Uncertainty analysis and evaluation of measurement of the positioning repeatability for industrial robots

Purpose This paper aims to solve the nonlinear problem in the uncertainty evaluation of the measurement of the positioning repeatability (RP) of industrial robots and provide guidance to restrict the uncertainty of measurement of RP (uRP). Design/methodology/approach Firstly, some uncertain sources existing in the measurement procedure of RP are identified. Secondly, the probability distribution function (PDF) of every source is established on the basis of its measurements. Some spatial combined normal distributions are adopted. Then, a method, based on Monte Carlo method (MCM) and established measurement model, is developed for the estimation of uRP. Thirdly, some tests are developed for the identification and validation of the selected PDFs of uncertain sources. Afterwards, the proposed method is applied for the evaluation and validation of the uRP. Finally, influence analyses of some key factors are proposed for the quantification of their relative contributions to uRP. Findings Results show that the proposed method can reasonably and objectively estimate the uRP of the selected industrial robot, and changes of the industrial robots’ position and the laser trackers measurement are correlated. Additionally, the uRP of the selected industrial robot can be restricted by using the results of its key factors on uRP. Originality/value This paper proposes the spatial combined normal distribution to model the uncertainty of the repeatability of the laser tracker and industrial robot. Meanwhile, the proposed method and influence analyses can be used in estimating and restricting the uRP and thus useful in determining whether the RP of a tested industrial robot meets its requirements.

[1]  Chen-Gang,et al.  Review on kinematics calibration technology of serial robots , 2014 .

[2]  A. Maritan,et al.  Applications of the principle of maximum entropy: from physics to ecology , 2010, Journal of physics. Condensed matter : an Institute of Physics journal.

[3]  Lining Sun,et al.  A distance error based industrial robot kinematic calibration method , 2014, Ind. Robot.

[4]  Tomasz Trzepieciński,et al.  The repeatability positioning analysis of the industrial robot arm , 2014 .

[5]  T Bajd,et al.  Comparison of position repeatability of a human operator and an industrial manipulating robot. , 1998, Computers in biology and medicine.

[6]  John W. Emerson,et al.  Nonparametric Goodness-of-Fit Tests for Discrete Null Distributions , 2011, R J..

[7]  J. Santolaria,et al.  Uncertainty estimation in robot kinematic calibration , 2013 .

[8]  Jie Wang,et al.  Comparison of GUF and Monte Carlo methods to evaluate task-specific uncertainty in laser tracker measurement , 2014 .

[9]  Lin-An Chen,et al.  Uncertainty analysis for measurement of measurand , 2010 .

[10]  Thomas Ulrich Uncertainty estimation for kinematic laser tracker measurements , 2012, 2012 International Conference on Indoor Positioning and Indoor Navigation (IPIN).

[11]  Liang Mi,et al.  A four-point measurement model for evaluating the pose of industrial robot and its influence factor analysis , 2017, Ind. Robot.

[12]  Ilian A. Bonev,et al.  Assessment of the positioning performance of an industrial robot , 2012, Ind. Robot.

[13]  J. J. Aguilar,et al.  Performance evaluation of laser tracker kinematic models and parameter identification , 2015 .

[14]  Bijan Shirinzadeh,et al.  The measurement uncertainties in the laser interferometry-based sensing and tracking technique , 2002 .

[15]  J. J. Aguilar,et al.  Identification and Kinematic Calculation of Laser Tracker Errors , 2013 .

[16]  Andrew Lewis,et al.  Laser tracker error determination using a network measurement , 2011 .

[17]  Marie Havlikova,et al.  Comparison of GUM and Monte Carlo method for evaluation measurement uncertainty of indirect measurements , 2013, Proceedings of the 14th International Carpathian Control Conference (ICCC).