Statistical analyses support power law distributions found in neuronal avalanches
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A neural network model of reliably optimized spike transmissionWord decoding of protein amino Acid sequences with availability analysis: a linguistic approachBeing critical of criticality in the brain.Identification of Criticality in Neuronal Avalanches: II. A Theoretical and Empirical Investigation of the Driven Case.Scale-invariant neuronal avalanche dynamics and the cut-off in size distributions.Spontaneous cortical activity is transiently poised close to criticalityAdaptation towards scale-free dynamics improves cortical stimulus discrimination at the cost of reduced detectionSpike avalanches in vivo suggest a driven, slightly subcritical brain state.Fluorescence laser microdissection reveals a distinct pattern of gene activation in the mouse hippocampal region.Neuronal avalanches differ from wakefulness to deep sleep--evidence from intracranial depth recordings in humans.Voltage imaging of waking mouse cortex reveals emergence of critical neuronal dynamicsNetwork bursting dynamics in excitatory cortical neuron cultures results from the combination of different adaptive mechanisms.Criticality as a signature of healthy neural systemsScale-free functional connectivity of the brain is maintained in anesthetized healthy participants but not in patients with unresponsive wakefulness syndrome.Irregular spiking of pyramidal neurons organizes as scale-invariant neuronal avalanches in the awake state.Patterns and Limitations of Urban Human Mobility Resilience under the Influence of Multiple Types of Natural Disaster.Avalanche Analysis from Multielectrode Ensemble Recordings in Cat, Monkey, and Human Cerebral Cortex during Wakefulness and Sleep.A Low-Correlation Resting State of the Striatum during Cortical Avalanches and Its Role in Movement Suppression.Topological constraints on network control profiles.Dynamic systems approaches and levels of analysis in the nervous system.Statistical Evaluation of Waveform Collapse Reveals Scale-Free Properties of Neuronal Avalanches.Neuronal avalanches in the resting MEG of the human brain.Analysis of Power Laws, Shape Collapses, and Neural Complexity: New Techniques and MATLAB Support via the NCC ToolboxUniversal organization of resting brain activity at the thermodynamic critical point.Criticality Maximizes Complexity in Neural Tissue.Powerlaw: a Python package for analysis of heavy-tailed distributions.Self-organized criticality as a fundamental property of neural systems.Generalized Information Equilibrium Approaches to EEG Sleep Stage Discrimination.Trajectory-probed instability and statistics of desynchronization events in coupled chaotic systems.Self-organized criticality in cortical assemblies occurs in concurrent scale-free and small-world networks.Criticality predicts maximum irregularity in recurrent networks of excitatory nodes.Limits of Predictability of Cascading Overload Failures in Spatially-Embedded Networks with Distributed Flows.Dynamical correlation patterns and corresponding community structure in neural spontaneous activity at criticality.Multifractal detrended fluctuation analysis of human EEG: preliminary investigation and comparison with the wavelet transform modulus maxima technique.Identification of Criticality in Neuronal Avalanches: I. A Theoretical Investigation of the Non-driven Case.Discrete Scale Invariance of Human Large EEG Voltage Deflections is More Prominent in Waking than Sleep Stage 2.Marginally subcritical dynamics explain enhanced stimulus discriminability under attention.Maintained avalanche dynamics during task-induced changes of neuronal activity in nonhuman primates.Speech emotional features extraction based on electroglottograph.Optimal channel efficiency in a sensory network.
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P2860
Statistical analyses support power law distributions found in neuronal avalanches
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2011 nî lūn-bûn
@nan
2011 թուականին հրատարակուած գիտական յօդուած
@hyw
2011 թվականին հրատարակված գիտական հոդված
@hy
2011年の論文
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2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
name
Statistical analyses support power law distributions found in neuronal avalanches
@ast
Statistical analyses support power law distributions found in neuronal avalanches
@en
Statistical analyses support power law distributions found in neuronal avalanches
@en-gb
Statistical analyses support power law distributions found in neuronal avalanches
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type
label
Statistical analyses support power law distributions found in neuronal avalanches
@ast
Statistical analyses support power law distributions found in neuronal avalanches
@en
Statistical analyses support power law distributions found in neuronal avalanches
@en-gb
Statistical analyses support power law distributions found in neuronal avalanches
@nl
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Statistical Analyses Support Power Law Distributions Found in Neuronal Avalanches
@en
prefLabel
Statistical analyses support power law distributions found in neuronal avalanches
@ast
Statistical analyses support power law distributions found in neuronal avalanches
@en
Statistical analyses support power law distributions found in neuronal avalanches
@en-gb
Statistical analyses support power law distributions found in neuronal avalanches
@nl
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P3181
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P1476
Statistical analyses support power law distributions found in neuronal avalanches
@en
P2093
Dietmar Plenz
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P304
P3181
P356
10.1371/JOURNAL.PONE.0019779
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P577
2011-01-01T00:00:00Z