Balanced Excitation and Inhibition are Required for High-Capacity, Noise-Robust Neuronal Selectivity
May 03, 2017 Β· Declared Dead Β· π Proceedings of the National Academy of Sciences of the United States of America
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Authors
Ran Rubin, L. F. Abbott, Haim Sompolinsky
arXiv ID
1705.01502
Category
q-bio.NC
Cross-listed
cond-mat.dis-nn,
cs.LG,
cs.NE,
stat.ML
Citations
117
Venue
Proceedings of the National Academy of Sciences of the United States of America
Last Checked
4 months ago
Abstract
Neurons and networks in the cerebral cortex must operate reliably despite multiple sources of noise. To evaluate the impact of both input and output noise, we determine the robustness of single-neuron stimulus selective responses, as well as the robustness of attractor states of networks of neurons performing memory tasks. We find that robustness to output noise requires synaptic connections to be in a balanced regime in which excitation and inhibition are strong and largely cancel each other. We evaluate the conditions required for this regime to exist and determine the properties of networks operating within it. A plausible synaptic plasticity rule for learning that balances weight configurations is presented. Our theory predicts an optimal ratio of the number of excitatory and inhibitory synapses for maximizing the encoding capacity of balanced networks for a given statistics of afferent activations. Previous work has shown that balanced networks amplify spatio-temporal variability and account for observed asynchronous irregular states. Here we present a novel type of balanced network that amplifies small changes in the impinging signals, and emerges automatically from learning to perform neuronal and network functions robustly.
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