Reinforcement Learning Control of a Reconfigurable Planar Cable Driven Parallel Manipulator

Published in 2023 International Conference on Robotics and Automation (ICRA), 2023

Cable driven parallel robots (CDPRs) are often challenging to model and to dynamically control due to the inherent flexibility and elasticity of the cables. The additional inclusion of online geometric reconfigurability to a CDPR results in a complex underdetermined system with highly non-linear dynamics. The necessary (numerical) redundancy resolution requires multiple layers of optimization rendering its application computationally prohibitive for real-time control. Here, deep reinforcement learning approaches can offer a model-free framework to overcome these challenges and can provide a real-time capable dynamic control. This study discusses three settings for a model-free DRL implementation in dynamic trajectory tracking: (i) for a standard non-redundant CDPR with a fixed workspace; (ii) in an end-to-end setting with redundancy resolution on a reconfigurable CDPR; and (iii) in a decoupled approach resolving kinematic and actuation redundancies individually.

Citation : A. Raman, A. Salvi, M. Schmid and V. Krovi, “Reinforcement Learning Control of a Reconfigurable Planar Cable Driven Parallel Manipulator,” 2023 IEEE International Conference on Robotics and Automation (ICRA), London, United Kingdom, 2023, pp. 9644-9650, doi: 10.1109/ICRA48891.2023.10160498.

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