Add to ORKGa b s t r a c t We study the dynamical stability of pulse coupled networks of leaky integrate-and-fire neurons against infinitesimal and finite perturbations. In particular, we compare mean versus fluctuations driven networks, the former (latter) is realized by considering purely excitatory (inhibitory) sparse neural circuits. In the excitatory case the instabilities of the system can be completely captured by an usual linear stability (Lyapunov) analysis, whereas the inhibitory networks can display the coexistence of linear and nonlinear instabilities. The nonlinear effects are associated to finite amplitude instabilities, which have been characterized in terms of suitable indicators. For inhibitory coupling one observes a transition from ...
Large networks of sparsely coupled, excitatory and inhibitory cells occur throughout the brain. For ...
We present a generic model that generates long-range (power-law) temporal correlations, 1/f noise, a...
Dynamic excitatory-inhibitory (E-I) balance is a paradigmatic mechanism invoked to explain the irreg...
Recurrent networks of non-linear units display a variety of dynamical regimes depending on the struc...
Firing patterns in the central nervous system often exhibit strong temporal irregularity and conside...
Large sparse circuits of spiking neurons exhibit a balanced state of highly irregular activity under...
Large sparse circuits of spiking neurons exhibit a balanced state of highly irregular activity under...
Neuronal activity in the central nervous system varies strongly in time and across neuronal populati...
Neuronal activity in the central nervous system varies strongly in time and across neuronal populati...
The irregular activity of neurons in the cortex [1] is thought to arise from strong input fluctuatio...
The brain processes sensory information about the outside world in large complex networks of neurons...
<div><p>The brain exhibits temporally complex patterns of activity with features similar to those of...
The study of balanced networks of excitatory and inhibitory neurons has led to several open question...
Is a periodic orbit underlying a periodic pattern of spikes in a heterogeneous neural network stable...
Open Access via the AIP Agreement ACKNOWLEDGMENTS Afifurrahman was supported by the Ministry of Fina...
Large networks of sparsely coupled, excitatory and inhibitory cells occur throughout the brain. For ...
We present a generic model that generates long-range (power-law) temporal correlations, 1/f noise, a...
Dynamic excitatory-inhibitory (E-I) balance is a paradigmatic mechanism invoked to explain the irreg...
Recurrent networks of non-linear units display a variety of dynamical regimes depending on the struc...
Firing patterns in the central nervous system often exhibit strong temporal irregularity and conside...
Large sparse circuits of spiking neurons exhibit a balanced state of highly irregular activity under...
Large sparse circuits of spiking neurons exhibit a balanced state of highly irregular activity under...
Neuronal activity in the central nervous system varies strongly in time and across neuronal populati...
Neuronal activity in the central nervous system varies strongly in time and across neuronal populati...
The irregular activity of neurons in the cortex [1] is thought to arise from strong input fluctuatio...
The brain processes sensory information about the outside world in large complex networks of neurons...
<div><p>The brain exhibits temporally complex patterns of activity with features similar to those of...
The study of balanced networks of excitatory and inhibitory neurons has led to several open question...
Is a periodic orbit underlying a periodic pattern of spikes in a heterogeneous neural network stable...
Open Access via the AIP Agreement ACKNOWLEDGMENTS Afifurrahman was supported by the Ministry of Fina...
Large networks of sparsely coupled, excitatory and inhibitory cells occur throughout the brain. For ...
We present a generic model that generates long-range (power-law) temporal correlations, 1/f noise, a...
Dynamic excitatory-inhibitory (E-I) balance is a paradigmatic mechanism invoked to explain the irreg...