Abstract
Abstract. GPS radio occultation can estimate ionospheric electron density and total electron content (TEC) with high spatial resolution, e.g., China's recent Fengyun-3C GPS radio occultation. However, high-order ionospheric delays are normally ignored. In this paper, the high-order ionospheric effects on electron density estimation from the Fengyun-3C GPS radio occultation data are estimated and investigated using the NeQuick2 ionosphere model and the IGRF12 (International Geomagnetic Reference Field, 12th generation) geomagnetic model. Results show that the high-order ionospheric delays have large effects on electron density estimation with up to 800 el cm−3, which should be corrected in high-precision ionospheric density estimation and applications. The second-order ionospheric effects are more significant, particularly at 250–300 km, while third-order ionospheric effects are much smaller. Furthermore, the high-order ionospheric effects are related to the location, the local time, the radio occultation azimuth and the solar activity. The large high-order ionospheric effects are found in the low-latitude area and in the daytime as well as during strong solar activities. The second-order ionospheric effects have a maximum positive value when the radio occultation azimuth is around 0–20°, and a maximum negative value when the radio occultation azimuth is around −180 to −160°. Moreover, the geomagnetic storm also affects the high-order ionospheric delay, which should be carefully corrected.
Highlights
GPS has been widely used in positioning, navigation and timing (PNT) as well as remote sensing (Wu et al, 2010; Najibi and Jin, 2013; Jin et al, 2014a)
Almost 80 % of maximum residual total electron content (TEC) are located between −0.25 TECU and 0.25 TECU, and about 80 % of the maximum residual electron densities are located between −500 and 500 el cm−3
Most heights of maximum residual electron density are around 250–350 km, which is the range of the peak height of layer F2, indicating that the heights of the line of sight (LOS) tangent point around 250–350 km have a greater
Summary
GPS has been widely used in positioning, navigation and timing (PNT) as well as remote sensing (Wu et al, 2010; Najibi and Jin, 2013; Jin et al, 2014a). Wang et al (2014) estimated the second-order ionospheric effect on the GPS positioning using the measured electron density and found the maximum second-order ionospheric delay error with about 0.6, 0.8 and 0.6 cm for L1 signals at the Published by Copernicus Publications on behalf of the European Geosciences Union. One of Fengyun-3C payloads is the GNSS (Global Navigation Satellite System) occultation sounder (GNOS), which will retrieve atmospheric parameters and the electron density for atmospheric and ionospheric studies. The second- and third-order ionospheric effects on the ionospheric parameter estimation from Fengyun-3C GPS radio occultation data are estimated and investigated. 2, the theory and method of the second- and third-order ionospheric delay estimation are introduced, the secondand third-order ionospheric effects are presented, a case study of high-order ionospheric effects during the geomagnetic storm is presented, and conclusions are given in Sect.
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