Statistical complexity is maximized in a small-world brain
In this paper, we study a network of Izhikevich neurons to explore what it means for a brain to be at the edge of chaos. To do so, we first constructed the phase diagram of a single Izhikevich excitatory neuron, and identified a small region of the parameter space where we find a large number of pha...
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sg-ntu-dr.10356-881672023-02-28T19:34:21Z Statistical complexity is maximized in a small-world brain Tan, Teck Liang Cheong, Siew Ann Ma, Jun School of Physical and Mathematical Sciences Complexity Institute Information Processing Time Series Analysis In this paper, we study a network of Izhikevich neurons to explore what it means for a brain to be at the edge of chaos. To do so, we first constructed the phase diagram of a single Izhikevich excitatory neuron, and identified a small region of the parameter space where we find a large number of phase boundaries to serve as our edge of chaos. We then couple the outputs of these neurons directly to the parameters of other neurons, so that the neuron dynamics can drive transitions from one phase to another on an artificial energy landscape. Finally, we measure the statistical complexity of the parameter time series, while the network is tuned from a regular network to a random network using the Watts-Strogatz rewiring algorithm. We find that the statistical complexity of the parameter dynamics is maximized when the neuron network is most small-world-like. Our results suggest that the small-world architecture of neuron connections in brains is not accidental, but may be related to the information processing that they do. Published version 2018-03-16T05:02:15Z 2019-12-06T16:57:34Z 2018-03-16T05:02:15Z 2019-12-06T16:57:34Z 2017 Journal Article Tan, T. L., & Cheong, S. A. (2017). Statistical complexity is maximized in a small-world brain. PLOS ONE, 12(8), e0183918-. https://hdl.handle.net/10356/88167 http://hdl.handle.net/10220/44576 10.1371/journal.pone.0183918 en PLOS ONE © 2017 Tan, Cheong. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. 15 p. application/pdf |
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Information Processing Time Series Analysis Tan, Teck Liang Cheong, Siew Ann Statistical complexity is maximized in a small-world brain |
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In this paper, we study a network of Izhikevich neurons to explore what it means for a brain to be at the edge of chaos. To do so, we first constructed the phase diagram of a single Izhikevich excitatory neuron, and identified a small region of the parameter space where we find a large number of phase boundaries to serve as our edge of chaos. We then couple the outputs of these neurons directly to the parameters of other neurons, so that the neuron dynamics can drive transitions from one phase to another on an artificial energy landscape. Finally, we measure the statistical complexity of the parameter time series, while the network is tuned from a regular network to a random network using the Watts-Strogatz rewiring algorithm. We find that the statistical complexity of the parameter dynamics is maximized when the neuron network is most small-world-like. Our results suggest that the small-world architecture of neuron connections in brains is not accidental, but may be related to the information processing that they do. |
| author2 |
Ma, Jun |
| author_facet |
Ma, Jun Tan, Teck Liang Cheong, Siew Ann |
| format |
Article |
| author |
Tan, Teck Liang Cheong, Siew Ann |
| author_sort |
Tan, Teck Liang |
| title |
Statistical complexity is maximized in a small-world brain |
| title_short |
Statistical complexity is maximized in a small-world brain |
| title_full |
Statistical complexity is maximized in a small-world brain |
| title_fullStr |
Statistical complexity is maximized in a small-world brain |
| title_full_unstemmed |
Statistical complexity is maximized in a small-world brain |
| title_sort |
statistical complexity is maximized in a small-world brain |
| publishDate |
2018 |
| url |
https://hdl.handle.net/10356/88167 http://hdl.handle.net/10220/44576 |
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1759855622072827904 |