PREVENT-JACK: Context Steering for Swarms of Long Heavy Articulated Vehicles
Adrian Baruck, Michael Dubé, Christoph Steup, Sanaz Mostaghim
TLDR
Prevent-Jack introduces a context steering framework for swarms of long articulated vehicles, guaranteeing against jackknifing and collisions.
Key contributions
- Introduces "Prevent-Jack," a novel context steering framework for swarms of Heavy Articulated Vehicles (HAVs).
- Fuses six local behaviors to guarantee against jackknifing and collisions for HAVs with up to ten trailers.
- Identifies "Evade Attraction" as crucial for deadlock prevention in HAV swarms through parameter studies.
- Evaluates swarm performance across 15,000 simulations, observing dead/livelocks in larger, denser swarms.
Why it matters
This paper extends swarm robotics to Heavy Articulated Vehicles, solving jackknifing and collision issues. Its decentralized steering framework provides practical solutions for real-world use. Insights on dead/livelocks are vital for robust HAV swarm design.
Original Abstract
In this paper, we aim to extend the traditional point-mass-like robot representation in swarm robotics and instead study a swarm of long Heavy Articulated Vehicles (HAVs). HAVs are kinematically constrained, elongated, and articulated, introducing unique challenges. Local, decentralized coordination of these vehicles is motivated by many real-world applications. Our approach, Prevent-Jack, introduces the sparsely covered context steering framework in robotics. It fuses six local behaviors, providing guarantees against jackknifing and collisions at the cost of potential dead- and livelocks, tested for vehicles with up to ten trailers. We highlight the importance of the Evade Attraction behavior for deadlock prevention using a parameter study, and use 15,000 simulations to evaluate the swarm performance. Our extensive experiments and the results show that both the dead- and livelocks occur more frequently in larger swarms and denser scenarios, affecting a peak average of 27%/31% of vehicles. We observe that larger swarms exhibit increased waiting, while smaller swarms show increased evasion.
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