A new combination of Hankel and sparsity-promoting dynamic mode decompositions and its application to the prediction of plasma turbulence

Kusaba, Akira; Kuboyama, Tetsuji; Shin, Kilho; Sasaki, M.; Inagaki, S.

doi:10.35848/1347-4065/ac1c3c

Cited by 3 publications

(2 citation statements)

References 31 publications

(31 reference statements)

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“…Given that incorporating trajectory history through delay embedding reconstructs the underlying attractor from partial observation, we might surmise that the dimension-expansion from delay embeddings constitutes a reasonable finite-dimensional representation in which the Koopman theory approximately holds 35,36,40,41,[57][58][59] . An approach that exploits exactly this insight is the Hankel Alternative View of Koopman (HAVOK) 35 , which uses a de-correlated and low-rank representation of the delay embedding matrix (known as eigen-time-delay coordinates) as an embedding space in which to estimate the Koopman operator.…”

Section: Tractability and Nonlinearitymentioning

confidence: 99%

Propofol anesthesia destabilizes neural dynamics across cortex

Eisen,

Kozachkov,

Bastos

et al. 2023

Preprint

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Every day, hundreds of thousands of people undergo general anesthesia. One hypothesis is that anesthesia disrupts dynamic stability, the ability of the brain to balance excitability with the need to be stable and thus controllable. We tested this hypothesis using a new method for quantifying population-level dynamic stability in complex systems,DelayedLinearAnalysis forStabilityEstimation (DeLASE). Propofol was used to transition animals between the awake state and anesthetized unconsciousness. DeLASE was applied to macaque cortex local field potentials (LFPs). We found that neural dynamics were more unstable in unconsciousness compared to the awake state. Cortical trajectories mirrored predictions from destabilized linear systems. We mimicked the effect of propofol in simulated neural networks by increasing inhibitory tone. Paradoxically, increased inhibition also destabilized the networks. Our results suggest that anesthesia disrupts dynamical stability that is required for consciousness.

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Section: Tractability and Nonlinearitymentioning

confidence: 99%

Propofol anesthesia destabilizes neural dynamics across cortex

Eisen,

Kozachkov,

Bastos

et al. 2023

Preprint

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“…Modal decomposition into a few degrees of freedom on real space is easier to understand detailed spatiotemporal dynamics. Analyses based on data-driven methods, such as dynamic mode decompositions (DMDs) [2,3] and singular value decompositions (SVDs), have been applied to turbulence [4]. In particular, the SVD is possible to analyze interactions between modes, because it is based on orthogonal bases so that the energy of the mode can be defined.…”

mentioning

confidence: 99%

Analysis of Turbulence Driven Particle Transport in PANTA by Using Multi-Field Singular Value Decomposition

KODAHARA,

SASAKI,

KAWACHI

et al. 2023

Plasma and Fusion Research

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Multi-field singular value decompositions (SVDs) is applied to turbulence obtained in a cylindrical magnetized plasma, PANTA. This method enables us to obtain the spatial mode structures with common temporal evolution of different physical quantities, such as the fluctuations of density and flows. Turbulence driven particle transport is evaluated by the method. It is shown that only the coupling of the same mode drives the transport, which stems from the orthogonality of the SVD. Thanks to this characteristics, the number of degrees of freedom which plays roles for the transport dynamics could be significantly reduced. c

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