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Neural-Swarm: Decentralized Close-Proximity Multirotor Control Using Learned Interactions

Guanya Shi, Wolfgang Hönig, Yisong Yue, Soon‐Jo Chung

202068 citationsDOI

Abstract

In this paper, we present Neural-Swarm, a nonlinear decentralized stable controller for close-proximity flight of multirotor swarms. Close-proximity control is challenging due to the complex aerodynamic interaction effects between multirotors, such as downwash from higher vehicles to lower ones. Conventional methods often fail to properly capture these interaction effects, resulting in controllers that must maintain large safety distances between vehicles, and thus are not capable of close-proximity flight. Our approach combines a nominal dynamics model with a regularized permutation-invariant Deep Neural Network (DNN) that accurately learns the high-order multi-vehicle interactions. We design a stable nonlinear tracking controller using the learned model. Experimental results demonstrate that the proposed controller significantly outperforms a baseline nonlinear tracking controller with up to four times smaller worst-case height tracking errors. We also empirically demonstrate the ability of our learned model to generalize to larger swarm sizes.

Topics & Concepts

MultirotorControl theory (sociology)Swarm behaviourNonlinear systemController (irrigation)Computer scienceAerodynamicsArtificial neural networkVehicle dynamicsDownwashArtificial intelligenceControl engineeringControl (management)EngineeringAutomotive engineeringQuantum mechanicsAgronomyPhysicsAerospace engineeringBiologyRobotic Path Planning AlgorithmsDistributed Control Multi-Agent SystemsAerospace and Aviation Technology
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