粒子群优化
人工神经网络
惯性
天然橡胶
材料科学
模数
生物系统
趋同(经济学)
收敛速度
人工智能
结构工程
计算机科学
复合材料
算法
工程类
计算机网络
频道(广播)
物理
经典力学
经济
生物
经济增长
作者
Zengrui Yuan,Mu‐Qing Niu,Hongtu Ma,Tao Gao,Jian Zang,Yewei Zhang,Li‐Qun Chen
标识
DOI:10.1016/j.ijmecsci.2023.108265
摘要
Rubber is considered as a new material for making landing gear shock absorbers for new energy electric aircraft. This investigation tested nitrile butadiene rubber blocks with different hardness at different loading rates to determine their stress-strain relationships. The mechanical behaviors of rubbers are predicted via an artificial neural network model for the first time. A self-adjusting particle swarm optimization was proposed to optimize the artificial neural network's weights and thresholds with the inertia factors and learning factors automatically adjusted. The number of neurons was optimized. The results revealed that the Young's modulus of the rubber increases with the increasing strain. With larger hardness and a larger strain rate, both the Young's modulus and its increasing rate become larger. The proposed self-adjusting particle swarm optimization improves the accuracy and the convergence speed. With the optimal number of neurons, the proposed artificial neural network has a mean square error of 1.611 × 10−4 in predicting the stress-strain relationships of the rubber. Compared with traditional artificial neural network models and an artificial neural network optimized by a traditional particle swarm optimization, the proposed model increases the accuracy by 56.5% and 26.5%, respectively. It is an initial attempt to account the coupling effect of the hardness and the strain rate in the rubber constitutive model.
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