Tuning network dynamics from criticality to the chaotic balanced state

Abstract: According to many experimental observations, neurons in cerebral cortex tend to operate in an asynchronous regime, firing independently of each other. In contrast, many other experimental observations reveal cortical population firing dynamics that are relatively coordinated and occasionally synchronous. These discrepant observations have naturally led to a lively debate surrounding discrepant hypotheses. A commonly hypothesized explanation of asynchronous firing is that excitatory and inhibitory neurons are p… Show more

“…This typically involves stochastic processes, such as (probabilistic) cellular automata [8][9][10], contact processes [10,11], or interacting Hawkes processes [12]. In particular, infectious diseases have been modeled by so-called susceptible-infectious models or generalizations thereof [13], whereas spikepropagation in neural networks has been modeled by socalled branching networks [14][15][16][17][18][19][20][21][22], Hawkes processes [23][24][25], or probabilistic integrate-and-fire networks [26,27]. These models can be either constructed as independentinteraction models (static interactions), or as threshold models with interactions depending on the states of the interacting partners [28].…”

Description of spreading dynamics by microscopic network models and macroscopic branching processes can differ due to coalescence

“…This typically involves stochastic processes, such as (probabilistic) cellular automata [8][9][10], contact processes [10,11], or interacting Hawkes processes [12]. In particular, infectious diseases have been modeled by so-called susceptible-infectious models or generalizations thereof [13], whereas spikepropagation in neural networks has been modeled by socalled branching networks [14][15][16][17][18][19][20][21][22], Hawkes processes [23][24][25], or probabilistic integrate-and-fire networks [26,27]. These models can be either constructed as independentinteraction models (static interactions), or as threshold models with interactions depending on the states of the interacting partners [28].…”

Description of spreading dynamics by microscopic network models and macroscopic branching processes can differ due to coalescence