How modernized and strengthened GPS signals enhance the system performance during solar radio bursts

Yasyukevich, Yury; Yasyukevich, A. S.; Astafyeva, Elvira

doi:10.1007/s10291-021-01091-5

Cited by 17 publications

(9 citation statements)

References 33 publications

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“…[36]. Increase in the satellite transmitter power [37], application of choke ring antennas, or advanced signal coding (providing a steeper and narrower main maximum of the autocorrelation function) could, to some extent, compensate for such negative factors.…”

Section: Discussionmentioning

confidence: 99%

Galileo E5 AltBOC Signals: Application for Single-Frequency Total Electron Content Estimations

et al. 2021

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Global navigation satellite system signals are known to be an efficient tool to monitor the Earth ionosphere. We suggest Galileo E5 AltBOC phase and pseudorange observables— a single-frequency combination—to estimate the ionospheric total electron content (TEC). We performed a one-month campaign in September 2020 to compare the noise level for different TEC estimations based on single-frequency and dual-frequency data. Unlike GPS, GLONASS, or Galileo E5a and E5b single-frequency TEC estimations (involving signals with binary and quadrature phase-shift keying, such as BPSK and QPSK, or binary offset carrier (BOC) modulation), an extra wideband Galileo E5 AltBOC signal provided the smallest noise level, comparable to that of dual-frequency GPS. For elevation higher than 60 degrees, the 100-sec root-mean-square (RMS) of TEC, an estimated TEC noise proxy, was as follows for different signals: ~0.05 TECU for Galileo E5 AltBOC, 0.09 TECU for GPS L5, ~0.1TECU for Galileo E5a/E5b BPSK, and 0.85 TECU for Galileo E1 CBOC. Dual-frequency phase combinations provided RMS values of 0.03 TECU for Galileo E1/E5, 0.03 and 0.07 TECU for GPS L1/L2 and L1/L5. At low elevations, E5 AltBOC provided at least twice less single-frequency TEC noise as compared with data obtained from E5a or E5b. The short dataset of our study could limit the obtained estimates; however, we expect that the AltBOC single-frequency TEC will still surpass the BPSK analogue in noise parameters when the solar cycle evolves and geomagnetic activity increases. Therefore, AltBOC signals could advance geoscience.

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Section: Discussionmentioning

confidence: 99%

Galileo E5 AltBOC Signals: Application for Single-Frequency Total Electron Content Estimations

et al. 2021

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“…Accordingly, the synchronization operators that are obtained in (8) and ( 12) are generally different, except at the bus where the event occurs. Thus, we can use the mismatch between the calculation of δ in (8) and the calculation of δ in (12) as the metric to obtain the unknowns:…”

Section: A Methodologymentioning

confidence: 99%

“…For example, GPS signals can be jammed due to natural causes, e.g. irregularities of the ionosphere, geomagnetic storms, solar radio bursts [12]. GPS signals can also be jammed due to adversarial reasons, e.g.…”

Section: Problem Statementmentioning

confidence: 99%

Impact Analysis and Mitigation of Losing Time Synchronization at Micro-PMUs in Event Location Identification

Farajollahi

Mohsenian‐Rad

2022

2022 IEEE Power &Amp; Energy Society Innovative Smart Grid Technologies Conference (ISGT)

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Prior studies have shown that most phasor measurement units (PMUs) in practice suffer from some level of time synchronization loss at least once every day. We address this issue in the context of distribution-level PMUs, i.e., micro-PMUs, and with focus on the application of micro-PMUs in event location identification in situational awareness. We show that a state-of-the-art method that is highly successful in identifying the correct event location when the micro-PMUs are synchronized, fails when time synchronization is lost among the micro-PMUs. An alternative method is proposed to identify the location of events not only when the micro-PMUs are time synchronized but also when micro-PMUs lose time synchronization. The proposed model works for different scenarios for losing time synchronization among some or all micro-PMUs.

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“…3, meaning that the high ionospheric disturbance has decreased the positioning performance considerably. This mainly because irregularities of the ionospheric plasma density can cause rapid amplitude and random phase variations of satellite navigation signals (Yasyukevich et al 2021). Even so, the convergence behavior of the IW-RTK model, especially for the horizontal components, is superior to that of the RTK model, which means that the between-station single-differenced ionospheric pseudo-observations can still reduce the convergence time during the high ionospheric disturbance.…”

Section: Positioning Performance During the High Solar Activity Daysmentioning

confidence: 99%

Ionosphere-weighted undifferenced and uncombined PPP-RTK: theoretical models and experimental results

Zha

Zhang

et al. 2021

GPS Solut

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Precise ionospheric information, as like precise satellite orbits, clocks, and code/phase biases, is a critical factor for achieving fast integer ambiguity resolution in precise point positioning (PPP-AR). This study develops an ionosphere-weighted (IW) undifferenced and uncombined PPP real-time kinematic (PPP-RTK) network model using code and phase observations. We introduce between-station single-differenced ionospheric delay pseudo-observations to take advantage of the similar characteristics of ionospheric delays between two receivers tracking the same satellite. The estimable ionospheric parameters are commonly affected by the differential code bias referring to a particular receiver assigned as pivot, which facilitates the ionospheric interpolation at the user side. Then, the kinematic positioning performance of the IW PPP-RTK user model is analyzed and compared with those of PPP-AR without ionospheric corrections, RTK, and IW-RTK models during low and high solar activity days. The results show that for the PPP-RTK model, the positioning errors converge to thresholds of 2 cm for the horizontal components and 5 cm for the vertical component within 20 epochs, and the positioning errors become stable after an initialization of 20 epochs with root-mean-squared (RMS) values of approximately 0.47, 0.58 and 1.66 cm for the east, north and up components, respectively, which are superior to those of the other three models. Owing to the high ionospheric disturbance influence, the RMS values of the east and up components increase by approximately double and the mean time-to-first-fix increases by 61.5% for the PPP-RTK case.

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How modernized and strengthened GPS signals enhance the system performance during solar radio bursts

Cited by 17 publications

References 33 publications

Galileo E5 AltBOC Signals: Application for Single-Frequency Total Electron Content Estimations

Galileo E5 AltBOC Signals: Application for Single-Frequency Total Electron Content Estimations

Impact Analysis and Mitigation of Losing Time Synchronization at Micro-PMUs in Event Location Identification

Ionosphere-weighted undifferenced and uncombined PPP-RTK: theoretical models and experimental results

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