Neuronal networks exhibit a wide diversity of structures, which contributes to the diversity of the dynamics therein. The presented work applies an information theoretic framework to simultaneously analyze structure and dynamics in neuronal networks. Information diversity within the structure and dynamics of a neuronal network is studied using the normalized compression distance. To describe the structure, a scheme for generating distance-dependent networks with identical in-degree distribution but variable strength of dependence on distance is presented. The resulting network structure classes possess differing path length and clustering coefficient distributions. In parallel, comparable realistic neuronal networks are generated with NETMO...
<p>The diversity of intrinsic dynamics observed in neurons may enhance the computations implemented ...
Abstract Neurons respond to external stimuli by emitting sequences of action potentials (spike train...
A statement like “$N_\text{s}$ source neurons and $N_\text{t}$ target neurons are connected randomly...
Neuronal networks exhibit a wide diversity of structures, which contributes to the diversity of the ...
<div><p>The question of how the structure of a neuronal network affects its functionality has gained...
Experimental studies of neuronal cultures have revealed a wide variety of spiking network activity r...
We address the problem of estimating the effective connectivity of the brain network, using the inpu...
We define a stochastic neuron as an element that increases its internal state with probability p unt...
We study a model of spiking neurons, with recurrent connections that result from learning a set of s...
Biological neuronal networks constitute a special class of dynamical systems, as they are formed by ...
The representation of the natural-density, heterogeneous connectivity of neuronalnetwork models at r...
We study the effect of learning dynamics on network topology. Firstly, a network of discrete dynamic...
The cerebral cortex exhibits distinct connectivity patterns on different length scales. Long range c...
Neurons compute and communicate by transforming synaptic input patterns into output spike trains. Th...
The representation of the natural-density, heterogeneous connectivity of neuronal network models at ...
<p>The diversity of intrinsic dynamics observed in neurons may enhance the computations implemented ...
Abstract Neurons respond to external stimuli by emitting sequences of action potentials (spike train...
A statement like “$N_\text{s}$ source neurons and $N_\text{t}$ target neurons are connected randomly...
Neuronal networks exhibit a wide diversity of structures, which contributes to the diversity of the ...
<div><p>The question of how the structure of a neuronal network affects its functionality has gained...
Experimental studies of neuronal cultures have revealed a wide variety of spiking network activity r...
We address the problem of estimating the effective connectivity of the brain network, using the inpu...
We define a stochastic neuron as an element that increases its internal state with probability p unt...
We study a model of spiking neurons, with recurrent connections that result from learning a set of s...
Biological neuronal networks constitute a special class of dynamical systems, as they are formed by ...
The representation of the natural-density, heterogeneous connectivity of neuronalnetwork models at r...
We study the effect of learning dynamics on network topology. Firstly, a network of discrete dynamic...
The cerebral cortex exhibits distinct connectivity patterns on different length scales. Long range c...
Neurons compute and communicate by transforming synaptic input patterns into output spike trains. Th...
The representation of the natural-density, heterogeneous connectivity of neuronal network models at ...
<p>The diversity of intrinsic dynamics observed in neurons may enhance the computations implemented ...
Abstract Neurons respond to external stimuli by emitting sequences of action potentials (spike train...
A statement like “$N_\text{s}$ source neurons and $N_\text{t}$ target neurons are connected randomly...