2011
NIPS
NeurIPS 2011
Sequence learning with hidden units in spiking neural networks
Abstract
We consider a statistical framework in which recurrent networks of spiking neurons learn to generate spatio-temporal spike patterns. Given biologically realistic stochastic neuronal dynamics we derive a tractable learning rule for the synaptic weights towards hidden and visible neurons that leads to optimal recall of the training sequences. We show that learning synaptic weights towards hidden neurons significantly improves the storing capacity of the network. Furthermore, we derive an approximate online learning rule and show that our learning rule is consistent with Spike-Timing Dependent Plasticity in that if a presynaptic spike shortly precedes a postynaptic spike, potentiation is induced and otherwise depression is elicited.
🌉
Interdisciplinary Bridge
— Deep Learning and Machine Learning
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Keyword Pioneer
— spike-timing dependent plasticity
🐝
Cross-Pollinator
— Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Speech & Audio
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Trend Setter
— Sequence Modeling
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Hot Topic Early Bird
— spiking neural network
Authors
Topics
Machine Learning > Core Methods > Representation Learning
Machine Learning > Optimization & Theory > Learning Theory
Deep Learning > Architectures > Neural Networks
Machine Learning > Learning Types > Representation Learning
Machine Learning > Core Methods > Sequence Modeling
Deep Learning > Architectures > Recurrent Neural Networks
Interdisciplinary > Science > Neuroscience