Dynamic linear models for forecasting of radiation belt electrons and limitations on physical interpretation of predictive models

Osthus, Dave; Caragea, Petruţa C.; Higdon, David; Morley, S.; Reeves, G. D.; Weaver, Brian P.

doi:10.1002/2014sw001057

Cited by 16 publications

(19 citation statements)

References 28 publications

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“…It has been known for decades that the intensity of the outer belt is positively correlated with solar wind speed [e.g., Paulikas and Blake , ; Baker et al ., ; Li et al ., ; Lyatsky and Khazanov , ; Reeves et al ., ; Kellerman et al ., ; Osthus et al ., ]. Also required for the enhancement of outer belt electrons is geomagnetic activity, which requires a southward component of the interplanetary magnetic field (IMF) [e.g., Miyoshi and Kataoka , ; McPherron et al ., ; Li et al ., ; Miyoshi et al ., ; Jaynes et al ., ].…”

Section: Long‐term Observationsmentioning

confidence: 99%

Radiation belt electron dynamics at low L (<4): Van Allen Probes era versus previous two solar cycles

Baker

Zhao

et al. 2017

JGR Space Physics

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Long‐term (>2 solar cycles) measurements reveal that MeV electron fluxes, solar wind speed, and geomagnetic activity have been extremely low during this current solar cycle, including years before and during the Van Allen Probes era. This study examines solar wind speed, the geomagnetic storm index (Dst), >2 MeV electrons at geostationary orbit, and ~2 MeV electrons across various L shells measured by Solar Anomalous Magnetospheric Particle Explorer in low Earth orbit (LEO) and by the Van Allen Probes/Relativistic Electron and Proton Telescope (REPT) in a geotransfer‐like orbit; the latter measurements are normalized to LEO based on comparison with Colorado Student Space Weather Experiment/Relativistic Electron and Proton Telescope integrated little experiment (REPTile) measurements in LEO. The average ratio of REPTile/REPT varies in a systematic manner with L, ~16% at L = 2.7, decreasing with L and reaching ~0.7% at L = 4.7, and increasing again with L though with greater uncertainty. We show that there have been no ~2 MeV electron enhancements inside L ~ 2.6 since 2006, prior to which numerous penetrations of ~2 MeV electrons into L < 2.5 were measured during periods of stronger solar wind conditions (in terms of high‐speed solar wind, magnitude of interplanetary magnetic field, B, and a sustained southward Bz) and thus stronger geomagnetic activity. We conclude that results from the Van Allen Probes, which have been providing the finest measurements but in operation during a quiet solar activity period, may not be representative of radiation belt dynamics, particularly for the inner edge of the outer belt, during other solar cycle phases.

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Section: Long‐term Observationsmentioning

confidence: 99%

Radiation belt electron dynamics at low L (<4): Van Allen Probes era versus previous two solar cycles

Baker

Zhao

et al. 2017

JGR Space Physics

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“…An alternative approach to first principles‐based forecast models is the system identification or machine learning approach, where the models are automatically derived from input‐output data by computer algorithms. These algorithms include linear prediction filters (Baker et al, ; Rigler et al, ), dynamic linear models (Osthus et al, ), neural networks (Freeman et al, ; Koons & Gorney, ; Ling et al, ), and Nonlinear AutoRegressive Moving Average with eXogenous (NARMAX) inputs (Boynton, Balikhin, Billings, & Amariutei, ; Boynton et al, ; Wei et al, ). Neural networks and NARMAX methodologies are more suited to modeling the radiation belts, as the system is nonlinear with respect to the solar wind input.…”

Section: Introductionmentioning

confidence: 99%

The System Science Development of Local Time‐Dependent 40‐keV Electron Flux Models for Geostationary Orbit

et al. 2019

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At geosynchronous Earth orbit, the radiation belt/ring current electron fluxes with energies up to several hundred kiloelectron volts can vary widely in magnetic local time (MLT). This study aims to develop Nonlinear AutoRegressive eXogenous models using system science techniques, which account for the spatial variation in MLT. This is difficult for system science techniques, since there is sparse data availability of the electron fluxes at different MLT. To solve this problem, the data are binned from Geostationary Operational Environmental Satellites (GOES) 13, 14, and 15 by MLT, and a separate Nonlinear AutoRegressive eXogenous model is deduced for each bin using solar wind variables as the inputs to the model. These models are then conjugated into one spatiotemporal forecast. The model performance statistics for each model varies in MLT with a prediction efficiency between 47% and 75% and a correlation coefficient between 51.3% and 78.9% for the period from 1 March 2013 to 31 December 2017.

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“…In this approach, models are automatically deduced from input‐output data by the system identification algorithms. The system identification methodologies include linear prediction filters [ Baker et al , ], dynamic linear models [ Osthus et al , ], neural networks [ Koons and Gorney , ; Freeman et al , ; Ling et al , ], and Nonlinear Autoregressive Moving Average with Exogenous inputs (NARMAX) [ Wei et al , ; Boynton et al , , ]. While linear prediction filters and dynamic linear models are suitable for linear systems, the main advantage of NARMAX and neural networks is that they are capable of modeling nonlinear dynamics within the system.…”

Section: Introductionmentioning

confidence: 99%

Electron flux models for different energies at geostationary orbit

et al. 2016

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Forecast models were derived for energetic electrons at all energy ranges sampled by the third‐generation Geostationary Operational Environmental Satellites (GOES). These models were based on Multi‐Input Single‐Output Nonlinear Autoregressive Moving Average with Exogenous inputs methodologies. The model inputs include the solar wind velocity, density and pressure, the fraction of time that the interplanetary magnetic field (IMF) was southward, the IMF contribution of a solar wind‐magnetosphere coupling function proposed by Boynton et al. (2011b), and the Dst index. As such, this study has deduced five new 1 h resolution models for the low‐energy electrons measured by GOES (30–50 keV, 50–100 keV, 100–200 keV, 200–350 keV, and 350–600 keV) and extended the existing >800 keV and >2 MeV Geostationary Earth Orbit electron fluxes models to forecast at a 1 h resolution. All of these models were shown to provide accurate forecasts, with prediction efficiencies ranging between 66.9% and 82.3%.

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Dynamic linear models for forecasting of radiation belt electrons and limitations on physical interpretation of predictive models

Cited by 16 publications

References 28 publications

Radiation belt electron dynamics at low L (<4): Van Allen Probes era versus previous two solar cycles

Radiation belt electron dynamics at low L (<4): Van Allen Probes era versus previous two solar cycles

The System Science Development of Local Time‐Dependent 40‐keV Electron Flux Models for Geostationary Orbit

Electron flux models for different energies at geostationary orbit

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