Self-training-based approach with improved XGBoost for aluminum alloy casting quality prediction

IF 9.1 1区计算机科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Robotics and Computer-integrated Manufacturing Pub Date : 2024-11-02 DOI:10.1016/j.rcim.2024.102890

Haonan Wang , Quanzhi Sun , Jun Wu , Xuxia Zhang , Weipeng Liu , Tao Peng , Renzhong Tang

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引用次数: 0

Abstract

The revolutionary advances in integrated components in current automotive industry have led to a sharply rising demand for aluminum alloy castings. Targeted quality inspection is thus proposed for components manufacturers to achieve high responsiveness and low operational cost. This suggests casting machine manufacturers to integrate advanced quality prediction functions into the next generation of intelligent casting machines. However, acquiring ample quality inspection data is essential for implementing such functions, which is often challenging, if not infeasible, due to practical issues such as data proprietorship or privacy. Self-training is a good candidate for dealing with scarce labeled data, and XGBoost is commonly used as the base classifier. However, misclassification of unlabeled data happens using XGBoost, which could lead to incorrect pseudo-label assignments, eventually resulting in higher misclassification rate. To address this challenge, a self-training and improved XGBoost-based aluminum alloy casting quality prediction approach is proposed. This approach integrates the classification loss of unlabeled data in the objective function as a new regularization term and considers first and second partial derivatives of the classification loss function for unlabeled data in the leaf node's weight score. The proposed approach penalizes those classification models that misclassify unlabeled data, thereby improves quality prediction performance. To evaluate the effectiveness of our approach, a casting machine manufacturer was collaborated to conduct a case study. The results on three-type casting quality prediction demonstrate that our approach could achieve an accuracy, precision, recall and F1 score of 93.2 %, 90 %, 64.2 %, and 0.75, respectively, outperforming all compared approaches. The approach supports casting machine manufacturers to pre-train a casting quality prediction models with scarce labeled data, enabling swift deployment and customization for targeted quality inspection.

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基于自训练和改进 XGBoost 的铝合金铸件质量预测方法

当前，汽车工业中集成组件的革命性进步导致对铝合金铸件的需求急剧上升。因此，为了实现高响应速度和低运营成本，零部件制造商需要进行有针对性的质量检测。这建议铸造机制造商在下一代智能铸造机中集成先进的质量预测功能。然而，要实现这些功能，获取充足的质量检测数据是必不可少的，但由于数据所有权或隐私等实际问题，这往往具有挑战性，甚至是不可行的。自我训练是处理稀缺标记数据的好方法，XGBoost 通常被用作基本分类器。然而，使用 XGBoost 时会出现对未标记数据的误分类，这可能会导致错误的伪标签分配，最终导致更高的误分类率。为了应对这一挑战，我们提出了一种基于 XGBoost 的自训练改进型铝合金铸件质量预测方法。该方法将目标函数中未标注数据的分类损失作为一个新的正则项，并在叶节点的权重得分中考虑未标注数据的分类损失函数的一阶和二阶偏导数。所提出的方法可以惩罚那些对未标注数据进行错误分类的分类模型，从而提高质量预测性能。为了评估我们方法的有效性，我们与一家铸造机制造商合作进行了案例研究。三类铸件质量预测结果表明，我们的方法在准确度、精确度、召回率和 F1 分数上分别达到了 93.2%、90%、64.2% 和 0.75，优于所有比较方法。该方法支持铸造机制造商利用稀缺的标注数据预先训练铸造质量预测模型，从而实现快速部署和定制目标质量检测。

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来源期刊

Robotics and Computer-integrated Manufacturing 工程技术-工程：制造

CiteScore

24.10

自引率

13.50%

发文量

160

审稿时长

50 days

期刊介绍： The journal, Robotics and Computer-Integrated Manufacturing, focuses on sharing research applications that contribute to the development of new or enhanced robotics, manufacturing technologies, and innovative manufacturing strategies that are relevant to industry. Papers that combine theory and experimental validation are preferred, while review papers on current robotics and manufacturing issues are also considered. However, papers on traditional machining processes, modeling and simulation, supply chain management, and resource optimization are generally not within the scope of the journal, as there are more appropriate journals for these topics. Similarly, papers that are overly theoretical or mathematical will be directed to other suitable journals. The journal welcomes original papers in areas such as industrial robotics, human-robot collaboration in manufacturing, cloud-based manufacturing, cyber-physical production systems, big data analytics in manufacturing, smart mechatronics, machine learning, adaptive and sustainable manufacturing, and other fields involving unique manufacturing technologies.