Real-Time Constrained Tracking Control of Redundant Manipulators Using a Koopman-Zeroing Neural Network Framework

This study proposes a combined Koopman-ZNN (Zeroing Neural Network) architecture for real-time control of redundant manipulators subject to input constraints. An autoencoder-based neural architecture is employed to discover the bilinear Koopman model for manipulator dynamics in joint space using inp...

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Veröffentlicht in:IEEE robotics and automation letters Jg. 9; H. 2; S. 1 - 8
Hauptverfasser: Sah, Chandan Kumar, Singh, Rajpal, Keshavan, Jishnu
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Piscataway IEEE 01.02.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Schlagworte:
Aerospace electronics
Cartesian coordinates
Computational modeling
Computer architecture
Constraints
Control systems
Controllers
End effectors
Learning
Machine Learning for Robot Control
Manipulator dynamics
Manipulators
Model Learning for Control
Neural networks
Nonlinear control
Performance assessment
Predictive control
Real time
Real-time systems
Redundant Robots
Robot arms
System dynamics
Tracking control
ISSN:2377-3766, 2377-3766
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Zusammenfassung:This study proposes a combined Koopman-ZNN (Zeroing Neural Network) architecture for real-time control of redundant manipulators subject to input constraints. An autoencoder-based neural architecture is employed to discover the bilinear Koopman model for manipulator dynamics in joint space using input-output data, which is subsequently integrated with a feed-forward neural network that maps the joint coordinates to end-effector Cartesian coordinates. The proposed architecture allows for efficient learning of highly accurate models using a significantly lower number of observable states compared to the previous studies. This learning architecture is then coupled with a ZNN controller, which offers a computationally inexpensive alternative to state-of-the-art Nonlinear Model Predictive Control (NMPC) controllers whose computational burden might render real-time control infeasible. The low-dimensional nature of the learned model, combined with a computationally inexpensive ZNN controller, facilitates real-time control applications with improved tracking accuracy. Simulation and experimental studies of trajectory tracking, including performance comparisons with leading alternative designs, are used to verify the efficacy of the proposed scheme.
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ISSN:2377-3766
2377-3766
DOI:10.1109/LRA.2024.3349966