Abstract
In order to efficiently analyse the vast amount of data generated by solar space missions and ground-base instruments, modern machine learning techniques such as decision trees, support vector machines (SVMs) and neural networks can be very useful. In this paper we present initial results from using a convolutional neural network (CNN) to analyse observations from the Atmospheric Imaging Assembly (AIA) in the 1600A wavelength. The data is pre-processed to locate flaring regions where flare ribbons are visible in the observations. The CNN is created and trained to automatically analyse the shape and position of the flare ribbons, by identifying whether each image belongs into one of four classes: two-ribbon flare, compact/circular ribbon flare, limb flare or quiet Sun, with the final class acting as a control for any data included in the training or test sets where flaring regions are not present. The network created can classify flare ribbon observations into any of the four classes with a final accuracy of 94%. Initial results show that most of the images are correctly classified with the compact flare class being the only class where accuracy drops below 90% ad some observations are wrongly classified as belonging to the limb class.
Highlights
The steady improvement of technology and instrumentation applied to solar observations has led to the generation of vast amounts of data, for example the Solar Dynamics Observatory (SDO) collects approximately 1.5 terabytes of data everyday (Pesnell et al, 2012)
We have demonstrated a basic application of convolutional neural network (CNN) to solar image data
The model classifies the shapes of solar flare ribbons that are visible in 1,600 Å Atmospheric Imaging Assembly (AIA) observations
Summary
The steady improvement of technology and instrumentation applied to solar observations has led to the generation of vast amounts of data, for example the Solar Dynamics Observatory (SDO) collects approximately 1.5 terabytes of data everyday (Pesnell et al, 2012). The analysis of these data products can be made much more efficient by the use of modern machine learning techniques such as decision trees, support vector machines (SVMs) and neural networks. These observations clearly show the flare ribbons as they appear on the solar surface
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