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浙江大学学报(工学版)
浙江大学学报(工学版)  2020, Vol. 54 Issue (1): 40-47    DOI: 10.3785/j.issn.1008-973X.2020.01.005
机械工程     
基于GA-WPT-ELM的6061铝合金表面粗糙度预测
谭芳芳1(),朱俊江1,严天宏1,*(),高志强2,何岭松2
1. 中国计量大学 机电工程学院,浙江 杭州 310018
2. 华中科技大学 机械科学与工程学院,湖北 武汉 430074
Surface roughness prediction of 6061 aluminum alloy based on GA-WPT-ELM
Fang-fang TAN1(),Jun-jiang ZHU1,Tian-hong YAN1,*(),Zhi-qiang GAO2,Ling-song HE2
1. College of Mechanical and Electronic Engineering, China Jiliang University, Hangzhou 310018, China
2. School of Mechanical Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, China
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摘要:

为了提高工件表面粗糙度预测的准确性,针对振动信号特征识别和表面粗糙度预测建模时多个参数难以同步优化和人工经验调优误差较大的问题,提出基于遗传算法(GA)的信号特征识别和表面粗糙度预测的优化算法. 对采集的6061铝合金铣削振动信号进行小波包变换(WPT)和多个特征提取,利用GA优化WPT母小波和特征向量;将信号特征向量和表面粗糙度分别作为极限学习机(ELM)的输入和输出,对预测模型训练的同时,利用GA优化ELM隐含层的神经元个数;对训练好的预测模型进行测试. 实验结果表明,通过GA对振动信号识别和表面粗糙度预测的3类参数同步优化,获得了最佳的信号特征和较高的表面粗糙度预测精度,节省了建模分析计算成本.
关键词: 在线振动信号遗传算法(GA)小波包变换极限学习机(ELM)表面粗糙度预测    
Abstract:

The problem of multi-parameter simultaneous optimization and large error of empirical tuning should be solved in the vibration signal feature recognition and surface roughness prediction processes in order to improve the on-line prediction accuracy of workpiece surface roughness. The optimization method of signal feature recognition and surface roughness prediction modeling was proposed based on genetic algorithm (GA). GA was used to choose mother wavelet and feature quantities when signal features of milling 6061 aluminum alloy was recognized based on wavelet packet transform (WPT). The number of neurons in hidden layer was selected by GA when signal features and surface roughness were used to train extreme learning machine (ELM). The prediction modeling which has been trained was tested. The experimental results show that the three types of parameters for signal recognition and surface roughness prediction were simultaneously optimized by GA. GA-WPT-ELM not only obtains the best features of signal and the higher prediction accuracy of surface roughness, but also reduces analytical-computational cost in the modeling processes.
Key words: on-line vibration signal    genetic algorithm (GA)    wavelet packet transform    extreme learning machine (ELM)    surface roughness predicting
收稿日期: 2018-12-03 出版日期: 2020-01-05
CLC:  TP 18  
基金资助: 国家自然科学基金资助项目(61801454,51379198,51075377);浙江省自然科学基金资助项目(LQ18F010006)
通讯作者: 严天宏     E-mail: tff097443@yeah.net;thyan@163.com
作者简介: 谭芳芳(1993—),女,硕士生,从事信号处理的研究. orcid.org/0000-0003-2728-9476. E-mail: tff097443@yeah.net
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引用本文:

谭芳芳,朱俊江,严天宏,高志强,何岭松. 基于GA-WPT-ELM的6061铝合金表面粗糙度预测[J]. 浙江大学学报(工学版), 2020, 54(1): 40-47.

Fang-fang TAN,Jun-jiang ZHU,Tian-hong YAN,Zhi-qiang GAO,Ling-song HE. Surface roughness prediction of 6061 aluminum alloy based on GA-WPT-ELM. Journal of ZheJiang University (Engineering Science), 2020, 54(1): 40-47.

