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In April 2016 Manchester eScholar was replaced by the University of Manchester’s new Research Information Management System, Pure. In the autumn the University’s research outputs will be available to search and browse via a new Research Portal. Until then the University’s full publication record can be accessed via a temporary portal and the old eScholar content is available to search and browse via this archive.

Plasticity in large-scale neuromorphic models of the neocortex

Knight, James Courtney

[Thesis]. Manchester, UK: The University of Manchester; 2016.

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Abstract

The neocortex is the most recently evolved part of the mammalian brain and enables the intelligent, adaptable behaviour that has allowed mammals to conquer much of planet earth. The human neocortex consists of a thin sheet of neural tissue containing approximately 20*10^9 neurons. These neurons are connected by a dense network of highly plastic synapses whose efficacy and structure constantly change in response to internal and external stimuli. Understanding exactly how we perceive the world, plan our actions and use language, using this computational substrate, is one of the grand challenges of computing research. One of the ways to address this challenge is to build and simulate neural systems, an approach neuromorphic systems such as SpiNNaker are designed to enable.The basic computational unit of a SpiNNaker system is a general-purpose ARM processor, which allows it to be programmed to simulate a wide variety of neuron and synapse models. This flexibility is particularly valuable in the study of synaptic plasticity, which has been described using a plethora of models. In this thesis I present a new SpiNNaker synaptic plasticity implementation and, using this, develop a neocortically-inspired model of temporal sequence learning consisting of 2*10^4 neurons and 5.1*10^7 plastic synapses: the largest plastic neural network ever to be simulated on neuromorphic hardware. I then identify several problems that occur when using existing approaches to simulate such models on SpiNNaker before presenting a new, more flexible approach. This new approach not only solves many of these problems but also suggests directions for architectural improvements in future neuromorphic systems.

Additional content not available electronically

Synapse-centric SpiNNaker simulation software (Chapter 6): https://github.com/project-rig/pynn_spinnakerBayesian Confidence Propagation Neural Network plasticty implementation (Chapter 5): https://github.com/project-rig/pynn_spinnaker_bcpnn

Keyword(s)

Plasticity; SpiNNaker

Bibliographic metadata

Type of resource:
Content type:
Administered thesis
Form of thesis:
Traditional
Type of submission:
Doctoral level ETD - final
Thesis title:
Plasticity in large-scale neuromorphic models of the neocortex
Degree type:
Doctor of Philosophy
Degree programme:
PhD Computer Science
Publication date:
2016-12-19T13:41:44
Institution:
The University of Manchester
Location:
Manchester, UK
Total pages:
169
Abstract:
The neocortex is the most recently evolved part of the mammalian brain and enables the intelligent, adaptable behaviour that has allowed mammals to conquer much of planet earth. The human neocortex consists of a thin sheet of neural tissue containing approximately 20*10^9 neurons. These neurons are connected by a dense network of highly plastic synapses whose efficacy and structure constantly change in response to internal and external stimuli. Understanding exactly how we perceive the world, plan our actions and use language, using this computational substrate, is one of the grand challenges of computing research. One of the ways to address this challenge is to build and simulate neural systems, an approach neuromorphic systems such as SpiNNaker are designed to enable.The basic computational unit of a SpiNNaker system is a general-purpose ARM processor, which allows it to be programmed to simulate a wide variety of neuron and synapse models. This flexibility is particularly valuable in the study of synaptic plasticity, which has been described using a plethora of models. In this thesis I present a new SpiNNaker synaptic plasticity implementation and, using this, develop a neocortically-inspired model of temporal sequence learning consisting of 2*10^4 neurons and 5.1*10^7 plastic synapses: the largest plastic neural network ever to be simulated on neuromorphic hardware. I then identify several problems that occur when using existing approaches to simulate such models on SpiNNaker before presenting a new, more flexible approach. This new approach not only solves many of these problems but also suggests directions for architectural improvements in future neuromorphic systems.
Additional digital content not deposited electronically:
Synapse-centric SpiNNaker simulation software (Chapter 6): https://github.com/project-rig/pynn_spinnakerBayesian Confidence Propagation Neural Network plasticty implementation (Chapter 5): https://github.com/project-rig/pynn_spinnaker_bcpnn
Keyword(s):
Thesis main supervisor(s):
Thesis co-supervisor(s):
Degree grantor:
Language:
en

Institutional metadata

University researcher(s):
Academic department(s):

Record metadata

Manchester eScholar ID:
uk-ac-man-scw:306282
Created by:
Knight, James
Created:
19th December, 2016, 13:41:44
Last modified by:
Knight, James
Last modified:
3rd November, 2017, 11:17:00

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