Generation of proxy GIM‐TEC for extreme storms before the era of GNSS observations

AbstractIonospheric irregularities can adversely affect the performance of Global Navigation Satellite System (GNSS). However, this opens the possibility of using GNSS as an effective ionospheric remote sensing tool. Despite ionospheric monitoring has been undertaken for decades, these irregularities in multiple spatial and temporal scales are still not fully understood. This paper reviews Virginia Tech’s recent studies on multi-scale ionospheric irregularities using ground-based and space-based GNSS observations. First, the relevant background of ionospheric irregularities and their impact on GNSS signals is reviewed. Next, three topics of ground-based observations of ionospheric irregularities for which GNSS and other ground-based techniques are used simultaneously are reviewed. Both passive and active measurements in high-latitude regions are covered. Modelling and observations in mid-latitude regions are considered as well. Emphasis is placed on the increased capability of assessing the multi-scale nature of ionospheric irregularities using other traditional techniques (e.g., radar, magnetometer, high frequency receivers) as well as GNSS observations (e.g., Total-Electron-Content or TEC, scintillation). Besides ground-based observations, recent advances in GNSS space-based ionospheric measurements are briefly reviewed. Finally, a new space-based ionospheric observation technique using GNSS-based spacecraft formation flying and a differential TEC method is demonstrated using the newly developed Virginia Tech Formation Flying Testbed (VTFFTB). Based on multi-constellation multi-band GNSS, the VTFFTB has been developed into a hardware-in-the-loop simulation testbed with external high-fidelity global ionospheric model(s) for 3-satellite formation flying, which can potentially be used for new multi-scale ionospheric measurement mission design.

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Precise Point Positioning Using Dual-Frequency GNSS Observations on Smartphone

Sensors ◽

10.3390/s19092189 ◽

2019 ◽

Vol 19 (9) ◽

pp. 2189 ◽

Cited By ~ 27

Author(s):

Qiong Wu ◽

Mengfei Sun ◽

Changjie Zhou ◽

Peng Zhang

Keyword(s):

Precise Point Positioning ◽

Frequency Mode ◽

Single Frequency ◽

Dual Frequency ◽

Static Mode ◽

Position Errors ◽

Point Positioning ◽

Similar Accuracy ◽

Positioning Algorithm ◽

Gnss Observations

The update of the Android system and the emergence of the dual-frequency GNSS chips enable smartphones to acquire dual-frequency GNSS observations. In this paper, the GPS L1/L5 and Galileo E1/E5a dual-frequency PPP (precise point positioning) algorithm based on RTKLIB and GAMP was applied to analyze the positioning performance of the Xiaomi Mi 8 dual-frequency smartphone in static and kinematic modes. The results showed that in the static mode, the RMS position errors of the dual-frequency smartphone PPP solutions in the E, N, and U directions were 21.8 cm, 4.1 cm, and 11.0 cm, respectively, after convergence to 1 m within 102 min. The PPP of dual-frequency smartphone showed similar accuracy with geodetic receiver in single-frequency mode, while geodetic receiver in dual-frequency mode has higher accuracy. In the kinematic mode, the positioning track of the smartphone dual-frequency data had severe fluctuations, the positioning tracks derived from the smartphone and the geodetic receiver showed approximately difference of 3–5 m.

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Estimation and Analysis of GNSS Differential Code Biases (DCBs) Using a Multi-Spacing Software Receiver

Sensors ◽

10.3390/s21020443 ◽

2021 ◽

Vol 21 (2) ◽

pp. 443

Author(s):

Ye Wang ◽

Lin Zhao ◽

Yang Gao

Keyword(s):

Primary Source ◽

Intermediate Frequency ◽

Global Navigation Satellite Systems ◽

Electron Content ◽

Software Receiver ◽

International Gnss Service ◽

Total Electron ◽

Satellite Systems ◽

Differential Code Biases ◽

Gnss Observations

In the use of global navigation satellite systems (GNSS) to monitor ionosphere variations by estimating total electron content (TEC), differential code biases (DCBs) in GNSS measurements are a primary source of errors. Satellite DCBs are currently estimated and broadcast to users by International GNSS Service (IGS) using a network of GNSS hardware receivers which are inside structure fixed. We propose an approach for satellite DCB estimation using a multi-spacing GNSS software receiver to analyze the influence of the correlator spacing on satellite DCB estimates and estimate satellite DCBs based on different correlator spacing observations from the software receiver. This software receiver-based approach is called multi-spacing DCB (MSDCB) estimation. In the software receiver approach, GNSS observations with different correlator spacings from intermediate frequency datasets can be generated. Since each correlator spacing allows the software receiver to output observations like a local GNSS receiver station, GNSS observations from different correlator spacings constitute a network of GNSS receivers, which makes it possible to use a single software receiver to estimate satellite DCBs. By comparing the MSDCBs to the IGS DCB products, the results show that the proposed correlator spacing flexible software receiver is able to predict satellite DCBs with increased flexibility and cost-effectiveness than the current hardware receiver-based DCB estimation approach.

