Determining the Timing of Driver Influences on 1.8–3.5 MeV Electron Flux at Geosynchronous Orbit Using ARMAX Methodology and Stepwise Regression

Simms, Laura E.; Engebretson, M. J.; Reeves, G. D.

doi:10.1029/2022ja030963

Cited by 2 publications

(4 citation statements)

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“…The ULF influence is seen mostly in the 1–2 MeV range. In previous work, ULF waves have been found to be a stronger influence if only storm recovery time periods are considered (at ∼L‐shell 6) as long quiet periods might tend to “wash out” the influence of parameters that are only rarely strong enough to be active (Simms, Engebretson, & Reeves, 2023). For MeV electrons, which rise after geomagnetic storms, it is possible to study just the after‐storm response with a reasonable sample size (i.e., more than just one or a few storms) (Simms et al., 2014), but lower energy electrons do not show stronger responses to drivers during storms (Simms, Ganushkina, et al., 2022), so there are no easily identifiable points at which responses can be studied.…”

Section: Discussionmentioning

confidence: 96%

“…These include solar wind velocity (V) (Kellerman & Shprits, 2012; Li et al., 2001, 2005; Paulikas & Blake, 1979), and number density (N) (Balikhin et al., 2011; Lyatsky & Khazanov, 2008). However, the influence of these possible drivers on MeV electron flux may not be direct, but mediated by electromagnetic waves (ULF: ultralow frequency and VLF: very low frequency) and by the electron injections of substorms (Simms, Engebretson, & Reeves, 2023; Simms et al., 2014, 2016; Simms, Engebretson, Clilverd, Rodger, Lessard, et al., 2018). Depending on the situation, higher ULF wave activity is thought to both decrease electron flux levels through outward radial diffusion (Katsavrias et al., 2015; Kellerman & Shprits, 2012; Loto'aniu et al., 2010; K. R. Mann et al., 2012; Ozeke et al., 2020; Turner et al., 2012) or enhance levels through inward radial diffusion (Hao et al., 2019; Katsavrias et al., 2019; I. Mann et al., 2004).…”

Section: Introductionmentioning

confidence: 99%

“…In addition, autocorrelation in the response variable (electron flux) can increase the apparent statistical significance of correlations. ARMAX models (autoregressive, moving average transfer functions) can address both these problems and are a better choice for analyzing the associations between time series variables (Balikhin et al., 2011; Boynton et al., 2011, 2013, 2015; Sakaguchi et al., 2015; Simms, Engebretson, & Reeves, 2022; Simms, Engebretson, & Reeves, 2023; Simms et al., 2019; Simms, Ganushkina, et al., 2022). The time series behavior of the response variable can be partitioned out by the use of AR (autoregressive) and MA (moving average terms of the error).…”

Section: Introductionmentioning

confidence: 99%

“…Using ARMAX models, we have previously explored the influence of parameters on hourly averaged geosynchronous orbit (L‐shell 6.6) 40–150 keV and 1.8–3.5 MeV electron flux (Simms, Engebretson, & Reeves, 2022; Simms, Engebretson, & Reeves, 2023; Simms, Ganushkina, et al., 2022) (GOES and LANL satellites). In the present paper, using 10 min averaged electron flux data from the van Allen probes (RBSP: Radiation Belt Storm Probes), we expand our investigation to include more L‐shells (L‐shell 2‐L‐shell 7) and a wider range of energies (20 eV–2 MeV).…”

Section: Introductionmentioning

confidence: 99%

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Comparing Influences of Solar Wind, ULF Waves, and Substorms on 20 eV–2 MeV Electron Flux (RBSP) Using ARMAX Models

