学习可扩展且高效的多机器人防撞通信策略

IF 3.7 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Autonomous Robots Pub Date : 2023-08-19 DOI:10.1007/s10514-023-10127-3

Álvaro Serra-Gómez, Hai Zhu, Bruno Brito, Wendelin Böhmer, Javier Alonso-Mora

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引用次数: 0

摘要

分散式多机器人系统通常通过不断地广播它们的意图来执行协调运动规划，以避免碰撞。然而，机器人之间发生碰撞的风险随着它们的移动而变化，而且通信可能并不总是需要的。本文提出了一种有效的通信方法，解决了多机器人避碰场景中“何时”和“与谁”进行通信的问题。在这种方法中，每个机器人学习推理其他机器人的状态，并在询问其他机器人的轨迹计划之前考虑未来碰撞的风险。我们为学习到的通信策略引入了一种新的神经结构，使我们的方法具有可扩展性。我们在多达12个四旋翼机的仿真中评估和验证了所提出的通信策略，并给出了该策略在不同场景下的零射击泛化/鲁棒性能力的结果。我们证明了我们的策略(在模拟环境中学习)可以成功地转移到真实的机器人上。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Learning scalable and efficient communication policies for multi-robot collision avoidance

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Learning scalable and efficient communication policies for multi-robot collision avoidance

Decentralized multi-robot systems typically perform coordinated motion planning by constantly broadcasting their intentions to avoid collisions. However, the risk of collision between robots varies as they move and communication may not always be needed. This paper presents an efficient communication method that addresses the problem of “when” and “with whom” to communicate in multi-robot collision avoidance scenarios. In this approach, each robot learns to reason about other robots’ states and considers the risk of future collisions before asking for the trajectory plans of other robots. We introduce a new neural architecture for the learned communication policy which allows our method to be scalable. We evaluate and verify the proposed communication strategy in simulation with up to twelve quadrotors, and present results on the zero-shot generalization/robustness capabilities of the policy in different scenarios. We demonstrate that our policy (learned in a simulated environment) can be successfully transferred to real robots.

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来源期刊

Autonomous Robots 工程技术-机器人学

CiteScore

7.90

自引率

5.70%

发文量

审稿时长

3 months

期刊介绍： Autonomous Robots reports on the theory and applications of robotic systems capable of some degree of self-sufficiency. It features papers that include performance data on actual robots in the real world. Coverage includes: control of autonomous robots · real-time vision · autonomous wheeled and tracked vehicles · legged vehicles · computational architectures for autonomous systems · distributed architectures for learning, control and adaptation · studies of autonomous robot systems · sensor fusion · theory of autonomous systems · terrain mapping and recognition · self-calibration and self-repair for robots · self-reproducing intelligent structures · genetic algorithms as models for robot development. The focus is on the ability to move and be self-sufficient, not on whether the system is an imitation of biology. Of course, biological models for robotic systems are of major interest to the journal since living systems are prototypes for autonomous behavior.