AUTHOR=Yeakel Kiley L. , Vandegriff Jon D. , Garton Tadhg M. , Jackman Caitriona M. , Clark George , Vines Sarah K. , Smith Andrew W. , Kollmann Peter 

TITLE=Classification of Cassini’s Orbit Regions as Magnetosphere, Magnetosheath, and Solar Wind via Machine Learning

JOURNAL=Frontiers in Astronomy and Space Sciences

VOLUME=9

YEAR=2022

URL=https://www.frontiersin.org/journals/astronomy-and-space-sciences/articles/10.3389/fspas.2022.875985

DOI=10.3389/fspas.2022.875985

ISSN=2296-987X

ABSTRACT=<p>Several machine learning algorithms and feature subsets from a variety of particle and magnetic field instruments on-board the Cassini spacecraft were explored for their utility in classifying orbit segments as magnetosphere, magnetosheath or solar wind. Using a list of manually detected magnetopause and bow shock crossings from mission scientists, random forest (RF), support vector machine (SVM), logistic regression (LR) and recurrent neural network long short-term memory (RNN LSTM) classification algorithms were trained and tested. A detailed error analysis revealed a RNN LSTM model provided the best overall performance with a 93.1% accuracy on the unseen test set and MCC score of 0.88 when utilizing 60 min of magnetometer data (|<italic>B</italic>|, <italic>B</italic><sub><italic>θ</italic></sub>, <italic>B</italic><sub><italic>ϕ</italic></sub> and <italic>B</italic><sub><italic>R</italic></sub>) to predict the region at the final time step. RF models using a combination of magnetometer and particle data, spanning H<sup>+</sup>, He<sup>+</sup>, He<sup>++</sup> and electrons at a single time step, provided a nearly equivalent performance with a test set accuracy of 91.4% and MCC score of 0.84. Derived boundary crossings from each model’s region predictions revealed that the RNN model was able to successfully detect 82.1% of labeled magnetopause crossings and 91.2% of labeled bow shock crossings, while the RF model using magnetometer and particle data detected 82.4 and 74.3%, respectively.</p>