Optimal Distributed Control for Platooning via Sparse Coprime Factorizations

Sabău, Şerban; Oară, Cristian; Warnick, Sean; Jadbabaie, Ali

doi:10.1109/tac.2016.2572002

Cited by 36 publications

(6 citation statements)

References 54 publications

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“…In the literature, the main focus has been on the technological aspects of platooning and how vehicle-to-vehicle communication and sensor technology can be applied to facilitate platooning (Bergenhem et al, 2012). Along these lines, mathematical models for platooning control and optimal stability as well as adaptive cruise control manoeuvres have been developed (e.g, (Sabau et al, 2017;Nowakowski et al, 2015)). Numerous technological challenges still remain related to platooning, including enabling multi-brand platooning (Fornells & Arrue, 2014;Brizzolara & Toth, 2016;Berger, 2016), restrictions on platoons in mixed traffic conditions (Alkim et al, 2016) and incompatible braking and acceleration profiles (Nowakowski et al, 2015).…”

Section: Literature Reviewmentioning

confidence: 99%

Hub-based truck platooning: Potentials and profitability

Larsen

Rich

Rasmussen

2019

Transportation Research Part E: Logistics and Transportation Re

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This paper presents a model for optimising truck platoons formed at a platooning hub. Different planning and dispatching strategies, from static to dynamic, are investigated with respect to profitability and fuel savings across a range of input variables. The problem is solved using a dynamic programming based local search heuristic. As a case study, a virtual platooning hub close to the German Elb Tunnel is examined using data from a large European transport network model. It is concluded that profitability crucially depends on; i) dynamic outlook and ii) if chauffeurs are allowed to rest while driving in platoons.

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Section: Literature Reviewmentioning

confidence: 99%

Hub-based truck platooning: Potentials and profitability

Larsen

Rich

Rasmussen

2019

Transportation Research Part E: Logistics and Transportation Re

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“…The i-th member of the platoon, QP i , is expected to track a relative position in the platoon r i = (r i x , r i y ) with respect to the leader's position pP 1 , and the leader's velocity vP 1 at all times. The resulting control law has the form: (25) for some kp, kv > 0. In particular, a simple rule for determining r i (t) in a single-file platoon is given for QP i as:…”

Section: Following a Platoonmentioning

confidence: 99%

Reachability-Based Safety and Goal Satisfaction of Unmanned Aerial Platoons on Air Highways

Chen

Fisac

et al. 2017

Journal of Guidance, Control, and Dynamics

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Recently, there has been immense interest in using unmanned aerial vehicles (UAVs) for civilian operations. As a result, unmanned aerial systems traffic management is needed to ensure the safety and goal satisfaction of potentially thousands of UAVs flying simultaneously. Currently, the analysis of large multi-agent systems cannot tractably provide these guarantees if the agents' set of maneuvers is unrestricted. In this paper, platoons of UAVs flying on air highways is proposed to impose an airspace structure that allows for tractable analysis. For the air highway placement problem, the fast marching method is used to produce a sequence of air highways that minimizes the cost of flying from an origin to any destination. The placement of air highways can be updated in real-time to accommodate sudden airspace changes. Within platoons traveling on air highways, each vehicle is modeled as a hybrid system. Using Hamilton-Jacobi reachability, safety and goal satisfaction are guaranteed for all mode transitions. For a single altitude range, the proposed approach guarantees safety for one safety breach per vehicle; in the unlikely event of multiple safety breaches, safety can be guaranteed over multiple altitude ranges. We demonstrate the platooning concept through simulations of three representative scenarios.

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“…This paper considers a velocity control problem for autonomous vehicle platoons by Intelligent Transport Systems (ITS). The development of connected vehicles advances platoon control methods [1]. In the platoon control, each vehicle adjusts its velocity and its inter-vehicular distance based on the information by sensing or vehicle to vehicle (V2V) communications.…”

Section: Introductionmentioning

confidence: 99%

Multi-Rate Switched Pinning Control for Velocity Control of Vehicle Platoons

Wakasa

Sawada

2021

IEICE Trans. Fundamentals

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This paper proposes a switched pinning control method with a multi-rating mechanism for vehicle platoons. The platoons are expressed as multi-agent systems consisting of mass-damper systems in which pinning agents receive target velocities from external devices (ex. intelligent traffic signals). We construct model predictive control (MPC) algorithm that switches pinning agents via mixed-integer quadratic programmings (MIQP) problems. The optimization rate is determined according to the convergence rate to the target velocities and the inter-vehicular distances. This multirating mechanism can reduce the computational load caused by iterative calculation. Numerical results demonstrate that our method has a reduction effect on the string instability by selecting the pinning agents to minimize errors of the inter-vehicular distances to the target distances.

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Optimal Distributed Control for Platooning via Sparse Coprime Factorizations

Cited by 36 publications

References 54 publications

Hub-based truck platooning: Potentials and profitability

Hub-based truck platooning: Potentials and profitability

Reachability-Based Safety and Goal Satisfaction of Unmanned Aerial Platoons on Air Highways

Multi-Rate Switched Pinning Control for Velocity Control of Vehicle Platoons

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