Liquid computing on and off the edge of chaos with a striatal microcircuit

Liquid computing on and off the edge of chaos with a striatal microcircuit

In reinforcement learning theories of the basal ganglia, there is a need for the expected rewards corresponding to relevant environmental states to be maintained and modified during the learning process. However, the representation of these states that allows them to be associated with reward expect...

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Main Authors: Carlos eToledo-Suárez, Renato eDuarte, Abigail eMorrison
Format: Article
Language:English
Published: Frontiers Media S.A. 2014-11-01
Series:Frontiers in Computational Neuroscience
Subjects:
simulation
Striatum
Liquid State Machines
edge of chaos
State Representation
Online Access:http://journal.frontiersin.org/Journal/10.3389/fncom.2014.00130/full
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spelling doaj-d4edcb1b33f04c679e700c6793be6b372020-11-24T21:28:33ZengFrontiers Media S.A.Frontiers in Computational Neuroscience1662-51882014-11-01810.3389/fncom.2014.0013066301Liquid computing on and off the edge of chaos with a striatal microcircuitCarlos eToledo-Suárez0Carlos eToledo-Suárez1Carlos eToledo-Suárez2Renato eDuarte3Renato eDuarte4Renato eDuarte5Renato eDuarte6Abigail eMorrison7Abigail eMorrison8Abigail eMorrison9Bernstein Center FreiburgFaculty of BiologyDepartment of Computational BiologyInstitute for Advanced Simulation (IAS-6) and Institute of Neuroscience and Medicine (INM-6)Bernstein Center FreiburgFaculty of BiologyUniversity of EdinburghInstitute for Advanced Simulation (IAS-6) and Institute of Neuroscience and Medicine (INM-6)Institute of Cognitive NeuroscienceBernstein Center FreiburgIn reinforcement learning theories of the basal ganglia, there is a need for the expected rewards corresponding to relevant environmental states to be maintained and modified during the learning process. However, the representation of these states that allows them to be associated with reward expectations remains unclear. Previous studies have tended to rely on pre-defined partitioning of states encoded by disjunct neuronal groups or sparse topological drives. A more likely scenario is that striatal neurons are involved in the encoding of multiple different states through their spike patterns, and that an appropriate partitioning of an environment is learned on the basis of task constraints, thus minimizing the number of states involved in solving a particular task. Here we show that striatal activity is sufficient to implement a liquid state, an important prerequisite for such a computation, whereby transient patterns of striatal activity are mapped onto the relevant states. We develop a simple small scale model of the striatum which can reproduce key features of the experimentally observed activity of the major cell types of the striatum. We then use the activity of this network as input for the supervised training of four simple linear readouts to learn three different functions on a plane, where the network is stimulated with the spike coded position of the agent. We discover that the network configuration that best reproduces striatal activity statistics lies on the edge of chaos and has good performance on all three tasks, but that in general, the edge of chaosis a poor predictor of network performance.http://journal.frontiersin.org/Journal/10.3389/fncom.2014.00130/fullsimulationStriatumLiquid State Machinesedge of chaosState Representation
collection DOAJ
language English
format Article
sources DOAJ
author Carlos eToledo-Suárez
Carlos eToledo-Suárez
Carlos eToledo-Suárez
Renato eDuarte
Renato eDuarte
Renato eDuarte
Renato eDuarte
Abigail eMorrison
Abigail eMorrison
Abigail eMorrison
spellingShingle Carlos eToledo-Suárez
Carlos eToledo-Suárez
Carlos eToledo-Suárez
Renato eDuarte
Renato eDuarte
Renato eDuarte
Renato eDuarte
Abigail eMorrison
Abigail eMorrison
Abigail eMorrison
Liquid computing on and off the edge of chaos with a striatal microcircuit
Frontiers in Computational Neuroscience
simulation
Striatum
Liquid State Machines
edge of chaos
State Representation
author_facet Carlos eToledo-Suárez
Carlos eToledo-Suárez
Carlos eToledo-Suárez
Renato eDuarte
Renato eDuarte
Renato eDuarte
Renato eDuarte
Abigail eMorrison
Abigail eMorrison
Abigail eMorrison
author_sort Carlos eToledo-Suárez
title Liquid computing on and off the edge of chaos with a striatal microcircuit
title_short Liquid computing on and off the edge of chaos with a striatal microcircuit
title_full Liquid computing on and off the edge of chaos with a striatal microcircuit
title_fullStr Liquid computing on and off the edge of chaos with a striatal microcircuit
title_full_unstemmed Liquid computing on and off the edge of chaos with a striatal microcircuit
title_sort liquid computing on and off the edge of chaos with a striatal microcircuit
publisher Frontiers Media S.A.
series Frontiers in Computational Neuroscience
issn 1662-5188
publishDate 2014-11-01
description In reinforcement learning theories of the basal ganglia, there is a need for the expected rewards corresponding to relevant environmental states to be maintained and modified during the learning process. However, the representation of these states that allows them to be associated with reward expectations remains unclear. Previous studies have tended to rely on pre-defined partitioning of states encoded by disjunct neuronal groups or sparse topological drives. A more likely scenario is that striatal neurons are involved in the encoding of multiple different states through their spike patterns, and that an appropriate partitioning of an environment is learned on the basis of task constraints, thus minimizing the number of states involved in solving a particular task. Here we show that striatal activity is sufficient to implement a liquid state, an important prerequisite for such a computation, whereby transient patterns of striatal activity are mapped onto the relevant states. We develop a simple small scale model of the striatum which can reproduce key features of the experimentally observed activity of the major cell types of the striatum. We then use the activity of this network as input for the supervised training of four simple linear readouts to learn three different functions on a plane, where the network is stimulated with the spike coded position of the agent. We discover that the network configuration that best reproduces striatal activity statistics lies on the edge of chaos and has good performance on all three tasks, but that in general, the edge of chaosis a poor predictor of network performance.
topic simulation
Striatum
Liquid State Machines
edge of chaos
State Representation
url http://journal.frontiersin.org/Journal/10.3389/fncom.2014.00130/full
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