Spike-timing dependent plasticity is a learning mechanism used extensively within neural modelling.
The learning rule has been shown to allow a neuron to find the onset of a spatio-temporal
pattern repeated among its afferents. In this thesis, the first question addressed is ‘what does
this neuron learn?’ With a spiking neuron model and linear prediction, evidence is adduced that
the neuron learns two components: (1) the level of average background activity and (2) specific
spike times of a pattern.
Taking advantage of these findings, a network is developed that can train recognisers for longer
spatio-temporal input signals using spike-timing dependent plasticity. Using a number of neurons
that are mutually connected by plastic synapses and subject to a global winner-takes-all
mechanism, chains of neurons can form where each neuron is selective to a different segment
of a repeating input pattern, and the neurons are feedforwardly connected in such a way that
both the correct stimulus and the firing of the previous neurons are required in order to activate
the next neuron in the chain. This is akin to a simple class of finite state automata.
Following this, a novel resource-based STDP learning rule is introduced. The learning rule
has several advantages over typical implementations of STDP and results in synaptic statistics
which match favourably with those observed experimentally. For example, synaptic weight
distributions and the presence of silent synapses match experimental data.
Date of Award | 2013 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Gayle Letherby (Other Supervisor) |
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- Spike-timing dependent plasticity
- STDP
- Learning
- Spiking neuron
- Neural network
- Homeostasis
- Self-organisation
Learning, self-organisation and homeostasis in spiking neuron networks using spike-timing dependent plasticity
Humble, J. (Author). 2013
Student thesis: PhD