15.3.1.11.7 GPS, GNSS Ionospheric Effects, Ionospheric Delay

Chapter Contents (Back)
Ionosphere. GPS. GNSS.
See also Ionosphere, Ionosphere Tomography, Reflections, Ionospheric Effects.

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

Wang, J.[Jun], Morton, Y.T.,
High-Latitude Ionospheric Irregularity Drift Velocity Estimation Using Spaced GPS Receiver Carrier Phase Time-Frequency Analysis,
GeoRS(53), No. 11, November 2015, pp. 6099-6113.
IEEE DOI 1509
Global Positioning System BibRef

Srinivas, V.S., Sarma, A.D., Achanta, H.K.,
Modeling of Ionospheric Time Delay Using Anisotropic IDW With Jackknife Technique,
GeoRS(54), No. 1, January 2016, pp. 513-519.
IEEE DOI 1601
Global Positioning System BibRef

Khodabandeh, A., Teunissen, P.J.G.,
Array-Aided Multifrequency GNSS Ionospheric Sensing: Estimability and Precision Analysis,
GeoRS(54), No. 10, October 2016, pp. 5895-5913.
IEEE DOI 1610
Global Positioning System 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

Lee, J., Morton, Y.T.J., Lee, J., Moon, H.S., Seo, J.,
Monitoring and Mitigation of Ionospheric Anomalies for GNSS-Based Safety Critical Systems: A review of up-to-date signal processing techniques,
SPMag(34), No. 5, September 2017, pp. 96-110.
IEEE DOI 1709
Decorrelation, Delays, Ionosphere, Monitoring, Receivers, Satellites 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.[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

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

Peng, Y.X.[Yu-Xiang], 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

Zhao, D.S.[Dong-Sheng], Hancock, C.M.[Craig M.], Roberts, G.W.[Gethin Wyn], Jin, S.G.[Shuang-Gen],
Cycle Slip Detection during High Ionospheric Activities Based on Combined Triple-Frequency GNSS Signals,
RS(11), No. 3, 2019, pp. xx-yy.
DOI Link 1902
BibRef

Su, K.[Ke], Jin, S.G.[Shuang-Gen], Hoque, M.M.,
Evaluation of Ionospheric Delay Effects on Multi-GNSS Positioning Performance,
RS(11), No. 2, 2019, pp. xx-yy.
DOI Link 1902
BibRef

Wang, A.[Ahao], Chen, J.P.[Jun-Ping], Zhang, Y.[Yize], Meng, L.[Lingdong], Wang, J.[Jiexian],
Performance of Selected Ionospheric Models in Multi-Global Navigation Satellite System Single-Frequency Positioning over China,
RS(11), No. 17, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Wang, D.[Di], Luo, X.[Xiaowen], Wang, J.[Jinling], Gao, J.[Jinyao], Zhang, T.[Tao], Wu, Z.[Ziyin], Yang, C.[Chunguo], Wu, Z.[Zhaocai],
Global Ionospheric Model Accuracy Analysis Using Shipborne Kinematic GPS Data in the Arctic Circle,
RS(11), No. 17, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Choi, B.K.[Byung-Kyu], Sohn, D.H.[Dong-Hyo], Lee, S.J.[Sang Jeong],
Correlation between Ionospheric TEC and the DCB Stability of GNSS Receivers from 2014 to 2016,
RS(11), No. 22, 2019, pp. xx-yy.
DOI Link 1911
BibRef
And: Reply to comments: RS(12), No. 21, 2020, pp. xx-yy.
DOI Link 2011
Comments:
See also Comment on Choi et al. Correlation between Ionospheric TEC and the DCB Stability of GNSS Receivers from 2014 to 2016. Remote Sens. 2019, 11, 2657. BibRef

Yang, H.Y.[Hai-Yan], Yang, X.H.[Xu-Hai], Zhang, Z.[Zhe], Sun, B.Q.[Bao-Qi], Qin, W.J.[Wei-Jin],
Evaluation of the Effect of Higher-Order Ionospheric Delay on GPS Precise Point Positioning Time Transfer,
RS(12), No. 13, 2020, pp. xx-yy.
DOI Link 2007
BibRef

