English

Solving Multi-Entity Robotic Problems Using Permutation Invariant Neural Networks

Robotics 2024-02-29 v1

Abstract

Challenges in real-world robotic applications often stem from managing multiple, dynamically varying entities such as neighboring robots, manipulable objects, and navigation goals. Existing multi-agent control strategies face scalability limitations, struggling to handle arbitrary numbers of entities. Additionally, they often rely on engineered heuristics for assigning entities among agents. We propose a data driven approach to address these limitations by introducing a decentralized control system using neural network policies trained in simulation. Leveraging permutation invariant neural network architectures and model-free reinforcement learning, our approach allows control agents to autonomously determine the relative importance of different entities without being biased by ordering or limited by a fixed capacity. We validate our approach through both simulations and real-world experiments involving multiple wheeled-legged quadrupedal robots, demonstrating their collaborative control capabilities. We prove the effectiveness of our architectural choice through experiments with three exemplary multi-entity problems. Our analysis underscores the pivotal role of the end-to-end trained permutation invariant encoders in achieving scalability and improving the task performance in multi-object manipulation or multi-goal navigation problems. The adaptability of our policy is further evidenced by its ability to manage varying numbers of entities in a zero-shot manner, showcasing near-optimal autonomous task distribution and collision avoidance behaviors.

Keywords

Cite

@article{arxiv.2402.18345,
  title  = {Solving Multi-Entity Robotic Problems Using Permutation Invariant Neural Networks},
  author = {Tianxu An and Joonho Lee and Marko Bjelonic and Flavio De Vincenti and Marco Hutter},
  journal= {arXiv preprint arXiv:2402.18345},
  year   = {2024}
}
R2 v1 2026-06-28T15:03:17.396Z