Publication Type : Journal Article
Thematic Areas : Center for Computational Engineering and Networking (CEN)
Publisher : Springer
Source : Journal of Bionic Engineering, 2022. 20, 953–966. (SCIE, IF: 4.0)
Url : https://link.springer.com/article/10.1007/s42235-022-00309-7
Campus : Coimbatore
School : School of Artificial Intelligence - Coimbatore
Center : Computational Engineering and Networking
Year : 2022
Abstract : It is common for robotic fish to generate thrust using reactive force generated by the tail’s physical motion, which interacts with the surrounding fluid. The coupling effect of the body strongly correlates with this thrust. However, hydrodynamics cannot be wholly modeled in analytical form. Therefore, data-assisted modeling is necessary for robotic fish. This work presents the first method of its kind using Genetic Algorithm (GA)-based optimization methods for data-assistive modeling for robotic fish applications. To begin, experimental data are collected in real time with the robotic fish that has been designed and fabricated using 3D printing. Then, the model’s influential parameters are estimated using an optimization problem. Further, a model-based deep reinforcement learning (DRL) controller is proposed to track the desired speed through extensive simulation work. In addition to a deep deterministic policy gradient (DDPG), a twin delayed DDPG (TD3) is employed in the training of the RL agent. Unfortunately, due to its local optimization problem, the RL-DDPG controller failed to perform well during training. In contrast, the RL-TD3 controller effectively learns the control policies and overcomes the local optima problem. As a final step, controller performance is evaluated under different disturbance conditions. In contrast to DDPG and GA-tuned proportional-integral controllers, the proposed model with RL-TD3 controller significantly improves the performance.
Cite this Research Publication : Palmani Duraisamy, Manigandan Nagarajan Santhanakrishnan, Amirtharajan Rengarajan, "Design of deep reinforcement learning controller through data-assisted model for robotic fish speed tracking", Journal of Bionic Engineering, 2022. 20, 953–966. (SCIE, IF: 4.0)