Neural Coding by Temporal and Spatial Correlations

With the rapid growth of renewable energy generation, it has become essential to give a comprehensive evaluation of renewable energy integration capability in power systems to reduce renewable generation curtailment. Existing research has not considered the correlations between wind power and photovoltaic (PV) power. In this paper, temporal and spatial correlations among different renewable generations are utilized to evaluate the integration capability of power systems based on the copula model. Firstly, the temporal and spatial correlation between wind and PV power generation is analyzed. Secondly, the temporal and spatial distribution model of both wind and PV power generation output is formulated based on the copula model. Thirdly, aggregated generation output scenarios of wind and PV power are generated. Fourthly, wind and PV power scenarios are utilized in an optimal power flow calculation model of power systems. Lastly, the integration capacity of wind power and PV power is shown to be able to be evaluated by satisfying the reliability of power system operation. Simulation results of a modified IEEE RTS-24 bus system indicate that the integration capability of renewable energy generation in power systems can be comprehensively evaluated based on the temporal and spatial correlations of renewable energy generation.

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Subdiffusive Dynamics of Bump Attractors: Mechanisms and Functional Roles

Neural Computation ◽

10.1162/neco_a_00698 ◽

2015 ◽

Vol 27 (2) ◽

pp. 255-280 ◽

Cited By ~ 4

Author(s):

Yang Qi ◽

Michael Breakspear ◽

Pulin Gong

Keyword(s):

Neural Coding ◽

Spatial Working Memory ◽

Activity Patterns ◽

Stimulus Presentation ◽

Generalized Langevin Equation ◽

Spatial Correlations ◽

Temporal Correlations ◽

Normal Diffusion ◽

Characteristic Features ◽

Noisy Inputs

Bump attractors are localized activity patterns that can self-sustain after stimulus presentation, and they are regarded as the neural substrate for a host of perceptual and cognitive processes. One of the characteristic features of bump attractors is that they are neutrally stable, so that noisy inputs cause them to drift away from their initial locations, severely impairing the accuracy of bump location-dependent neural coding. Previous modeling studies of such noise-induced drifting activity of bump attractors have focused on normal diffusive dynamics, often with an assumption that noisy inputs are uncorrelated. Here we show that long-range temporal correlations and spatial correlations in neural inputs generated by multiple interacting bumps cause them to drift in an anomalous subdiffusive way. This mechanism for generating subdiffusive dynamics of bump attractors is further analyzed based on a generalized Langevin equation. We demonstrate that subdiffusive dynamics can significantly improve the coding accuracy of bump attractors, since the variance of the bump displacement increases sublinearly over time and is much smaller than that of normal diffusion. Furthermore, we reanalyze existing psychophysical data concerning the spread of recalled cue position in spatial working memory tasks and show that its variance increases sublinearly with time, consistent with subdiffusive dynamics of bump attractors. Based on the probability density function of bump position, we also show that the subdiffusive dynamics result in a long-tailed decay of firing rate, greatly extending the duration of persistent activity.

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Embracing the uncertainty: the evolution of SOFI into a diverse family of ﬂuctuation-based super-resolution microscopy methods

Journal of Physics Photonics ◽

10.1088/2515-7647/ac3838 ◽

2021 ◽

Author(s):

Monika Pawlowska ◽

Ron Tenne ◽

Bohnishikha Ghosh ◽

Adrian Makowski ◽

Radek Lapkiewicz

Keyword(s):

3D Imaging ◽

Deep Neural Networks ◽

Fluorescent Proteins ◽

Super Resolution ◽

Significant Progress ◽

Spatial Correlations ◽

Order Of Magnitude ◽

Temporal And Spatial ◽

Microscopy Techniques ◽

Super Resolution Microscopy

Abstract Super-resolution microscopy techniques have pushed the limits of resolution in optical imaging by more than an order of magnitude. However, these methods often require long acquisition times as well as complex setups and sample preparation protocols. Super-resolution Optical Fluctuation Imaging (SOFI) emerged over ten years ago as an approach that exploits temporal and spatial correlations within the acquired images to obtain increased resolution with less strict requirements. This review follows the progress of SOFI from its ﬁrst demonstration to the development of a branch of methods that treat ﬂuctuations as a source of contrast, rather than noise. Among others, we highlight the implementation of SOFI with standard ﬂuorescent proteins as well as the microscope modiﬁcation that facilitate 3D imaging and the application of modern cameras. Going beyond the classical framework of SOFI, we explore diﬀerent innovative concepts from deep neural networks all the way to a quantum analogue of SOFI, antibunching microscopy. While SOFI has not reached the same level of ubiquity as other super-resolution methods, our overview ﬁnds signiﬁcant progress and substantial potential for the concept of leveraging ﬂuorescence ﬂuctuations to obtain super-resolved images.

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