Tactile Active Inference Reinforcement Learning for Efficient Robotic Manipulation Skill Acquisition

Robotic manipulation holds the potential to re- place humans in the execution of tedious or dangerous tasks. However, control-based approaches are not suitable due to the difficulty of formally describing open-world manipulation in reality, and the inefficiency of existing learning methods. Therefore, applying manipulation in a wide range of scenarios presents significant challenges. In this study, we propose a novel framework for skill learning in robotic manipulation called Tactile Active Inference Reinforcement Learning (Tactile- AIRL), aimed at achieving efficient learning. To enhance the performance of reinforcement learning (RL), we introduce active inference, which integrates model-based techniques and intrinsic curiosity into the RL process. This integration im- proves the algorithm’s training efficiency and adaptability to sparse rewards. Additionally, we have designed universal tactile static and dynamic features based on vision-based tactile sensors, making our framework scalable to many manipulation tasks learning involving tactile feedback. Simulation results demonstrate that our method achieves significantly high train- ing efficiency in objects pushing tasks. It enables agents to excel in both dense and sparse reward tasks with just few interaction episodes, surpassing the SAC baseline. Furthermore, we conduct physical experiments on a gripper screwing task using our method, which showcases the algorithm’s rapid learning capability and its potential for practical applications.