Learning-based Kinematic Calibration using Adjoint Error Model

This paper presents a kinematic calibration of a 6-RRRPRR parallel kinematic mechanism with offset RR-joints that would be applied in space positioning field. In order to ensure highly accurate and highly effective calibration process, the complete error model, which contains offset universal joint errors, is established by differentiating inverse kinematic model. A calibration simulation comparison with non-complete error model shows that offset universal joint errors are crucial to improve the calibration accuracy. Using the error model, an optimal calibration configuration selection algorithm is developed to determine the least number of measurement configurations as well as the optimal selection of these configurations from the feasible configuration set. To verify the effectiveness of kinematic calibration, a simulation and experiment were performed. The results show that the developed approach can effectively improve accuracy of a parallel kinematic mechanism with relatively low number of calibration configurations.

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Kinematic calibration of serial robot using dual quaternions

Industrial Robot the international journal of robotics research and application ◽

10.1108/ir-10-2018-0221 ◽

2019 ◽

Vol 46 (2) ◽

pp. 247-258 ◽

Cited By ~ 3

Author(s):

Guozhi Li ◽

Fuhai Zhang ◽

Yili Fu ◽

Shuguo Wang

Keyword(s):

Kinematic Analysis ◽

Quaternion Algebra ◽

Error Model ◽

Kinematic Calibration ◽

Dual Quaternion ◽

Robot Calibration ◽

Geometrical Meaning ◽

Content Type ◽

Dual Quaternions ◽

Serial Robot

Purpose The purpose of this paper is to propose an error model for serial robot kinematic calibration based on dual quaternions. Design/methodology/approach The dual quaternions are the combination of dual-number theory and quaternion algebra, which means that they can represent spatial transformation. The dual quaternions can represent the screw displacement in a compact and efficient way, so that they are used for the kinematic analysis of serial robot. The error model proposed in this paper is derived from the forward kinematic equations via using dual quaternion algebra. The full pose measurements are considered to apply the error model to the serial robot by using Leica Geosystems Absolute Tracker (AT960) and tracker machine control (T-MAC) probe. Findings Two kinematic-parameter identification algorithms are derived from the proposed error model based on dual quaternions, and they can be used for serial robot calibration. The error model uses Denavit–Hartenberg (DH) notation in the kinematic analysis, so that it gives the intuitive geometrical meaning of the kinematic parameters. The absolute tracker system can measure the position and orientation of the end-effector (EE) simultaneously via using T-MAC. Originality/value The error model formulated by dual quaternion algebra contains all the basic geometrical parameters of serial robot during the kinematic calibration process. The vector of dual quaternion error can be used as an indicator to represent the trend of error change of robot’s EE between the nominal value and the actual value. The accuracy of the EE is improved after nearly 20 measurements in the experiment conduct on robot SDA5F. The simulation and experiment verify the effectiveness of the error model and the calibration algorithms.

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Kinematic calibration of the 3-degree-of-freedom redundantly actuated spatial parallel module of a five-axis hybrid machine

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/0954405420911299 ◽

2020 ◽

Vol 234 (9) ◽

pp. 1185-1197

Author(s):

Xuan Luo ◽

Fugui Xie ◽

Xin-Jun Liu

Keyword(s):

Error Model ◽

Error Modeling ◽

Kinematic Calibration ◽

Bilinear Interpolation ◽

Position Errors ◽

Redundantly Actuated ◽

Parallel Module ◽

Hybrid Machine ◽

Five Axis ◽

Active Joints

As a new type of manufacturing equipment, redundant hybrid machines have the theoretical advantage over the traditional serial machines in efficiently processing large structural parts with high material removal ratio and complex parts with curved surfaces. In order to solve the accuracy problem of the redundantly actuated spatial parallel module of a five-axis hybrid machine, an improved kinematic calibration method is proposed in this article. First, different from error modeling for the corresponding non-redundant parallel module, the geometric error model of the redundantly actuated spatial parallel module considers the deformations at active joints caused by actuation redundancy as an error source. Then, the applicable error model is developed using projection technique to remove the need of active joints’ stiffness measurement or modeling. Later, the practical error model is derived from model reduction method to avoid using additional sensors or gratings. Finally, three forms of relative measurement and step identification are adopted for the calibration work, and the bilinear interpolation compensation function is introduced to ensure the calibration effect. On this basis, the kinematic calibration of the redundantly actuated spatial parallel module is conducted. The max position errors are reduced from original −0.192 to 0.075 mm after RM1 and SI1, and then further reduced to 0.014 mm after bilinear interpolation compensation, while the max orientation errors are reduced from −0.017° and 0.249° to −0.005° and −0.007° after RM2 and SI2, and RM3 and SI3, respectively. A contrasting experiment is also carried out with the previous method for the corresponding non-redundant parallel module. As a result, the proposed method shows better convergence value and speed in identifying error parameters, and therefore the effectiveness and efficiency of the proposed method for the redundantly actuated spatial parallel module are validated.

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Complete, Minimal and Continuous Kinematic Error Models of Perfect Multi-DOF Joints for Parallel Manipulators

Volume 10: 44th Mechanisms and Robotics Conference (MR) ◽

10.1115/detc2020-22328 ◽

2020 ◽

Author(s):

Lingyu Kong ◽

Genliang Chen ◽

Zhuang Zhang ◽

Anhuan Xie ◽

Hao Wang ◽

...