链接本文:

http://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2020.01.005        http://www.zjujournals.com/eng/CN/Y2020/V54/I1/40

图 1  小波包分解结构图
图 2  极限学习机网络结构图
图 3  GA优化特征提取和预测模型的流程图
图 4  铣削振动信号采集与分析系统
n/(103 r·min?1 f/(103 mm·min?1 d/mm
6 1 1.0
9 1.65 0.7
12 2.3 0.5
15 3 0.3
18
表 1  铣削加工参数
图 5  主轴铣削实验及传感器测量
类型 族系 Ψ
正交 Daubechies db2,db3,db4,db5,db6,db7,db8,db9,
db10,db11,db12,db13,db14
正交 Haar Haar
正交 Coiflets coif1,coif2,coif3,coif4,coif5
正交 Symmlets sym2,sym3,sym4,sym5,sym6,sym7, sym8
双正交 Biorthogonal bior1.3,bior1.5,bior2.2,bior2.4,bior2.6,
bior2.8,bior3.1,bior3.3,bior3.5,bior3.7,
bior3.9,bior4.4,bior5.5,bior6.8
表 2  小波包分解的母小波类型
特征 v 特征 v
均值 $J_{_{Gj}}^{{\lambda ^i}}$ 偏态 $P_{_{Gj}}^{{\lambda ^i}}$
标准差 $B_{_{Gj}}^{{\lambda ^i}}$ 峰态 $F_{_{Gj}}^{{\lambda ^i}}$
峰峰值 ${\rm{FF}}_{_{Gj}}^{{\lambda ^i}}$ 能量熵 $H_{_{Gj}}^{{\lambda ^i}}$
表 3  振动信号的统计特征量
图 6  母小波优化选取结果
图 7  bior5.5的尺度函数和小波函数
振动信号组别 Ψ v l σ/%
Gx bior5.5 $H_{G_{x}}^{\rm{DAAAA}}$ 76 88.95
Gx db8 $H_{G_{x}}^{\rm{DAAA}}$ 62 83.46
Gx Haar $P_{G_{x}}^{\rm{DAD}}$ 49 80.53
Gx coif3 $F_{G_{x}}^{\rm{DADAA}}$ 96 80.22
Gy db14 $H_{G_{y}}^{\rm{ADA}}$ 86 83.82
Gy db5 $H_{G_{y}}^{\rm{ADAA}}$ 64 82.22
Gy bior1.5 $H_{G_{y}}^{\rm{AAADA}}$ 31 81.24
Gz db6 $H_{G_{z}}^{\rm{AADAD}}$ 26 80.69
Gz sym6 $H_{G_{z}}^{\rm{DADA}}$ 38 82.92
表 4  GA优化算法训练结果
图 8  GA优化曲线及个体选择
图 9  表面粗糙度拟合曲线
组序号 n/(103
r·min?1		 f/(103
mm·min?1		 d/
mm 		$ \hat R_{\rm{a}} $/μm Ra/μm Δe/
μm
1 18 1.65 0.3 0.122 8 0.137 1 0.014 4
2 12 1.65 0.3 0.146 3 0.176 9 0.030 7
3 15 2.3 0.3 0.173 0 0.132 4 ?0.040 6
4 6 1 1.0 0.187 5 0.206 5 0.019 0
5 12 2.3 1.0 0.216 5 0.242 2 0.025 7
6 15 3 1.0 0.262 5 0.242 2 ?0.020 3
7 9 2.3 0.5 0.350 5 0.419 8 0.069 3
8 12 3 0.3 0.356 3 0.367 6 0.011 4
9 9 2.3 0.7 0.396 8 0.347 3 ?0.049 5
10 6 1.65 0.5 0.506 5 0.496 5 ?0.010 0
11 9 3 1.0 0.624 0 0.629 7 0.005 7
12 9 3 0.5 0.694 3 0.700 2 0.005 9
13 6 2.3 1.0 0.772 3 0.770 0 ?0.002 2
14 6 2.3 0.5 0.849 3 0.837 5 ?0.011 8
15 6 3 0.5 0.967 3 0.977 9 0.010 6
表 5  表面粗糙度预测结果
比较对象 信号源 样本数 方法 v σ/%
本文研究 振动信号 960 GA-WPT $H_{G_{x}}^{\rm{DAAAA}}$ 88.95
文献[14] 振动信号 360 SSA $a_y^{{\lambda _i}}$ 85.4
文献[13] 振动信号 20 TDA ax, v,f,d 80.0
文献[15] 切削力信号 360 G-WPT $X_{{F_X}}^{\rm{AAAA}}$ 88.1
表 6  不同研究方法的表面粗糙度预测结果对比
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