Dynamics of learning in coupled oscillators tutored with delayed reinforcements

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In this work we analyze the solutions of a simple system of coupled phase oscillators in which the connectivity is learned dynamically. The model is inspired by the process of learning of birdsongs by oscine birds. An oscillator acts as the generator of a basic rhythm and drives slave oscillators wh...

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Autores principales: Trevisan, M.A., Bouzat, S., Samengo, I., Mindlin, G.B.
Formato: JOUR
Materias:
Coupling coefficients
Learning schemes
Oscine birds
Mathematical models
Oscillators (electronic)
Signal processing
Learning systems
animal
animal behavior
biological model
biophysics
bird
learning
memory
metabolism
nerve cell
nerve cell network
oscillometry
procedures
songbird
statistical model
teaching
time
Animals
Behavior, Animal
Biophysics
Birds
Learning
Memory
Models, Neurological
Models, Statistical
Nerve Net
Neurons
Oscillometry
Songbirds
Teaching
Time Factors
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_15393755_v72_n1_p_Trevisan
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_15393755_v72_n1_p_Trevisan
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spelling todo:paper_15393755_v72_n1_p_Trevisan2023-10-03T16:22:07Z Dynamics of learning in coupled oscillators tutored with delayed reinforcements Trevisan, M.A. Bouzat, S. Samengo, I. Mindlin, G.B. Coupling coefficients Learning schemes Oscine birds Mathematical models Oscillators (electronic) Signal processing Learning systems animal animal behavior biological model biophysics bird learning memory metabolism nerve cell nerve cell network oscillometry procedures songbird statistical model teaching time Animals Behavior, Animal Biophysics Birds Learning Memory Models, Neurological Models, Statistical Nerve Net Neurons Oscillometry Songbirds Teaching Time Factors In this work we analyze the solutions of a simple system of coupled phase oscillators in which the connectivity is learned dynamically. The model is inspired by the process of learning of birdsongs by oscine birds. An oscillator acts as the generator of a basic rhythm and drives slave oscillators which are responsible for different motor actions. The driving signal arrives at each driven oscillator through two different pathways. One of them is a direct pathway. The other one is a reinforcement pathway, through which the signal arrives delayed. The coupling coefficients between the driving oscillator and the slave ones evolve in time following a Hebbian-like rule. We discuss the conditions under which a driven oscillator is capable of learning to lock to the driver. The resulting phase difference and connectivity are a function of the delay of the reinforcement. Around some specific delays, the system is capable of generating dramatic changes in the phase difference between the driver and the driven systems. We discuss the dynamical mechanism responsible for this effect and possible applications of this learning scheme. © 2005 The American Physical Society. Fil:Trevisan, M.A. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Samengo, I. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_15393755_v72_n1_p_Trevisan
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Coupling coefficients
Learning schemes
Oscine birds
Mathematical models
Oscillators (electronic)
Signal processing
Learning systems
animal
animal behavior
biological model
biophysics
bird
learning
memory
metabolism
nerve cell
nerve cell network
oscillometry
procedures
songbird
statistical model
teaching
time
Animals
Behavior, Animal
Biophysics
Birds
Learning
Memory
Models, Neurological
Models, Statistical
Nerve Net
Neurons
Oscillometry
Songbirds
Teaching
Time Factors
spellingShingle Coupling coefficients
Learning schemes
Oscine birds
Mathematical models
Oscillators (electronic)
Signal processing
Learning systems
animal
animal behavior
biological model
biophysics
bird
learning
memory
metabolism
nerve cell
nerve cell network
oscillometry
procedures
songbird
statistical model
teaching
time
Animals
Behavior, Animal
Biophysics
Birds
Learning
Memory
Models, Neurological
Models, Statistical
Nerve Net
Neurons
Oscillometry
Songbirds
Teaching
Time Factors
Trevisan, M.A.
Bouzat, S.
Samengo, I.
Mindlin, G.B.
Dynamics of learning in coupled oscillators tutored with delayed reinforcements
topic_facet Coupling coefficients
Learning schemes
Oscine birds
Mathematical models
Oscillators (electronic)
Signal processing
Learning systems
animal
animal behavior
biological model
biophysics
bird
learning
memory
metabolism
nerve cell
nerve cell network
oscillometry
procedures
songbird
statistical model
teaching
time
Animals
Behavior, Animal
Biophysics
Birds
Learning
Memory
Models, Neurological
Models, Statistical
Nerve Net
Neurons
Oscillometry
Songbirds
Teaching
Time Factors
description In this work we analyze the solutions of a simple system of coupled phase oscillators in which the connectivity is learned dynamically. The model is inspired by the process of learning of birdsongs by oscine birds. An oscillator acts as the generator of a basic rhythm and drives slave oscillators which are responsible for different motor actions. The driving signal arrives at each driven oscillator through two different pathways. One of them is a direct pathway. The other one is a reinforcement pathway, through which the signal arrives delayed. The coupling coefficients between the driving oscillator and the slave ones evolve in time following a Hebbian-like rule. We discuss the conditions under which a driven oscillator is capable of learning to lock to the driver. The resulting phase difference and connectivity are a function of the delay of the reinforcement. Around some specific delays, the system is capable of generating dramatic changes in the phase difference between the driver and the driven systems. We discuss the dynamical mechanism responsible for this effect and possible applications of this learning scheme. © 2005 The American Physical Society.
format JOUR
author Trevisan, M.A.
Bouzat, S.
Samengo, I.
Mindlin, G.B.
author_facet Trevisan, M.A.
Bouzat, S.
Samengo, I.
Mindlin, G.B.
author_sort Trevisan, M.A.
title Dynamics of learning in coupled oscillators tutored with delayed reinforcements
title_short Dynamics of learning in coupled oscillators tutored with delayed reinforcements
title_full Dynamics of learning in coupled oscillators tutored with delayed reinforcements
title_fullStr Dynamics of learning in coupled oscillators tutored with delayed reinforcements
title_full_unstemmed Dynamics of learning in coupled oscillators tutored with delayed reinforcements
title_sort dynamics of learning in coupled oscillators tutored with delayed reinforcements
url http://hdl.handle.net/20.500.12110/paper_15393755_v72_n1_p_Trevisan
work_keys_str_mv AT trevisanma dynamicsoflearningincoupledoscillatorstutoredwithdelayedreinforcements
AT bouzats dynamicsoflearningincoupledoscillatorstutoredwithdelayedreinforcements
AT samengoi dynamicsoflearningincoupledoscillatorstutoredwithdelayedreinforcements
AT mindlingb dynamicsoflearningincoupledoscillatorstutoredwithdelayedreinforcements
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