Entrainment of competitive threshold-linear networks
- Autores
- Bel, Andrea Liliana; Rotstein, Horacio; Reartes, Walter A.
- Año de publicación
- 2021
- Idioma
- inglés
- Tipo de recurso
- documento de conferencia
- Estado
- versión publicada
- Descripción
- Neuronal oscillations are ubiquitous in the brain and emerge from the combined activity of the participating neurons (or nodes), the connec- tivity and the network topology. Recent neurotechnological advances have made it possible to interrogate neuronal circuits by perturbing one or more of its nodes. The response to periodic inputs has been used as a tool to identify the oscillatory properties of circuits and the flow of information in networks. However, a general theory that explains the underlying mechanisms and allows to make predictions is lacking beyond the single neuron level. Threshold-linear network (TLN) models describe the activity of con- nected nodes where the contribution of the connectivity terms is lin- ear above some threshold value (typically zero), while the network is disconnected below it. In their simplest description, the dynamics of the individual nodes are one-dimensional and linear. When the nodes in the network are neurons or neuronal populations, their activity can be interpreted as the firing rate, and therefore the TLNs represent fir- ing rate models [1]. Competitive threshold-linear networks (CTLNs) are a class of TLNs where the connectivity weights are all negative and there are no self- connections [2,3]. Inhibitory networks arise in many neuronal systems and have been shown to underlie the generation of rhythmic activity in cognition and motor behavior [4,5]. Despite their simplicity, TLNs and CTLNs produce complex behavior including multistability, peri- odic, quasi-periodic and chaotic solutions [2,3,6]. In this work, we consider CTLNs with three or more nodes and cyclic symmetry in which oscillatory solutions are observed. We first assume that an external oscillatory input is added to one of the nodes and, by defining a Poincaré map, we numerically study the response proper- ties of the CTLN networks. We determine the ranges of input ampli- tude and frequency in which the CTLN is able to follow the input (1:1 entrainment). For this we define local and global entrainment measures that convey different information. We then study how the entrainment properties of the CTLNs is affected by changes in (i) the time scale of each node, (ii) the number of nodes in the network, and (iii) the strength of the inhibitory connections. Finally, we extend our results to include other entrainment scenarios (e.g., 2:1) and other net- work topologies.
Fil: Bel, Andrea Liliana. Universidad Nacional del Sur. Departamento de Matemática; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Unidad de Direccion; Argentina
Fil: Rotstein, Horacio. New Jersey Institute of Technology; Estados Unidos. Rutgers University; Estados Unidos
Fil: Reartes, Walter A.. Universidad Nacional del Sur. Departamento de Matemática; Argentina
29th Annual Computacional Neuroscience Meeting
Online
Estados Unidos
Organization for Computational Neurosciences - Materia
-
THRESHOLD-LINEAR NETWORKS
PERIODIC SOLUTIONS
ENTRAINMENT - Nivel de accesibilidad
- acceso abierto
- Condiciones de uso
- https://creativecommons.org/licenses/by-nc-sa/2.5/ar/
- Repositorio
.jpg)
- Institución
- Consejo Nacional de Investigaciones Científicas y Técnicas
- OAI Identificador
- oai:ri.conicet.gov.ar:11336/259020
Ver los metadatos del registro completo
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Entrainment of competitive threshold-linear networksBel, Andrea LilianaRotstein, HoracioReartes, Walter A.THRESHOLD-LINEAR NETWORKSPERIODIC SOLUTIONSENTRAINMENThttps://purl.org/becyt/ford/1.1https://purl.org/becyt/ford/1Neuronal oscillations are ubiquitous in the brain and emerge from the combined activity of the participating neurons (or nodes), the connec- tivity and the network topology. Recent neurotechnological advances have made it possible to interrogate neuronal circuits by perturbing one or more of its nodes. The response to periodic inputs has been used as a tool to identify the oscillatory properties of circuits and the flow of information in networks. However, a general theory that explains the underlying mechanisms and allows to make predictions is lacking beyond the single neuron level. Threshold-linear network (TLN) models describe the activity of con- nected nodes where the contribution of the connectivity terms is lin- ear above some threshold value (typically zero), while the network is disconnected below it. In their simplest description, the dynamics of the individual nodes are one-dimensional and linear. When the nodes in the network are neurons or neuronal populations, their activity can be interpreted as the firing rate, and therefore the TLNs represent fir- ing