Thermal error modeling analysis of CNC machine tool based on optimized least squares support vector machine

Abstract

Abstract: The thermal error of CNC machine tools is one of the main factors that reduce the accuracy of the machining operation. For the establishment of the thermal error model, combined with the cuckoo algorithm random Levi flight mechanism, the least squares support vector machine structure risk minimization and linear programming advantages, a thermal error modeling method is proposed based on the least squares support vector machine which optimized by cuckoo algorithm. When the least squares support vector machine transforms the low-dimensional nonlinear problem into the high-dimensional linear problem, a hybrid kernel function is constructed, and the cuckoo algorithm is used. The penalty factor γ, the kernel width parameter σ and the mixed kernel weight λ of the least squares support vector machine is optimized by cuckoo algorithm. Taking the GMC2000A machine tool as the experimental object, clustering analysis and modeling analysis of the thermal error data are carried out. The prediction comparison analysis concluded that the error model established based on the cuckoo algorithm to optimize the hybrid kernel least squares support vector machine has achieved good prediction results, and is significantly better than the predictive effect of BP neural network model and the unoptimized least squares support vector machine model.

Key words: cuckoo algorithm, least squares support vector machine, thermal error, modeling, prediction

CLC Number:

TG659

LI You-tang, TANG Lei-wu, HUANG Hua, WU Rong-rong. Thermal error modeling analysis of CNC machine tool based on optimized least squares support vector machine[J]. Journal of Lanzhou University of Technology, 2022, 48(3): 35-41.

References

[1] RAMESH R,MANNAN M A,POO A N.Error compensation in machine tools-a review Part Ⅰ:geometric,cutting-force induced and fixture-dependent errors [J].International Journal of Machine Tools and Manufacture,2000,40(9):1235-1256.
[2] SUYKENS J A K,VANDEWALLE J.Least squares support vector machines [J].Neural Processing Letters,1999,9(1):293-300.
[3] 林伟青,傅建中,许亚洲,等.基于最小二乘支持向量机的数控机床热误差预测 [J].浙江大学学报(工学版),2008(6):905-908.
[4] 林伟青,傅建中,许亚洲,等.基于在线最小二乘支持向量机的数控机床热误差建模与补偿 [J].计算机集成制造系统,2008(2):295-299.
[5] 雷春丽,芮执元,刘军.数控机床电主轴热误差的预测方法 [J].兰州理工大学学报,2012,38(1):28-31.
[6] ABDULSHAHED A M,LONGSTAFF A P,FLETCHER S.The application of ANFIS prediction models for thermal error compensation on CNC machine tools [J].Applied Soft Computing,2015,27:158-168.
[7] ECHERFAOUI Y,OUAFI A E,CHEBAK A,et al.Laser interferometer based measurement for positioning error compensation in cartesian muti-axis system [J].Journal of Analytical Sciences,Methods and Instrumentation,2017,7(3):79-92.
[8] 马英芝.基于遗传模拟退火算法的LSSVM参数选取 [J].民营科技,2011(11):7-17.
[9] 李高强,张宇,李鸣.基于GA-LSSVM的数控机床热误差建模方法研究 [J].机床与液压,2021,49(2):26-30.
[10] 谢飞,王玲,谭峰,等.基于新陈代谢原理的机床热误差伪滞后建模 [J].哈尔滨工业大学学报,2019,51(7):154-159,170.
[11] 张腰,杨庆东.数控机床热误差预测的PSO-SVM模型 [J].北京信息科技大学学报(自然科学版),2020,35(2):100-103.
[12] 马卫,孙正兴.采用搜索趋化策略的布谷鸟全局优化算法 [J].电子学报,2015,43(12):2429-2439.
[13] 钟伟民.支持向量机在先进控制中的应用研究 [D].杭州:浙江大学,2006.
[14] BOUSHAKI S I,KLAMEL N,BENDJEGHABA O.A new quantum chaotic cuckoo search algorithm for data clustering [J].Expert Systems with Applications,2018,96:358-372.
[15] 王凡,贺兴时,王燕,等.基于CS算法的Markov模型及收敛性分析 [J].计算机工程,2012,38(11):180-182,185.
[16] 刘小览,赵英凯,陆金桂.数据挖掘中Fuzzy c-means的自适应聚类算法 [J].南京化工大学学报(自然科学版),2001(5):17-20,24.
[17] 杨柳.基于综合智能的数控机床热误差补偿研究 [D].成都:电子科技大学,2019.
[18] 李逢春,王海同,李铁民.重型数控机床热误差建模及预测方法的研究 [J].机械工程学报,2016,52(11):154-160.