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http://dx.doi.org/10.5140/JASS.2015.32.1.39

Heliocentric Potential (HCP) Prediction Model for Nowscast of Aviation Radiation Dose  

Hwang, Junga (Korea Astronomy and Space Science Institute)
Kim, Kyung-Chan (Korea Astronomy and Space Science Institute)
Dokgo, Kyunghwan (Korea Advanced Institute of Science and Technology)
Choi, Enjin (Korea Astronomy and Space Science Institute)
Kim, Hang-Pyo (Korea Astronomy and Space Science Institute)
Publication Information
Journal of Astronomy and Space Sciences / v.32, no.1, 2015 , pp. 39-44 More about this Journal
Abstract
It is well known that the space radiation dose over the polar route should be carefully considered especially when the space weather shows sudden disturbances such as CME and flares. The National Meteorological Satellite Center (NMSC) and Korea Astronomy and Space Science Institute (KASI) recently established a basis for a space radiation service for the public by developing a space radiation prediction model and heliocentric potential (HCP) prediction model. The HCP value is used as a critical input value of the CARI-6 and CARI-6M programs, which estimate the aviation route dose. The CARI-6/6M is the most widely used and confidential program that is officially provided by the U.S. Federal Aviation Administration (FAA). The HCP value is given one month late in the FAA official webpage, making it difficult to obtain real-time information on the aviation route dose. In order to overcome this limitation regarding time delay, we developed a HCP prediction model based on the sunspot number variation. In this paper, we focus on the purpose and process of our HCP prediction model development. Finally, we find the highest correlation coefficient of 0.9 between the monthly sunspot number and the HCP value with an eight month time shift.
Keywords
space radiation; CARI-6/6M; Heliocentric Potential (HCP);
Citations & Related Records
Times Cited By KSCI : 3  (Citation Analysis)
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1 O'Brien K, Cosmic-Ray Propagation in the Atmosphere, Il Nuovo Cimento A, 3A, 521-547 (1971).
2 O'Brien K, Felsberger E, Kindl P, Application of the heliocentric potential to aircraft dosimetry, Radiation Protection Dosimetry, 116, 336-342 (2005).   DOI
3 Press WH, Teukolsky SA, Vetterling WT, Flannery BP, Numerical Recipes in FORTRAN 77: The Art of Scientific Computing (Cambridge University Press, Cambridge, 1992), 634-637.
4 Taylor G, Recent Developments investigating Radiation Doses to Aircraft Crew, in Twelfth Neutron Users Club, London, 7 Oct 2004.
5 Tiwari RK, Pandey A, Shrivstava PK, Srivastava SK, Relationship of Cosmic Rays with Solar and Geomagnetic Activity, Indian J. Sci. Res. 2, 15-19 (2011).   DOI
6 Tobiska WK, Atwell W, Beck P, Benton E, Copeland K, et al., Advances in atmospheric radiation measurements and modeling needed to improve international air safety, Space Weather submitted (2015).
7 U.S. COESA, U.S. Standard Atmosphere 1976 (the U.S. Government Printing Office, Washington D.C., 1976).
8 Copeland K, Recent and Planned Developments in the CARI Program, Aerospace Medicine Technical Reports, DOT/FAA/AM-13/6 (2013).
9 Hwang J, Lee J, Cho KS, Choi HS, Rho SR, et al., Space Radiation Measurement on the Polar Route onboard the Korean Commercial Flights, JASS 27, 43-54 (2010).
10 Hwang J, Shin DY, Pre-study for Polar Routes Space Radiation Forecast Model Development, The Journal of The Korea Society of Space Technology 8, 23-30 (2013).
11 Hwang J, Dokgo K, Choi E, Park JS, Kim KC, et al., Modeling of Space Radiation Exposure Estimation Program for Pilots, Crew and Passengers on Commercial Flights, JASS 31, 25-31 (2014). http://dx.doi.org/10.5140/JASS.2014.31.1.25   DOI
12 Lantos P, Predictions of Galactic Cosmic Ray Intensity Deduced from that of Sunspot Number, SoPh 229, 373-386 (2005).