The paper systematically analyzes the properties of a spiking neural network model that is analytically derived from the principles of efficient coding. The key findings are:
The optimal network has biologically-plausible features, including realistic integrate-and-fire spiking dynamics, spike-triggered adaptation, and structured recurrent connectivity that implements feature-specific competition between excitatory neurons.
The optimal network has a 4:1 ratio of excitatory to inhibitory neurons and a 3:1 ratio of mean inhibitory-to-inhibitory vs. excitatory-to-inhibitory connectivity, closely matching experimental observations in cortical sensory networks.
The efficient network exhibits a tight instantaneous balance between excitation and inhibition, enabling efficient coding of external stimuli varying over multiple timescales.
The structure of recurrent connectivity, particularly the excitatory-to-inhibitory and inhibitory-to-excitatory connections, is crucial for achieving efficient coding and implementing feature-specific lateral inhibition.
The metabolic cost parameter controls the operating regime of the network, modulating firing rates, variability, and the balance between excitation and inhibition.
The model makes quantitative predictions about experimentally measurable structural, coding, and dynamical features of neural activity that emerge from efficient coding principles.
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by Koren,V., Bl... a las www.biorxiv.org 04-27-2024
https://www.biorxiv.org/content/10.1101/2024.04.24.590955v1Consultas más profundas