We study a model of spiking neurons, with recurrent connections that result from learning a set of spatio-temporal patterns with a spike-timing dependent plasticity rule and a global inhibition. We investigate the ability of the network to store and selectively replay multiple patterns of spikes, with a combination of spatial population and phase-of-spike code. Each neuron in a pattern is characterized by a binary variable determining if the neuron is active in the pattern, and a phase-lag variable representing the spike-timing order among the active units. After the learning stage, we study the dynamics of the network induced by a brief cue stimulation, and verify that the network is able to selectively replay the pattern correctly and per...
In this paper, we consider networks of deterministic spiking neurons, firing synchronously at discre...
Neurons spike on a millisecond time scale while behaviour typically spans hundreds of milliseconds t...
The most biologically-inspired artificial neurons are those of the third generation, and are termed ...
We study a model of spiking neurons, with recurrent connections that result from learning a set of s...
SCOPUS=eid=2-s2.0-80052989624 We study the storage and retrieval of phase-coded patterns as stable ...
We study the collective dynamics of a Leaky Integrate and Fire network in which precise relative pha...
© 2017 IEEE. In this work the model of a spiking recurrent neural network where any pair of neurons ...
It has previously been shown that by using spike-timing-dependent plasticity (STDP), neurons can ada...
International audienceCompelling behavioral evidence suggests that humans can make optimal decisions...
Indicizzato scopus: eid=2-s2.0-84867909032 Abstract:We analyse the storage and retrieval capacity i...
It is well accepted that the brain's computation relies on spatiotemporal activity of neural network...
Storing and recalling spiking sequences is a general problem the brain needs to solve. It is, howeve...
<p>It has previously been shown that by using spike-timing-dependent plasticity, neurons can adapt t...
In this paper, we consider networks of deterministic spiking neurons, firing synchronously at discre...
Neurons spike on a millisecond time scale while behaviour typically spans hundreds of milliseconds t...
The most biologically-inspired artificial neurons are those of the third generation, and are termed ...
We study a model of spiking neurons, with recurrent connections that result from learning a set of s...
SCOPUS=eid=2-s2.0-80052989624 We study the storage and retrieval of phase-coded patterns as stable ...
We study the collective dynamics of a Leaky Integrate and Fire network in which precise relative pha...
© 2017 IEEE. In this work the model of a spiking recurrent neural network where any pair of neurons ...
It has previously been shown that by using spike-timing-dependent plasticity (STDP), neurons can ada...
International audienceCompelling behavioral evidence suggests that humans can make optimal decisions...
Indicizzato scopus: eid=2-s2.0-84867909032 Abstract:We analyse the storage and retrieval capacity i...
It is well accepted that the brain's computation relies on spatiotemporal activity of neural network...
Storing and recalling spiking sequences is a general problem the brain needs to solve. It is, howeve...
<p>It has previously been shown that by using spike-timing-dependent plasticity, neurons can adapt t...
In this paper, we consider networks of deterministic spiking neurons, firing synchronously at discre...
Neurons spike on a millisecond time scale while behaviour typically spans hundreds of milliseconds t...
The most biologically-inspired artificial neurons are those of the third generation, and are termed ...