Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities

Pawel Flisek; Biagio Forte; Richard Fallows; Kacper Kotulak; A. Krankowski; Mario M Bisi; Maaijke Mevius; Adam Fron; C. Tiburzi; M. Soida; M. Grzesiak; B.  Smierciak; B Matyjasiak; M Pozoga; B. Dabrowski; G. Mann; Christian Vocks; Pietro Zucca; Leszek Błaszkiewicz

doi:10.1051/swsc/2023021

Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities

Pawel Flisek, Biagio Forte, Richard Fallows, Kacper Kotulak, A. Krankowski, Mario M Bisi, Maaijke Mevius, Adam Fron, C. Tiburzi, M. Soida, M. Grzesiak, B. Smierciak, B Matyjasiak, M Pozoga, B. Dabrowski, G. Mann, Christian Vocks, Pietro Zucca, Leszek Błaszkiewicz

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Abstract

Inhomogeneities within the ionospheric plasma density affect trans-ionospheric radio signals, causing radio wave scintillation in the amplitude and phase of the signals. The amount of scintillation induced by ionospheric irregularities typically decreases with the radio wave frequency. As the ionosphere affects a variety of technological systems (e.g., civil aviation, financial operations) as well as low-frequency radio astronomy observations, it is important to detect and monitor ionospheric effects with higher accuracy than currently available. Here, a novel methodology for the detection and characterization of ionospheric irregularities is established on the basis of LOFAR (Low-Frequency Array) scintillation measurements at Very High Frequency (VHF) that take into account the lack of ergodicity in the intensity fluctuations induced by scintillation. The methodology estimates the S4 scintillation index originating from irregularities with spatial scales in the inertial sub-range of electron density fluctuations in the ionosphere. The methodology is illustrated by means of observations that were collected through the Polish LOFAR stations located in Bałdy, Borowiec and Łazy: its validation was carried out by comparing LOFAR VHF scintillation observations with independent Global Navigation Satellite Systems (GNSS) observations that were collected through a high-rate receiver located near the LOFAR station in Bałdy as well as through geodetic receivers from the Polish ASG-EUPOS network. Two case studies are presented: 31 March 2017 and 28 September 2017. The comparison between LOFAR S4 observations and independent ionospheric measurements of both scintillation and rate of change of Total Electron Content (TEC) from GNSS reveals that the sensitivity of LOFAR and GNSS to ionospheric structures is different as a consequence of the frequency dependency of radio wave scintillation. Furthermore, it can be noticed that observations of LOFAR VHF scintillation can be utilised to detect plasma structures forming in the mid-latitude ionosphere, including electron density gradients occurring over spatial scales that are not necessarily detected through traditional GNSS measurements: the detection of all spatial scales is important for correct monitoring and modelling of ionospheric processes. Hence, the different sensitivity of LOFAR to ionospheric structures, in addition to traditional GNSS ionospheric measurements, allows us to expand the knowledge of ionospheric processes.

Original language	English
Article number	27
Number of pages	22
Journal	Journal of Space Weather and Space Climate
Volume	13
Early online date	3 Nov 2023
DOIs	https://doi.org/10.1051/swsc/2023021
Publication status	Published - 31 Dec 2023

Bibliographical note

Funding Information:
This paper is based on data obtained with the International LOFAR Telescope (ILT) under project codes LC7_001 and LC8_001 available through LOFAR Long Term Archive (LTA): https://lta.lofar.eu/Lofar . LOFAR (van Haarlem et al., 2013) is the Low-Frequency Array designed and constructed by ASTRON. It has observing, data processing, and data storage facilities in several countries, that are owned by various parties (each with their own funding sources), and that are collectively operated by the ILT foundation under a joint scientific policy. The ILT resources have benefitted from the following recent major funding sources: CNRS-INSU, Observatoire de Paris and Université d’Orléans, France; BMBF, MIWF-NRW, MPG, Germany; Science Foundation Ireland (SFI), Department of Business, Enterprise and Innovation (DBEI), Ireland; NWO, The Netherlands; The Science and Technology Facilities Council, UK; Ministry of Science and Higher Education, Poland.

Funding Information:
UWM would like to thank the Ministry of Education and Science of Poland for granting funds for the Polish contribution to the International LOFAR Telescope (decision number 2021/WK/02) and for maintenance of the LOFAR PL-612 Baldy (MSHE decision no. 28/530020/SPUB/SP/2022). The UWM contribution is also supported by the National Centre for Research and Development, Poland, through grant ARTEMIS (decision numbers DWM/PL-CHN/97/2019 and WPC1/ARTEMIS/2019) and the National Science Centre, Poland, through grant 2017/27/B/ST10/02190 and the National Science Centre, Poland for granting “LOFAR observations of the solar corona during Parker Solar Probe perihelion passages” in the Beethoven Classic 3 funding initiative under project number 2018/31/G/ST9/01341.

