Observations of quiet-time moderate midlatitude L-band scintillation in association with plasma bubbles

Veettil, Sreeja Vadakke; Haralambous, Haris; Aquino, Márcio

doi:10.1007/s10291-016-0598-x

Cited by 11 publications

(4 citation statements)

References 37 publications

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“…The signal intensity attenuation led by ionospheric anomaly can be observed with the SNR measurements (Bong et al, 2015; He et al, 2016; Vadakke Veettil et al, 2017). Even more, the attenuation will affect the accuracy of pseudorange to some degree.…”

Section: Positioning Performance With Multi‐gnssmentioning

confidence: 95%

Assessing the Positioning Performance Under the Effects of Strong Ionospheric Anomalies With Multi‐GNSS in Hong Kong

Lü

Wang

et al. 2020

Radio Science

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Global navigation satellite system (GNSS) precise positioning performance will be strongly affected under severe ionospheric anomaly conditions. The combination of multi‐GNSS can increase the available observations and improve the geometry of continuously tracked satellites. This paper focuses on assessing the positioning performance with the combination of Global Positioning System (GPS), Global'naya Navigatsionnaya Sputnikova Sistema (GLONASS), and BeiDou System (BDS) around the St. Patrick's Day geomagnetic storm (9–18 March) in 2015 in Hong Kong. The rate of total electron content (TEC) index (ROTI) indicates severe ionospheric anomalies before the superstorm, while it was absent during the main phase of the storm in Hong Kong. Furthermore, strong scintillation events on signal‐to‐noise ratio (SNR) and multipath (MP) observables are observed during ionospheric anomalies period. Then the performance of single‐point positioning (SPP) and precise point positioning (PPP) with multi‐GNSS is shown. The ionospheric scintillation events may reduce pseudorange accuracy but affect SPP performance a little in this study, while the PPP accuracy is vastly decreased due to the subsequent reconvergence caused by frequent cycle slip (CS). Compared to PPP solutions with GPS only, the accuracy is improved significantly with the combination of multi‐GNSS.

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Section: Positioning Performance With Multi‐gnssmentioning

confidence: 95%

Assessing the Positioning Performance Under the Effects of Strong Ionospheric Anomalies With Multi‐GNSS in Hong Kong

Lü

Wang

et al. 2020

Radio Science

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“…On the model development at these latitudes, the statistical test described in Section 2 indicated that none of the estimated coefficients were statistically significant, leading to conclude that any attempt using our approach to develop a model specific for the mid-latitudes would be meaningless. Nevertheless, during weak scintillation periods at the mid-latitude station of CYP, the variations in S4 are more pronounced than the variations in r u (Vadakke Veettil et al, 2017) Therefore, the models developed for the low latitudes were tested at this station. Concurrently, at the European mid-latitude station NOT, during weak scintillation periods the variations in r u are more pronounced than the variations in S4 (Aquino et al, 2005).…”

Section: Mid-latitude Modelmentioning

confidence: 99%

A statistical approach to estimate Global Navigation Satellite Systems (GNSS) receiver signal tracking performance in the presence of ionospheric scintillation

Veettil

Aquino

Spogli

et al. 2018

J. Space Weather Space Clim.

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Ionospheric scintillation can seriously impair the Global Navigation Satellite Systems (GNSS) receiver signal tracking performance, thus affecting the required levels of availability, accuracy and integrity of positioning that supports modern day GNSS based applications. We present results from the research work carried out under the Horizon 2020 European Commission (EC) funded Ionospheric Prediction Service (IPS) project. The statistical models developed to estimate the standard deviation of the receiver Phase Locked Loop (PLL) tracking jitter on the Global Positioning System (GPS) L1 frequency as a function of scintillation levels are presented. The models were developed following the statistical approach of generalized linear modelling on data recorded by networks in operation at high and low latitudes during the years of 2012–2015. The developed models were validated using data from different stations over varying latitudes, which yielded promising results. In the case of mid-latitudes, as the occurrence of strong scintillation is absent, an attempt to develop a dedicated model proved fruitless and, therefore, the models developed for the high and low latitudes were tested for two mid-latitude stations. The developed statistical models can be used to generate receiver tracking jitter maps over a region, providing users with the expected tracking conditions. The approach followed for the development of these models for the GPS L1 frequency can be used as a blueprint for the development of similar models for other GNSS frequencies, which will be the subject of follow on research.

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“…Compared to its equatorial and polar counterparts, the midlatitude ionosphere is less affected by ionospheric irregularities [10]. Scintillation patches (S 4 ) noted in GNSS trans-ionospheric links, as a consequence of ionospheric irregularities, over the nighttime midlatitude ionosphere, are not as frequent [11] except during disturbed geomagnetic conditions. The midlatitude nighttime F region is characterised by multiple diffused patterns of plasma structure irregularities, which may last from a few minutes to several hours, referred to as midlatitude spread F [12][13][14][15].…”

Section: Introductionmentioning

confidence: 97%

Correlation of Rate of TEC Index and Spread F over European Ionosondes

Paul,

Rafi,

Haralambous

et al. 2024

Atmosphere

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One of the most popular indices for monitoring the occurrence and intensity of ionospheric L-band irregularities is the Rate of TEC Index (ROTI). Due to low TEC in the mid-latitude ionosphere, ROTI has received significantly less attention than the equatorial and polar ionosphere. On the other hand, spread F is an established ionogram irregularity signature. The present study aims to correlate ROTI and spread F activity over European Digisonde stations for a low-to-moderate solar activity year (2011). With a focus on the latitude-dependent occurrence, the analysis demonstrates that range spread F (RSF) has been identified for all notable ROTI (>0.15 TECU/min) cases which also coincide with MSTID activity over the stations, suggesting induced gravity waves or polarization electric fields as the driving mechanism for enhanced ROTI activity. The diurnal and seasonal features are also presented. Maximum irregularity occurrence was observed around the 45° N from 18:00 to 05:00 UT with the seasonal maximum occurrence in January. Over lower mid-latitude Digisonde stations (latitude < 45° N), the diurnal and seasonal occurrence was observed from 19:00 to 04:30 UT in July.

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Observations of quiet-time moderate midlatitude L-band scintillation in association with plasma bubbles

Cited by 11 publications

References 37 publications

Assessing the Positioning Performance Under the Effects of Strong Ionospheric Anomalies With Multi‐GNSS in Hong Kong

Assessing the Positioning Performance Under the Effects of Strong Ionospheric Anomalies With Multi‐GNSS in Hong Kong

A statistical approach to estimate Global Navigation Satellite Systems (GNSS) receiver signal tracking performance in the presence of ionospheric scintillation

Correlation of Rate of TEC Index and Spread F over European Ionosondes

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