A Two-Step Method for Dynamic Parameter Identification of Indy7 Collaborative Robot Manipulator

Accurate dynamic model is critical for collaborative robots to achieve satisfactory performance in model-based control or other applications such as dynamic simulation and external torque estimation. Such dynamic models are frequently restricted to identifying important system parameters and compens...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Switzerland), 2022-12, Vol.22 (24), p.9708
Main Authors: Tadese, Meseret, Pico, Nabih, Seo, Sungwon, Moon, Hyungpil
Format: Article
Language:English
Subjects:
Accuracy
Analysis
Collaboration
Dynamic models
dynamic parameters identification
Friction
friction identification
friction model
Inverse dynamics
Least squares method
Manipulators
Mathematical models
Methods
Model accuracy
Parameter identification
Random variables
Robot arms
robot dynamics
Robotics
Robots
Temperature dependence
Torque
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Summary:Accurate dynamic model is critical for collaborative robots to achieve satisfactory performance in model-based control or other applications such as dynamic simulation and external torque estimation. Such dynamic models are frequently restricted to identifying important system parameters and compensating for nonlinear terms. Friction, as a primary nonlinear element in robotics, has a significant impact on model accuracy. In this paper, a reliable dynamic friction model, which incorporates the influence of temperature fluctuation on the robot joint friction, is utilized to increase the accuracy of identified dynamic parameters. First, robot joint friction is investigated. Extensive test series are performed in the full velocity operating range at temperatures ranging from 19 °C to 51 °C to investigate friction dependency on joint module temperature. Then, dynamic parameter identification is performed using an inverse dynamics identification model and weighted least squares regression constrained to the feasible space, guaranteeing the optimal solution. Using the identified friction model parameters, the friction torque is computed for measured robot joint velocity and temperature. Friction torque is subtracted from the measured torque, and a non-friction torque is used to identify dynamic parameters. Finally, the proposed notion is validated experimentally on the Indy7 collaborative robot manipulator, and the results show that the dynamic model with parameters identified using the proposed method outperforms the dynamic model with parameters identified using the conventional method in tracking measured torque, with a relative improvement of up to 70.37%.
ISSN:1424-8220
1424-8220
DOI:10.3390/s22249708