Funding Information:
The work carried out by BF at the University of Bath was supported by the UK Natural Environment Research Council [Grant number NE/R009082/1, Grant number NE/V002597/1, and Grant number NE/W003074/1]. The editor thanks four anonymous reviewers for their assistance in evaluating this paper.

Keywords

GNSS
Ionospheric irregularities
LOFAR
Scintillation

ASJC Scopus subject areas

Space and Planetary Science
Atmospheric Science

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10.1051/swsc/2023021Licence: CC BY

Flisek_Forte_et_al_manuscript_1Accepted author manuscript, 14.8 MBLicence: CC BY

Cite this

Flisek, P., Forte, B., Fallows, R., Kotulak, K., Krankowski, A., Bisi, M. M., Mevius, M., Fron, A., Tiburzi, C., Soida, M., Grzesiak, M., Smierciak, B., Matyjasiak, B., Pozoga, M., Dabrowski, B., Mann, G., Vocks, C., Zucca, P., & Błaszkiewicz, L. (2023). Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities. Journal of Space Weather and Space Climate, 13, Article 27. https://doi.org/10.1051/swsc/2023021

Flisek, P, Forte, B, Fallows, R, Kotulak, K, Krankowski, A, Bisi, MM, Mevius, M, Fron, A, Tiburzi, C, Soida, M, Grzesiak, M, Smierciak, B, Matyjasiak, B, Pozoga, M, Dabrowski, B, Mann, G, Vocks, C, Zucca, P & Błaszkiewicz, L 2023, 'Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities', Journal of Space Weather and Space Climate, vol. 13, 27. https://doi.org/10.1051/swsc/2023021

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title = "Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities",

abstract = "Inhomogeneities within the ionospheric plasma density affect trans-ionospheric radio signals, causing radio wave scintillation in the amplitude and phase of the signals. The amount of scintillation induced by ionospheric irregularities typically decreases with the radio wave frequency. As the ionosphere affects a variety of technological systems (e.g., civil aviation, financial operations) as well as low-frequency radio astronomy observations, it is important to detect and monitor ionospheric effects with higher accuracy than currently available. Here, a novel methodology for the detection and characterization of ionospheric irregularities is established on the basis of LOFAR (Low-Frequency Array) scintillation measurements at Very High Frequency (VHF) that take into account the lack of ergodicity in the intensity fluctuations induced by scintillation. The methodology estimates the S4 scintillation index originating from irregularities with spatial scales in the inertial sub-range of electron density fluctuations in the ionosphere. The methodology is illustrated by means of observations that were collected through the Polish LOFAR stations located in Ba{\l}dy, Borowiec and {\L}azy: its validation was carried out by comparing LOFAR VHF scintillation observations with independent Global Navigation Satellite Systems (GNSS) observations that were collected through a high-rate receiver located near the LOFAR station in Ba{\l}dy as well as through geodetic receivers from the Polish ASG-EUPOS network. Two case studies are presented: 31 March 2017 and 28 September 2017. The comparison between LOFAR S4 observations and independent ionospheric measurements of both scintillation and rate of change of Total Electron Content (TEC) from GNSS reveals that the sensitivity of LOFAR and GNSS to ionospheric structures is different as a consequence of the frequency dependency of radio wave scintillation. Furthermore, it can be noticed that observations of LOFAR VHF scintillation can be utilised to detect plasma structures forming in the mid-latitude ionosphere, including electron density gradients occurring over spatial scales that are not necessarily detected through traditional GNSS measurements: the detection of all spatial scales is important for correct monitoring and modelling of ionospheric processes. Hence, the different sensitivity of LOFAR to ionospheric structures, in addition to traditional GNSS ionospheric measurements, allows us to expand the knowledge of ionospheric processes.",

keywords = "GNSS, Ionospheric irregularities, LOFAR, Scintillation",

author = "Pawel Flisek and Biagio Forte and Richard Fallows and Kacper Kotulak and A. Krankowski and Bisi, {Mario M} and Maaijke Mevius and Adam Fron and C. Tiburzi and M. Soida and M. Grzesiak and B. Smierciak and B Matyjasiak and M Pozoga and B. Dabrowski and G. Mann and Christian Vocks and Pietro Zucca and Leszek B{\l}aszkiewicz",

