Comparison of the characteristics of ionospheric parameters obtained from FORMOSAT-3 and digisonde over Ascension Island

Chuo, Y. J.; Lee, C. C.; Chen, W. S.; Reinisch, B. W.

doi:10.5194/angeo-31-787-2013

Cited by 18 publications
(27 citation statements)

References 28 publications

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“…For example, Krankowski et al [] obtained a correlation ( R ) of 0.986 when validating COSMIC N m F 2 with ionosonde data over European midlatitude region during 2008, while R values of 0.96 [ Chu et al , ] and 0.92 [ Habarulema et al , ] were reported for global and African sector studies using 2006 and 2008 data, respectively. Furthermore, single station [e.g., Chuo et al , ] and global simulation [e.g., Yue et al , ] studies have also reported R values (0.96 and 0.95) in the same range. Comparing GPS/MET‐derived N m F 2 with collocated ionosonde observations, Hajj and Romans [] reported an agreement to within 20% at 1 σ level.…”

Section: Resultsmentioning
confidence: 98%

“…Thus, some comparative studies between RO and ground‐based observations preferred analyses during geomagnetically quiet conditions [e.g., Chu et al , ; Wu et al , ] to avoid errors related to the occurrence of ionospheric electron density irregularities. However, other studies have done validation case studies on one storm period [e.g., Krankowski et al , ], while significant literature that exists performs statistics based on large data sets without necessarily doing any isolation based on geomagnetic activity or occurrence of ionospheric irregularities [e.g., Yue et al , ; Chuo et al , ; Pedatella et al , , and references therein]. These studies give an indication that RO data may be able to follow ionospheric dynamics even during geomagnetic storms, although not in a detailed quantitative sense.…”

Section: Introductionmentioning
confidence: 99%

See 1 more Smart Citation
Long‐term analysis between radio occultation and ionosonde peak electron density and height during geomagnetic storms
Habarulema
¹
,
Carelse
²

2016
Geophysical Research Letters
15
6
15
0
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For the first time, a long‐term comparative analysis of radio occultation (RO) maximum electron density and peak height of the F2 layer (NmF2 and hmF2) with ionosonde data is presented during geomagnetic storm periods. Using the optimum spatial resolution of 4.5° × 4.5° in both latitude and longitude space over Grahamstown, GR13L(33.3°S, 26.5°E), South Africa, RO NmF2 and hmF2 (from CHAMP and COSMIC/FORMOSAT‐3) are directly compared to ionosonde values within 15 min of ionosonde observational data from 2003 to end of May 2015. This study provides for the first time the deviation of RO data from ionosonde data on a long‐term scale during disturbed conditions in a midlatitude region. We have found that maximum deviations between RO and ionosonde hmF2/NmF2 occur during the high solar activity periods. For some storms, deviations between RO and ionosonde hmF2 can reach values just over 30 km and 85 km during 2005–2010 and 2011–2015, respectively. Overall, statistical results show that hmF2 and NmF2 from these independent data sets agree to within ∼9% and 21% (1 standard deviation, 1σ) from 2003 to 2015. While the deviation can be large during some storm events, statistically and based on ionosonde data, RO F2 peak parameters in midlatitudes are not degraded significantly during disturbed conditions and can therefore be reliably used to study ionospheric dynamics during extreme space weather events.
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Section: Resultsmentioning
confidence: 98%

Section: Introductionmentioning
confidence: 99%

Long‐term analysis between radio occultation and ionosonde peak electron density and height during geomagnetic storms
Habarulema
¹
,
Carelse
²

2016
Geophysical Research Letters
15
6
15
0
View full text Add to dashboard Cite

For the first time, a long‐term comparative analysis of radio occultation (RO) maximum electron density and peak height of the F2 layer (NmF2 and hmF2) with ionosonde data is presented during geomagnetic storm periods. Using the optimum spatial resolution of 4.5° × 4.5° in both latitude and longitude space over Grahamstown, GR13L(33.3°S, 26.5°E), South Africa, RO NmF2 and hmF2 (from CHAMP and COSMIC/FORMOSAT‐3) are directly compared to ionosonde values within 15 min of ionosonde observational data from 2003 to end of May 2015. This study provides for the first time the deviation of RO data from ionosonde data on a long‐term scale during disturbed conditions in a midlatitude region. We have found that maximum deviations between RO and ionosonde hmF2/NmF2 occur during the high solar activity periods. For some storms, deviations between RO and ionosonde hmF2 can reach values just over 30 km and 85 km during 2005–2010 and 2011–2015, respectively. Overall, statistical results show that hmF2 and NmF2 from these independent data sets agree to within ∼9% and 21% (1 standard deviation, 1σ) from 2003 to 2015. While the deviation can be large during some storm events, statistically and based on ionosonde data, RO F2 peak parameters in midlatitudes are not degraded significantly during disturbed conditions and can therefore be reliably used to study ionospheric dynamics during extreme space weather events.

