Visibility Graph Based Community Detection for Biological Time Series

Min, Zheng; Domanskyi, Sergii; Piermarocchi, Carlo; Mias, George I.

doi:10.1101/2020.03.02.973263

Cited by 3 publications

(3 citation statements)

References 36 publications

(47 reference statements)

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“…the nodes v i and v j are connected if the node v j is visible from the node v i and vice versa, therefore the resulting graph is undirected (for more details on the properties of VGs, see [36]). In general, there are two ways to construct a network (graph) from a time-series: the horizontal visibility graph (HVG) [39,101,102] and the natural visibility graph (NVG) [103][104][105], the former is more sparse than the latter case and in this work we focus on the NVG. In Fig.…”

Section: Visibility Graphmentioning

confidence: 99%

Persistent Homology of Weighted Visibility Graph from Fractional Gaussian Noise

Masoomy,

Askari,

Najafi

et al. 2021

Preprint

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In this paper, we utilize persistent homology technique to examine the topological properties of the visibility graph constructed from fractional Gaussian noise (fGn). We develop the weighted natural visibility graph algorithm and the standard network in addition to the global properties in the context of topology, will be examined. Our results demonstrate that the distribution of eigenvector and betweenness centralities behave as power-law decay. The scaling exponent of eigenvector centrality and the moment of eigenvalue distribution, Mn, for n ≥ 1 reveal the dependency on the Hurst exponent, H, containing the sample size effect. We also focus on persistent homology of kdimensional topological holes incorporating the filtration of simplicial complexes of associated graph. The dimension of homology group represented by Betti numbers demonstrates a strong dependency on the Hurst exponent. More precisely, the scaling exponent of the number of k-dimensional topological holes appearing and disappearing at a given threshold, depends on H which is almost not affected by finite sample size. We show that the distribution function of lifetime for k-dimensional topological holes decay exponentially and corresponding slope is an increasing function versus H and more interestingly, the sample size effect is completely disappeared in this quantity. The persistence entropy logarithmically grows with the size of visibility graph of system with almost H-dependent prefactors.

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Section: Visibility Graphmentioning

confidence: 99%

Persistent Homology of Weighted Visibility Graph from Fractional Gaussian Noise

Masoomy,

Askari,

Najafi

et al. 2021

Preprint

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show abstract

“…Those studies show different time series analysis in plasmas. However, not only fractals and multifractals could be useful in the study of time series, complex networks, particularly the Visibility Graph method, allow for a simple and direct time series analysis in self-organized critical phenomena, such as earthquakes [ 37 ], macroeconomic systems [ 38 ], or biological systems [ 39 ].…”

Section: Introductionmentioning

confidence: 99%

Applying the Horizontal Visibility Graph Method to Study Irreversibility of Electromagnetic Turbulence in Non-Thermal Plasmas

Acosta-Tripailao

Pastén

Moya

2021

Entropy

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One of the fundamental open questions in plasma physics is the role of non-thermal particles distributions in poorly collisional plasma environments, a system that is commonly found throughout the Universe, e.g., the solar wind and the Earth’s magnetosphere correspond to natural plasma physics laboratories in which turbulent phenomena can be studied. Our study perspective is born from the method of Horizontal Visibility Graph (HVG) that has been developed in the last years to analyze time series avoiding the tedium and the high computational cost that other methods offer. Here, we build a complex network based on directed HVG technique applied to magnetic field fluctuations time series obtained from Particle In Cell (PIC) simulations of a magnetized collisionless plasma to distinguish the degree distributions and calculate the Kullback–Leibler Divergence (KLD) as a measure of relative entropy of data sets produced by processes that are not in equilibrium. First, we analyze the connectivity probability distribution for the undirected version of HVG finding how the Kappa distribution for low values of κ tends to be an uncorrelated time series, while the Maxwell–Boltzmann distribution shows a correlated stochastic processes behavior. Subsequently, we investigate the degree of temporary irreversibility of magnetic fluctuations that are self-generated by the plasma, comparing the case of a thermal plasma (described by a Maxwell–Botzmann velocity distribution function) with non-thermal Kappa distributions. We have shown that the KLD associated to the HVG is able to distinguish the level of reversibility that is associated to the thermal equilibrium in the plasma, because the dissipative degree of the system increases as the value of κ parameter decreases and the distribution function departs from the Maxwell–Boltzmann equilibrium.

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“…VG is a tool to convert a given time series to a network and plays an essential role in determining the properties of nonlinear dynamical systems. Many statistical [14] and topological [15] aspects of VGs have been studied numerically and analytically, making it a standard powerful tool to study various systems like earthquakes [16], economics [17], ecology [18], neuroscience [19,20], and biology [21]. An important step towards an understanding the scaling properties of VGs was taken by Lacasa, who showed that a self-similar time series converts into an SF network, emphasizing that the power-law degree distributions are related to the fractality [14,22].…”

mentioning

confidence: 99%

The Visibility Graphs of Correlated Time Series Violate the Barthelemy's Conjecture for Degree and Betweenness Centralities

Masoomy¹,

Najafi²

2021

Preprint

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The problem of betweenness centrality remains a fundamental unsolved problem in complex networks. After a pioneering work by Barthelemy, it has been well-accepted that the maximal betweenness-degree (b-k) exponent for scale-free (SF) networks is ηmax = 2, belonging to scale-free trees (SFTs), based on which one concludes δ ≥ γ+1 2 , where γ and δ are the scaling exponents of the distribution functions of the degree and betweenness centrality, respectively. Here we present evidence for violation of this conjecture for SF visibility graphs (VGs). To this end, we consider the VG of three models: two-dimensional (2D) Bak-Tang-Weisenfeld (BTW) sandpile model, 1D fractional Brownian motion (FBM) and, 1D Levy walks, the two later cases are controlled by the Hurst exponent H and step-index α, respectively. Specifically, for the BTW model and FBM with H 0.5, η is greater than 2, and also δ < γ+1 2 for the BTW model, while Barthelemy's conjecture remains valid for the Levy process. We argue that this failure of Barthelemy's conjecture is due to large fluctuations in the scaling b-k relation resulting in the violation of hyperscaling relation η = γ−1 δ−1 and emergent anomalous behaviors for the BTW model and FBM. A super-universal behavior is found for the distribution function for a generalized degree function identical to the Barabasi-Albert network model.

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Visibility Graph Based Community Detection for Biological Time Series

Cited by 3 publications

References 36 publications

Persistent Homology of Weighted Visibility Graph from Fractional Gaussian Noise

Persistent Homology of Weighted Visibility Graph from Fractional Gaussian Noise

Applying the Horizontal Visibility Graph Method to Study Irreversibility of Electromagnetic Turbulence in Non-Thermal Plasmas

The Visibility Graphs of Correlated Time Series Violate the Barthelemy's Conjecture for Degree and Betweenness Centralities

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