<p><b>A</b>: Distribution of firing rates of excitatory neurons. The magenta line shows a log-normal fit. <b>B</b>: Distribution of excitatory-excitatory synaptic weights. The magenta line shows a power-law fit to the middle part of the distribution. <b>C</b>: Distribution of inhibitory-excitatory synaptic weights. The dashed line indicates the mean. <b>D</b>: Evolution of excitatory-excitatory and inhibitory-excitatory weight means and variances.</p
<p>Summary histograms and scatter plots of the distributions of firing rate (<b>A</b>) and regularit...
<p>(A) Time courses of the mean synaptic weight <i>S</i>(<i>t</i>) for different CR stimulation inte...
<p>(<b>A</b>) Evolution of the synaptic weight distribution over 8 h of background activity. (<b>B</...
<p>The graphs show the relative excitability as a function of the additional synaptic input per ne...
<p>Distribution of synaptic weights for different connection types: feedforward (left), feedback (mi...
<p><b>(A)</b> Initial connectivity matrix of the random network. Each excitatory neuron is connected...
<p>Top panels: a) Two self-similar Gaussian synaptic weight distributions. b) The distribution of th...
<p>The asymptotic value of the homogeneous inhibitory synaptic weight is shown as a function of the ...
<p>Distribution of synaptic weights for three different connection types: feedforward (left), feedba...
A. The steady state E/I weight ratio as a function of the presynaptic excitatory rate ρE. Inset: RE...
<p><b>(A)</b> Evolution of synaptic weights in the network during plasticity. After each batch of le...
<p>The learning dynamics of a population of inhibitory and excitatory presynaptic neurons was simu...
<p>A: example traces of different synaptic weights. B: distribution of life times of newly created s...
<p>Each dot represents a synaptic weight on a linear scale such that white and black correspond to 0...
<p>(A) The non-zero inhibitory synaptic weights in the RPCA model have a near log-normal distributio...
<p>Summary histograms and scatter plots of the distributions of firing rate (<b>A</b>) and regularit...
<p>(A) Time courses of the mean synaptic weight <i>S</i>(<i>t</i>) for different CR stimulation inte...
<p>(<b>A</b>) Evolution of the synaptic weight distribution over 8 h of background activity. (<b>B</...
<p>The graphs show the relative excitability as a function of the additional synaptic input per ne...
<p>Distribution of synaptic weights for different connection types: feedforward (left), feedback (mi...
<p><b>(A)</b> Initial connectivity matrix of the random network. Each excitatory neuron is connected...
<p>Top panels: a) Two self-similar Gaussian synaptic weight distributions. b) The distribution of th...
<p>The asymptotic value of the homogeneous inhibitory synaptic weight is shown as a function of the ...
<p>Distribution of synaptic weights for three different connection types: feedforward (left), feedba...
A. The steady state E/I weight ratio as a function of the presynaptic excitatory rate ρE. Inset: RE...
<p><b>(A)</b> Evolution of synaptic weights in the network during plasticity. After each batch of le...
<p>The learning dynamics of a population of inhibitory and excitatory presynaptic neurons was simu...
<p>A: example traces of different synaptic weights. B: distribution of life times of newly created s...
<p>Each dot represents a synaptic weight on a linear scale such that white and black correspond to 0...
<p>(A) The non-zero inhibitory synaptic weights in the RPCA model have a near log-normal distributio...
<p>Summary histograms and scatter plots of the distributions of firing rate (<b>A</b>) and regularit...
<p>(A) Time courses of the mean synaptic weight <i>S</i>(<i>t</i>) for different CR stimulation inte...
<p>(<b>A</b>) Evolution of the synaptic weight distribution over 8 h of background activity. (<b>B</...