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“…Chuo et al, 2011). Comparison of characteristics of ionospheric parameters obtained from COSMIC and a digisonde over Ascension Island also illustrates similar diurnal variation and high correlation for both NmF2 (> 0.91) and hmF2 (> 0.72) in the equinox, summer and winter periods (Chuo et al, 2013). Comparison between RO EDPs from the COSMIC satellites with digisonde data over the Brazilian region shows generally good correlation for NmF2 (0.92) and hmF2 (0.78) (Ely et al, 2012).…”

Section: Discussionmentioning
confidence: 61%

“…Statistical comparisons of ionospheric peak parameters (NmF2 and hmF2) measured by COSMIC satellites and ionosondes indicate that there are considerable high correlations between COS-MIC and ionosonde ionospheric parameters (Lei et al, 2007;Chu et al, 2010;Chuo et al, 2011Chuo et al, , 2013Ely et al, 2012;Krankowski et al, 2011;J.-Y. Liu et al, 2010;Hu et al, 2014).…”

Section: Hu Et Al: Validation Of Cosmic Ionospheric Peak Parametersmentioning
confidence: 99%

Validation of COSMIC ionospheric peak parameters by the measurements of an ionosonde chain in China
Hu
¹
,
Ning
²
,
Liu
³

et al. 2014
Ann. Geophys.
30
0
20
0
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Abstract. Although the electron density profiles (EDPs) from Constellation Observing System for Meteorology, Ionosphere, and Climate (COSMIC) measurement have been validated by ionosonde data at a number of locations during the solar minimum period, the performance of COSMIC measurements at different latitudes has not been well evaluated, particularly during the solar maximum period. In this paper the COSMIC ionospheric peak parameters (peak electron density of the F region -NmF2; peak height of the F region -hmF2) are validated by the ionosonde data from an observation chain in China during the solar maximum period of 2011-2013. The validations show that the COSMIC measurement generally agrees well with the ionosonde observation. The error in NmF2 from COSMIC and ionosonde measurements varies with latitude. At midlatitude stations, the differences between COSMIC NmF2s and those of ionosondes are very slight. However, COSMIC NmF2 overestimates (underestimates) that of the ionosonde at the north (south) of the equatorial ionization anomaly (EIA) crest. The relative errors of hmF2s are much lower than those of NmF2s at all stations, which indicates the EDP retrieval algorithm of the COSMIC measurement has a better performance in determining the ionospheric peak height. The root mean square errors (RMSEs) of NmF2s (hmF2s) are higher (lower) during the daytime than during the nighttime at all stations. Correlation analysis shows that the correlations for both NmF2s and hmF2s are comparably good (correlation coefficients > 0.9) at midlatitude stations, while correlations of NmF2 (correlation coefficients > 0.9) are higher than those of hmF2 (correlation coefficients > 0.8) at low-latitude stations.

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“…The impacts of the recent deep and prolonged solar minimum on the electron density, temperature, spread F, and total electron content, as well as the vertical and zonal plasma drifts, over the equatorial and low-latitude ionosphere have been studied using different types of observational data, such as digisondes (Liu Libo et al, 2011;Candido et al, 2011;Chuo et al, 2013;Solomon et al, 2013;Narayanan et al, 2014), satellites (Solomon et al, 2011;Huang et al, 2010Huang et al, , 2012Chuo et al, 2013;Fejer et al, 2013) and incoherent scatter radar (Aponte et al, 2013;Kotov et al, 2015;Santos et al, 2016a). During the period of June 2008 the mean monthly F10.7 radio index reached an extremely low value of ∼ 65.7 × 10 −22 W m −2 Hz −1 , which represented a solar extreme ultraviolet (EUV) irradiance that was lower than during previous solar cycles.…”

Section: Introductionmentioning
confidence: 99%

Unusual behavior of quiet-time zonal and vertical plasma drift velocities over Jicamarca during the recent extended solar minimum of 2008
Santos
¹
,
Abdu
²
,
Souza
³

et al. 2017
Ann. Geophys.
3
0
3
0
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Abstract. The influence of the recent deep and prolonged solar minimum on the daytime zonal and vertical plasma drift velocities during quiet time is investigated in this work. Analyzing the data obtained from incoherent scatter radar from Jicamarca (11.95 • S, 76.87 • W) we observe an anomalous behavior of the zonal plasma drift during June 2008 characterized by lower than usual daytime westward drift and its early afternoon reversal to eastward. As a case study the zonal drift observed on 24 June 2008 is modeled using a realistic low-latitude ionosphere simulated by the Sheffield University Plasmasphere-Ionosphere Model-INPE (SUPIM-INPE). The results show that an anomalously low zonal wind was mainly responsible for the observed anomalous behavior in the zonal drift. A comparative study of the vertical plasma drifts obtained from magnetometer data for some periods of maximum (2000)(2001)(2002) and minimum solar activity (1998, 2008, 2010) phases reveal a considerable decrease on the E-region conductivity and the dynamo electric field during 2008. However, we believe that the contribution of these characteristics to the unusual behavior of the zonal plasma drift is significantly smaller than that arising from the anomalously low zonal wind. The SUPIM-INPE result of the critical frequency of the F layer (foF2) over Jicamarca suggested a lower radiation flux than that predicted by solar irradiance model (SOLAR2000) for June 2008.

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Comparison of the characteristics of ionospheric parameters obtained from FORMOSAT-3 and digisonde over Ascension Island

Cited by 18 publications

References 28 publications

Long‐term analysis between radio occultation and ionosonde peak electron density and height during geomagnetic storms

Long‐term analysis between radio occultation and ionosonde peak electron density and height during geomagnetic storms

Validation of COSMIC ionospheric peak parameters by the measurements of an ionosonde chain in China

Unusual behavior of quiet-time zonal and vertical plasma drift velocities over Jicamarca during the recent extended solar minimum of 2008

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