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

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Enhanced Polar Outflow Probe Ionospheric Radio Occultation Measurements at High Latitudes : Receiver Bias Estimation and Comparison With Ground-Based Observations. / Watson, C.; Langley, R. B.; Themens, D. R.; Yau, A. W.; Howarth, A. D.; Jayachandran, P. T.

In: Radio Science, Vol. 53, No. 2, 02.2018, p. 166-182.

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@article{300cb7b016de4377a82c34ed14adfa2e,
title = "Enhanced Polar Outflow Probe Ionospheric Radio Occultation Measurements at High Latitudes: Receiver Bias Estimation and Comparison With Ground-Based Observations",
abstract = "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.",
keywords = "GPS, high latitudes, ionosphere, polar, radio occultation, receiver bias",
author = "C. Watson and Langley, {R. B.} and Themens, {D. R.} and Yau, {A. W.} and Howarth, {A. D.} and Jayachandran, {P. T.}",
year = "2018",
month = feb,
doi = "10.1002/2017RS006453",
language = "English",
volume = "53",
pages = "166--182",
journal = "Radio Science",
issn = "0048-6604",
publisher = "American Geophysical Union",
number = "2",

}

RIS

TY - JOUR

T1 - Enhanced Polar Outflow Probe Ionospheric Radio Occultation Measurements at High Latitudes

T2 - Receiver Bias Estimation and Comparison With Ground-Based Observations

AU - Watson, C.

AU - Langley, R. B.

AU - Themens, D. R.

AU - Yau, A. W.

AU - Howarth, A. D.

AU - Jayachandran, P. T.

PY - 2018/2

Y1 - 2018/2

N2 - 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.

AB - 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.

KW - GPS

KW - high latitudes

KW - ionosphere

KW - polar

KW - radio occultation

KW - receiver bias

UR - http://www.scopus.com/inward/record.url?scp=85041565344&partnerID=8YFLogxK

U2 - 10.1002/2017RS006453

DO - 10.1002/2017RS006453

M3 - Article

AN - SCOPUS:85041565344

VL - 53

SP - 166

EP - 182

JO - Radio Science

JF - Radio Science

SN - 0048-6604

IS - 2

ER -