30th International Colloquium on Group Theoretical Methods in Physics | |
Phase transitions in small-world systems: application to functional brain networks | |
Gadjiev, B.R.^1 ; Progulova, T.B.^1 | |
Dubna International University for Nature, Society and Man, 19 Universitetskaya street, Dubna | |
141980, Russia^1 | |
关键词: Energy functionals; Equation of motion; Fractional differential equations; Irreducible representations; Maximum entropy principle; Q-exponential distributions; Regular sub-group; Small-world systems; | |
Others : https://iopscience.iop.org/article/10.1088/1742-6596/597/1/012038/pdf DOI : 10.1088/1742-6596/597/1/012038 |
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来源: IOP | |
【 摘 要 】
In the present paper the problem of symmetry breaking in the systems with a small- world property is considered. The obtained results are applied to the description of the functional brain networks. Origin of the entropy of fractal and multifractal small-world systems is discussed. Applying the maximum entropy principle the topology of these networks has been determined. The symmetry of the regular subgroup of a small-world system is described by a discrete subgroup of the Galilean group. The algorithm of determination of this group and transformation properties of the order parameter have been proposed. The integer basis of the irreducible representation is constructed and a free energy functional is introduced. It has been shown that accounting the presence of random connections leads to an integro- differential equation for the order parameter. For q-exponential distributions an equation of motion for the order parameter takes the form of a fractional differential equation. We consider the system that is described by a two-component order parameter and discuss the features of the spatial distribution of solutions.
【 预 览 】
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Phase transitions in small-world systems: application to functional brain networks | 1221KB | download |