Zhong, J.[Jiahao], Lei, J.[Jiuhou], Yue, X.[Xinan],
Comment on Choi et al. Correlation between Ionospheric TEC and the DCB Stability of GNSS Receivers from 2014 to 2016. Remote Sens. 2019, 11, 2657,
RS(12), No. 21, 2020, pp. xx-yy.
DOI Link 2011
Paper and reply:
See also Correlation between Ionospheric TEC and the DCB Stability of GNSS Receivers from 2014 to 2016. BibRef

She, C., Yue, X., Hu, L., Zhang, F.,
Estimation of Ionospheric Total Electron Content From a Multi-GNSS Station in China,
GeoRS(58), No. 2, February 2020, pp. 852-860.
IEEE DOI 2001
Global navigation satellite system, Receivers, Satellite broadcasting, Global Positioning System, Satellites, total electron content (TEC) BibRef

An, X.D.[Xiang-Dong], Meng, X.L.[Xiao-Lin], Chen, H.[Hua], Jiang, W.P.[Wei-Ping], Xi, R.[Ruijie], Chen, Q.[Qusen],
Modelling Global Ionosphere Based on Multi-Frequency, Multi-Constellation GNSS Observations and IRI Model,
RS(12), No. 3, 2020, pp. xx-yy.
DOI Link 2002
BibRef

Håkansson, M.[Martin],
Nadir-Dependent GNSS Code Biases and their Effect on 2D and 3D Ionosphere Modeling,
RS(12), No. 6, 2020, pp. xx-yy.
DOI Link 2003
BibRef

Gao, C.[Chao], Jin, S.[Shuanggen], Yuan, L.L.[Liang-Liang],
Ionospheric Responses to the June 2015 Geomagnetic Storm from Ground and LEO GNSS Observations,
RS(12), No. 14, 2020, pp. xx-yy.
DOI Link 2007
BibRef

Tang, L.[Long], Chen, W.[Wu], Louis, O.P.[Osei-Poku], Chen, M.L.[Ming-Li],
Study on Seasonal Variations of Plasma Bubble Occurrence over Hong Kong Area Using GNSS Observations,
RS(12), No. 15, 2020, pp. xx-yy.
DOI Link 2008
BibRef

Kotulak, K.[Kacper], Zakharenkova, I.[Irina], Krankowski, A.[Andrzej], Cherniak, I.[Iurii], Wang, N.[Ningbo], Fron, A.[Adam],
Climatology Characteristics of Ionospheric Irregularities Described with GNSS ROTI,
RS(12), No. 16, 2020, pp. xx-yy.
DOI Link 2008
BibRef

Poniatowski, M.[Mateusz], Nykiel, G.[Grzegorz],
Degradation of Kinematic PPP of GNSS Stations in Central Europe Caused by Medium-Scale Traveling Ionospheric Disturbances During the St. Patrick's Day 2015 Geomagnetic Storm,
RS(12), No. 21, 2020, pp. xx-yy.
DOI Link 2011
BibRef

Liu, C.L.[Cong-Liang], Kirchengast, G.[Gottfried], Syndergaard, S.[Stig], Schwaerz, M.[Marc], Danzer, J.[Julia], Sun, Y.Q.[Yue-Qiang],
New Higher-Order Correction of GNSS RO Bending Angles Accounting for Ionospheric Asymmetry: Evaluation of Performance and Added Value,
RS(12), No. 21, 2020, pp. xx-yy.
DOI Link 2011
BibRef

Molina, C.[Carlos], Camps, A.[Adriano],
First Evidences of Ionospheric Plasma Depletions Observations Using GNSS-R Data from CYGNSS,
RS(12), No. 22, 2020, pp. xx-yy.
DOI Link 2011
BibRef

Wen, Y.[Yiduo], Jin, S.[Shuanggen],
Traveling Ionospheric Disturbances Characteristics during the 2018 Typhoon Maria from GPS Observations,
RS(12), No. 4, 2020, pp. xx-yy.
DOI Link 2003
BibRef

Yasyukevich, Y.[Yury], Vasilyev, R.[Roman], Ratovsky, K.[Konstantin], Setov, A.[Artem], Globa, M.[Maria], Syrovatskii, S.[Semen], Yasyukevich, A.[Anna], Kiselev, A.[Alexander], Vesnin, A.[Artem],
Small-Scale Ionospheric Irregularities of Auroral Origin at Mid-latitudes during the 22 June 2015 Magnetic Storm and Their Effect on GPS Positioning,
RS(12), No. 10, 2020, pp. xx-yy.
DOI Link 2006
BibRef

