validated through comprehensive milling experiments and vibration signal analyses, showcasing ParaCRN-AMResNet’s superior performance. In evaluation metrics, the model achieved a MAE of 2.6015, MSE of 15.1921, R2 of 0.9897, and MAPE of 2.7997%, conclusively proving its efficiency and accuracy in the precise prediction of tool wear.
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