Sparse Reconstruction of 3-D Regional Ionospheric Tomography Using Data From a Network of GNSS Reference Stations

3-D computerized ionospheric tomography (CIT) is an ill-posed problem due to the insufficient amount of observations, it remains challenging for practical applications. In this article, we proposed an ionospheric tomography method that combined data-driven methods with compressed sensing (CS) to dea...

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Bibliographic Details
Published in:IEEE transactions on geoscience and remote sensing 2022, Vol.60, p.1-15
Main Authors: Sui, Yun, Fu, Haiyang, Wang, Denghui, Xu, Feng, Feng, Shaojun, Cheng, Jin, Jin, Ya-Qiu
Format: Article
Language:English
Subjects:
Compressed sensing
Compressed sensing (CS)
computerized ionospheric tomography (CIT)
Constraints
data-driven methods
Error analysis
Global navigation satellite system
global navigation satellite system (GNSS)
Global positioning systems
GPS
Ill posed problems
Image reconstruction
Ionosondes
Ionosphere
Methods
Positioning systems
Principal components analysis
Receivers
Reconstruction
Resolution
Satellites
Tomography
Total Electron Content
uncombined precise point positioning (UCPPP)
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Summary:3-D computerized ionospheric tomography (CIT) is an ill-posed problem due to the insufficient amount of observations, it remains challenging for practical applications. In this article, we proposed an ionospheric tomography method that combined data-driven methods with compressed sensing (CS) to deal with the ill-posed problem. First, slant total electron content (STEC) data were extracted by undifferenced and uncombined precise point positioning (UCPPP) with known fixed station coordinates. Second, data-driven methods were adopted to construct the projection matrix from the ionospheric model. Third, compressed sensing was used to derive the sparse solution based on L_{1} norm. The ionospheric tomography can be achieved well by using observations during the shorter time interval and in a sparse receiver distribution based on the property of compressed sensing. Results of experiment based on real Global Positioning System (GPS) observation data verified the effectiveness of the proposed methods. By comparing with the colocated ionosonde, it is found that the CS methods are more consistent with the actual ionospheric fluctuation than the modified constrained algebraic reconstruction technique (CART). In terms of the differential STEC (dSTEC) analysis, the error of the tomography model by Compressed Sensing-Principal Component Analysis (CS-PCA) is less than 0.2 TEC unit (TECU), and the time resolution is 5 min. The UCPPP with constraint by CS-PCA shows the best performance of 12.2%, 40.9% and 0.31% improvement in positioning accuracy, convergence time, and fixed rate over the UCPPP with constraint by modified CART. The proposed data-driven methods may be important for high-resolution 4-D ionospheric tomography in the future.
ISSN:0196-2892
1558-0644
DOI:10.1109/TGRS.2021.3087789