Abstract
Most human actions are composed of two fundamental movement types, discrete and rhythmic movements. These movement types, or primitives, are analogous to the two elemental behaviors of nonlinear dynamical systems, namely, fixed-point and limit cycle behavior, respectively. Furthermore, there is now a growing body of research demonstrating how various human actions and behaviors can be effectively modeled and understood using a small set of low-dimensional, fixed-point and limit cycle dynamical systems (differential equations). Here, we provide an overview of these dynamical motor primitives and detail recent research demonstrating how these dynamical primitives can be used to model the task dynamics of complex multiagent behavior. More specifically, we review how a task-dynamic model of multiagent shepherding behavior, composed of rudimentary fixed-point and limit cycle dynamical primitives, can not only effectively model the behavior of cooperating human co-actors, but also reveals how the discovery and intentional use of optimal behavioral coordination during task learning is marked by a spontaneous, self-organized transition between fixed-point and limit cycle dynamics (i.e., via a Hopf bifurcation).
Highlights
A differentiating factor between novice and expert teams is the development of robust patterns of behavior that enable teams to behave in a responsive and effective manner
The recent work of Nalepka and colleagues [15,16,54,55] on multiagent shepherding provides an excellent example of how a dynamical perceptual-motor primitive (DPMP) based task/behavioral dynamics approach can provide a rich understating of individual and multiagent perceptual-motor behavior
The presence of subsequent Hopf bifurcations reflect the realization of this latent dynamic and its exploitation, as well as evidence that the appropriate control law has been learned. Note that this interpretation of the nonlinear phenomena exhibited by human participants assumes that the transition between search and recover (S&R) and coupled oscillatory containment (COC) behavior is the result of a change in the parameter-dynamics that lead to a Hopf bifurcation
Summary
A differentiating factor between novice and expert teams is the development of robust patterns of behavior that enable teams to behave in a responsive and effective manner. The development of such patterns, or coordinative structures [1], within multiagent settings reflects the formation of an interpersonal or multiagent synergy [2]. As we detail is that these perceptual-motor behaviors is reflect twoperceptual-motor elemental behaviors of nonlinear dynamical below, the corresponding implication that the these behaviors reflect the two systems, fixed-point (discrete)dynamical and limit cycle (rhythmic) behaviors. The cycle task elementalnamely, behaviors of nonlinear systems, namely, fixed-point (discrete) andcan limit dynamics complex human be modelled using human these dynamical primitives,. About the realization and development of robust and effective behavioral actions
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