Nonlinear dynamical modeling and prediction of the terrestrial magnetospheric activity
The irregular activity of the magnetosphere results from its complex internal dynamics as well as the external influence of the solar wind. The dominating self-organization of the magnetospheric plasma gives rise to repetitive, large-scale coherent behavior manifested in phenomena such as the magnetic substorm. Based on the nonlinearity of the global dynamics this dissertation examines the magnetosphere as a nonlinear dynamical system using time series analysis techniques. Initially the magnetospheric activity is modeled in terms of an autonomous system. A dimension study shows that its observed time series is self-similar, but the correlation dimension is high. The implication of a large number of degrees of freedom is confirmed by other state space techniques such as Poincare sections and search for unstable periodic orbits. At the same time a stability study of the time series in terms of Lyapunov exponents suggests that the series is not chaotic. The absence of deterministic chaos is supported by the low predictive capability of the autonomous model. Rather than chaos, it is an external input which is largely responsible for the irregularity of the magnetospheric activity. In fact, the external driving is so strong that the above state space techniques give results for magnetospheric and solar wind time series that are at least qualitatively similar. Therefore the solar wind input has to be included in a low-dimensional nonautonomous model. Indeed it is shown that such a model can reproduce the observed magnetospheric behavior up to 80-90 percent. The characteristic coefficients of the model show little variation depending on the external disturbance. The impulse response is consistent with earlier results of linear prediction filters. The model can be easily extended to contain nonlinear features of the magnetospheric activity and in particular the loading-unloading behavior of substorms.
- Research Organization:
- Maryland Univ., College Park, MD (United States)
- OSTI ID:
- 6306170
- Resource Relation:
- Other Information: Ph.D. Thesis
- Country of Publication:
- United States
- Language:
- English
Similar Records
Nonlinear dynamics of the magnetosphere and space weather
The evolution from weak to strong geomagnetic activity: An interpretation in terms of deterministic chaos
Related Subjects
GENERAL PHYSICS
EARTH MAGNETOSPHERE
DYNAMICS
TIME-SERIES ANALYSIS
COUPLING
DEGREES OF FREEDOM
MAGNETIC STORMS
MATHEMATICAL MODELS
NONLINEAR PROBLEMS
SOLAR WIND
EARTH ATMOSPHERE
MATHEMATICS
MECHANICS
SOLAR ACTIVITY
661320* - Auroral
Ionospheric
& Magnetospheric Phenomena- (1992-)