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Constructing accurate maps of atmospheric water vapor by combining interferometric synthetic aperture radar and GNSS observations

Journal of Geophysical Research Atmospheres ◽

10.1002/2014jd022419 ◽

2015 ◽

Vol 120 (4) ◽

pp. 1391-1403 ◽

Cited By ~ 18

Author(s):

Fadwa Alshawaf ◽

Stefan Hinz ◽

Michael Mayer ◽

Franz J. Meyer

Keyword(s):

Water Vapor ◽

Synthetic Aperture Radar ◽

Atmospheric Water Vapor ◽

Synthetic Aperture ◽

Interferometric Synthetic Aperture Radar ◽

Atmospheric Water ◽

Gnss Observations ◽

Aperture Radar

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Ice flow velocities over Vostok Subglacial Lake, East Antarctica, determined by 10 years of GNSS observations

Journal of Glaciology ◽

10.3189/2013jog12j056 ◽

2013 ◽

Vol 59 (214) ◽

pp. 315-326 ◽

Cited By ~ 12

Author(s):

A. Richter ◽

D.V. Fedorov ◽

M. Fritsche ◽

S.V. Popov ◽

V.Ya. Lipenkov ◽

...

Keyword(s):

Flow Velocity ◽

East Antarctica ◽

Global Navigation Satellite Systems ◽

Steady Increase ◽

Lake Area ◽

Ice Flow ◽

Satellite Systems ◽

Subglacial Lake ◽

Gnss Observations ◽

Flow Velocities

AbstractRepeated Global Navigation Satellite Systems (GNSS) observations were carried out at 50 surface markers in the Vostok Subglacial Lake (East Antarctica) region between 2001 and 2011. The horizontal ice flow velocity vectors were derived with accuracies of 1 cm a−1 and 0.5°, representing the first reliable information on ice flow kinematics in the northern part of the lake. Within the lake area, ice flow velocities do not exceed 2 m a−1. The ice flow azimuth is southeast in the southern part of the lake and turns gradually to east-northeast in the northern part. In the northern part, as the ice flow enters the lake at the western shore, the velocity decreases towards the central lake axis, then increases slightly past the central axis. In the southern part, a continued acceleration is observed from the central lake axis across the downstream grounding line. Based on the observed flow velocity vectors and ice thickness data, mean surface accumulation rates are inferred for four surface segments between Ridge B and Vostok Subglacial Lake and show a steady increase towards the north.

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DAY BY DAY BEHAVIOR OF GNNS POSITIONING ERRORS AND TEC FLUCTUATIONS ASSOCIATED AURORAL DISTURBANCES OVER MARCH 2015

PHYSICS OF AURORAL PHENOMENA ◽

10.51981/2588-0039.2021.44.005 ◽

2021 ◽

Vol 44 ◽

pp. 24-27

Author(s):

I.I. Efishov ◽

◽

I.I. Shagimuratov ◽

I.E. Zakharenkova ◽

N.Yu. Tepenitsyna ◽

...

Keyword(s):

Precise Point Positioning ◽

Efficient Computation ◽

Gps Measurements ◽

Auroral Activity ◽

Positioning Errors ◽

Point Positioning ◽

European Sector ◽

Day By Day ◽

Single Receiver ◽

Gnss Observations

We analyzed the occurrence of TEC fluctuations and an impact of auroral disturbances on the Precise Point Positioning (PPP) errors in European sector using GPS measurements of EPN network. Index AE was used as indicator of auroral activity. The fluctuation activity was evaluated by indexes ROT and ROTI. The positioning errors were determined using the GIPSY-OASIS software (http://apps.gdgps.net). The Precise Point Positioning is the processing strategy of the single receiver for GNSS observations that enables the efficient computation of the high-quality coordinates. For quiet conditions the algorithm provided for TRO1 stations daily average PPP errors less than 4-5 sm. The analysis indicated regular increasing positioning errors around MLT (22 UT) during March 2015. While raising the auroral activity it was observed increasing TEC fluctuation as well as positioning errors. In the report we discus also behavior PPP errors during super storm 17 March 2015. During storm at TRO1 the PPP errors reached more than 20 m. The increasing errors were observed on latitudes low than 52-54°N.

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