22.1.6.44 Ionosphere, Ionosphere Tomography, Reflections, Ionospheric Effects

Liu, J.[Jun], Kuga, Y., Ishimaru, A., Pi, X.Q.[Xiao-Qing], Freeman, A.,
Ionospheric effects on SAR imaging: a numerical study,
GeoRS(41), No. 5, May 2003, pp. 939-947.
IEEE Abstract. 0307
BibRef

Pallares, J.M., Ruffini, G., Ruffini, L.,
Ionospheric tomography using GNSS reflections,
GeoRS(43), No. 2, February 2005, pp. 321-326.
IEEE Abstract. 0501
Global Navigation Satellite System Reflections. BibRef

Li, L.L.[Lian-Lin], Li, F.[Fang],
SAR Imaging Degradation by Ionospheric Irregularities Based on TFTPCF Analysis,
GeoRS(45), No. 5, May 2007, pp. 1123-1130.
IEEE DOI 0704
BibRef

Mai, C.L., Kiang, J.F.,
Reconstruction of Ionospheric Perturbation Induced by 2004 Sumatra Tsunami Using a Computerized Tomography Technique,
GeoRS(47), No. 10, October 2009, pp. 3303-3312.
IEEE DOI 0910
BibRef

Wen, D., Yuan, Y., Ou, J., Zhang, K., Liu, K.,
A Hybrid Reconstruction Algorithm for 3-D Ionospheric Tomography,
GeoRS(46), No. 6, June 2008, pp. 1733-1739.
IEEE DOI 0711
BibRef

Tsynkov, S.V.,
On SAR Imaging Through The Earth'S Ionosphere,
SIIMS(2), No. 1, 2009, pp. 140-182. synthetic aperture radar (SAR); spaceborne radar; ionosphere; dispersion of electromagnetic waves; cold plasma; ionospheric distortions; turbulent fluctuations; geometrical optics; refraction index; range and azimuthal resolution; scattering
DOI Link BibRef 0900

Chen, J., Zebker, H.A.,
Ionospheric Artifacts in Simultaneous L-Band InSAR and GPS Observations,
GeoRS(50), No. 4, April 2012, pp. 1227-1239.
IEEE DOI 1204
BibRef

Chen, A.C., Zebker, H.A.,
Reducing Ionospheric Effects in InSAR Data Using Accurate Coregistration,
GeoRS(52), No. 1, January 2014, pp. 60-70.
IEEE DOI 1402
geophysical image processing BibRef

Meyer, F.J.,
Performance Requirements for Ionospheric Correction of Low-Frequency SAR Data,
GeoRS(49), No. 10, October 2011, pp. 3694-3702.
IEEE DOI 1110
BibRef

Jung, H.S., Lee, D.T., Lu, Z., Won, J.S.,
Ionospheric Correction of SAR Interferograms by Multiple-Aperture Interferometry,
GeoRS(51), No. 5, May 2013, pp. 3191-3199.
IEEE DOI 1305
BibRef

Jung, H.S., Lee, W.,
An Improvement of Ionospheric Phase Correction by Multiple-Aperture Interferometry,
GeoRS(53), No. 9, September 2015, pp. 4952-4960.
IEEE DOI 1506
Azimuth BibRef

Burston, R., Jayachandran, P.T.,
Effect of Grid Boundary Expansion to Include One Additional Data Source on Ionospheric Imaging Accuracy,
GeoRS(52), No. 10, October 2014, pp. 6216-6225.
IEEE DOI 1407
Accuracy. BibRef

Seo, J.[Jiwon], Walter, T.,
Future Dual-Frequency GPS Navigation System for Intelligent Air Transportation Under Strong Ionospheric Scintillation,
ITS(15), No. 5, October 2014, pp. 2224-2236.
IEEE DOI 1410
Global Positioning System BibRef

Yao, Y.[Yibin], Kong, J.[Jian], Tang, J.[Jun],
A New Ionosphere Tomography Algorithm With Two-Grid Virtual Observations Constraints and Three-Dimensional Velocity Profile,
GeoRS(53), No. 5, May 2015, pp. 2373-2383.
IEEE DOI 1502
ionospheric techniques BibRef

Yao, Y.[Yibin], Tang, J.[Jun], Chen, P.[Peng], Zhang, S.[Shun], Chen, J.[Jiajun],
An Improved Iterative Algorithm for 3-D Ionospheric Tomography Reconstruction,
GeoRS(52), No. 8, August 2014, pp. 4696-4706.
IEEE DOI 1403
Global Positioning System BibRef