note = "Funding Information: This paper is based on data obtained with the International LOFAR Telescope (ILT) under project codes LC7_001 and LC8_001 available through LOFAR Long Term Archive (LTA): https://lta.lofar.eu/Lofar . LOFAR (van Haarlem et al., 2013) is the Low-Frequency Array designed and constructed by ASTRON. It has observing, data processing, and data storage facilities in several countries, that are owned by various parties (each with their own funding sources), and that are collectively operated by the ILT foundation under a joint scientific policy. The ILT resources have benefitted from the following recent major funding sources: CNRS-INSU, Observatoire de Paris and Universit{\'e} d{\textquoteright}Orl{\'e}ans, France; BMBF, MIWF-NRW, MPG, Germany; Science Foundation Ireland (SFI), Department of Business, Enterprise and Innovation (DBEI), Ireland; NWO, The Netherlands; The Science and Technology Facilities Council, UK; Ministry of Science and Higher Education, Poland. Funding Information: UWM would like to thank the Ministry of Education and Science of Poland for granting funds for the Polish contribution to the International LOFAR Telescope (decision number 2021/WK/02) and for maintenance of the LOFAR PL-612 Baldy (MSHE decision no. 28/530020/SPUB/SP/2022). The UWM contribution is also supported by the National Centre for Research and Development, Poland, through grant ARTEMIS (decision numbers DWM/PL-CHN/97/2019 and WPC1/ARTEMIS/2019) and the National Science Centre, Poland, through grant 2017/27/B/ST10/02190 and the National Science Centre, Poland for granting “LOFAR observations of the solar corona during Parker Solar Probe perihelion passages” in the Beethoven Classic 3 funding initiative under project number 2018/31/G/ST9/01341. Funding Information: The work carried out by BF at the University of Bath was supported by the UK Natural Environment Research Council [Grant number NE/R009082/1, Grant number NE/V002597/1, and Grant number NE/W003074/1]. The editor thanks four anonymous reviewers for their assistance in evaluating this paper. ",

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T1 - Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities

AU - Flisek, Pawel

AU - Forte, Biagio

AU - Fallows, Richard

AU - Kotulak, Kacper

AU - Krankowski, A.

AU - Bisi, Mario M

AU - Mevius, Maaijke

AU - Fron, Adam

AU - Tiburzi, C.

AU - Soida, M.

AU - Grzesiak, M.

AU - Smierciak, B.

AU - Matyjasiak, B

AU - Pozoga, M

AU - Dabrowski, B.

AU - Mann, G.

AU - Vocks, Christian

AU - Zucca, Pietro

AU - Błaszkiewicz, Leszek

N1 - Funding Information: This paper is based on data obtained with the International LOFAR Telescope (ILT) under project codes LC7_001 and LC8_001 available through LOFAR Long Term Archive (LTA): https://lta.lofar.eu/Lofar . LOFAR (van Haarlem et al., 2013) is the Low-Frequency Array designed and constructed by ASTRON. It has observing, data processing, and data storage facilities in several countries, that are owned by various parties (each with their own funding sources), and that are collectively operated by the ILT foundation under a joint scientific policy. The ILT resources have benefitted from the following recent major funding sources: CNRS-INSU, Observatoire de Paris and Université d’Orléans, France; BMBF, MIWF-NRW, MPG, Germany; Science Foundation Ireland (SFI), Department of Business, Enterprise and Innovation (DBEI), Ireland; NWO, The Netherlands; The Science and Technology Facilities Council, UK; Ministry of Science and Higher Education, Poland. Funding Information: UWM would like to thank the Ministry of Education and Science of Poland for granting funds for the Polish contribution to the International LOFAR Telescope (decision number 2021/WK/02) and for maintenance of the LOFAR PL-612 Baldy (MSHE decision no. 28/530020/SPUB/SP/2022). The UWM contribution is also supported by the National Centre for Research and Development, Poland, through grant ARTEMIS (decision numbers DWM/PL-CHN/97/2019 and WPC1/ARTEMIS/2019) and the National Science Centre, Poland, through grant 2017/27/B/ST10/02190 and the National Science Centre, Poland for granting “LOFAR observations of the solar corona during Parker Solar Probe perihelion passages” in the Beethoven Classic 3 funding initiative under project number 2018/31/G/ST9/01341. Funding Information: The work carried out by BF at the University of Bath was supported by the UK Natural Environment Research Council [Grant number NE/R009082/1, Grant number NE/V002597/1, and Grant number NE/W003074/1]. The editor thanks four anonymous reviewers for their assistance in evaluating this paper.

