Abstract
Large-scale brain simulations require the investigation of large networks of realistic neuron models, usually represented by sets of differential equations. Here we report a detailed fine-scale study of the dynamical response over extended parameter ranges of a computationally inexpensive model, the two-dimensional Rulkov map, which reproduces well the spiking and spiking-bursting activity of real biological neurons. In addition, we provide evidence of the existence of nested arithmetic progressions among periodic pulsing and bursting phases of Rulkov’s neuron. We find that specific remarkably complex nested sequences of periodic neural oscillations can be expressed as simple linear combinations of pairs of certain basal periodicities. Moreover, such nested progressions are robust and can be observed abundantly in diverse control parameter planes which are described in detail. We believe such findings to add significantly to the knowledge of Rulkov neuron dynamics and to be potentially helpful in large-scale simulations of the brain and other complex neuron networks.
Highlights
Despite the significant progress in neuroscience during the last years, there are still several unveiled questions and mysteries about the brain functionality
Similar to the Hodgkin and Huxley (HH) model, neuron models are usually based on continuous-time differential equations, or on a discrete-time dynamics, i.e. on discrete maps
Among the continuous-time models, one can mention those based on the HH model [6,7], or models taking into account other approaches such as the consideration of relaxation oscillators, emphasizing on bursting behaviors [1,2,8]
Summary
Despite the significant progress in neuroscience during the last years, there are still several unveiled questions and mysteries about the brain functionality. Similar to the HH model, neuron models are usually based on continuous-time differential equations, or on a discrete-time dynamics, i.e. on discrete maps. Among the continuous-time models, one can mention those based on the HH model [6,7], or models taking into account other approaches such as the consideration of relaxation oscillators, emphasizing on bursting behaviors [1,2,8]. The ability to reproduce bursting behavior is one of the main aspects required for realistic neuron models [9,10,11], independently if governed by differential equations [12,13,14,15,16,17] or by maps [18,19,20,21,22,23,24,25,26,27]
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