rate models [1]. Competitive threshold-linear networks (CTLNs) are a class of TLNs where the connectivity weights are all negative and there are no self- connections [2,3]. Inhibitory networks arise in many neuronal systems and have been shown to underlie the generation of rhythmic activity in cognition and motor behavior [4,5]. Despite their simplicity, TLNs and CTLNs produce complex behavior including multistability, peri- odic, quasi-periodic and chaotic solutions [2,3,6]. In this work, we consider CTLNs with three or more nodes and cyclic symmetry in which oscillatory solutions are observed. We first assume that an external oscillatory input is added to one of the nodes and, by defining a Poincaré map, we numerically study the response proper- ties of the CTLN networks. We determine the ranges of input ampli- tude and frequency in which the CTLN is able to follow the input (1:1 entrainment). For this we define local and global entrainment measures that convey different information. We then study how the entrainment properties of the CTLNs is affected by changes in (i) the time scale of each node, (ii) the number of nodes in the network, and (iii) the strength of the inhibitory connections. Finally, we extend our results to include other entrainment scenarios (e.g., 2:1) and other net- work topologies.Fil: Bel, Andrea Liliana. Universidad Nacional del Sur. Departamento de Matemática; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Unidad de Direccion; ArgentinaFil: Rotstein, Horacio. New Jersey Institute of Technology; Estados Unidos. Rutgers University; Estados UnidosFil: Reartes, Walter A.. Universidad Nacional del Sur. Departamento de Matemática; Argentina29th Annual Computacional Neuroscience MeetingOnlineEstados UnidosOrganization for Computational NeurosciencesBioMed Central2021info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/conferenceObjectCongresoJournalhttp://purl.org/coar/resource_type/c_5794info:ar-repo/semantics/documentoDeConferenciaapplication/pdfapplication/pdfhttp://hdl.handle.net/11336/259020Entrainment of competitive threshold-linear networks; 29th Annual Computacional Neuroscience Meeting; Online; Estados Unidos; 2020; 95-951471-2202CONICET DigitalCONICETenginfo:eu-repo/semantics/altIdentifier/url/https://bmcneurosci.biomedcentral.com/articles/supplements/volume-21-supplement-1info:eu-repo/semantics/altIdentifier/doi/10.1186/s12868-020-00593-1Internacionalinfo:eu-repo/semantics/openAccesshttps://creativecommons.org/licenses/by-nc-sa/2.5/ar/reponame:CONICET Digital (CONICET)instname:Consejo Nacional de Investigaciones Científicas y Técnicas2025-10-22T12:11:31Zoai:ri.conicet.gov.ar:11336/259020instacron:CONICETInstitucionalhttp://ri.conicet.gov.ar/Organismo científico-tecnológicoNo correspondehttp://ri.conicet.gov.ar/oai/requestdasensio@conicet.gov.ar; lcarlino@conicet.gov.arArgentinaNo correspondeNo correspondeNo correspondeopendoar:34982025-10-22 12:11:31.347CONICET Digital (CONICET) - Consejo Nacional de Investigaciones Científicas y Técnicasfalse |
| dc.title.none.fl_str_mv |
Entrainment of competitive threshold-linear networks |
| title |
Entrainment of competitive threshold-linear networks |
| spellingShingle |
Entrainment of competitive threshold-linear networks Bel, Andrea Liliana THRESHOLD-LINEAR NETWORKS PERIODIC SOLUTIONS ENTRAINMENT |
| title_short |
Entrainment of competitive threshold-linear networks |
| title_full |
Entrainment of competitive threshold-linear networks |
| title_fullStr |
Entrainment of competitive threshold-linear networks |
| title_full_unstemmed |
Entrainment of competitive threshold-linear networks |
| title_sort |
Entrainment of competitive threshold-linear networks |
| dc.creator.none.fl_str_mv |
Bel, Andrea Liliana Rotstein, Horacio Reartes, Walter A. |
| author |
Bel, Andrea Liliana |
| author_facet |
Bel, Andrea Liliana Rotstein, Horacio Reartes, Walter A. |
| author_role |
author |
| author2 |
Rotstein, Horacio Reartes, Walter A. |
| author2_role |
author author |
| dc.subject.none.fl_str_mv |
THRESHOLD-LINEAR NETWORKS PERIODIC SOLUTIONS ENTRAINMENT |
| topic |
THRESHOLD-LINEAR NETWORKS PERIODIC SOLUTIONS ENTRAINMENT |
| purl_subject.fl_str_mv |
https://purl.org/becyt/ford/1.1 https://purl.org/becyt/ford/1 |
| dc.description.none.fl_txt_mv |
