Please use this identifier to cite or link to this item:
https://hdl.handle.net/20.500.14279/27028
Title: | Spatiotemporal dynamics in spiking recurrent neural networks using modified-full-FORCE on EEG signals | Authors: | Ioannides, Georgios Kourouklides, Ioannis Astolfi, Alessandro |
Major Field of Science: | Engineering and Technology | Field Category: | Electrical Engineering - Electronic Engineering - Information Engineering | Keywords: | Behavior;Brain;Cognition;Electroencephalography;Neural Networks;Neurons;Perception | Issue Date: | 21-Feb-2022 | Source: | Scientific Reports, 2022, vol. 12, articl. no. 2896 | Volume: | 12 | Journal: | Scientific Reports | Abstract: | Methods on modelling the human brain as a Complex System have increased remarkably in the literature as researchers seek to understand the underlying foundations behind cognition, behaviour, and perception. Computational methods, especially Graph Theory-based methods, have recently contributed significantly in understanding the wiring connectivity of the brain, modelling it as a set of nodes connected by edges. Therefore, the brain's spatiotemporal dynamics can be holistically studied by considering a network, which consists of many neurons, represented by nodes. Various models have been proposed for modelling such neurons. A recently proposed method in training such networks, called full-Force, produces networks that perform tasks with fewer neurons and greater noise robustness than previous least-squares approaches (i.e. FORCE method). In this paper, the first direct applicability of a variant of the full-Force method to biologically-motivated Spiking RNNs (SRNNs) is demonstrated. The SRNN is a graph consisting of modules. Each module is modelled as a Small-World Network (SWN), which is a specific type of a biologically-plausible graph. So, the first direct applicability of a variant of the full-Force method to modular SWNs is demonstrated, evaluated through regression and information theoretic metrics. For the first time, the aforementioned method is applied to spiking neuron models and trained on various real-life Electroencephalography (EEG) signals. To the best of the authors' knowledge, all the contributions of this paper are novel. Results show that trained SRNNs match EEG signals almost perfectly, while network dynamics can mimic the target dynamics. This demonstrates that the holistic setup of the network model and the neuron model which are both more biologically plausible than previous work, can be tuned into real biological signal dynamics. | URI: | https://hdl.handle.net/20.500.14279/27028 | ISSN: | 20452322 | DOI: | 10.1038/s41598-022-06573-1 | Rights: | © The Author(s). Open Access Tis article is licensed under a Creative Commons Attribution 4.0 International License | Type: | Article | Affiliation : | Imperial College London Cyprus University of Technology |
Publication Type: | Peer Reviewed |
Appears in Collections: | Άρθρα/Articles |
Files in This Item:
File | Description | Size | Format | |
---|---|---|---|---|
s41598-022-06573-1.pdf | Fulltext | 6.09 MB | Adobe PDF | View/Open |
CORE Recommender
SCOPUSTM
Citations
4
checked on Feb 2, 2024
WEB OF SCIENCETM
Citations
2
Last Week
0
0
Last month
0
0
checked on Oct 29, 2023
Page view(s)
217
Last Week
0
0
Last month
5
5
checked on Dec 28, 2024
Download(s) 50
70
checked on Dec 28, 2024
Google ScholarTM
Check
Altmetric
This item is licensed under a Creative Commons License