The Data Big Bang and the Expanding Digital Universe: High‐Dimensional, Complex and Massive Data Sets in an Inflationary Epoch

Pesenson, Meyer Z.; Pesenson, Isaac Z.; McCollum, B.

doi:10.1155/2010/350891

Cited by 23 publications

(12 citation statements)

References 132 publications

(155 reference statements)

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“…CMB data analysis is very demanding -both in terms of computational power required and sophistication of the necessary techniques -due to the complexity of the datasets and to the high degree of accuracy one wants to achieve. An overview on the techniques recently applied to astrophysical data analysis can be found in Pesenson et al (2010). This holds in particular for cutting-edge experi-Electronic address: davide.pietrobon@jpl.nasa.gov Electronic address: amedeo.balbi@roma2.infn.it Electronic address: paolo.cabella@roma2.infn.it Electronic address: krzysztof.m.gorski@jpl.nasa.gov ments such as the ongoing Planck satellite 1 .…”

Section: Introductionmentioning

confidence: 99%

NeedATool: A NEEDLET ANALYSIS TOOL FOR COSMOLOGICAL DATA PROCESSING

Pietrobon

Balbi

Cabella

et al. 2010

ApJ

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We introduce NeedATool (Needlet Analysis Tool), a software for data analysis based on needlets, a wavelet rendition which is powerful for the analysis of fields defined on a sphere. Needlets have been applied successfully to the treatment of astrophysical and cosmological observations, and in particular to the analysis of cosmic microwave background (CMB) data.Usually, such analyses are performed in real space as well as in its dual domain, the harmonic one. Both spaces have advantages and disadvantages: for example, in pixel space it is easier to deal with partial sky coverage and experimental noise; in harmonic domain, beam treatment and comparison with theoretical predictions are more effective. During the last decade, however, wavelets have emerged as a useful tool for CMB data analysis, since they allow to combine most of the advantages of the two spaces, one of the main reasons being their sharp localisation.In this paper, we outline the analytical properties of needlets and discuss the main features of the numerical code, which should be a valuable addition to the CMB analyst's toolbox.

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Section: Introductionmentioning

confidence: 99%

NeedATool: A NEEDLET ANALYSIS TOOL FOR COSMOLOGICAL DATA PROCESSING

Pietrobon

Balbi

Cabella

et al. 2010

ApJ

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“…The issue of computing covariance for ultra-high dimensional data can occur in other areas of neuroscience (raw EEG, MEG data, neurogenetics Data (Genome-Wide Association Study of Parkinson’s Disease: Genes and Environment, n.d.) and many other fields like microarrays in genetics, data from an array of sensors to capture geological or astronomical data, etc. ( Bonham-Carter et al, 1990 ; Pesenson et al, 2010 ; Alonso-Betanzos et al, 2019 ). In repetitive resampling like bootstrap, where multiple CPCs are required, we can use stepwise CF-CPC.…”

Section: Discussionmentioning

confidence: 99%

Stepwise Covariance-Free Common Principal Components (CF-CPC) With an Application to Neuroscience

Riaz

Razzaq

Hu³

et al. 2021

Front. Neurosci.

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Finding the common principal component (CPC) for ultra-high dimensional data is a multivariate technique used to discover the latent structure of covariance matrices of shared variables measured in two or more k conditions. Common eigenvectors are assumed for the covariance matrix of all conditions, only the eigenvalues being specific to each condition. Stepwise CPC computes a limited number of these CPCs, as the name indicates, sequentially and is, therefore, less time-consuming. This method becomes unfeasible when the number of variables p is ultra-high since storing k covariance matrices requires O(kp2) memory. Many dimensionality reduction algorithms have been improved to avoid explicit covariance calculation and storage (covariance-free). Here we propose a covariance-free stepwise CPC, which only requires O(kn) memory, where n is the total number of examples. Thus for n < < p, the new algorithm shows apparent advantages. It computes components quickly, with low consumption of machine resources. We validate our method CFCPC with the classical Iris data. We then show that CFCPC allows extracting the shared anatomical structure of EEG and MEG source spectra across a frequency range of 0.01–40 Hz.

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“…We live in an era where data become rapidly available due to technological advances in sensory devices and computational infrastructures for archiving and sharing information. The inflationary epoch of data explosion is also referred to as the "Data Big Bang" (Pesenson et al, 2010). New data sources relevant for SES modeling include non-traditional sources of socio-environmental data.…”

Section: 8mentioning

confidence: 99%

Eight grand challenges in socio-environmental systems modeling

Elsawah

Filatova

Jakeman

et al. 2020

SESMO

131

120

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Modeling is essential to characterize and explore complex societal and environmental issues in systematic and collaborative ways. Socio-environmental systems (SES) modeling integrates knowledge and perspectives into conceptual and computational tools that explicitly recognize how human decisions affect the environment. Depending on the modeling purpose, many SES modelers also realize that involvement of stakeholders and experts is fundamental to support social learning and decision-making processes for achieving improved environmental and social outcomes. The contribution of this paper lies in identifying and formulating grand challenges that need to be overcome to accelerate the development and adaptation of SES modeling. Eight challenges are delineated: bridging epistemologies across disciplines; multi-dimensional uncertainty assessment and management; scales and scaling issues; combining qualitative and quantitative methods and data; furthering the adoption and impacts of SES modeling on policy; capturing structural changes; representing human dimensions in SES; and leveraging new data types and sources. These challenges limit our ability to effectively use SES modeling to provide the knowledge and information essential for supporting decision making. Whereas some of these challenges are not unique to SES modeling and may be pervasive in other scientific fields, they still act as barriers as well as research opportunities for the SES modeling community. For each challenge, we outline basic steps that can be taken to surmount the underpinning barriers. Thus, the paper identifies priority research areas in SES modeling, chiefly related to progressing modeling products, processes and practices.

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The Data Big Bang and the Expanding Digital Universe: High‐Dimensional, Complex and Massive Data Sets in an Inflationary Epoch

Cited by 23 publications

References 132 publications

NeedATool: A NEEDLET ANALYSIS TOOL FOR COSMOLOGICAL DATA PROCESSING

NeedATool: A NEEDLET ANALYSIS TOOL FOR COSMOLOGICAL DATA PROCESSING

Stepwise Covariance-Free Common Principal Components (CF-CPC) With an Application to Neuroscience

Eight grand challenges in socio-environmental systems modeling

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