Yue, X., Schreiner, W.S., Kuo, Y.H., Braun, J.J., Lin, Y.C., Wan, W.,
Observing System Simulation Experiment Study on Imaging the Ionosphere by Assimilating Observations From Ground GNSS, LEO-Based Radio Occultation and Ocean Reflection, and Cross Link,
GeoRS(52), No. 7, July 2014, pp. 3759-3773.
IEEE DOI 1403
Data models BibRef

Liu, Z., Jung, H.S., Lu, Z.,
Joint Correction of Ionosphere Noise and Orbital Error in L-Band SAR Interferometry of Interseismic Deformation in Southern California,
GeoRS(52), No. 6, June 2014, pp. 3421-3427.
IEEE DOI 1403
Azimuth BibRef

Chen, P.[Peng], Yao, W.Q.[Wan-Qiang], Zhu, X.J.[Xue-Jun],
Combination of Ground- and Space-Based Data to Establish a Global Ionospheric Grid Model,
GeoRS(53), No. 2, February 2015, pp. 1073-1081.
IEEE DOI 1411
ionosphere BibRef

Shi, S.Z.[Shu-Zhu], Chen, G.[Gang], Yang, G.B.[Guo-Bin], Li, T.[Ting], Zhao, Z.Y.[Zheng-Yu], Liu, J.N.[Jing-Nan],
Wuhan Ionospheric Oblique-Incidence Sounding System and Its New Application in Localization of Ionospheric Irregularities,
GeoRS(53), No. 4, April 2015, pp. 2185-2194.
IEEE DOI 1502
Global Positioning System BibRef

Wang, C.[Cheng], Zhang, M.[Min], Xu, Z.W.[Zheng-Wen], Chen, C.[Chun], Guo, L.X.[Li-Xin],
Cubic Phase Distortion and Irregular Degradation on SAR Imaging Due to the Ionosphere,
GeoRS(53), No. 6, June 2015, pp. 3442-3451.
IEEE DOI 1503
ionospheric disturbances BibRef

Rovira-Garcia, A., Juan, J.M., Sanz, J., Gonzalez-Casado, G.,
A Worldwide Ionospheric Model for Fast Precise Point Positioning,
GeoRS(53), No. 8, August 2015, pp. 4596-4604.
IEEE DOI 1506
ionospheric techniques BibRef

Hervás, M.[Marcos], Alsina-Pagès, R.M.[Rosa Ma], Orga, F.[Ferran], Altadill, D.[David], Pijoan, J.L.[Joan Lluís], Badia, D.[David],
Narrowband and Wideband Channel Sounding of an Antarctica to Spain Ionospheric Radio Link,
RS(7), No. 9, 2015, pp. 11712.
DOI Link 1511
BibRef

Ning, Y.F.[Ya-Fei], Yuan, Y.B.[Yun-Bin], Huang, Z.[Zhen], Chai, Y.J.[Yan-Ju], Tan, B.F.[Bing-Feng],
A Long Baseline Three Carrier Ambiguity Resolution with a New Ionospheric Constraint,
IJGI(5), No. 11, 2016, pp. 198.
DOI Link 1612
BibRef

Chen, J.S.[Jenn-Shyong], Chu, Y.H.[Yen-Hsyang], Su, C.L.[Ching-Lun], Hashiguchi, H.[Hiroyuki], Li, Y.[Ying],
Range Imaging of E-Region Field-Aligned Irregularities by Using a Multifrequency Technique: Validation and Initial Results,
GeoRS(54), No. 7, July 2016, pp. 3739-3749.
IEEE DOI 1606
in the midlatitude ionosphere. BibRef

Gomba, G., Parizzi, A., de Zan, F., Eineder, M.[Michael], Bamler, R.[Richard],
Toward Operational Compensation of Ionospheric Effects in SAR Interferograms: The Split-Spectrum Method,
GeoRS(54), No. 3, March 2016, pp. 1446-1461.
IEEE DOI 1603
Accuracy BibRef

Hu, C.[Cheng], Li, Y.H.[Yuan-Hao], Dong, X.[Xichao], Cui, C.[Chang], Long, T.[Teng],
Impacts of Temporal-Spatial Variant Background Ionosphere on Repeat-Track GEO D-InSAR System,
RS(8), No. 11, 2016, pp. 916.
DOI Link 1612
BibRef

