Real-time solar image classification: Assessing spectral, pixel-based approaches

Hughes, J. Marcus; Hsu, V.; Seaton, Daniel B.; Bain, H. M.; Darnel, Jonathan; Krista, L. D.

doi:10.1051/swsc/2019036

Cited by 5 publications

(3 citation statements)

References 38 publications

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“…The algorithm currently used to produce operational thematic maps is an improved version of the random forest approach described in Hughes et al. (2019). The current algorithm is still a pixel based random‐forest approach, that is, it classifies each pixel separately with a random forest without knowledge of neighboring pixels and instead only using spectral information from the six SUVI channels.…”

Section: Suvi Productsmentioning

confidence: 99%

The GOES‐R Solar UltraViolet Imager

et al. 2022

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The four Solar Ultraviolet Imagers (SUVI) on board the Geostationary Operational Environmental Satellite (GOES)‐16 and GOES‐17 and the upcoming GOES‐T and GOES‐U weather satellites serve as National Oceanic and Atmospheric Administration's operational solar coronal imagers. These four identically designed solar Extreme UltraViolet instruments are similar in design and capability to the Solar Dynamics Observatory‐Atmospheric Imaging Assembly suite of solar telescopes, and are planned to operationally span two solar cycles or more, from 2017 through 2040. We present the concept of operations for the SUVI instruments, operational requirements, and constraints. The reader is also introduced to the instrument design, testing, and performance characteristics. Finally, the various data products are described along with their potential utility to the operational user or researcher.

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Section: Suvi Productsmentioning

confidence: 99%

The GOES‐R Solar UltraViolet Imager

et al. 2022

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“…Several observatories have been collect- ing images in extreme ultra-violet (EUV) filters and in X-ray passbands for several decades, and analyzing them to pick out interesting changes using automated routines have been largely unsuccessful. Catalogs like the HEK (Heliophysics Events Knowledgebase Hurlburt et al 2012;Martens et al 2012) can detect and mark features of particular varieties, though these compilations remain beset by incompleteness (see, e.g., Aggar-wal et al 2018;Hughes et al 2019;Barnes et al 2017). In this context, our method provides a way to model solar features without limiting it to a particular feature set to identify and locate regions in images where something interesting has transpired.…”

Section: Isolated Evolving Solar Coronal Loopmentioning

confidence: 99%

Change point detection and image segmentation for time series of astrophysical images

Xu,

Günther,

Kashyap

et al. 2021

Preprint

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Many astrophysical phenomena are time-varying, in the sense that their intensity, energy spectrum, and/or the spatial distribution of the emission suddenly change. This paper develops a method for modeling a time series of images. Under the assumption that the arrival times of the photons follow a Poisson process, the data are binned into 4D grids of voxels (time, energy band, and x-y coordinates), and viewed as a time series of non-homogeneous Poisson images. The method assumes that at each time point, the corresponding multi-band image stack is an unknown 3D piecewise constant function including Poisson noise. It also assumes that all image stacks between any two adjacent change points (in time domain) share the same unknown piecewise constant function. The proposed method is designed to estimate the number and the locations of all the change points (in time domain), as well as all the unknown piecewise constant functions between any pairs of the change points. The method applies the minimum description length (MDL) principle to perform this task. A practical algorithm is also developed to solve the corresponding complicated optimization problem. Simulation experiments and applications to real datasets show that the proposed method enjoys very promising empirical properties. Applications to two real datasets, the XMM observation of a flaring star and an emerging solar coronal loop, illustrate the usage of the proposed method and the scientific insight gained from it.

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“…Over the last ∼10 years, a rising number of researchers moved their interest to the promising research fields of Artificial Intelligence and Machine Learning (see review by Camporeale, 2019) applied to solar and i.p. physics data for SW forecasting purposes, for instance to predict the occurrence of solar eruptions and flares (e.g., Ahmed et al, 2013;Benvenuto et al, 2018;Florios et al, 2018), predict geomagnetic storms (e.g., Sexton et al, 2019), and to detect and classify solar events (Martens et al, 2012;Armstrong and Fletcher 2019;Hughes et al, 2019). These methods are really promising, but it is maybe too early to know what will be the new results that these methods will provide in the end.…”

Section: Introduction: State Of the Artmentioning

confidence: 99%

Possible Advantages of a Twin Spacecraft Heliospheric Mission at the Sun-Earth Lagrangian Points L4 and L5

Бемпорад

2021

Front. Astron. Space Sci.

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After the launch of STEREO twin spacecraft, and most recently of Solar Orbiter and Parker Solar Probe spacecraft, the next mission that will explore Sun-Earth interactions and how the Sun modulates the Heliosphere will be the “Lagrange” mission, which will consist of two satellites placed in orbit around L1 and L5 Sun-Earth Lagrangian points. Despite the significant novelties that will be provided by such a double vantage point, there will be also missing information, that are briefly discussed here. For future heliospheric missions, an alternative advantageous approach that has not been considered so far would be to place two twin spacecraft not in L1 and L5, but in L4 and L5 Lagrangian points. If these two spacecraft will be equipped with in situ instruments, and also remote sensing instruments measuring not only photospheric but also coronal magnetic fields, significant advancing will be possible. In particular, data provided by such a twin mission will allow to follow the evolution of magnetic fields from inside the Sun (with stereoscopic helioseismology), to its surface (with classical photospheric magnetometers), and its atmosphere (with spectro-polarimeters); this will provide a tremendous improvement in our physical understanding of solar activity. Moreover, the L4-L5 twin satellites will take different interesting configurations, such as relative quadrature, and quasi-quadrature with the Earth, providing a baseline for monitoring the Sun-to-Earth propagation of solar disturbances.

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Real-time solar image classification: Assessing spectral, pixel-based approaches

Cited by 5 publications

References 38 publications

The GOES‐R Solar UltraViolet Imager

The GOES‐R Solar UltraViolet Imager

Change point detection and image segmentation for time series of astrophysical images

Possible Advantages of a Twin Spacecraft Heliospheric Mission at the Sun-Earth Lagrangian Points L4 and L5

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