The nature of GPS differential receiver bias variability: An examination in the polar cap region

Themens, David R.; Jayachandran, P. T.; Langley, Richard B.

doi:10.1002/2015ja021639

Cited by 38 publications

(34 citation statements)

References 38 publications

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“…These issues are, however, not solely limited to the IRI. Themens et al [2013] demonstrated that the sparsity of data in high-latitude regions contributes to significant errors in the representation of TEC in these regions by global TEC maps, and Themens et al [2015] showed that the strong gradients in TEC at high latitudes significantly degrade the performance of standard Global Positioning System (GPS)-based TEC calibration techniques. Also, Athieno et al [2015] and Athieno and Jayachandran [2016] show that standard HF communication models exhibit significant errors at high latitudes, largely due to errors in the URSI and International Radio Consultative Committee critical frequency maps, which are also used in the IRI.…”

Section: Introductionmentioning

confidence: 99%

The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): N_mF₂ and h_mF₂

et al. 2017

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We present here the Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM) quiet NmF2, perturbation NmF2, and quiet hmF2 models. These models provide peak ionospheric characteristics for a domain above 50°N geomagnetic latitude. Model fitting is undertaken using all available ionosonde and radio occultation electron density data, constituting a data set of over 28 million observations. A comprehensive validation of the model is undertaken, and performance is compared to that of the International Reference Ionosphere (IRI). In the case of the quiet NmF2 model, the E‐CHAIM model provides a systematic improvement over the IRI Union Radio Scientifique Internationale maps. At all stations within the polar cap, we see drastic RMS error improvements over the IRI by up to 1.3 MHz in critical frequency (up to 60% in NmF2). These improvements occur primarily during equinox periods and at low solar activities, decreasing somewhat as one tends to lower latitudes. Qualitatively, the E‐CHAIM is capable of representing auroral enhancements in NmF2, as well as the location and extent of the main ionospheric trough, not reproduced by the IRI. The included NmF2 storm model demonstrates improvements over the IRI by up to 35% and over the quiet time E‐CHAIM model by up to 30%. In terms of hmF2, over the validation periods used in this study, we found overall RMS errors of ~13 km for E‐CHAIM, with IRI2007 overall hmF2 errors ranging between 16 km and 22 km. The E‐CHAIM performs comparably to or slightly better than the IRI within the polar cap; however, significant improvements are found within the auroral oval.

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Section: Introductionmentioning

confidence: 99%

The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): N_mF₂ and h_mF₂

et al. 2017

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“…Compared to satellite DCBs, the receiver DCBs are less stable, and their magni- tudes and variations show large differences for different types of receivers. The receiver DCB seems to be related to the temperature around antennas (Coster et al, 2013;Yasyukevich et al, 2015;Themens et al, 2015). Besides its intrinsic variations, the estimated DCB series includes the signal associated with ionospheric anomalous variations and other errors, such as the multipath effect and the high-order effect of ionospheric delay, that are ignored in traditional TEC and DCB estimation, since non-modeling errors will affect the DCB estimation (Petrie et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Assessment of BeiDou differential code bias variations from multi-GNSS network observations

Jin

2016

Ann. Geophys.

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Abstract. The differential code bias (DCB) of global navigation satellite systems (GNSSs) affects precise ionospheric modeling and applications. In this paper, daily DCBs of the BeiDou Navigation Satellite System (BDS) are estimated and investigated from 2-year multi-GNSS network observations (2013-2014) based on global ionospheric maps (GIMs) from the Center for Orbit Determination in Europe (CODE), which are compared with Global Positioning System (GPS) results. The DCB of BDS satellites is a little less stable than GPS solutions, especially for geostationary Earth orbit (GEO) satellites. The BDS GEO observations decrease the precision of inclined geosynchronous satellite orbit (IGSO) and medium Earth orbit (MEO) DCB estimations. The RMS of BDS satellites DCB decreases to about 0.2 ns when we remove BDS GEO observations. Zero-mean condition effects are not the dominant factor for the higher RMS of BDS satellites DCB. Although there are no obvious secular variations in the DCB time series, sub-nanosecond variations are visible for both BDS and GPS satellites DCBs during 2013-2014. For satellites in the same orbital plane, their DCB variations have similar characteristics. In addition, variations in receivers DCB in the same region are found with a similar pattern between BDS and GPS. These variations in both GPS and BDS DCBs are mainly related to the estimated error from ionospheric variability, while the BDS DCB intrinsic variation is in sub-nanoseconds.

