2016
DOI: 10.1016/j.physleta.2016.06.038
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Can recurrence networks show small-world property?

Abstract: Recurrence networks are complex networks, constructed from time series data, having several practical applications. Though their properties when constructed with the threshold value ǫ chosen at or just above the percolation threshold of the network are quite well understood, what happens as the threshold increases beyond the usual operational window is still not clear from a complex network perspective. The present Letter is focused mainly on the network properties at intermediate-to-large values of the recurr… Show more

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Cited by 10 publications
(5 citation statements)
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“…To our best knowledge, a similar crossover behavior has not been described in ES based climate networks before, but was reported for the ( networks established based on classical Pearson correlation [22]. Future work should further address this kind of transition behavior in network properties when increasing the density of connections, which has also been reported in other types of spatial networks [71][72][73][74] and could be related to a change in the structural complexity of the investigated network structures [21].…”
Section: Node Degreesupporting
confidence: 76%
“…To our best knowledge, a similar crossover behavior has not been described in ES based climate networks before, but was reported for the ( networks established based on classical Pearson correlation [22]. Future work should further address this kind of transition behavior in network properties when increasing the density of connections, which has also been reported in other types of spatial networks [71][72][73][74] and could be related to a change in the structural complexity of the investigated network structures [21].…”
Section: Node Degreesupporting
confidence: 76%
“…If ε is too small, the volume of the neighborhood will be small and therefore there will be almost no recurrence points and the information incorporated in the network will be insufficient. On the other hand, if ε is too large we observe a general qualitative change in the network topology (Jacob, Harikrishnan, Misra, & Ambika, 2016), namely, each node will behave like a hub, leading to an excess of recurring points and misleading information. Donner et al (2010) and Donner, Small, et al (2011) studied properties of ε-recurrence networks at three different scales, namely local, intermediate, and global on several paradigmatic systems: Hénon map, Bernoulli map, Lorenz system, and Rössler system.…”
Section: Adaptive Nearest Neighbor Networkmentioning
confidence: 96%
“…If ε is too small, the volume of the neighborhood will be small and therefore there will be almost no recurrence points and the information incorporated in the network will be insufficient. On the other hand, if ε is too large we observe a general qualitative change in the network topology (Jacob, Harikrishnan, Misra, & Ambika, 2016), namely, each node will behave like a hub, leading to an excess of recurring points and misleading information.…”
Section: Mapping Univariate Time Series Into Complex Networkmentioning
confidence: 99%
“…Beyond this, our framework might also be applicable to networks constructed from non-pairwise interdependencies that are investigated in, e.g, causal effect networks [74,85,86]. The assessment of statistical complexity could help to more objectively choose thresholds for the construction of such networks and complements existing approaches based on, e.g., the assessment of the recurrence network's percolation threshold [76,87,88].…”
Section: Threshold-based Networkmentioning
confidence: 99%