Model predictive path integral for decentralized multi-agent collision avoidance

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Stepan Dergachev, Konstantin Yakovlev
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Abstract

Collision avoidance is a crucial component of any decentralized multi-agent navigation system. Currently, most of the existing multi-agent collision-avoidance methods either do not take into account the kinematic constraints of the agents (i.e., they assume that an agent might change the direction of movement instantaneously) or are tailored to specific kinematic motion models (e.g., car-like robots). In this work, we suggest a novel generalized approach to decentralized multi-agent collision-avoidance that can be applied to agents with arbitrary affine kinematic motion models, including but not limited to differential-drive robots, car-like robots, quadrotors, etc. The suggested approach is based on the seminal sampling-based model predictive control algorithm, i.e., MPPI, that originally solves a single-agent problem. We enhance it by introducing safe distributions for the multi-agent setting that are derived from the Optimal Reciprocal Collision Avoidance (ORCA) linear constraints, an established approach from the multi-agent navigation domain. We rigorously show that such distributions can be found by solving a specific convex optimization problem. We also provide a theoretical justification that the resultant algorithm guarantees safety, i.e., that at each time step the control suggested by our algorithm does not lead to a collision. We empirically evaluate the proposed method in simulation experiments that involve comparison with the state of the art in different setups. We find that in many cases, the suggested approach outperforms competitors and allows solving problem instances that the other methods cannot successfully solve.
分散式多机器人防撞的模型预测路径积分
避免碰撞是任何分散式多代理导航系统的重要组成部分。目前,大多数现有的多代理防撞方法要么没有考虑代理的运动学约束(即假设代理可能瞬间改变运动方向),要么是针对特定的运动学运动模型(如类车机器人)量身定制的。在这项工作中,我们提出了一种新颖的分散式多代理防撞通用方法,可应用于具有任意仿射运动模型的代理,包括但不限于差动驱动机器人、类车机器人、四旋翼机器人等。建议的方法基于开创性的基于采样的模型预测控制算法,即 MPPI,该算法最初解决的是单个代理问题。我们通过引入多机器人环境下的安全分布来增强该算法,这些安全分布来自于最优互撞避免(ORCA)线性约束,是多机器人导航领域的一种成熟方法。我们严谨地证明,这种分布可以通过解决一个特定的凸优化问题来找到。我们还提供了理论依据,说明由此产生的算法能保证安全性,即在每个时间步,我们算法建议的控制不会导致碰撞。我们在模拟实验中对所提出的方法进行了实证评估,包括在不同设置下与现有技术进行比较。我们发现,在许多情况下,建议的方法都优于竞争对手,并能解决其他方法无法成功解决的问题实例。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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