Random-matrix spectra as a time series

Fossión, Rubén; Vargas, G Torres; Vieyra, J. C. López

doi:10.1103/physreve.88.060902

Cited by 40 publications

(48 citation statements)

References 31 publications

(51 reference statements)

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“…. , r associated to the oscillating normal modes of the fluctuations E [21]. In the present calculation, we find one global mode (n T = 1) for the matrix ensembles in the ergodic regime, and two global modes (n T = 2) in the nonergodic regime.…”

Section: A Trend and Fluctuation Normal Modessupporting

confidence: 48%

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Data-adaptive unfolding of nonergodic spectra: Two-Body Random Ensemble

Fossión

Vargas

Velázquez

et al. 2015

J. Phys.: Conf. Ser.

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The statistics of spectral fluctuations is sensitive to the unfolding procedure that separates global from local properties. Previously, we presented a parameter-free unfolding method applied to standard Gaussian ensembles of Random Matrix Theory (RMT). More general ensembles often break the ergodicity property, leading to ambiguities between spectrum-unfolded and ensemble-unfolded fluctuation statistics. Here, we use a disordered random-matrix ensemble with tunable nonergodicity to study its effect on the unfolding. We show that spectrum and ensemble averages can be calculated consistently using the same data-adaptive basis of normal modes. In this context, nonergodicity is explained as a breakdown of the common normal-mode basis.

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Section: A Trend and Fluctuation Normal Modessupporting

confidence: 48%

“…In Ref. [21], we applied the above data-adaptive unfolding to ergodic Gaussian ensembles. On the one hand, the fluctuation part k = n T +1, .…”

Section: B Fluctuation Measuresmentioning

confidence: 99%

Data-adaptive unfolding of nonergodic spectra: Two-Body Random Ensemble

Fossión

Vargas

Velázquez

et al. 2015

J. Phys.: Conf. Ser.

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“…[10]. In order to obtain results for the traditional fluctuation measures, we perform the data-adaptive unfolding of the spectra E (m) (n) using the global part E(n) calculated when we applied SVD to the ensemble [17]. In Fig.…”

Section: ν−Hermite Ensemblementioning

confidence: 99%

“…spectrum containing N = 2000 levels. The optimal ensemble size is M ≈ N/4, because for M ≫ N/4 there is a long tail of insignificant partial variances in the scree diagram, whereas for M ≪ N/4 the range of scales of the scree diagram becomes restrained, but the statistical properties do not depend on the particular choices of N and M[17]…”

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confidence: 99%

Crossover in nonstandard random-matrix spectral fluctuations without unfolding

et al. 2018

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Recently, singular value decomposition (SVD) was applied to standard Gaussian ensembles of random-matrix theory to determine the scale invariance in spectral fluctuations without performing any unfolding procedure. Here, SVD is applied directly to the β-Hermite ensemble and to a sparse matrix ensemble, decomposing the corresponding spectra in trend and fluctuation modes. In correspondence with known results, we obtain that fluctuation modes exhibit a crossover between soft and rigid behavior. In this way, possible artifacts introduced applying unfolding techniques are avoided. By using the trend modes, we perform data-adaptive unfolding, and we calculate traditional spectral fluctuation measures. Additionally, ensemble-averaged and individual-spectrum averaged statistics are calculated consistently within the same basis of normal modes.

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“…Besides, in order to calculate the standard spectral fluctuation measures from RMT, a data-adaptive unfolding can be realized. This unfolding method has the advantage of being a self-consisted method, defined in an intrinsic way, such that the global part of the spectra is obtained from the data itself, instead of being imposed extrinsically [1].…”

Section: Introductionmentioning

confidence: 99%

Normal mode analysis of spectra of random networks

Vargas

Fossión

Méndez-Bermúdez

2020

Physica A: Statistical Mechanics and its Applications

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Several spectral fluctuation measures of random matrix theory (RMT) have been applied in the study of spectral properties of networks. However, the calculation of those statistics requires performing an unfolding procedure, which may not be an easy task. In this work, network spectra are interpreted as time series, and we show how their short and long-range correlations can be characterized without implementing any previous unfolding. In particular, we consider three different representations of Erdős-Rényi (ER) random networks: standard ER networks, ER networks with random-weighted self-edges, and fully random-weighted ER networks. In each case, we apply singular value decomposition (SVD) such that the spectra are decomposed in trend and fluctuation normal modes. We obtain that the fluctuation modes exhibit a clear crossover between the Poisson and the Gaussian orthogonal ensemble statistics when increasing the average degree of ER networks. Moreover, by using the trend modes, we perform a data-adaptive unfolding to calculate, for comparison purposes, traditional fluctuation measures such as the nearest neighbor spacing distribution, number variance Σ 2 , as well as ∆3 and δn statistics. The thorough comparison of RMT short and long-range correlation measures make us identify the SVD method as a robust tool for characterizing random network spectra. arXiv:1911.05231v1 [cond-mat.dis-nn]

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Random-matrix spectra as a time series

Cited by 40 publications

References 31 publications

Data-adaptive unfolding of nonergodic spectra: Two-Body Random Ensemble

Data-adaptive unfolding of nonergodic spectra: Two-Body Random Ensemble

Crossover in nonstandard random-matrix spectral fluctuations without unfolding

Normal mode analysis of spectra of random networks

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