Zhang, Y., Jehle, M., Li, L., Dong, Z., Liang, D.,
Comment on 'Measurement of Ionospheric TEC in Spaceborne SAR Data',
GeoRS(54), No. 2, February 2016, pp. 1240-1242.
IEEE DOI 1601
Bandwidth BibRef

Yoon, M., Kim, D., Lee, J.,
Validation of Ionospheric Spatial Decorrelation Observed During Equatorial Plasma Bubble Events,
GeoRS(55), No. 1, January 2017, pp. 261-271.
IEEE DOI 1701
bubbles BibRef

Gomba, G., Rodríguez-González, F., de Zan, F.,
Ionospheric Phase Screen Compensation for the Sentinel-1 TOPS and ALOS-2 ScanSAR Modes,
GeoRS(55), No. 1, January 2017, pp. 223-235.
IEEE DOI 1701
ionospheric disturbances BibRef

Gomba, G., de Zan, F.,
Bayesian Data Combination for the Estimation of Ionospheric Effects in SAR Interferograms,
GeoRS(55), No. 11, November 2017, pp. 6582-6593.
IEEE DOI 1711
Azimuth, Bayes methods, Extraterrestrial measurements, Faraday effect, Ionosphere, Ionosphere estimation, SAR ionospheric effects, interferometric synthetic aperture radar (SAR). BibRef

Hu, C., Li, Y., Dong, X., Wang, R., Ao, D.,
Performance Analysis of L-Band Geosynchronous SAR Imaging in the Presence of Ionospheric Scintillation,
GeoRS(55), No. 1, January 2017, pp. 159-172.
IEEE DOI 1701
BibRef
And: Corrections: GeoRS(55), No. 1, January 2017, pp. 615-615.
IEEE DOI 1701
Performance evaluation; Synthetic aperture radar; Global Positioning System BibRef

Wang, C., Chen, L., Liu, L.,
A New Analytical Model to Study the Ionospheric Effects on VHF/UHF Wideband SAR Imaging,
GeoRS(55), No. 8, August 2017, pp. 4545-4557.
IEEE DOI 1708
Analytical models, Azimuth, Bandwidth, Biomass, Radar polarimetry, Synthetic aperture radar, Taylor series, Ionospheric effects, Legendre orthogonal polynomials, synthetic, aperture, radar, (SAR), imaging, degradation BibRef

Belcher, D.P., Mannix, C.R., Cannon, P.S.,
Measurement of the Ionospheric Scintillation Parameter C_kL From SAR Images of Clutter,
GeoRS(55), No. 10, October 2017, pp. 5937-5943.
IEEE DOI 1710
atmospheric turbulence, ionospheric techniques, optical transfer function, BibRef

Mannix, C.R., Belcher, D.P., Cannon, P.S.,
Measurement of Ionospheric Scintillation Parameters From SAR Images Using Corner Reflectors,
GeoRS(55), No. 12, December 2017, pp. 6695-6702.
IEEE DOI 1712
Extraterrestrial measurements, Ionosphere, Radar tracking, Satellites, Spaceborne radar, Synthetic aperture radar, Ionosphere, synthetic aperture radar BibRef

Fattahi, H., Simons, M., Agram, P.,
InSAR Time-Series Estimation of the Ionospheric Phase Delay: An Extension of the Split Range-Spectrum Technique,
GeoRS(55), No. 10, October 2017, pp. 5984-5996.
IEEE DOI 1710
Global Positioning System, ionosphere, synthetic aperture radar, time series, earthquake-induced ground displacement, BibRef

Freeman, A., Pi, X., Heggy, E.,
Radar Sounding Through the Earth's Ionosphere at 45 MHz,
GeoRS(55), No. 10, October 2017, pp. 5833-5842.
IEEE DOI 1710
ionospheric techniques, Mars, earths ionosphere, ice layers, radar sounding, retrieve local depth, spaceborne remote sensing, Airborne radar, Earth, Ground penetrating radar, Ice, Ionosphere, Spaceborne radar, Ionospheric propagation, radar sounding, very, high, frequency, (VHF) BibRef

Kim, J.S., Papathanassiou, K.P., Sato, H., Quegan, S.,
Detection and Estimation of Equatorial Spread F Scintillations Using Synthetic Aperture Radar,
GeoRS(55), No. 12, December 2017, pp. 6713-6725.
IEEE DOI 1712
Azimuth, Geometry, Ionosphere, Magnetic resonance imaging, Orbits, Plasmas, Synthetic aperture radar, Ionosphere, scintillations, synthetic aperture radar (SAR) BibRef

