基于数据驱动的Al-Cu合金多目标性能模型预测OA
Data-driven multi-objective property model prediction in Al-Cu alloys
铸造铝合金因其优异的力学性能广泛应用于航空航天、汽车等领域,但传统合金设计面临成分空间庞大、试错实验成本高和成分与性能之间非线性关系难以预测的问题.本工作提出一种反向传播神经网络、主成分分析和遗传算法相结合的机器学习模型,用于铸造铝合金的多目标性能预测.该模型通过反向传播神经网络非线性映射建立合金成分与性能的关系、主成分分析降维、遗传算法优化网络参数,从而提升预测精度和训练效率.结果表明,优化后的模型均方误差、决定系数和平均绝对误差分别为 36.28、0.91和 2.44,在极限抗拉强度、屈服强度和断后伸长率的实验验证中,预测值与实验值控制在±5%误差范围内,具有较高预测精度,证明该模型具有高效性与可靠性.
Cast aluminum alloys are widely used in aerospace,automotive and other industries due to their excellent mechanical properties.However,traditional alloy design faces challenges such as vast composition space,high costs of trial-and-error experiments and difficulty in predicting the nonlinear relationship between composition and properties.This paper proposes a machine learning model that combines backpropagation neural networks,principal component analysis,and genetic algorithms for multi-objective property prediction of cast aluminum alloys.The model establishes the relationship between alloy composition and properties through the nonlinear mapping of backpropagation neural networks,reduces dimensionality via principal component analysis,and optimizes network parameters using genetic algorithms-thereby improving prediction accuracy and training efficiency.The results show that the optimized model has mean squared error of 36.28,correlation coefficient of 0.91,and mean absolute error of 2.44.In the experimental verification of ultimate strength,yield strength,and elongation after fracture,the error between experimental values and predicted values is controlled within the range of±5%.This high prediction accuracy demonstrates the efficiency and reliability of the proposed model.
廉红珍;陆春月
太原城市职业技术学院 机电工程系,太原 030027中北大学 机械工程学院,太原 030051
航空航天
铸造铝合金主成分分析反向传播神经网络遗传算法力学性能
cast aluminum alloyprincipal component analysisbackpropagation neural networkgenetic algorithmmechanical property
《航空材料学报》 2026 (3)
47-55,9
国家科技部创新方法专项(2020IM020700)
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