Simms,

Ganushkina,

Dubyagin

2024

JGR Space Physics

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Electron fluxes (20 eV–2 MeV, RBSP‐A satellite) show reasonable simple correlation with a variety of parameters (solar wind, IMF, substorms, ultralow frequency (ULF) waves, geomagnetic indices) over L‐shells 2–6. Removing correlation‐inflating common cycles and trends (using autoregressive and moving average terms in an ARMAX analysis) results in a 10 times reduction in apparent association between drivers and electron flux, although many are still statistically significant (p < 0.05). Corrected influences are highest in the 20 eV–1 keV and 1–2 MeV electrons, more modest in the midrange (2–40 keV). Solar wind velocity and pressure (but not number density), IMF magnitude (with lower influence of Bz), SME (a substorm measure), a ULF wave index, and geomagnetic indices Kp and SymH all show statistically significant associations with electron flux in the corrected individual ARMAX analyses. We postulate that only pressure, ULF waves, and substorms are direct drivers of electron flux and compare their influences in a combined analysis. SME is the strongest influence of these three, mainly in the eV and MeV electrons. ULF is most influential on the MeV electrons. Pressure shows a smaller positive influence and some indication of either magnetopause shadowing or simply compression on the eV electrons. While strictly predictive models may improve forecasting ability by including indirect driver and proxy parameters, and while these models may be made more parsimonious by choosing not to explicitly model time series behavior, our present analyses include time series variables in order to draw valid conclusions about the physical influences of exogenous parameters.

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Section: Discussionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Comparing Influences of Solar Wind, ULF Waves, and Substorms on 20 eV–2 MeV Electron Flux (RBSP) Using ARMAX Models

Simms,

Ganushkina,

Dubyagin

2024

JGR Space Physics

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Predicting Geostationary (GOES) 4.1–30 keV Electron Flux Over All MLT Using LEEMYR Regression Models

Simms,

Ganushkina,

van de Kamp

et al. 2024

Space Weather

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Regression models (LEEMYR: Low Energy Electron MLT geosYnchronous orbit Regression) predict hourly 4.1–30 keV electron flux at geostationary orbit (GOES‐16) using solar wind, IMF, and geomagnetic index parameters. Multiplicative interaction and polynomial terms describe synergistic and nonlinear effects. We reduce predictors to an optimal set using stepwise regression, resulting in models with validation comparable to a neural network. Models predict 1, 3, 6, 12, and 24 hr into the future. Validation correlations are as high as 0.78 (4.1 and 11 keV, 1 hr prediction) and Heidke Skill scores (HSS) up to 0.66. A 3 hr ahead prediction is more practical, with slightly lower validation correlation (0.75) and HSS (0.61). The addition of location (MLT: magnetic local time) as a covariate, including multiplicative interaction terms, accounts for location‐dependent flux differences and variation of parameter influence, and allows prediction over the full orbit. Adding a substorm index (SME) provides minimal increase in validation correlation (0.81) showing that other parameters are good proxies for an unavailable real time substorm index. Prediction intervals on individual values provide more accurate assessments of model quality than confidence intervals on the mean values. An inverse N‐weighted least squares approach is impractical as it increases false positive warnings. Physical interpretations are not possible as spurious correlations due to common cycles are not removed. However, SME, Bz, Kp, and Dst are the highest correlates of electron flux, with solar wind velocity, density, and pressure, and IMF magnitude being less well correlated.

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Determining the Timing of Driver Influences on 1.8–3.5 MeV Electron Flux at Geosynchronous Orbit Using ARMAX Methodology and Stepwise Regression

Abstract: The response of high energy (MeV) electron flux at geosynchronous orbit to various solar wind, interplanetary magnetic field (IMF), and magnetospheric parameters has been well studied at a daily cadence (e.g.,

Cited by 2 publications

References 46 publications

Comparing Influences of Solar Wind, ULF Waves, and Substorms on 20 eV–2 MeV Electron Flux (RBSP) Using ARMAX Models

Comparing Influences of Solar Wind, ULF Waves, and Substorms on 20 eV–2 MeV Electron Flux (RBSP) Using ARMAX Models

Predicting Geostationary (GOES) 4.1–30 keV Electron Flux Over All MLT Using LEEMYR Regression Models

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