Neuronal oscillations are ubiquitous in the brain and emerge from the combined activity of the participating neurons (or nodes), the connec- tivity and the network topology. Recent neurotechnological advances have made it possible to interrogate neuronal circuits by perturbing one or more of its nodes. The response to periodic inputs has been used as a tool to identify the oscillatory properties of circuits and the flow of information in networks. However, a general theory that explains the underlying mechanisms and allows to make predictions is lacking beyond the single neuron level. Threshold-linear network (TLN) models describe the activity of con- nected nodes where the contribution of the connectivity terms is lin- ear above some threshold value (typically zero), while the network is disconnected below it. In their simplest description, the dynamics of the individual nodes are one-dimensional and linear. When the nodes in the network are neurons or neuronal populations, their activity can be interpreted as the firing rate, and therefore the TLNs represent fir- ing rate models [1]. Competitive threshold-linear networks (CTLNs) are a class of TLNs where the connectivity weights are all negative and there are no self- connections [2,3]. Inhibitory networks arise in many neuronal systems and have been shown to underlie the generation of rhythmic activity in cognition and motor behavior [4,5]. Despite their simplicity, TLNs and CTLNs produce complex behavior including multistability, peri- odic, quasi-periodic and chaotic solutions [2,3,6]. In this work, we consider CTLNs with three or more nodes and cyclic symmetry in which oscillatory solutions are observed. We first assume that an external oscillatory input is added to one of the nodes and, by defining a Poincaré map, we numerically study the response proper- ties of the CTLN networks. We determine the ranges of input ampli- tude and frequency in which the CTLN is able to follow the input (1:1 entrainment). For this we define local and global entrainment measures that convey different information. We then study how the entrainment properties of the CTLNs is affected by changes in (i) the time scale of each node, (ii) the number of nodes in the network, and (iii) the strength of the inhibitory connections. Finally, we extend our results to include other entrainment scenarios (e.g., 2:1) and other net- work topologies. Fil: Bel, Andrea Liliana. Universidad Nacional del Sur. Departamento de Matemática; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Unidad de Direccion; Argentina Fil: Rotstein, Horacio. New Jersey Institute of Technology; Estados Unidos. Rutgers University; Estados Unidos Fil: Reartes, Walter A.. Universidad Nacional del Sur. Departamento de Matemática; Argentina 29th Annual Computacional Neuroscience Meeting Online Estados Unidos Organization for Computational Neurosciences |
| description |
Neuronal oscillations are ubiquitous in the brain and emerge from the combined activity of the participating neurons (or nodes), the connec- tivity and the network topology. Recent neurotechnological advances have made it possible to interrogate neuronal circuits by perturbing one or more of its nodes. The response to periodic inputs has been used as a tool to identify the oscillatory properties of circuits and the flow of information in networks. However, a general theory that explains the underlying mechanisms and allows to make predictions is lacking beyond the single neuron level. Threshold-linear network (TLN) models describe the activity of con- nected nodes where the contribution of the connectivity terms is lin- ear above some threshold value (typically zero), while the network is disconnected below it. In their simplest description, the dynamics of the individual nodes are one-dimensional and linear. When the nodes in the network are neurons or neuronal populations, their activity can be interpreted as the firing rate, and therefore the TLNs represent fir- ing rate models [1]. Competitive threshold-linear networks (CTLNs) are a class of TLNs where the connectivity weights are all negative and there are no self- connections [2,3]. Inhibitory networks arise in many neuronal systems and have been shown to underlie the generation of rhythmic activity in cognition and motor behavior [4,5]. Despite their simplicity, TLNs and CTLNs produce complex behavior including multistability, peri- odic, quasi-periodic and chaotic solutions [2,3,6]. In this work, we consider CTLNs with three or more nodes and cyclic symmetry in which oscillatory solutions are observed. We first assume that an external oscillatory input is added to one of the nodes and, by defining a Poincaré map, we numerically study the response proper- ties of the CTLN networks. We determine the ranges of input ampli- tude and frequency in which the CTLN is able to follow the input (1:1 entrainment). For this we define local and global entrainment measures that convey different information. We then study how the entrainment properties of the CTLNs is affected by changes in (i) the time scale of each node, (ii) the number of nodes in the network, and (iii) the strength of the inhibitory connections. Finally, we extend our results to include other entrainment scenarios (e.g., 2:1) and other net- work topologies. |
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2021 |
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2021 |
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