PY - 2023/12/31

Y1 - 2023/12/31

N2 - Inhomogeneities within the ionospheric plasma density affect trans-ionospheric radio signals, causing radio wave scintillation in the amplitude and phase of the signals. The amount of scintillation induced by ionospheric irregularities typically decreases with the radio wave frequency. As the ionosphere affects a variety of technological systems (e.g., civil aviation, financial operations) as well as low-frequency radio astronomy observations, it is important to detect and monitor ionospheric effects with higher accuracy than currently available. Here, a novel methodology for the detection and characterization of ionospheric irregularities is established on the basis of LOFAR (Low-Frequency Array) scintillation measurements at Very High Frequency (VHF) that take into account the lack of ergodicity in the intensity fluctuations induced by scintillation. The methodology estimates the S4 scintillation index originating from irregularities with spatial scales in the inertial sub-range of electron density fluctuations in the ionosphere. The methodology is illustrated by means of observations that were collected through the Polish LOFAR stations located in Bałdy, Borowiec and Łazy: its validation was carried out by comparing LOFAR VHF scintillation observations with independent Global Navigation Satellite Systems (GNSS) observations that were collected through a high-rate receiver located near the LOFAR station in Bałdy as well as through geodetic receivers from the Polish ASG-EUPOS network. Two case studies are presented: 31 March 2017 and 28 September 2017. The comparison between LOFAR S4 observations and independent ionospheric measurements of both scintillation and rate of change of Total Electron Content (TEC) from GNSS reveals that the sensitivity of LOFAR and GNSS to ionospheric structures is different as a consequence of the frequency dependency of radio wave scintillation. Furthermore, it can be noticed that observations of LOFAR VHF scintillation can be utilised to detect plasma structures forming in the mid-latitude ionosphere, including electron density gradients occurring over spatial scales that are not necessarily detected through traditional GNSS measurements: the detection of all spatial scales is important for correct monitoring and modelling of ionospheric processes. Hence, the different sensitivity of LOFAR to ionospheric structures, in addition to traditional GNSS ionospheric measurements, allows us to expand the knowledge of ionospheric processes.

AB - Inhomogeneities within the ionospheric plasma density affect trans-ionospheric radio signals, causing radio wave scintillation in the amplitude and phase of the signals. The amount of scintillation induced by ionospheric irregularities typically decreases with the radio wave frequency. As the ionosphere affects a variety of technological systems (e.g., civil aviation, financial operations) as well as low-frequency radio astronomy observations, it is important to detect and monitor ionospheric effects with higher accuracy than currently available. Here, a novel methodology for the detection and characterization of ionospheric irregularities is established on the basis of LOFAR (Low-Frequency Array) scintillation measurements at Very High Frequency (VHF) that take into account the lack of ergodicity in the intensity fluctuations induced by scintillation. The methodology estimates the S4 scintillation index originating from irregularities with spatial scales in the inertial sub-range of electron density fluctuations in the ionosphere. The methodology is illustrated by means of observations that were collected through the Polish LOFAR stations located in Bałdy, Borowiec and Łazy: its validation was carried out by comparing LOFAR VHF scintillation observations with independent Global Navigation Satellite Systems (GNSS) observations that were collected through a high-rate receiver located near the LOFAR station in Bałdy as well as through geodetic receivers from the Polish ASG-EUPOS network. Two case studies are presented: 31 March 2017 and 28 September 2017. The comparison between LOFAR S4 observations and independent ionospheric measurements of both scintillation and rate of change of Total Electron Content (TEC) from GNSS reveals that the sensitivity of LOFAR and GNSS to ionospheric structures is different as a consequence of the frequency dependency of radio wave scintillation. Furthermore, it can be noticed that observations of LOFAR VHF scintillation can be utilised to detect plasma structures forming in the mid-latitude ionosphere, including electron density gradients occurring over spatial scales that are not necessarily detected through traditional GNSS measurements: the detection of all spatial scales is important for correct monitoring and modelling of ionospheric processes. Hence, the different sensitivity of LOFAR to ionospheric structures, in addition to traditional GNSS ionospheric measurements, allows us to expand the knowledge of ionospheric processes.

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DO - 10.1051/swsc/2023021

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JF - Journal of Space Weather and Space Climate

M1 - 27

ER -

Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

EISCAT_3D FINESSE: Fine-scale Structuring, Scintillation, and Electrodynamics

BABHM - Space Weather Instrumentation, Measurement, Modelling and Risk: Ionosphere (SWIMMR-I)

Space weather disruptions to satellite navigation and telecommunications: ionospheric scintillation

Cite this

Towards the possibility to combine LOFAR and GNSS measurements to sense ionospheric irregularities

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Projects

EISCAT_3D FINESSE: Fine-scale Structuring, Scintillation, and Electrodynamics

BABHM - Space Weather Instrumentation, Measurement, Modelling and Risk: Ionosphere (SWIMMR-I)

Space weather disruptions to satellite navigation and telecommunications: ionospheric scintillation

Cite this