Wang, C.[Cheng], Chen, L.[Liang], Zhao, H.S.[Hai-Sheng], Lu, Z.[Zheng], Bian, M.M.[Ming-Ming], Zhang, R.N.[Run-Ning], Feng, J.[Jian],
Ionospheric Reconstructions Using Faraday Rotation in Spaceborne Polarimetric SAR Data,
RS(9), No. 11, 2017, pp. xx-yy.
DOI Link 1712
BibRef

Guo, W.L.[Wu-Long], Liu, L.[Lu], Liu, B.[Bo], Chen, L.[Liang], Zhao, H.S.[Hai-Sheng], Wang, C.[Cheng],
Improved Faraday Rotation Estimation in Spaceborne PolSAR Data Using Total Variation Denoising,
RS(11), No. 24, 2019, pp. xx-yy.
DOI Link 1912
BibRef

Krypiak-Gregorczyk, A.[Anna], Wielgosz, P.[Pawel], Borkowski, A.[Andrzej],
Ionosphere Model for European Region Based on Multi-GNSS Data and TPS Interpolation,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Jia, C.[Chun], Zhao, L.[Lin], Li, L.[Liang], Li, H.[Hui], Cheng, J.H.[Jian-Hua], Li, Z.[Zishen],
Improving the Triple-Carrier Ambiguity Resolution with a New Ionosphere-Free and Variance-Restricted Method,
RS(9), No. 11, 2017, pp. xx-yy.
DOI Link 1712
BibRef

Wang, C.[Cheng], Shi, C.[Chuang], Fan, L.[Lei], Zhang, H.P.[Hong-Ping],
Improved Modeling of Global Ionospheric Total Electron Content Using Prior Information,
RS(10), No. 1, 2018, pp. xx-yy.
DOI Link 1802
BibRef

Zhang, X.[Xin], Yao, D.[Di], Yang, Q.A.[Qi-Ang], Dong, Y.[Yingning], Deng, W.[Weibo],
Knowledge-Based Generalized Side-Lobe Canceller for Ionospheric Clutter Suppression in HFSWR,
RS(10), No. 1, 2018, pp. xx-yy.
DOI Link 1802
BibRef

Nie, W.F.[Wen-Feng], Xu, T.[Tianhe], Rovira-Garcia, A.[Adrià], Zornoza, J.M.J.[José Miguel Juan], Subirana, J.S.[Jaume Sanz], González-Casado, G.[Guillermo], Chen, W.[Wu], Xu, G.C.[Guo-Chang],
The Impacts of the Ionospheric Observable and Mathematical Model on the Global Ionosphere Model,
RS(10), No. 2, 2018, pp. xx-yy.
DOI Link 1804
BibRef

Deng, C.L.[Chen-Long], Tang, W.M.[Wei-Ming], Cui, J.H.[Jian-Hui], Shen, M.X.[Ming-Xing], Li, Z.N.[Zong-Nan], Zou, X.[Xuan], Zhang, Y.F.[Yong-Feng],
Triple-Frequency Code-Phase Combination Determination: A Comparison with the Hatch-Melbourne-Wübbena Combination Using BDS Signals,
RS(10), No. 2, 2018, pp. xx-yy.
DOI Link 1804
BibRef

Liu, L.[Lei], Yao, Y.[Yibin], Kong, J.[Jian], Shan, L.[Lulu],
Plasmaspheric Electron Content Inferred from Residuals between GNSS-Derived and TOPEX/JASON Vertical TEC Data,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Liu, Y.[Yang], Fu, L.J.[Lian-Jie], Wang, J.L.[Jin-Ling], Zhang, C.X.[Chun-Xi],
Studying Ionosphere Responses to a Geomagnetic Storm in June 2015 with Multi-Constellation Observations,
RS(10), No. 5, 2018, pp. xx-yy.
DOI Link 1806
BibRef

Zhang, Q.A.[Qi-Ang], Zhao, Q.[Qile],
Global Ionosphere Mapping and Differential Code Bias Estimation during Low and High Solar Activity Periods with GIMAS Software,
RS(10), No. 5, 2018, pp. xx-yy.
DOI Link 1806
BibRef

Rudenko, S., Bloßfeld, M., Müller, H., Dettmering, D., Angermann, D., Seitz, M.,
Evaluation of DTRF2014, ITRF2014, and JTRF2014 by Precise Orbit Determination of SLR Satellites,
GeoRS(56), No. 6, June 2018, pp. 3148-3158.
IEEE DOI 1806
Atmospheric modeling, Computational modeling, Earth, Planetary orbits, Satellites, Time series analysis, Altimetry, terrestrial reference frames (TRFs) BibRef

