Relationships between GPS-signal propagation errors and EISCAT observations

Jakowski, N.; Sardón, E.; Engler, Evelin; Jungstand, A.; Klähn, D.

doi:10.1007/s00585-996-1429-0

Cited by 49 publications

(29 citation statements)

References 6 publications

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“…The vertical dashed lines indicate the longitude sectors where tomographic imaging is performed. sight between the satellite and the receiver (slant TEC) is calibrated from instrumental biases [e.g., Mannucci et al, 1998;Yizengaw et al, 2004] and then mapped to the vertical using a single spherical shell layer approximation of the ionosphere at h sp = 400 km altitude [e.g., Jakowski et al, 1996].…”

Section: Methods Of Analysis and Data Usedmentioning

confidence: 99%

Unusual topside ionospheric density response to the November 2003 superstorm

et al. 2006

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[1] We use observations from a variety of different ground-and space-based instruments, including ionosonde, ground-and space-based Global Positioning System (GPS) receivers, magnetometers, and solar wind data from the Advanced Composition Explorer (ACE), to examine the response of the ionospheric F2-layer height during the November 2003 superstorm. We found that the topside ionosphere responded unusually to the 20 November 2003 severe storm compared to behavior observed in a number of previous storms. While ground-based GPS receivers observed a large enhancement in dayside TEC, the low-Earth orbiting ($400 km) CHAMP satellite did not show any sign of dayside TEC enhancement. The real-time vertical density profiles, constructed from ground-based GPS TEC using a tomographic reconstruction technique, clearly revealed that the ionospheric F2-layer peak height had been depressed down to lower altitudes. Ionospheric F-layer peak height (hmF2) from the nearby ionosonde stations over Europe also showed that the dayside F2-layer peak height was below 350 km, which is below the orbiting height of CHAMP. The vertical E Â B drift (estimated from ground-based magnetometer equatorial electrojet delta H) showed strong dayside downward drifts, which may be due to the ionospheric disturbance dynamo electric field produced by the large amount of energy dissipation into high-latitude regions. This storm demonstrates that data from LEO satellites varies widely among different superstorms.

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Section: Methods Of Analysis and Data Usedmentioning

confidence: 99%

Unusual topside ionospheric density response to the November 2003 superstorm

et al. 2006

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“…GPS TEC estimates as from TEC maps were then compared with EIS-CAT TEC within an overlapping region. The EISCAT TEC was obtained by integration of CP3 electron density profiles from about 150 km to about 500 km height and then verticalised at ionospheric pierce points by means of a mapping function (Jakowski et al, 1996). The results indicated larger GPS TEC as compared with EISCAT TEC values, given the geometry considered, which suggested a plasmaspheric contribution not captured by the radar, yet present on GPS radio signals (Jakowski et al, 1996).…”

Section: Published By Copernicus Publications On Behalf Of the Europementioning

confidence: 99%

“…A different analysis showed a comparison between EIS-CAT TEC obtained by integration of electron density profiles and verticalised GPS TEC from nearly co-located stations, with equivalent ionospheric pierce points overlapping the area covered by EISCAT (Jakowski et al, 1996). In that case, EISCAT was operated in a scanning mode (CP3) and electron density profiles were measured at different latitudes between 62 and 78 • N during a 30 min north-south scan.…”

Section: Published By Copernicus Publications On Behalf Of the Europementioning

confidence: 99%

Comparison of temporal fluctuations in the total electron content estimates from EISCAT and GPS along the same line of sight

et al. 2013

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Abstract. The impact of space weather events on satellite-based technologies (e.g. satellite navigation and precise positioning) is typically quantified on the basis of the total electron content (TEC) and temporal fluctuations associated with it. GNSS (global navigation satellite systems) TEC measurements are integrated over a long distance and thus may include contributions from different regions of the ionised atmosphere which may prevent the resolution of the mechanisms ultimately responsible for given observations. The purpose of the experiment presented here was to compare TEC estimates from EISCAT and GPS measurements. The EISCAT measurements were obtained along the same line of sight of a given GPS satellite observed from Tromsø. The present analyses focussed on the comparison of temporal fluctuations in the TEC between aligned GPS and EISCAT measurements. A reasonably good agreement was found between temporal fluctuations in TEC observed by EISCAT and those observed by a co-located GPS ionospheric monitor along the same line of sight, indicating a contribution from structures at E and F altitudes mainly to the total TEC in the presence of ionisation enhancements possibly caused by particle precipitation in the nighttime sector. The experiment suggests the great potential in the measurements to be performed by the future EISCAT_3D system, limited only in the localised geographic region to be covered.

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“…Given that a typical ionospheric RO event lasts ∼ 1000 s, then the cumulative multipath-induced STEC would be <0.5 TECU. Additionally, it should be mentioned that the multipath effect in carrier-phase GPS measurements is two orders of magnitude smaller than that of the pseudo-range measurements [e.g., Jakowski et al, 1996;Byun et al, 2002;Kuang et al, 2008]. Simulating the local multipath is not the scope of this contribution, and we refer the reader to Byun et al [2002] for a more detailed description on existing theoretical models on local multipath simulators from reflecting surfaces.…”

Section: Theoretical Approximations and Error Budgetmentioning

confidence: 99%

First estimates of the second‐order ionospheric effect on radio occultation observations

Vergados

Pagiatakis

2010

J. Geophys. Res.

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[1] This study examines the impact of the second-order ionospheric effect on radio occultation (RO) data products. We propose a new linear combination between dual frequency GPS observables, which retrieves slant total electron content free from the second-order ionospheric effect. Our STEC values differ from those obtained by independent techniques by a maximum of 3 total electron content units (TECU), depending on the geographic location and geomagnetic activity. Additionally, we suggest an alternative method of computing the second-order ionospheric delay in RO experiments, which does not require the use of geomagnetic and ionospheric models. First estimates show that the second-order ionospheric delay for the RO experiments falls within the range [−10, −8] mm, which is of the same order of magnitude with second-order ionospheric delay estimates from ground-based experiments. Finally, as a by-product of our model, we retrieve weighted mean geomagnetic field values, which we compare with theoretical estimates computed by the International Geomagnetic Reference Field-10 (IGRF-10) model. Our estimations agree with the IGRF-10 model between 0.23% and 7.0%.Citation: Vergados, P., and S. D. Pagiatakis (2010), First estimates of the second-order ionospheric effect on radio occultation observations,

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Relationships between GPS-signal propagation errors and EISCAT observations

Cited by 49 publications

References 6 publications

Unusual topside ionospheric density response to the November 2003 superstorm

Unusual topside ionospheric density response to the November 2003 superstorm

Comparison of temporal fluctuations in the total electron content estimates from EISCAT and GPS along the same line of sight

First estimates of the second‐order ionospheric effect on radio occultation observations

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