Abstract
Using the solar-wind-driven magnetosphere-ionosphere-thermosphere system, a methodology is developed to reduce a state-vector description of a time-dependent driven system to a composite scalar picture of the activity in the system. The technique uses canonical correlation analysis to reduce the time-dependent system and driver state vectors to time-dependent system and driver scalars, with the scalars describing the response in the system that is most-closely related to the driver. This reduced description has advantages: low noise, high prediction efficiency, linearity in the described system response to the driver, and compactness. The methodology identifies independent modes of reaction of a system to its driver. The analysis of the magnetospheric system is demonstrated. Using autocorrelation analysis, Jensen-Shannon complexity analysis, and permutation-entropy analysis the properties of the derived aggregate scalars are assessed and a new mode of reaction of the magnetosphere to the solar wind is found. This state-vector-reduction technique may be useful for other multivariable systems driven by multiple inputs.
Cite
CITATION STYLE
Borovsky, J. E., & Osmane, A. (2019). Compacting the description of a time-dependent multivariable system and its multivariable driver by reducing the state vectors to aggregate scalars: The Earth’s solar-wind-driven magnetosphere. Nonlinear Processes in Geophysics, 26(4), 429–443. https://doi.org/10.5194/npg-26-429-2019
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