A‐CHAIM: Near‐Real‐Time Data Assimilation of the High Latitude Ionosphere With a Particle Filter

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The Assimilative Canadian High Arctic Ionospheric Model (A‐CHAIM) is a near‐real‐time data assimilation model of the high latitude ionosphere, incorporating measurements from many instruments, including slant Total Electron Content measurements from ground‐based Global Navigation Satellite System (GNSS) receivers. These measurements have receiver‐specific Differential Code Biases (DCB) which must be resolved to produce an absolute measurement, which are resolved simultaneously with the ionospheric state using Rao‐Blackwellized particle filtering. These DCBs are compared to published values and to DCBs determined using eight different Global Ionospheric Maps (GIM), which show small but consistent systematic differences. The potential cause of these systematic biases is investigated using multiple experimental A‐CHAIM test runs, including the effect of plasmaspheric electron content. By running tests using the GIM‐derived DCBs, it is shown that using A‐CHAIM DCBs produces the lowest overall error, and that using GIM DCBs causes an overestimation of the topside electron density which can exceed 100% when compared to in situ measurements from DMSP.

Section: Space Weathermentioning

confidence: 92%

Section: 1029/2023sw003611mentioning

confidence: 99%

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GNSS Differential Code Bias Determination Using Rao‐Blackwellized Particle Filtering

Reid,

Themens,

McCaffrey

et al. 2024

Self Cite

“…Furthermore, empirical ionospheric models, such as the International Reference Ionosphere (IRI, Bilitza, 2001; Bilitza et al., 2017) and the NeQuick model (Nava et al., 2008; Radicella, 2009), have also been extensively employed in the development of ionospheric data assimilation systems. Examples include the Ionospheric Data Assimilation Three/Four‐Dimensional (IDA3D/4D) (Bust et al., 2004, 2007), the Global Ionospheric Specification (GIS) (Lin et al., 2015, 2017), the United States/North American TEC (Fuller‐Rowell et al., 2006; Spencer et al., 2004), the Multi‐Instrument Data Analysis System (MIDAS) (Mitchell & Spencer, 2003; Spencer & Mitchell, 2007), as well as various global/regional ionospheric data assimilation systems driven by multiple data sources (e.g., Aa et al., 2018, 2022; Forsythe et al., 2020, 2021; Galkin et al., 2012; Mengist et al., 2019; Reid et al., 2023; Ssessanga et al., 2019; H. Wu et al., 2022; Yue et al., 2012, 2014). The empirical model‐based data assimilation system has the merits of low computational cost and can be used for ionospheric imaging with potential near‐real‐time capabilities, although it could be somewhat limited by the issue of under‐performance in regions with scarce data.…”

Section: Introductionmentioning

confidence: 99%

3‐D Ionospheric Imaging Over the South American Region With a New TEC‐Based Ionospheric Data Assimilation System (TIDAS‐SA)

Aa,

Zhang,

Erickson

et al. 2024

This study has developed a new TEC‐based ionospheric data assimilation system for 3‐D regional ionospheric imaging over the South American sector (TIDAS‐SA) (45°S–15°N, 35°–85°W, and 100–800 km). The TIDAS‐SA data assimilation system utilizes a hybrid Ensemble‐Variational approach to incorporate a diverse set of ionospheric data sources, including dense ground‐based Global Navigation Satellite System (GNSS) line‐of‐sight Total Electron Content (TEC) data, radio occultation data from the Constellation Observing System for Meteorology, Ionosphere, and Climate‐2 (COSMIC‐2), and altimeter TEC data from the JASON‐3 satellite. TIDAS‐SA can produce a reanalyzed three‐dimensional (3‐D) electron density spatial variation with a high time cadence, yielding spatial‐temporal resolution of 1° (latitude) × 1° (longitude) × 20 km (altitude) × 5 min. This allows us to reconstruct and study the 3‐D ionospheric morphology with multi‐scale structures. The performance of the data assimilation system is validated against independent ionosonde and in situ measurements through an experiment for a strong geomagnetic storm event on 03–04 November 2021. The results demonstrate that TIDAS‐SA can provide detailed and altitude‐resolved information that accurately characterizes the storm‐time ionospheric disturbances in vertical and horizontal domains over the equatorial and low‐latitude regions of South America.

“…Different studies (Bust et al, 2007;Elvidge & Angling, 2019;Mandrake et al, 2005;Matsuo & Araujo-Pradere, 2011;Qiao et al, 2021;Scherliess et al, 2006;Ssessanga et al, 2021;Wu et al, 2015) have estimated the ionospheric density by ingesting GNSS (Global Navigation Satellite Systems) global measurements of TEC (Total Electron Content). Reid et al (2023) introduced the application of particle filter in Assimilative Canadian High Arctic Ionospheric Model (A-CHAIM), which provides high-latitude ionosphere from ingesting slant TEC data from ionosondes and GNSS receivers, and vertical TEC from JASON-3 altimeter. Pignalberi et al (2019) also ingest global TEC measurements to update the background model International Reference Ionosphere (IRI).…”

Section: Introductionmentioning

confidence: 99%

Quantification of Representation Error in the Neutral Winds and Ion Drifts Using Data Assimilation

Hu,

López Rubio,

Chartier

et al. 2024

In this work we quantify the representation error of the algorithm Estimating Model Parameters from Ionospheric Reverse Engineering (EMPIRE), which estimates global neutral winds and ion drifts given time‐varying plasma densities. SAMI3 (Sami3 is A Model of the Ionosphere) serves as the background climate model and pseudo‐measurements for the EMPIRE observation system. This configuration allows the data assimilation inputs to be self‐consistent between each other and with the validation data. The estimated neutral winds and ion drifts are compared to the Horizontal Wind Model (HWM14) and SAMI3 “truth.” For both the quiet period on 25 August 2018 and subs7equent storm on 26 August, the EMPIRE estimation of ion drifts is better at low‐to‐mid geomagnetic latitudes with mean error up to 20 m/s. For the high latitudes (poleward of ±60° magnetic), the mean errors exceed 50 m/s with variances up to 200 m/s, and the relative errors are higher than the “truth.” At latitudes of ±87°, the large errors are attributed to a boundary effect. However, the neutral wind mean errors peak at 20 m/s at mid‐latitudes (40°–60° magnetic), with larger uncertainties, then converge to 0 approaching higher latitudes. By conducting this study, we define a method for obtaining the representation error covariance for future use of EMPIRE with SAMI3 as background.