Moreno, E.M.[Enrique Monte], Rigo, A.G.[Alberto García], Hernández-Pajares, M.[Manuel], Yang, H.[Heng],
TEC Forecasting Based on Manifold Trajectories,
RS(10), No. 7, 2018, pp. xx-yy.
DOI Link 1808
Total Electron Content. Ionosphere. BibRef

Alfonsi, L., Povero, G., Spogli, L., Cesaroni, C., Forte, B., Mitchell, C.N., Burston, R., Veettil, S.V., Aquino, M., Klausner, V., de Assis Honorato Muella, M.T., Pezzopane, M., Giuntini, A., Hunstad, I., De Franceschi, G., Musicò, E., Pini, M., La The, V., Tran Trung, H., Husin, A., Ekawati, S., de la Cruz-Cayapan, C.V., Abdullah, M., Mat Daud, N., Minh, L.H., Floury, N.,
Analysis of the Regional Ionosphere at Low Latitudes in Support of the Biomass ESA Mission,
GeoRS(56), No. 11, November 2018, pp. 6412-6424.
IEEE DOI 1811
Ionosphere, Biomass, Global navigation satellite system, Synthetic aperture radar, Receivers, Plasmas, Magnetosphere, total electron content (TEC) gradients BibRef

dos Santos Prol, F.[Fabricio], Hernández-Pajares, M.[Manuel], de Assis Honorato Muella, M.T.[Marcio Tadeu], de Oliveira Camargo, P.[Paulo],
Tomographic Imaging of Ionospheric Plasma Bubbles Based on GNSS and Radio Occultation Measurements,
RS(10), No. 10, 2018, pp. xx-yy.
DOI Link 1811
BibRef

dos Santos Prol, F.[Fabricio], de Oliveira Camargo, P.[Paulo], Hernández-Pajares, M.[Manuel], de Assis Honorato Muella, M.T.[Marcio Tadeu],
A New Method for Ionospheric Tomography and Its Assessment by Ionosonde Electron Density, GPS TEC, and Single-Frequency PPP,
GeoRS(57), No. 5, May 2019, pp. 2571-2582.
IEEE DOI 1905
electron density, F-region, geophysical signal processing, Global Positioning System, image reconstruction, ionosphere, radio occultation (RO) BibRef

Hu, A.[Andong], Zhang, K.[Kefei],
Using Bidirectional Long Short-Term Memory Method for the Height of F2 Peak Forecasting from Ionosonde Measurements in the Australian Region,
RS(10), No. 10, 2018, pp. xx-yy.
DOI Link 1811
BibRef
And: Correction: RS(10), No. 11, 2018, pp. xx-yy.
DOI Link 1812
BibRef

Niu, C., Zhang, J., Wang, Q., Liang, J.,
Weakly Supervised Semantic Segmentation for Joint Key Local Structure Localization and Classification of Aurora Image,
GeoRS(56), No. 12, December 2018, pp. 7133-7146.
IEEE DOI 1812
Magnetosphere, Ion radiation effects, Image segmentation, Semantics, Shape, Analytical models, Training, Aurora image analysis, weakly supervised semantic segmentation (WSSS) BibRef

Yang, H.[Heng], Moreno, E.M.[Enrique Monte], Hernández-Pajares, M.[Manuel],
Detection and Description of the Different Ionospheric Disturbances that Appeared during the Solar Eclipse of 21 August 2017,
RS(10), No. 11, 2018, pp. xx-yy.
DOI Link 1812
BibRef

Hosseini, P., Golkowski, M., Chorsi, H.T., Gedney, S.D., Moore, R.C.,
Using Eccentricity to Locate Ionospheric Exit Points of Magnetospheric Whistler Mode Waves,
GeoRS(56), No. 12, December 2018, pp. 7049-7061.
IEEE DOI 1812
Magnetosphere, Ionosphere, Receivers, Magnetic domains, Time-domain analysis, Electromagnetic waveguides, remote sensing BibRef

Norberg, J., Vierinen, J., Roininen, L., Orispää, M., Kauristie, K., Rideout, W.C., Coster, A.J., Lehtinen, M.S.,
Gaussian Markov Random Field Priors in Ionospheric 3-D Multi-Instrument Tomography,
GeoRS(56), No. 12, December 2018, pp. 7009-7021.
IEEE DOI 1812
Extraterrestrial measurements, Satellites, Global navigation satellite system, Density measurement, multi-instrument BibRef