Keyword(s):

Parallel Manipulators ◽

Error Model ◽

Parallel Robots ◽

Kinematic Error ◽

Kinematic Calibration ◽

Calibration Result ◽

Calibration Methods ◽

Manufacturing Errors ◽

The One ◽

Serial Chains

Abstract Kinematic error model plays an important role in improving the positioning accuracy of robot manipulators by kinematic calibration. In order to get a better calibration result, the error model should satisfy complete, minimal and continuous criteria. In order to meet the complete requirement, the multi degree-of-freedom (DOF) joints, such as universal or spherical joint in parallel robots, have to be regarded as serial chains formed by multiple independent single DOF joints, such that the manufacturing errors of these joints can be considered. However, several previous work found that these manufacturing errors for some parallel manipulators have little effect on the accuracy improvement. Besides, considering these kind of errors will cause the kinematics to be much more complicated. Therefore, under the assumptions of perfectly manufactured universal, spherical and cylinder joints, a complete, minimal and continuous (CMC) error model is presented in this paper. The identifiability of the kinematic errors of these multi-DOF joints are analytically analyzed. In order to verify the correctness and effectiveness of the proposed method, a numerical simulation of kinematic calibration is conducted on a 6-UPS parallel manipulator. The calibration result is also compared to the one derived from the error model with 138 error parameters. Since the error model and calibration methods are described uniformly, it can be applied to most parallel manipulators.

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A Comprehensive Numerical Study on the Number of Identifiable Kinematic Parameters of Parallel Mechanisms

10.1115/detc2021-70723 ◽

2021 ◽

Author(s):

Lingyu Kong ◽

Genliang Chen ◽

Guanyu Huang ◽

Sumian Song ◽

Anhuan Xie ◽

...

Keyword(s):

Numerical Study ◽

Error Model ◽

Error Modeling ◽

Kinematic Error ◽

Kinematic Calibration ◽

Parallel Mechanisms ◽

Kinematic Parameters ◽

Positioning Accuracy ◽

Prismatic Joints ◽

Kinematic Error Model

Abstract Kinematic error model plays an important role in improving the positioning accuracy of robot manipulators by kinematic calibration. The identifiability of kinematic parameters in the error model directly affects the positioning accuracy of the mechanism. And the number of identifiable kinematic parameters determines how many parameters can be accurately identified by kinematic calibration, which is one of the theoretical basis of kinematic error modeling. For serial mechanisms, a consensus has been reached that the maximum number of identifiable kinematic parameters is 4R + 2P + 6, where R and P represent the numbers of revolute and prismatic joints, respectively. Due to complex topologies of parallel mechanisms, there is still no agreement on the formula of the maximum number of identifiable parameters. In this paper, a comprehensive numerical study on the number of identifiable kinematic parameters of parallel mechanisms is conducted. The number of identifiable parameters of 3802 kinds of limbs with different types or actuation arrangements are analyzed. It can be concluded that the maximum number of identifiable kinematic parameters is Σ i = 1 n 4Ri + 2Pi + 6 − Ci − 2(PP)i/3(PPP1)i/(2Ri + 2Pi)(PPP)i, where Ci represents the number of joints whose motion cannot be measured and n denotes the number of limbs in a parallel mechanism; (PP)i, (PPP1)i, and (PPP)i represent two consecutive unmeasurable P joints, three consecutive P joints in which two of them cannot be measured, and three unmeasurable P joints, respectively.

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Error Model and Kinematic Calibration of a 5-axis Hybrid Machine Tool

2006 SICE-ICASE International Joint Conference ◽

10.1109/sice.2006.314800 ◽

2006 ◽

Cited By ~ 3

Author(s):

Jun-woo Kim ◽

Chang-rok Shin ◽

Han-sung Kim ◽

Jin-ho Kyung ◽

Young-ho Ha ◽

...

Keyword(s):

Machine Tool ◽

Error Model ◽

Kinematic Calibration ◽

Hybrid Machine Tool ◽

Hybrid Machine

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An improved kinematic calibration method for serial manipulators based on POE formula

Robotica ◽

10.1017/s0263574718000280 ◽

2018 ◽

Vol 36 (8) ◽

pp. 1244-1262 ◽

Cited By ~ 7

Author(s):

Chenguang Chang ◽

Jinguo Liu ◽

Zhiyu Ni ◽

Ruolong Qi

Keyword(s):

High Precision ◽

Least Square Method ◽

Calibration Method ◽

Error Model ◽

Least Square ◽

Identification Accuracy ◽

Kinematic Calibration ◽

Serial Manipulators ◽

Serial Robots ◽

Generic Modeling

SUMMARYExisting measurement equipments easily determine position with high precision. However, they evaluate orientation with low precision. It is necessary to minimize the effect of measurement error on identification accuracy. In this study, a method for kinematic calibration based on the product of exponentials (POE) is presented to improve the absolute positioning accuracy of a sliding manipulator. An error model with uniform and generic modeling rules is established in which the tool frame is selected as the reference frame. Furthermore, the redundant parameters of the error model are removed. Subsequently, the actual kinematic parameters are identified by using the least square method. Finally, the process of the improved method is discussed. Kinematic calibration simulations of a sliding manipulator are implemented. The results indicate that the proposed method significantly improves the precision of the sliding manipulator. The improved POE kinematic calibration method offers convenience, efficiency, and high precision. The proposed method can be applied to all types of serial robots with n-DOF

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