Cucker-Smale model with finite speed of information propagation: well-posedness, flocking and mean-field limit
Abstract
We study a variant of the Cucker-Smale model where information between agents propagates with a finite speed c>0. This leads to a system of functional differential equations with state-dependent delay. We prove that, if initially the agents travel slower than c, then the discrete model admits unique global solutions. Moreover, under a generic assumption on the influence function, we show that there exists a critical information propagation speed c>0 such that if c≥c, the system exhibits asymptotic flocking in the sense of the classical definition of Cucker and Smale. For constant initial datum the value of c is explicitly calculable. Finally, we derive a mean-field limit of the discrete system, which is formulated in terms of probability measures on the space of time-dependent trajectories. We show global well-posedness of the mean-field problem and argue that it does not admit a description in terms of the classical Fokker-Planck equation.
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