Zhou, C., Liu, Y., Tang, Q., Gu, X., Ni, B., Zhao, Z.,
Investigation on the Occurrence of Mid-Latitude E-Region Irregularity by Wuhan VHF Radar and Its Relationship With Sporadic E layer,
GeoRS(56), No. 12, December 2018, pp. 7207-7216.
IEEE DOI 1812
Doppler effect, Doppler radar, Radar scattering, Modulation, Signal to noise ratio, Radar antennas, Continuous echoes, very high-frequency (VHF) radar BibRef

Liu, H., Liu, Z., Liu, S., Liu, Y., Bin, J., Shi, F., Dong, H.,
A Nonlinear Regression Application via Machine Learning Techniques for Geomagnetic Data Reconstruction Processing,
GeoRS(57), No. 1, January 2019, pp. 128-140.
IEEE DOI 1901
Machine learning, Data models, Training, Support vector machines, Vegetation, Machine learning algorithms, Predictive models, reconstruction BibRef

Zhao, C., Yuan, Y., Zhang, B., Li, M.,
Ionosphere Sensing With a Low-Cost, Single-Frequency, Multi-GNSS Receiver,
GeoRS(57), No. 2, February 2019, pp. 881-892.
IEEE DOI 1901
Receivers, Ionosphere, Satellites, Sensors, Global Positioning System, Global navigation satellite system, vertical total electron content (VTEC) BibRef

Liu, Y.[Yuhan], Jin, S.G.[Shuang-Gen],
Ionospheric Rayleigh Wave Disturbances Following the 2018 Alaska Earthquake from GPS Observations,
RS(11), No. 8, 2019, pp. xx-yy.
DOI Link 1905
BibRef

Wang, S., Huang, S., Lu, S., Yan, B.,
3-D Ionospheric Tomography Using Model Function in the Modified L-Curve Method,
GeoRS(57), No. 6, June 2019, pp. 3135-3147.
IEEE DOI 1906
Global navigation satellite system, Tomography, Computational modeling, Receivers, Covariance matrices, Tikhonov regularization method BibRef

Fu, N.[Naifeng], Guo, P.[Peng], Wu, M.J.[Meng-Jie], Huang, Y.[Yong], Hu, X.[Xiaogong], Hong, Z.[Zhenjie],
The Two-Parts Step-by-Step Ionospheric Assimilation Based on Ground-Based/Spaceborne Observations and Its Verification,
RS(11), No. 10, 2019, pp. xx-yy.
DOI Link 1906
BibRef
And: Correction: RS(11), No. 17, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Liu, Z.D.[Zhen-Di], Fang, H.X.[Han-Xian], Hoque, M.M., Weng, L.B.[Li-Bin], Yang, S.G.[Sheng-Gao], Gao, Z.[Ze],
A New Empirical Model of NmF2 Based on CHAMP, GRACE, and COSMIC Radio Occultation,
RS(11), No. 11, 2019, pp. xx-yy.
DOI Link 1906
NmF2 observational data from ionospheric radio occultation. BibRef

Wang, H.[Han], Luo, J.[Jia], Xu, X.H.[Xiao-Hua],
Ionospheric Peak Parameters Retrieved from FY-3C Radio Occultation: A Statistical Comparison with Measurements from COSMIC RO and Digisondes Over the Globe,
RS(11), No. 12, 2019, pp. xx-yy.
DOI Link 1907
BibRef

Xiang, Y.[Yan], Gao, Y.[Yang],
An Enhanced Mapping Function with Ionospheric Varying Height,
RS(11), No. 12, 2019, pp. xx-yy.
DOI Link 1907
BibRef

Savastano, G.[Giorgio], Komjathy, A.[Attila], Shume, E.[Esayas], Vergados, P.[Panagiotis], Ravanelli, M.[Michela], Verkhoglyadova, O.[Olga], Meng, X.[Xing], Crespi, M.[Mattia],
Advantages of Geostationary Satellites for Ionospheric Anomaly Studies: Ionospheric Plasma Depletion Following a Rocket Launch,
RS(11), No. 14, 2019, pp. xx-yy.
DOI Link 1908
BibRef

