We have extended the study of the Kuramoto model with additive Gaussian noise running on the KKI-18
large human connectome graph. We determined the dynamical behavior of this model by solving it
numerically in an assumed homeostatic state, below the synchronization crossover point we determined
previously. The de-synchronization duration distributions exhibit power-law tails, characterized by the
exponent in the range 1:1 < st < 2, overlapping the in vivo human brain activity experiments by Palva
et ...
We have extended the study of the Kuramoto model with additive Gaussian noise running on the KKI-18
large human connectome graph. We determined the dynamical behavior of this model by solving it
numerically in an assumed homeostatic state, below the synchronization crossover point we determined
previously. The de-synchronization duration distributions exhibit power-law tails, characterized by the
exponent in the range 1:1 < st < 2, overlapping the in vivo human brain activity experiments by Palva
et al. We show that these scaling results remain valid, by a transformation of the ultra-slow eigenfrequencies to Gaussian with unit variance. We also compare the connectome results with those,
obtained on a regular cube with N ¼ 106 nodes, related to the embedding space, and show that the
quenched internal frequencies themselves can cause frustrated synchronization scaling in an extended
coupling space.
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