Attractor Metadynamics in Adapting Neural Networks
This provides a tool for understanding neural dynamics development, but it is incremental as it builds on existing concepts of attractor landscapes in neuroscience.
The paper investigates how slow adaptation processes in neural networks, termed attractor metadynamics, shape the evolving attractor landscape over time, finding both first- and second-order changes in attractor locations in continuous-time autonomous models.
Slow adaption processes, like synaptic and intrinsic plasticity, abound in the brain and shape the landscape for the neural dynamics occurring on substantially faster timescales. At any given time the network is characterized by a set of internal parameters, which are adapting continuously, albeit slowly. This set of parameters defines the number and the location of the respective adiabatic attractors. The slow evolution of network parameters hence induces an evolving attractor landscape, a process which we term attractor metadynamics. We study the nature of the metadynamics of the attractor landscape for several continuous-time autonomous model networks. We find both first- and second-order changes in the location of adiabatic attractors and argue that the study of the continuously evolving attractor landscape constitutes a powerful tool for understanding the overall development of the neural dynamics.