Thayaparan, T., Dupont, D., Ibrahim, Y., Riddolls, R.,
High-Frequency Ionospheric Monitoring System for Over-the-Horizon Radar in Canada,
GeoRS(57), No. 9, September 2019, pp. 6372-6384.
IEEE DOI 1909
Radar, Ray tracing, Ionosphere, Sea surface, Earth, Radar antennas, Monitoring, High-frequency (HF) radar, skywave radar BibRef

Yang, H.[Heng], Moreno, E.M.[Enrique Monte], Hernández-Pajares, M.[Manuel],
ADDTID: An Alternative Tool for Studying Earthquake/Tsunami Signatures in the Ionosphere. Case of the 2011 Tohoku Earthquake,
RS(11), No. 16, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Han, D.[Deokhwa], Kim, D.[Donguk], Song, J.[Junesol], Kee, C.[Changdon],
Improving the Accuracy of Regional Ionospheric Mapping with Double-Difference Carrier Phase Measurement,
RS(11), No. 16, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Mohanty, S., Carrano, C.S., Singh, G.,
Effect of Anisotropy on Ionospheric Scintillations Observed by SAR,
GeoRS(57), No. 9, September 2019, pp. 6888-6899.
IEEE DOI 1909
Anisotropic magnetoresistance, Synthetic aperture radar, Perpendicular magnetic anisotropy, Spaceborne radar, Ionosphere, scintillation BibRef

Liang, C., Agram, P., Simons, M., Fielding, E.J.,
Ionospheric Correction of InSAR Time Series Analysis of C-band Sentinel-1 TOPS Data,
GeoRS(57), No. 9, September 2019, pp. 6755-6773.
IEEE DOI 1909
Ionosphere, Ionization, Earth, Sun, Time series analysis, Synthetic aperture radar, Ionosphere, terrain observation by progressive scans (TOPS) BibRef

Hu, Z.[Zhongbo], Mallorquí, J.J.[Jordi J.],
An Accurate Method to Correct Atmospheric Phase Delay for InSAR with the ERA5 Global Atmospheric Model,
RS(11), No. 17, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Liu, Y., Zhou, C., Tang, Q., Kong, J., Gu, X., Ni, B., Yao, Y., Zhao, Z.,
Evidence of Mid- and Low-Latitude Nighttime Ionospheric E-F Coupling: Coordinated Observations of Sporadic E Layers, F-Region Field-Aligned Irregularities, and Medium-Scale Traveling Ionospheric Disturbances,
GeoRS(57), No. 10, October 2019, pp. 7547-7557.
IEEE DOI 1910
electron density, E-region, F-region, ionospheric disturbances, ionospheric electromagnetic wave propagation, polarized electric field BibRef

Xu, W., Marshall, R.A., Kero, A., Turunen, E., Drob, D., Sojka, J., Rice, D.,
VLF Measurements and Modeling of the D-Region Response to the 2017 Total Solar Eclipse,
GeoRS(57), No. 10, October 2019, pp. 7613-7622.
IEEE DOI 1910
D-region, electron density, ionospheric disturbances, ionospheric electromagnetic wave propagation, VLF BibRef

Luo, X.M.[Xiao-Min], Lou, Y.D.[Yi-Dong], Gu, S.F.[Sheng-Feng], Song, W.W.[Wei-Wei],
A Strategy to Mitigate the Ionospheric Scintillation Effects on BDS Precise Point Positioning: Cycle-Slip Threshold Model,
RS(11), No. 21, 2019, pp. xx-yy.
DOI Link 1911
BibRef

Peng, Y.[YuXiang], Scales, W.A.[Wayne A.],
Satellite Formation Flight Simulation Using Multi-Constellation GNSS and Applications to Ionospheric Remote Sensing,
RS(11), No. 23, 2019, pp. xx-yy.
DOI Link 1912
BibRef

Ahmed, W.A.[Wasiu Akande], Wu, F.L.[Fa-Lin], Marlia, D.[Dessi], Ednofri, Zhao, Y.[Yan],
Mitigation of Ionospheric Scintillation Effects on GNSS Signals with VMD-MFDFA,
RS(11), No. 23, 2019, pp. xx-yy.
DOI Link 1912
BibRef

