Deep Imitation Learning for Bimanual Robotic Manipulation

Fan Xie; Alexander Chowdhury; M. Clara De Paolis Kaluza; Linfeng Zhao; Lawson Wong; Rose Yu

2020 NIPS NeurIPS 2020

Deep Imitation Learning for Bimanual Robotic Manipulation

Abstract

We present a deep imitation learning framework for robotic bimanual manipulation in a continuous state-action space. A core challenge is to generalize the manipulation skills to objects in different locations. We hypothesize that modeling the relational information in the environment can significantly improve generalization. To achieve this, we propose to (i) decompose the multi-modal dynamics into elemental movement primitives, (ii) parameterize each primitive using a recurrent graph neural network to capture interactions, and (iii) integrate a high-level planner that composes primitives sequentially and a low-level controller to combine primitive dynamics and inverse kinematics control. Our model is a deep, hierarchical, modular architecture. Compared to baselines, our model generalizes better and achieves higher success rates on several simulated bimanual robotic manipulation tasks. We open source the code for simulation, data, and models at: https://github.com/Rose-STL-Lab/HDR-IL.

🌉 Interdisciplinary Bridge — Artificial Intelligence and Machine Learning and Reinforcement Learning and Robotics

🧭 Keyword Pioneer — bimanual manipulation

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

Fan Xie , Alexander Chowdhury , M. Clara De Paolis Kaluza , Linfeng Zhao , Lawson Wong , Rose Yu

Topics

Artificial Intelligence > Core AI > Agent Systems Artificial Intelligence > Learning Paradigms > Transfer Learning Machine Learning > Learning Types > Weakly Supervised Learning Reinforcement Learning > Applications > Robotics Robotics > Capabilities > Manipulation

Keywords

motion planning imitation learning hierarchical architecture inverse kinematics skill generalization graph neural network deep imitation learning bimanual manipulation recurrent graph neural network hierarchical modular architecture

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