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“…The shell height is taken as the center of mass of the ionosphere above CASSIOPE (Komjathy & Langley, ; Themens et al, ):

h_{shell} = \frac{\int_{h_{GAP}}^{\infty} N_{e} ((), h) h normald h}{\int_{h_{GAP}}^{\infty} N_{e} ((), h) normald h}

where N e ( h ) is the electron density at height h . Electron densities below auroral latitudes are taken from the International Reference Ionosphere (IRI) 2012 empirical model, which provides electron densities up to 2,000 km altitude.…”

Section: Receiver Dcb Estimatementioning

confidence: 99%

“…The shell height is taken as the center of mass of the ionosphere above CASSIOPE (Komjathy & Langley, 1996;Themens et al, 2015):…”

Section: 1002/2017rs006453mentioning

confidence: 99%

“…Large differences of 1.5-2.5 TECU coincide with large bias sensitivities in Figure 7a. As shown in Themens et al (2015), errors in the MSD method due to the use of a fixed shell height can introduce artificial seasonal and solar cycle variabilities in the bias estimates. Although an increase in bias difference is observed each spring in Figure 7b, there is no clear seasonal dependence.…”

Section: 1002/2017rs006453mentioning

confidence: 99%

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Enhanced Polar Outflow Probe Ionospheric Radio Occultation Measurements at High Latitudes: Receiver Bias Estimation and Comparison With Ground‐Based Observations

et al. 2018

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This paper presents validation of ionospheric Global Positioning System (GPS) radio occultation measurements of the GPS Attitude, Positioning, and Profiling Experiment occultation receiver (GAP‐O). GAP is one of eight instruments comprising the Enhanced Polar Outflow Probe (e‐POP) instrument suite on board the Cascade Smallsat and Ionospheric Polar Explorer (CASSIOPE) satellite. One of the main error sources for certain GAP‐O data products is the receiver differential code bias (rDCB). A minimization of standard deviations (MSD) technique has shown the most promise for rDCB estimation, with estimates ranging primarily from −40 to −28 total electron content units (TECU = 1016 el m−2; 21.6 to 15.1 ns), including a long‐term decrease in rDCB magnitude and variability over the first 3 years of instrument operation. In application of the MSD method, the sensitivity of bias estimates to ionospheric shell height are as large as 4.5 TECU per 100 km. MSD calculations also agree well with the “assumption of zero topside TEC” method for rDCB estimate at satellite apogee. Bias‐corrected topside TEC of GAP‐O was validated by statistical comparison with topside TEC obtained from ground‐based GPS TEC and ionosonde measurements. Although GAP‐O and ground‐based topside TEC had similar variability, GAP‐O consistently underestimated the ground‐derived topside TEC by up to 7 TECU. Ionospheric electron density profiles obtained from Abel inversion of GAP‐O occultation TEC showed good agreement with F region densities of ground‐based incoherent scatter radar measurements. Comparison of GAP‐O and ionosonde measurements revealed correlation coefficients of 0.78 and 0.79, for peak F region density and altitude, respectively.

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The nature of GPS differential receiver bias variability: An examination in the polar cap region

Cited by 38 publications

References 38 publications

The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): N_mF₂ and h_mF₂

The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): N_mF₂ and h_mF₂

Assessment of BeiDou differential code bias variations from multi-GNSS network observations

Enhanced Polar Outflow Probe Ionospheric Radio Occultation Measurements at High Latitudes: Receiver Bias Estimation and Comparison With Ground‐Based Observations

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The nature of GPS differential receiver bias variability: An examination in the polar cap region

Cited by 38 publications

References 38 publications

The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): NmF2 and hmF2

The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): NmF2 and hmF2

Assessment of BeiDou differential code bias variations from multi-GNSS network observations

Enhanced Polar Outflow Probe Ionospheric Radio Occultation Measurements at High Latitudes: Receiver Bias Estimation and Comparison With Ground‐Based Observations

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The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): N_mF₂ and h_mF₂

The Empirical Canadian High Arctic Ionospheric Model (E‐CHAIM): N_mF₂ and h_mF₂