Neural network based multi-objective active vibration optimization method for shell structure

被引：0

作者：

Zhang X. ^{[1
,2
]}

Liu J. ^{[1
,2
]}

Chen X. ^{[1
,2
]}

Cao H. ^{[1
,2
]}

机构：

[1] School of Mechanical Engineering, Xi'an Jiaotong University, Xi'an

[2] State Key Laboratory for Manufacturing System Engineering, Xi'an Jiaotong University, Xi'an

来源：

Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2016年 / 52卷 / 09期

关键词：

Frequency characteristic; Hybrid error criterion; Multi-objective; Neural network; Vibration optimization;

D O I：

10.3901/JME.2016.09.056

中图分类号：

学科分类号：

摘要：

Active control method mainly focuses on vibration and noise suspension at present thus can't satisfy the requirement of frequency characteristics control. Therefore, based on the multi-objective parallel processing ability of neural network, the multi-objective vibration optimization method is proposed to deal with this problem. First, the frequency-domain control frame is constructed based on neural network algorithm. Compared with traditional time-domain methods, the proposed control frame just require once FFT in each iteration and no IFFT needed, so the control efficiency can be guaranteed. Second, hybrid error criterion is constructed by combining global frequency error and frequency node error together to improve the adaptability, reliability and anti-interference ability. Third, the controllability problem of the multi-objective method in implementation is studied through mathematical analysis. At last, the effectiveness of the proposed multi-objective method is verified through vibration optimization on eight points of shell structure. © 2016 Journal of Mechanical Engineering.

引用

页码：56 / 64

页数：8

共 18 条

[1] Kwak M.K., Lee J.H., Yang D.H., Et al., Hardware-in-the-loop simulation experiment for semi-active vibration control of lateral vibrations of railway vehicle by magneto-rheological fluid damper, Vehicle System Dynamics, 52, 7, pp. 891-908, (2014)
[2] Zhang H., Wu Y., He D., Et al., Model predictive control to mitigate chatters in milling process with input constraints, International Journal of Machine Tools & Manufacture, 91, pp. 54-61, (2015)
[3] Yang T., Li X., Zhu M., Et al., Experimental investigation of active vibration control for diesel engine generators in marine applications, Journal of Vibration Engineering, 26, 2, pp. 160-168, (2013)
[4] Leug P., Process of silencing sound oscillations
[5] Silva A.C., Landau I.D., Airimitoaie T.B., Direct adaptive rejection of unknown time-varying narrow band disturbances applied to a benchmark problem, European Journal of Control, 19, 4, pp. 326-336, (2013)
[6] Li P., Zhang Z., Hua H., Theoretical analysis and experiment on active vibration control of a shaft-hull system, Journal of Mechanical Engineering, 48, 19, pp. 103-108, (2012)
[7] Lu Y., Gu Z., Ling A., Et al., Flight test of active control of structure response for helicopter, Journal of Vibration Engineering, 25, 1, pp. 24-29, (2012)
[8] Nguyen S.D., Nguyen Q.H., Choi S.B., Hybrid clustering based fuzzy structure for vibration control-part 1: A novel algorithm for building neuro-fuzzy system, Mechanical System and Signal Processing, 50-51, pp. 510-525, (2015)
[9] Nguyen S.D., Nguyen Q.H., Choi S.B., A hybrid clustering based fuzzy structure for vibration control-part 2: An application to semi-active vehicle seat-suspension system, Mechanical System and Signal Processing, 56-57, pp. 288-301, (2015)
[10] Tang E., Fang J., Zheng S., Vibration control and experimental study of flexible rotor in magnetically suspended motor, Journal of Mechanical Engineering, 51, 1, pp. 106-116, (2015)

← 1 2 →