A Dual-Layer Ionosphere Model Based on 3-D Ionospheric Constraint

Traditional ionospheric models were mostly constructed based on a single-layer assumption from global navigation satellite system (GNSS) observations, while it cannot capture vertical information of the ionosphere. This study proposes a new method to construct a double-layer ionospheric model based on constraints from a 3-D ionospheric model, whereby the bottom and topside ionospheric total electron content (TEC) can be represented by two spherical harmonic (SH) functions. The new improved model allows two SH functions to capture the spatiotemporal TEC variations across the vertical range of the ionosphere. The determination of the two thin layer heights (TLHs) in the double-layer model is achieved through a minimum mapping function error. Moreover, the performance of the new model is validated using GPS, BDS, and Galileo data from the International GNSS Server (IGS) network and compared with the global ionospheric map (GIM). During the experiment period, the results indicate that: 1) the TLHs of the bottom and topside ionosphere exhibit distinct spatiotemporal trends with the optimal global heights as 350 and 650 km, respectively; 2) the average relative accuracies of the bottom and topside ionospheric models are up to 86.80% and 85.33%, respectively; 3) the new model demonstrates an improvement of approximately 20%-27% in terms of TEC when compared to the GIM model, with the rms better than 4.64, 2.99, and 3.61 TECU in the low, middle, and high latitudes, respectively; and 4) with the increase of geomagnetic activity, the performance of the double-layer model shows a slight decline, but its relative accuracy can still reach over 84.8%.