Akgul, V.[Volkan], Gurbuz, G.[Gokhan], Kutoglu, S.H.[Senol Hakan], Jin, S.[Shuanggen],
Effects of the High-Order Ionospheric Delay on GPS-Based Tropospheric Parameter Estimations in Turkey,
RS(12), No. 21, 2020, pp. xx-yy.
DOI Link 2011
BibRef

Li, W.[Wang], Zhao, D.S.[Dong-Sheng], Shen, Y.[Yi], Zhang, K.F.[Ke-Fei],
Modeling Australian TEC Maps Using Long-Term Observations of Australian Regional GPS Network by Artificial Neural Network-Aided Spherical Cap Harmonic Analysis Approach,
RS(12), No. 23, 2020, pp. xx-yy.
DOI Link 2012
Total Electron Content. BibRef

Kim, M.Y.[Ming-Yu], Kim, J.[Jeongrae],
SBAS-Aided GPS Positioning with an Extended Ionosphere Map at the Boundaries of WAAS Service Area,
RS(13), No. 1, 2021, pp. xx-yy.
DOI Link 2101
BibRef

Jin, S.G.[Shuang-Gen], Gao, C.[Chao], Yuan, L.L.[Liang-Liang], Guo, P.[Peng], Calabia, A.[Andres], Ruan, H.[Haibing], Luo, P.[Peng],
Long-Term Variations of Plasmaspheric Total Electron Content from Topside GPS Observations on LEO Satellites,
RS(13), No. 4, 2021, pp. xx-yy.
DOI Link 2103
BibRef

Ren, X., Chen, J., Li, X., Zhang, X.,
Ionospheric Total Electron Content Estimation Using GNSS Carrier Phase Observations Based on Zero-Difference Integer Ambiguity: Methodology and Assessment,
GeoRS(59), No. 1, January 2021, pp. 817-830.
IEEE DOI 2012
Delays, Satellites, Ionosphere, Global navigation satellite system, Receivers, Satellite broadcasting, Reliability, Integer ambiguity, total electron content (TEC) BibRef

Yao, Y., Chen, X., Kong, J., Zhou, C., Liu, L., Shan, L., Guo, Z.,
An Updated Experimental Model of IG12 Indices Over the Antarctic Region via the Assimilation of IRI2016 With GNSS TEC,
GeoRS(59), No. 2, February 2021, pp. 1700-1717.
IEEE DOI 2101
Indexes, Data models, Ionosphere, Rough surfaces, Antarctica, Global navigation satellite system, Magnetosphere, spherical crown harmonic fitting BibRef

Prol, F.S.[Fabricio S.], Hoque, M.M.[M. Mainul],
Topside Ionosphere and Plasmasphere Modelling Using GNSS Radio Occultation and POD Data,
RS(13), No. 8, 2021, pp. xx-yy.
DOI Link 2104
BibRef

Peng, H.[Hai], Yao, Y.[Yibin], Kong, J.[Jian], Zhou, C.[Chen], Kuo, C.[Chungyen],
GNSS-Based Statistical Analysis of Ionospheric Anomalies During Typhoon Landings in Taiwan/Japan,
GeoRS(59), No. 6, June 2021, pp. 5272-5279.
IEEE DOI 2106
Tropical cyclones, Ionosphere, Global navigation satellite system, Indexes, Satellites, Storms, typhoon BibRef

Tang, J.[Jun], Gao, X.[Xin],
Adaptive Regularization Method for 3-D GNSS Ionospheric Tomography Based on the U-Curve,
GeoRS(59), No. 6, June 2021, pp. 4547-4560.
IEEE DOI 2106
Global navigation satellite system, Tomography, Ionosphere, Satellites, Receivers, Image reconstruction, Reliability, U-curve BibRef

Cheng, J.H.[Jian-Hua], Jiang, C.[Chao], Li, L.[Liang], Jia, C.[Chun], Qi, B.[Bing], Li, J.X.[Jia-Xiang],
Long Baseline Tightly Coupled DGNSS Positioning with Ionosphere-Free Inter-System Bias Calibration,
RS(13), No. 1, 2021, pp. xx-yy.
DOI Link 2101
BibRef

