STDP in recurrent neuronal networks

M Gilson; A Burkitt; J Leo van Hemmen

Journal article

STDP in recurrent neuronal networks

M Gilson, A Burkitt, J Leo van Hemmen

Frontiers in Computational Neuroscience | Published : 2010

DOI: 10.3389/fncom.2010.00023

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Abstract

Recent results about spike-timing-dependent plasticity (STDP) in recurrently connected neurons are reviewed, with a focus on the relationship between the weight dynamics and the emergence of network structure. In particular, the evolution of synaptic weights in the two cases of incoming connections for a single neuron and recurrent connections are compared and contrasted. A theoretical framework is used that is based upon Poisson neurons with a temporally inhomogeneous firing rate and the asymptotic distribution of weights generated by the learning dynamics. Different network configurations examined in recent studies are discussed and an overview of the current understanding of STDP in recur..

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University of Melbourne Researchers

Anthony Burkitt Author

Related Projects (2)

Understanding cortical processing: Neuronal activity and learning in recurrently connected networks

This project addresses fundamental cross-disciplinary issues of information processing and control in large-scale biological neural systems...

Temporal Pattern Learning and Recognition in Neural Systems

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Grants

Awarded by Australian Research Council

Funding Acknowledgements

Matthieu Gilson was funded by scholarships from the University of Melbourne and NICTA. J. Leo van Hemmen is partially supported by the BCCN-Munich. Funding is acknowledged from the Australian Research Council (ARC Discovery Projects #DP0771815 and #DP1096699). The Bionic Ear Institute acknowledges the support it receives from the Victorian Government through its Operational Infrastructure Support Program.