Comparison of GNSS Indices, Ionosondes and All-Sky Imagers in Monitoring the Ionosphere in Brazil During Quiet and Disturbed Days

Souza, Ana Lucia Christovam de; Camargo, Paulo de Oliveira

doi:10.1590/s1982-21702019000s00005

Cited by 5 publications

(3 citation statements)

References 18 publications

(17 reference statements)

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“…That means if you increases the frequency of the transmitter beyond the F2-layer the radio waves will not reflected but it will be transmitted. The trace around 100km is the Elayer and foE is the critical frequency of E-layer and ℎ ′ is the virtual height of E-layer (Souza and Camargo, 2019).…”

Section: Ionosondementioning

confidence: 99%

Ionosound Data Analysis for Precise Study of Ionospheric Electron Density

Dinede

2024

Preprint

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The ionosphere, crucial for communication, navigation, and space weather forecasting, pro foundly impacts our technological infrastructure by reflecting and refracting radio waves. Enter Ionosound, a cutting-edge ionospheric sounder system revolutionizing our ability to capture and analyze ionospheric data. Unlike traditional radar, Ionosound employs sound waves to probe electron density profiles, unlocking new insights into the ionosphere’s intricate dynamics. This paper delves into Ionosound’s principles, capabilities, and applications in studying electron density, showcasing its pivotal role in advancing atmospheric research and space weather prediction. With a focus on electron density profiles peaking between 150-350 km, we examine Ionosonde measurements capturing reflections from the E-layer to the F2 peak, with notable absorption observed in the D-layer below the E-layer. We leverage key ionospheric parameters such as electron density profile (Ne), maximum electron density (NmF2), maximum ionization height (hmF2), and critical frequency (foF2) to deepen our analysis. However, it’s important to acknowledge Ionosonde’s limitation in probing only the lower ionospheric region, prompting us to supplement our findings using the Chapman electron density profile to extend observations to upper layers. Through meticulous analysis, Ionosound empowers scientists to explore the ionosphere’s responses to diverse phenomena with unprecedented precision, shaping the future of atmospheric science and space exploration.

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Section: Ionosondementioning

confidence: 99%

Ionosound Data Analysis for Precise Study of Ionospheric Electron Density

Dinede

2024

Preprint

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“…On 6 September 2017, a X9.3 class solar flare occurred and Pereira et al (2021a) successfully proved that it was possible to use the International GNSS Service (IGS) network infrastructure to detect the event by evaluating an increase in the estimated TEC value. Souza and Camargo (2019) presented an interesting multi-instrumental study for two distinct nights, with and without records of ionospheric irregularities. Based on ionospheric irregularity indices, ionosonde data and all-sky optical imagers, the authors discussed the potential and limitations of each instrument, and confirmed the benefit of analyzing the ionosphere through the fusion of data from different sensors.…”

Section: Ionospheric Dynamics Over Brazilmentioning

confidence: 99%

The GNSS NavAer INCT Project Overview and Main Results

Monico

Paula

Moraes

et al. 2022

J. Aerosp. Technol. Manag.

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Air navigation is increasingly dependent on the use of Global Navigation Satellite Systems (GNSS). It allows the determination of the aircraft's position in all phases of the flight and brings many advantages. Although GNSS navigation results in gains, the radio signals from these systems are strongly influenced by the ionospheric environment. It introduces errors that can affect the accuracy, integrity, availability and continuity requirements established by the International Civil Aviation Organization (ICAO). The ionospheric layer has different behaviors depending on the latitude, time of day, season of the year, geomagnetic activity and solar cycle. Since Brazil is located in a region of low latitudes, it experiences a series of unique challenges when compared to regions of mid-latitudes. For this reason, the application of GNSS-based technologies in aviation over the Brazilian territory requires an in-depth assessment of the ionosphere effects. Therefore, the Instituto Nacional de Ciência e Tecnologia (INCT) named GNSS Technology for Supporting Air Navigation was formed in 2017 to better assess the ionosphere impacts and assist government agencies and companies in the development of safe air navigation procedures over Brazil in a near future. This paper presents the most relevant advances achieved so far within this multidisciplinary project that involves Brazilian research centers and universities.

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“…They found that the ROTI map describes the development of the TEC irregularities and characterizes the ionospheric responses to auroral activity in both hemispheres. Souza and Camargo (2019) showed that ROTI could present the temporal evolution of ionospheric irregularities in the Brazilian sector. However, it was not possible to observe the propagation direction, generation, and evolution of the observed irregularities because the authors used one station only.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Different Methods for Calculating the ROTI Index Over the Brazilian Sector

et al. 2021

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Ionospheric irregularities are known to interfere in the Global Navigation Satellite System (GNSS) radio signals leading to increases in positioning errors as a function of the Total Electron Content (TEC) dayto-day variability (Hoque & Jakowski, 2008). In addition, ionospheric scintillation caused by Equatorial Plasma Bubbles (EPBs) degrades the transmission of the signal that goes from the satellite to the receiver, which can cause the loss-of-lock in the receiver (Moraes et al., 2017). Thus, the low latitude ionospheric irregularities have been widely studied in the Brazilian sector using several techniques, such as ionosonde

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Comparison of GNSS Indices, Ionosondes and All-Sky Imagers in Monitoring the Ionosphere in Brazil During Quiet and Disturbed Days

Cited by 5 publications

References 18 publications

Ionosound Data Analysis for Precise Study of Ionospheric Electron Density

Ionosound Data Analysis for Precise Study of Ionospheric Electron Density

The GNSS NavAer INCT Project Overview and Main Results

Evaluation of Different Methods for Calculating the ROTI Index Over the Brazilian Sector

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