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1. Verfasser: MacLaurin, James
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2411.09260
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author MacLaurin, James
author_facet MacLaurin, James
contents We determine the large size limit of a network of interacting Hawkes Processes on an adaptive network. The flipping of the node variables is taken to have an intensity given by the mean-field of the afferent edges and nodes. The flipping of the edge variables is a function of the afferent node variables. The edge variables can be either symmetric or asymmetric. This model is motivated by applications in sociology, neuroscience and epidemiology. In general, the limiting probability law can be expressed as a fixed point of a self-consistent Poisson Process with intensity function that is (i) delayed and (ii) depends on its own probability law. In the particular case that the edge flipping is only determined by the state of the pre-synaptic neuron (as in neuroscience) it is proved that one obtains an autonomous neural-field type equation for the dual evolution of the synaptic potentiation and neural potentiation.
format Preprint
id arxiv_https___arxiv_org_abs_2411_09260
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle The Hydrodynamic Limit of Hawkes Processes on Adaptive Stochastic Networks
MacLaurin, James
Probability
We determine the large size limit of a network of interacting Hawkes Processes on an adaptive network. The flipping of the node variables is taken to have an intensity given by the mean-field of the afferent edges and nodes. The flipping of the edge variables is a function of the afferent node variables. The edge variables can be either symmetric or asymmetric. This model is motivated by applications in sociology, neuroscience and epidemiology. In general, the limiting probability law can be expressed as a fixed point of a self-consistent Poisson Process with intensity function that is (i) delayed and (ii) depends on its own probability law. In the particular case that the edge flipping is only determined by the state of the pre-synaptic neuron (as in neuroscience) it is proved that one obtains an autonomous neural-field type equation for the dual evolution of the synaptic potentiation and neural potentiation.
title The Hydrodynamic Limit of Hawkes Processes on Adaptive Stochastic Networks
topic Probability
url https://arxiv.org/abs/2411.09260