Aragon-Angel, A.[Angela], Rovira-Garcia, A.[Adria], Arcediano-Garrido, E.[Enrique], Ibáñez-Segura, D.[Deimos],
Galileo Ionospheric Correction Algorithm Integration into the Open-Source GNSS Laboratory Tool Suite (gLAB),
RS(13), No. 2, 2021, pp. xx-yy.
DOI Link 2101
BibRef

Li, D.[Dehai], Dang, Y.[Yaming], Yuan, Y.[Yunbin], Mi, J.Z.[Jin-Zhong],
A New Cycle-Slip Repair Method for Dual-Frequency BDS Against the Disturbances of Severe Ionospheric Variations and Pseudoranges with Large Errors,
RS(13), No. 5, 2021, pp. xx-yy.
DOI Link 2103
BibRef

Li, D.H.[De-Hai], Dang, Y.M.[Ya-Min], Yuan, Y.B.[Yun-Bin], Mi, J.Z.[Jin-Zhong],
Improved Cycle Slip Repair with GPS Triple-Frequency Measurements by Minifying the Influences of Ionospheric Variation and Pseudorange Errors,
RS(13), No. 4, 2021, pp. xx-yy.
DOI Link 2103
precise positioning. BibRef

Pezzopane, M.[Michael], Pignalberi, A.[Alessio], Coco, I.[Igino], Consolini, G.[Giuseppe], de Michelis, P.[Paola], Giannattasio, F.[Fabio], Marcucci, M.F.[Maria Federica], Tozzi, R.[Roberta],
Occurrence of GPS Loss of Lock Based on a Swarm Half-Solar Cycle Dataset and Its Relation to the Background Ionosphere,
RS(13), No. 11, 2021, pp. xx-yy.
DOI Link 2106
BibRef

Datta-Barua, S.[Seebany], Su, Y.[Yang], Rubio, A.L.[Aurora López], Bust, G.S.[Gary S.],
Ionospheric Irregularity Layer Height and Thickness Estimation With a GNSS Receiver Array,
GeoRS(59), No. 7, July 2021, pp. 6198-6207.
IEEE DOI 2106
Global navigation satellite system, Scattering, Receivers, Arrays, Global Positioning System, Satellite broadcasting, Plasmas, scintillation BibRef

Zhu, H.Z.[Hui-Zhong], Li, J.[Jun], Tang, L.J.[Long-Jiang], Ge, M.R.[Mao-Rong], Xu, A.G.[Ai-Gong],
Improving the Stochastic Model of Ionospheric Delays for BDS Long-Range Real-Time Kinematic Positioning,
RS(13), No. 14, 2021, pp. xx-yy.
DOI Link 2107
BibRef

Zhao, L.[Lewen], Douša, J.[Jan], Václavovic, P.[Pavel],
Accuracy Evaluation of Ionospheric Delay from Multi-Scale Reference Networks and Its Augmentation to PPP during Low Solar Activity,
IJGI(10), No. 8, 2021, pp. xx-yy.
DOI Link 2108
BibRef

Li, M.[Min], Yuan, Y.[Yunbin],
Estimation and Analysis of the Observable-Specific Code Biases Estimated Using Multi-GNSS Observations and Global Ionospheric Maps,
RS(13), No. 16, 2021, pp. xx-yy.
DOI Link 2109
BibRef

Lu, W.J.[Wei-Jun], Ma, G.[Guanyi], Wan, Q.[Qingtao],
A Review of Voxel-Based Computerized Ionospheric Tomography with GNSS Ground Receivers,
RS(13), No. 17, 2021, pp. xx-yy.
DOI Link 2109
BibRef

Milanowska, B.[Beata], Wielgosz, P.[Pawel], Krypiak-Gregorczyk, A.[Anna], Jarmolowski, W.[Wojciech],
Accuracy of Global Ionosphere Maps in Relation to Their Time Interval,
RS(13), No. 18, 2021, pp. xx-yy.
DOI Link 2109
BibRef


Kaselimi, M., Doulamis, N., Doulamis, A., Delikaraoglou, D.,
A Sequence-to-sequence Temporal Convolutional Neural Network For Ionosphere Prediction Using Gnss Observations,
ISPRS20(B3:813-820).
DOI Link 2012
BibRef

Chapter on Active Vision, Camera Calibration, Mobile Robots, Navigation, Road Following continues in
GPS Tropospheric Delay, Troposhperic Effects .


Last update:Nov 30, 2021 at 22:19:38