Thermal error modeling and compensation of long-travel nanopositioning stage

被引:0
|
作者
机构
[1] Wang, Jingshu
[2] Zhu, Changan
[3] Feng, Mingchi
[4] Ren, Wenqi
来源
Wang, J. (donot@mail.ustc.edu.cn) | 1600年 / Springer London卷 / 65期
关键词
Thermally induced error of nanopositioning systems is rarely studied specifically because most researchers strictly limit the ambient temperature in order to ignore the influences of thermal deformation. However; the control cost of a narrow temperature range is too high for widely application. This paper is addressed at modeling and compensation of thermal error with the purpose of ensuring the positioning accuracy with an extended temperature range. The finite element analysis and contrast experiments with different temperature ranges reveal the significant impact of temperature variation on positioning precision. A polynomial model based on the genetic algorithm is implemented to describe the relationship between deviations and temperatures. By utilizing the parametric study; the optimal parameters of the genetic algorithm are determined. Based on the thermal model; a compensation system has been developed. A constant proportional-integral-derivative (PID) controller and a single-neuron PID controller are employed for compensation; respectively. The results demonstrate that the single-neuron PID controller can effectively restrain thermal error and guarantee the location accuracy with extended temperature range. The positioning precision of the positioning stage with compensation system and temperature range of 20 + 0.3 C is improved to 12 nm; while the one of the original system with temperature range of 20 ± 0.01 C is 31 nm. © 2012 Springer-Verlag London Limited;
D O I
暂无
中图分类号
学科分类号
摘要
Journal article (JA)
引用
收藏
页码:1 / 4
相关论文
共 50 条
  • [41] Thermal error modeling and compensation for a high-speed motorized spindle
    Yang, Jun
    Shi, Hu
    Feng, Bin
    Zhao, Liang
    Ma, Chi
    Mei, Xuesong
    INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2015, 77 (5-8): : 1005 - 1017
  • [42] A novel flexure-based vertical nanopositioning stage with large travel range
    Zhu, Xiaobo
    Xu, Xiao
    Wen, Zhijie
    Ren, Jiaqi
    Liu, Pinkuan
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2015, 86 (10):
  • [43] Clustering Regression Modeling for Gear Hobbing Machine Thermal Error Compensation
    Guo, Qianjian
    Qi, Xiaoni
    ADVANCES IN GRINDING AND ABRASIVE TECHNOLOGY XV, 2009, 416 : 401 - +
  • [44] Spindle unit thermal error modeling and compensation based on digital twin
    Liu, Jialan
    Ma, Chi
    Yuan, Qiang
    INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2024, 132 (3-4): : 1525 - 1555
  • [45] Thermal error modeling and compensation for a high-speed motorized spindle
    Jun Yang
    Hu Shi
    Bin Feng
    Liang Zhao
    Chi Ma
    Xuesong Mei
    The International Journal of Advanced Manufacturing Technology, 2015, 77 : 1005 - 1017
  • [46] Integrated geometric and thermal error modeling and compensation for vertical machining centers
    Li, Zihan
    Yang, Jianguo
    Fan, Kaiguo
    Zhang, Yi
    INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2015, 76 (5-8): : 1139 - 1150
  • [47] DYNAMIC ANALYSIS OF LONG-TRAVEL, HIGH-EFFICIENCY SHOCK ABSORBERS IN FREIGHT CARS
    FREUDENS.F
    MECHANICAL ENGINEERING, 1970, 92 (07) : 59 - &
  • [48] DYNAMIC ANALYSIS OF LONG-TRAVEL, HIGH-EFFICIENCY SHOCK ABSORBERS IN FREIGHT CARS
    FREUDENS.F
    JOURNAL OF ENGINEERING FOR INDUSTRY, 1970, 92 (03): : 581 - &
  • [49] Error Modeling and Compensation of Linear Motors Positioning Stage Based on RBF Network
    Lin, Jian
    Wang, Mulan
    MANUFACTURING ENGINEERING AND AUTOMATION I, PTS 1-3, 2011, 139-141 : 1744 - 1748
  • [50] Measurements with an atomic force microscope using a long travel nanopositioning and nanomeasuring machine
    Hofmann, N
    Hausotte, T
    Jager, G
    Manske, E
    2004 4TH IEEE CONFERENCE ON NANOTECHNOLOGY, 2004, : 183 - 185
12345