Partial synchronization is characteristic phase dynamics of coupled
oscillators on various natural and artificial networks, which can remain
undetected due to the complexity of the systems. With an analogy between
pairwise asynchrony of oscillators and topological defects, i.e., vortices, in
the two-dimensional XY spin model, we propose a robust and data-driven method
to identify the partial synchronization on complex networks. The proposed
method is based on an integer matrix whose element is pseudo-vorticity that
discretely quantifies asynchronous phase dynamics in every two oscillators,
which results in graphical and entropic representations of partial synchrony.
As a first trial, we apply our method to 200 FitzHugh-Nagumo neurons on a
complex small-world network. Partially synchronized chimera states are revealed
by discriminating synchronized states even with phase lags. Such phase lags
also appear in partial synchronization in chimera states. Our topological,
graphical, and entropic method is implemented solely with measurable phase
dynamics data, which will lead to a straightforward application to general
oscillatory networks including neural networks in the brain.Comment: 9 pages, 5 figure