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Near real-time input to a propagation model for nowcasting of HF communications with aircraft on polar routes. / Warrington, E. M.; Stocker, A. J.; Siddle, D. R.; Hallam, J.; Al-Behadili, H. A.H.; Zaalov, N. Y.; Honary, F.; Rogers, N. C.; Boteler, D. H.; Danskin, D. W.

в: Radio Science, Том 51, № 7, 01.07.2016, стр. 1048-1059.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Warrington, EM, Stocker, AJ, Siddle, DR, Hallam, J, Al-Behadili, HAH, Zaalov, NY, Honary, F, Rogers, NC, Boteler, DH & Danskin, DW 2016, 'Near real-time input to a propagation model for nowcasting of HF communications with aircraft on polar routes', Radio Science, Том. 51, № 7, стр. 1048-1059. https://doi.org/10.1002/2015RS005880

APA

Warrington, E. M., Stocker, A. J., Siddle, D. R., Hallam, J., Al-Behadili, H. A. H., Zaalov, N. Y., Honary, F., Rogers, N. C., Boteler, D. H., & Danskin, D. W. (2016). Near real-time input to a propagation model for nowcasting of HF communications with aircraft on polar routes. Radio Science, 51(7), 1048-1059. https://doi.org/10.1002/2015RS005880

Vancouver

Warrington EM, Stocker AJ, Siddle DR, Hallam J, Al-Behadili HAH, Zaalov NY и пр. Near real-time input to a propagation model for nowcasting of HF communications with aircraft on polar routes. Radio Science. 2016 Июль 1;51(7):1048-1059. https://doi.org/10.1002/2015RS005880

Author

Warrington, E. M. ; Stocker, A. J. ; Siddle, D. R. ; Hallam, J. ; Al-Behadili, H. A.H. ; Zaalov, N. Y. ; Honary, F. ; Rogers, N. C. ; Boteler, D. H. ; Danskin, D. W. / Near real-time input to a propagation model for nowcasting of HF communications with aircraft on polar routes. в: Radio Science. 2016 ; Том 51, № 7. стр. 1048-1059.

BibTeX

@article{439a7b4255314a4390f924095c59a58d,
title = "Near real-time input to a propagation model for nowcasting of HF communications with aircraft on polar routes",
abstract = "There is a need for improved techniques for nowcasting and forecasting (over several hours) HF propagation at northerly latitudes to support airlines operating over the increasingly popular trans-polar routes. In this paper the assimilation of real-time measurements into a propagation model developed by the authors is described, including ionosonde measurements and total electron content (TEC) measurements to define the main parameters of the ionosphere. The effects of D region absorption in the polar cap and auroral regions are integrated with the model through satellite measurements of the flux of energetic solar protons (>1 MeV) and the X-ray flux in the 0.1–0.8 nm band, and ground-based magnetometer measurements which form the Kp and Dst indices of geomagnetic activity. The model incorporates various features (e.g., convecting patches of enhanced plasma density) of the polar ionosphere that are, in particular, responsible for off-great circle propagation and lead to propagation at times and frequencies not expected from on-great circle propagation alone. The model development is supported by the collection of HF propagation measurements over several paths within the polar cap, crossing the auroral oval, and along the midlatitude trough.",
keywords = "HF propagation, polar ionosphere",
author = "Warrington, {E. M.} and Stocker, {A. J.} and Siddle, {D. R.} and J. Hallam and Al-Behadili, {H. A.H.} and Zaalov, {N. Y.} and F. Honary and Rogers, {N. C.} and Boteler, {D. H.} and Danskin, {D. W.}",
year = "2016",
month = jul,
day = "1",
doi = "10.1002/2015RS005880",
language = "English",
volume = "51",
pages = "1048--1059",
journal = "Radio Science",
issn = "0048-6604",
publisher = "Wiley-Blackwell",
number = "7",

}

RIS

TY - JOUR

T1 - Near real-time input to a propagation model for nowcasting of HF communications with aircraft on polar routes

AU - Warrington, E. M.

AU - Stocker, A. J.

AU - Siddle, D. R.

AU - Hallam, J.

AU - Al-Behadili, H. A.H.

AU - Zaalov, N. Y.

AU - Honary, F.

AU - Rogers, N. C.

AU - Boteler, D. H.

AU - Danskin, D. W.

PY - 2016/7/1

Y1 - 2016/7/1

N2 - There is a need for improved techniques for nowcasting and forecasting (over several hours) HF propagation at northerly latitudes to support airlines operating over the increasingly popular trans-polar routes. In this paper the assimilation of real-time measurements into a propagation model developed by the authors is described, including ionosonde measurements and total electron content (TEC) measurements to define the main parameters of the ionosphere. The effects of D region absorption in the polar cap and auroral regions are integrated with the model through satellite measurements of the flux of energetic solar protons (>1 MeV) and the X-ray flux in the 0.1–0.8 nm band, and ground-based magnetometer measurements which form the Kp and Dst indices of geomagnetic activity. The model incorporates various features (e.g., convecting patches of enhanced plasma density) of the polar ionosphere that are, in particular, responsible for off-great circle propagation and lead to propagation at times and frequencies not expected from on-great circle propagation alone. The model development is supported by the collection of HF propagation measurements over several paths within the polar cap, crossing the auroral oval, and along the midlatitude trough.

AB - There is a need for improved techniques for nowcasting and forecasting (over several hours) HF propagation at northerly latitudes to support airlines operating over the increasingly popular trans-polar routes. In this paper the assimilation of real-time measurements into a propagation model developed by the authors is described, including ionosonde measurements and total electron content (TEC) measurements to define the main parameters of the ionosphere. The effects of D region absorption in the polar cap and auroral regions are integrated with the model through satellite measurements of the flux of energetic solar protons (>1 MeV) and the X-ray flux in the 0.1–0.8 nm band, and ground-based magnetometer measurements which form the Kp and Dst indices of geomagnetic activity. The model incorporates various features (e.g., convecting patches of enhanced plasma density) of the polar ionosphere that are, in particular, responsible for off-great circle propagation and lead to propagation at times and frequencies not expected from on-great circle propagation alone. The model development is supported by the collection of HF propagation measurements over several paths within the polar cap, crossing the auroral oval, and along the midlatitude trough.

KW - HF propagation

KW - polar ionosphere

UR - http://www.scopus.com/inward/record.url?scp=84978524313&partnerID=8YFLogxK

U2 - 10.1002/2015RS005880

DO - 10.1002/2015RS005880

M3 - Article

AN - SCOPUS:84978524313

VL - 51

SP - 1048

EP - 1059

JO - Radio Science

JF - Radio Science

SN - 0048-6604

IS - 7

ER -

ID: 36357164