Ionospheric effects on GPS signals in the Arctic region using early GPS data from Thule, Greenland

El-Arini, M. Bakry; Secan, J. A.; Klobuchar, J. A.; Doherty, Patricia H.; Bishop, G. J.; Groves, K. M.

doi:10.1029/2008rs004031

Cited by 7 publications

(3 citation statements)

References 2 publications

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“…This is particularly true in the Arctic Circle, due both to a lack of observational data from global positioning system (GPS) reference stations as well as more complicated ionospheric characteristics. Some scholars have used traditional ground-based stations to study the characteristics and effects of the Arctic ionosphere [27][28][29]. However, they could not reflect the situation well without high spatial and temporal resolution data.…”

Section: Introductionmentioning

confidence: 99%

Global Ionospheric Model Accuracy Analysis Using Shipborne Kinematic GPS Data in the Arctic Circle

et al. 2019

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The global ionospheric model built by the International Global Navigation Satellite System (GNSS) Service (IGS) using GNSS reference stations all over the world is currently the most widely used ionospheric product on a global scale. Therefore, analysis and evaluation of this ionospheric product’s accuracy and reliability are essential for the practical use of the product. In contrast to the traditional way of assessing global ionospheric models with ground-based static measurements, our study used shipborne kinematic global positioning system (GPS) measurements collected over 18 days to perform a preliminary analysis and evaluation of the accuracy of the global ionospheric models; our study took place in the Arctic Circle. The data from the International GNSS Service stations near the Arctic Circle were used to verify the ionospheric total electron contents derived from the kinematic data. The results suggested that the global ionospheric model had an approximate regional accuracy of 12 total electron content units (TECu) within the Arctic Circle and deviated from the actual ionospheric total electron content value by about 4 TECu.

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Section: Introductionmentioning

confidence: 99%

Global Ionospheric Model Accuracy Analysis Using Shipborne Kinematic GPS Data in the Arctic Circle

et al. 2019

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“…For dual frequency mechanism, loss of lock on either L1 or L2 due to fading prevents these corrections from being calculated during the time period that lock is lost and even for a few seconds after lock is regained, thereby leading to navigation errors. Furthermore, GPS receiver loses lock on L2 signal more often than on L1 signal of the same satellite when traversing ionospheric irregularities [ El ‐ Arini et al , 2003, 2009; Strangeways , 2009]. Consequently, the present study concentrated on L1 signal data only.…”

Section: Introductionmentioning

confidence: 99%

Impacts of ionospheric scintillations on GPS receivers intended for equatorial aviation applications

et al. 2012

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This study examines the impacts of ionospheric scintillations on GPS receivers that are intended for equatorial or transequatorial aviation applications. We analyzed GPS data that were acquired at Ascension Island during the Air Force Research Laboratory (AFRL) campaign of the solar maximum year of 2002. Strong scintillations impacted the receiver‐satellite geometry, leading to poor dilution of precisions and positioning accuracy. In addition, deep signal fades (>20 dB‐Hz), leading to navigation outages were observed during most of the nights of the campaign. Under quiescent conditions, the C/No of satellites fluctuated slowly between 50 dB‐Hz and 35 dB‐Hz baselines for both L1 (1.5754 GHz) and L2 (1.2276 GHz) signals, depending on the satellite's elevation angle. The satellite's elevation angle and the effective scan velocity of the satellite's ionospheric penetration point (IPP) with respect to the magnetic field and plasma drift influenced the rate of fading of satellite signals.

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“…Third, no field study has been conducted on the effect of ionosphere scintillation on the new GPS L5, GLONASS, Galileo, and Compass satellite signals. There is an urgent need to gain an understanding of the spatial correlation among the satellites and the frequency correlation among different signals under ionosphere scintillations (Seo et al 2009(Seo et al , 2011El-Arini et al 2009). The USRP2 offers a flexible and reconfigurable platform for these studies.…”

Section: Introductionmentioning

confidence: 99%

A USRP2-based reconfigurable multi-constellation multi-frequency GNSS software receiver front end

Peng

Morton

2012

GPS Solut

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We present a multi-constellation multi-band GNSS software receiver front end based on USRP2, a general purpose radio platform. When integrated with appropriate daughter boards, the USRP2 can be used to collect raw intermediate frequency (IF) data covering the entire GNSS family of signals. In this study, C?? classbased software receiver processing functions were developed to process the IF data for GPS L1, L2C, and L5 and GLONASS L1 and L2 signals collected by the USRP2 front end. The front end performance is evaluated against the outputs of a high end custom front end driven by the same local oscillator and two commercial receivers, all using the same real signal sources. The results show that for GPS signals, the USRP2 front end typically generates carrier-to-noise ratio (C/N 0 ) at 1-3 and 1-2 dB below that of the high end front end and a NovAtel receiver, respectively. For GLONASS signals, the USRP2 C/N 0 outputs are comparable to those of a Septentrio receiver. The carrier phase noise from the USRP2 outputs is similar to those of the benchmarking devices. These results demonstrate that the USRP2 is a suitable front end for applications, such as ionosphere scintillation studies.

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Ionospheric effects on GPS signals in the Arctic region using early GPS data from Thule, Greenland

Cited by 7 publications

References 2 publications

Global Ionospheric Model Accuracy Analysis Using Shipborne Kinematic GPS Data in the Arctic Circle

Global Ionospheric Model Accuracy Analysis Using Shipborne Kinematic GPS Data in the Arctic Circle

Impacts of ionospheric scintillations on GPS receivers intended for equatorial aviation applications

A USRP2-based reconfigurable multi-constellation multi-frequency GNSS software receiver front end

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