Low Latitude Ionospheric Irregularity Observations Across a Wide Frequency Spectrum From VHF to S‐Band in the Indian Longitudes

Low Latitude Ionospheric Irregularity Observations Across a Wide Frequency Spectrum From VHF to S‐Band in the Indian Longitudes

This study reports coordinated observation of ionospheric irregularities from VHF Radar, GPS and IRNSS (Indian Regional Navigation Satellite System), from regions near the northern crest of the EIA (Equatorial Ionization Anomaly), which has not been explored earlier. Efforts have been made to study...

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Bibliographic Details
Published in:Radio science Vol. 59; no. 8
Main Authors: Paul, A., Das, A., Biswas, T., Das, T., Nandakumar, P.
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 01-08-2024
Subjects:
Aerospace environments
Equatorial regions
Frequency spectrum
Global positioning systems
GPS
Indian spacecraft
Ionization
Ionosphere
ionospheric irregularity
IRNSS
Irregularities
Latitude
Navigation satellites
Noise intensity
Noise levels
Radar
Radar detection
Radio frequency
Radio signals
Satellite navigation systems
Satellite observation
Satellites
Scintillation
Signal to noise ratio
Superhigh frequencies
Very high frequencies
VHF radar
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Summary:This study reports coordinated observation of ionospheric irregularities from VHF Radar, GPS and IRNSS (Indian Regional Navigation Satellite System), from regions near the northern crest of the EIA (Equatorial Ionization Anomaly), which has not been explored earlier. Efforts have been made to study the signal‐in‐space environment for concurrent detection of ionospheric irregularities over a range of radio frequency, starting from 53 MHz of the Radar, to L‐band of GPS at 1,575.42 MHz and S band signal of IRNSS at 2,492.5 MHz. The radar is operational at Ionosphere Field Station, Haringhata (geographic latitude 22.93°N; geographic longitude 88.51°E; magnetic dip angle 36.2°N) of University of Calcutta. The GPS and IRNSS data are recorded at Calcutta (22.58°N, 88.38°E geographic; magnetic dip: 36°N), separated from Haringhata by 50 km. The spatial as well as temporal variations of irregularities affecting different radio frequencies have been presented. Coordinated observations have been made during period of March–April 2023. Results of the study reveal the common zone of impact of the different radio frequency links spanning from 53 to 2,592.5 MHz and was identified within 16°–25°N, 85°–90°E. During coordinated observations made over several days, irregularity structures have been observed with radar, having backscatter SNR (Signal to Noise ratio) intensity within −5 to 15 dB. During this time, while intense L band scintillation was recorded on multiple satellites of GPS, scintillation recorded at S band signal was moderate to intense. Key Points Coordinated observation of ionospheric irregularities from a low latitude station near the northern crest of equatorial ionization anomaly Study of Signal‐in‐Space (SIS) environment over a range of radio signal from 53 to 2,592.5 MHz Investigation of spatial confinement of ionospheric irregularities using radar and space based satellite signals at L band and S band
ISSN:0048-6604
1944-799X
DOI:10.1029/2023RS007928