Liu, Z.W.[Zhi-Wei], Zhou, C.[Cui], Fu, H.Q.[Hai-Qiang], Zhu, J.J.[Jian-Jun], Zuo, T.Y.[Ting-Ying],
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Kamal, S.[Sumon], Jakowski, N.[Norbert], Hoque, M.M.[Mohammed M.], Wickert, J.[Jens],
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Jonah, O.F.[Olusegun F.], Zhang, S.[Shunrong], Coster, A.J.[Anthea J.], Goncharenko, L.P.[Larisa P.], Erickson, P.J.[Philip J.], Rideout, W.[William], de Paula, E.R.[Eurico R.], de Jesus, R.[Rodolfo],
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Synthetic aperture radar, Clocks, Azimuth, Ionosphere, Perturbation methods, Spaceborne radar, Geometry, Bistatic SAR, synthetic aperture radar (SAR) BibRef

Chen, G., Li, Y., Zhang, S., Ning, B., Gong, W., Yoshikawa, A., Hozumi, K., Tsugawa, T., Wang, Z.,
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Ionosphere, Tides, Radar, Magnetometers, Atmosphere, Asia, Perturbation methods, Atmosphere and ionosphere coupling, sudden stratospheric warming (SSW) BibRef

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IEEE DOI 2001
Global navigation satellite system, Receivers, Satellite broadcasting, Global Positioning System, Satellites, total electron content (TEC) BibRef

Wang, J.[Jin], Huang, G.W.[Guan-Wen], Zhou, P.Y.[Pei-Yuan], Yang, Y.X.[Yuan-Xi], Zhang, Q.[Qin], Gao, Y.[Yang],
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An, X.D.[Xiang-Dong], Meng, X.L.[Xiao-Lin], Chen, H.[Hua], Jiang, W.P.[Wei-Ping], Xi, R.[Ruijie], Chen, Q.[Qusen],
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Liu, T.X.[Tong-Xin], Yang, G.B.[Guo-Bin], Zhao, Z.Y.[Zheng-Yu], Jiang, C.H.[Chun-Hua], Hu, Y.G.[Yao-Gai],
Application of Beamforming Technology in Ionospheric Oblique Backscatter Sounding with a Miniaturized L-Array,
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Wen, Y.[Yiduo], Jin, S.[Shuanggen],
Traveling Ionospheric Disturbances Characteristics during the 2018 Typhoon Maria from GPS Observations,
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Li, W.[Wang], Zhao, D.S.[Dong-Sheng], He, C.Y.[Chang-Yong], Hu, A.[Andong], Zhang, K.[Kefei],
Advanced Machine Learning Optimized by The Genetic Algorithm in Ionospheric Models Using Long-Term Multi-Instrument Observations,
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Rajabi, M.[Mahmoud], Amiri-Simkooei, A.[Alireza], Nahavandchi, H.[Hossein], Nafisi, V.[Vahab],
Modeling and Prediction of Regular Ionospheric Variations and Deterministic Anomalies,
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Håkansson, M.[Martin],
Nadir-Dependent GNSS Code Biases and their Effect on 2D and 3D Ionosphere Modeling,
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Marchetti, D.[Dedalo], De Santis, A.[Angelo], Jin, S.G.[Shuang-Gen], Campuzano, S.A.[Saioa A.], Cianchini, G.[Gianfranco], Piscini, A.[Alessandro],
Co-Seismic Magnetic Field Perturbations Detected by Swarm Three-Satellite Constellation,
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Assimilating VLF Transmitter Observations With an LETKF for Spatial Estimates of the D-Region Ionosphere,
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Data assimilation, Earth-ionosphere waveguide, ensemble Kalman filter (EnKF), ionosphere, very low frequency (VLF) BibRef

Ji, Y., Zhang, Y., Dong, Z., Zhang, Q., Li, D., Yao, B.,
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Azimuth-imaging degradation, decorrelations, geosynchronous synthetic aperture radar (GEO SAR), scintillation BibRef

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Target State and Markovian Jump Ionospheric Height Bias Estimation for OTHR Tracking Systems,
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Radar tracking, Target tracking, Ionosphere, Estimation, Clutter, Frequency measurement, Bias estimation, target tracking BibRef

Erdogan, E.[Eren], Schmidt, M.[Michael], Goss, A.[Andreas], Görres, B.[Barbara], Seitz, F.[Florian],
Adaptive Modeling of the Global Ionosphere Vertical Total Electron Content,
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Estimation of the Ionosphere Critical Frequency Without Radio Sounding,
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Resonant frequency, Ionosphere, Ions, Frequency estimation, Spectrogram, Magnetic analysis, remote monitoring BibRef

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MIMO channel measurements on a ionospheric HF (3-30 MHz) radio link,
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Array signal processing BibRef

Hall, B., Na, H.,
Measures of information content for computerized ionospheric tomography,
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Sutton, E., Na, H.,
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