Abstract
Several hybrid spiking neuron models combining continuous spike generation mechanisms and discontinuous resetting processes following spiking have been proposed. The Izhikevich neuron model, for example, can reproduce many spiking patterns. This model clearly possesses various types of bifurcations and routes to chaos under the effect of a state-dependent jump in the resetting process. In this study, we focus further on the relation between chaotic behaviour and the state-dependent jump, approaching the subject by comparing spiking neuron model versions with and without the resetting process. We first adopt a continuous two-dimensional spiking neuron model in which the orbit in the spiking state does not exhibit divergent behaviour. We then insert the resetting process into the model. An evaluation using the Lyapunov exponent with a saltation matrix and a characteristic multiplier of the Poincar’e map reveals that two types of chaotic behaviour (i.e. bursting chaotic spikes and near-period-two chaotic spikes) are induced by the resetting process. In addition, we confirm that this chaotic bursting state is generated from the periodic spiking state because of the slow- and fast-scale dynamics that arise when jumping to the hyperpolarization and depolarization regions, respectively.
Highlights
Many types of neural coding are known to exist in brain/nerve system adaptive information processing1
The Izhikevich neuron model can reproduce most spiking activities observed in actual neural systems by tuning a few parameters, including those relating to the resetting process13,14
Utilising a rigorous method to analyse the bifurcation and chaos in hybrid systems, we evaluate several routes to chaos, which cannot be achieved in a hybridised FitzHugh–Nagumo neuron model33, by changing the resetting process parameters and comparing the structure of the attractor between the system versions with and without the resetting process
Summary
Many types of neural coding (for e.g., rate, temporal, and population coding) are known to exist in brain/nerve system adaptive information processing1. The state-dependent jump induced by Eq [4] converges to a continuous trajectory under the condition vr → vpeak and d → 0 in the case which vpeak is set to a maximum value of v for the orbit of the continuous spiking neuron model given by Eqs [1] and [3].
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