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一种可变长度光电基准尺

吴斌 王晓蕾

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文章导航 > 激光技术  > 2016 >  40(5): 734-737
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一种可变长度光电基准尺

  • 1.

    天津大学 精密测试技术及仪器国家重点实验室, 天津 300072

    • 作者简介: 吴斌(1975-),男,副教授,硕士生导师,主要研究方向为工业视觉检测、大尺寸数字化测量及图像处理技术等。E-mail:wubin@tju.edu.cn.

  • 中图分类号: TN29

A variable-length photoelectric reference scale

  • 1.

    State Key Laboratory of Precision Measuring Technology and Instrument, Tianjin University, Tianjin 300072, China

  • CLC number: TN29

  • 摘要: 为了实现对非正交轴系激光经纬仪测量系统的快速、准确定向,采用构建新型光电基准尺的方法,提出并研究了一种基于高精度光电位置敏感器件的可变长度光电基准尺构建技术。阐述了非正交轴系激光经纬仪的特点,根据其特点及非正交轴系激光经纬仪测量系统定向的需要,确定了可变长度光电基准尺构建的总体思路,完成了硬件电路设计,构建了可变长度光电基准尺,并标定了两光电位置敏感探测器的空间位姿关系,以实现可变长度基准测量。结果表明,利用该可变长度光电基准尺定向后的测量系统,其相对测量精度优于0.03%,可方便、高精度地实现非正交轴系激光经纬仪测量系统的定向。
    Abstract: In order to orientate a non-orthogonal shafting laser theodolite measurement system quickly and accurately, a construction technology of variable-length photoelectric reference scale was proposed based on high-precision photoelectric position sensitive detector . Firstly, the feature of a non-orthogonal shafting laser theodolite was elaborated. According to the features and the orientation requirement of a non-orthogonal shafting laser theodolite measurement system, the general idea of the construction of variable-length photoelectric reference scale was confirmed. After that, the design of hardware circuit was finished and a variable-length photoelectric reference scale was constructed. Finally, spatial position relationship between two photoelectric position sensitive detectors was calibrated to realize the measurement of variable-length reference. The experiment results show that the relative measurement accuracy of variable-length photoelectric reference scale is better than 0.03%. The orientation of a non-orthogonal shafting laser theodolite measurement system can be realized conveniently and in high-precision.
  • [1]

    ZHANG Z L,ZHU J G,GENG N,et al.The design of double-theodolite 3-D coordinate measurement system[J].Chinese Journal of Sensors and Actuators,2010,23(5):660-664(in Chinese).
    [2]

    PEGGS G N,MAROPOULOS P G,HUGHES E B,et al.Recent developments in large-scale dimensional metrology[J].Proceedings of the Institution of Mechanical Engineers,2009,B223(6):571-595.
    [3]

    CUYPERS W,van GESTEL N,VOET A,et al.Optical measurement techniques for mobile and large-scale dimensional metrology[J].Optics and Lasers in Engineering,2009,47(3):292-300.
    [4]

    MAUTZ R.Overview of current indoor positioning systems[J].Geodesy and Cartography,2009,35(1):18-22.
    [5]

    HOPE C,CHUAQUI M.Geotechnical instrumentation news-manual total station monitoring[J].Geotechnical News,2008,26(3):28.
    [6]

    WU B,WANG B.Automatic measurement in large-scale space with the laser theodolite and vision guiding technology[J].Advances in Mechanical Engineering,2013,2013(5):629385.
    [7]

    WU B,SU X Y.A precise guiding method for automatic measurement with visual guiding theodolites[J].Laser Technology,2015,39(4):453-457(in Chinese).
    [8]

    LI G Y.Principle and development trend of non-orthogonal coordinate system[J].Journal of Geomatics,2003,28(1):4-10(in Chinese).
    [9]

    HUANG G Y,LI G Y.Study of system orientation and coordinate calculation of IMS[J].Acta Geodaetica Et Cartocgraphica Sinica,2003,32(3):256-260(in Chinese).
    [10]

    WU B,YANG S.Research on measurement technology of non-orthogonal shaft laser theodolites[J].Laser Technology,2015,39(5):603-609(in Chinese).
    [11]

    GENG N.Study on the calibration method of theodolite coordinate measurement and system implementation[D].Tianjin:Tianjin University of Instrument Science and Technology,2010:13-20(in Chinese).
    [12]

    FAN Zh G,ZHANG F Sh,ZUO B J,et al.Effect of noise ray on properties of position sensitive detector[J].Laser Technology,2004,28(4):442-444(in Chinese).
    [13]

    KOMATSU M,OHKAWA K,TSUCHIDA N,et al.Hole position and inclination sensor with 2 dimensional PSD,and its application to automatic shaft inserting[C]//International Conference on Multisensor and Integration for Intelligent Systems.New York,USA:IEEE,1996:78-85.
    [14]

    SONG D Y.Research and application on technology of precise PSD micro-displacement online measurement[D].Tianjin:Tianjin University of Photoelectron Technology,2012:21-24(in Chinese).
    [15]

    FU J,CHU W,DIXSON R,et al.Three-dimensional image correction of tilted samples through coordinate transformation[J].Scanning,2008,30(1):41-46.
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出版历程
  • 收稿日期:  2015-07-10
  • 录用日期:  2015-09-02
  • 刊出日期:  2016-09-25

一种可变长度光电基准尺

    作者简介: 吴斌(1975-),男,副教授,硕士生导师,主要研究方向为工业视觉检测、大尺寸数字化测量及图像处理技术等。E-mail:wubin@tju.edu.cn
  • 1. 天津大学 精密测试技术及仪器国家重点实验室, 天津 300072
  • 收稿日期: 2015-07-10
  • 录用日期: 2015-09-02
  • 网络出版日期: 2016-09-25

摘要: 为了实现对非正交轴系激光经纬仪测量系统的快速、准确定向,采用构建新型光电基准尺的方法,提出并研究了一种基于高精度光电位置敏感器件的可变长度光电基准尺构建技术。阐述了非正交轴系激光经纬仪的特点,根据其特点及非正交轴系激光经纬仪测量系统定向的需要,确定了可变长度光电基准尺构建的总体思路,完成了硬件电路设计,构建了可变长度光电基准尺,并标定了两光电位置敏感探测器的空间位姿关系,以实现可变长度基准测量。结果表明,利用该可变长度光电基准尺定向后的测量系统,其相对测量精度优于0.03%,可方便、高精度地实现非正交轴系激光经纬仪测量系统的定向。

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