METHOD OF EVALUATION OF THE ELECTRIC FIELD LEVEL OF DANGEROUS SIGNALS TO GNSS RECEIVERS
DOI:
https://doi.org/10.18372/2306-1472.75.13111Keywords:
dangerous signals level, integrity of navigation data, navigation, navigational task, power flux density, protection ratio, target functionAbstract
Purpose: It is necessary to develop and test a method for estimating the dangerous signals level to GNSS receivers in order to make a decision on the possibility of fulfilling the target function of the GNSS radio receiver under the influence of interference and to solve the navigation problem. Method: the approach is based on the analysis of the electromagnetic environment, the statistical criteria for optimal detection and instrumental measurements. Results: the article uses the basis of normative documents on the application of GNSS to propose a method for estimating the state of the electromagnetic environment at the location of the GNSS radio receiver in order to make a decision on the possibility of performing the target function by the radio receiver of navigation signals. The proposed method was tested at the National Aviation University.
Discussion: the method is proposed for a tactical assessment of the electromagnetic situation at the location of the GNSS radio receiver and making a decision on whether the target function can be performed by this radio receiver.
References
John Hopkins University Applied Physics Laboratory. GPS Risk Assessment Study – Final Report, January 1999. Available at: http://www.rvs.unibielefeld.de/publications/Incidents/DOCS/Research/Other/Article/gps-risk-ass.pdf (accessed 13.11.2017)
Vulnerability Assessment of the Transportation Infrastructure Relying on the Global Positioning System. A John Volpe National Transportation System Center Final Report, August 29, 2001. Available at: https://www.navcen.uscg.gov/pdf/vulnerability_assess_2001.pdf (accessed 13.11.2017)
Fundamentals of GPS Threats. European Global Navigation Satellite Systems Agency, GNSS Market Report Issue 4, March 2015 Available at: https://www.spirent.com/-/media/White-Papers/Positioning/Fundamentals-of-GPS-Threats.pdf (accessed 30.01.2018)
Federal Radionavigation Plan. Available at: https://www.navcen.uscg.gov/pdf/2008_Federal_Radionavigation_Plan.pdf (accessed 15.05.2018)
. Konin V. V., Melkumian V. H., Sushych O. P. (2005) Otsiniuvannia dostupnosti suputnykovykh navihatsiinykh system [Estimation of the availability of satellite navigation systems] Problemy informatyzatsii ta upravlinnia, no. 12, pp. 90 – 93.
Shvets V. A. (2015) Pidkhody shchodo doslidzhennia elektromahnytnoi sumisnosti hlobalnykh navihatsiinykh suputnykovykh system v zoni aeroportu [Approaches to study the electromagnetic compatibility of global navigation satellite systems in the airport area]. Visnyk inzhenernoyi akademiyi Ukrayiny, no. 4. pp. 61 – 64. (In Ukrainian).
Shvets V. A. (2016) Sposoby otsinky enerhetyky elektrychnoho polia hrupy vyprominiuvachiv v zoni aeroportu yaki stvoriuiut zavady hlobalnym navihatsiinym suputnykovym systemam [Ways of estimating the energy of an electric field of a group of radiators in the airport zone that create obstacles to global navigation satellite systems]. Visnyk inzhenernoyi akademiyi Ukrayiny, no. 1. pp. 45 – 48. (In Ukrainian).
Shvets V. A. (2016) Sproshchena kontseptsiia matematychnoho modeliuvannia elektromahnitnoi obstanovky systemam GPS, HLONASS, HALYLEO [Simplified concept of mathematical modeling of electromagnetic environment for GPS systems, GLONASS, GALILEO]. Visnyk inzhenernoyi akademiyi Ukrayiny, no. 2. pp. 23 – 26. (In Ukrainian).
Tsar'kov N. M. (1985) Elektromagnitnaya sovmestimost' radioelektronnykh sredstv i sistem [Electromagnetic Compatibility of Radioelectronic Facilities and Systems], Moskow, "Radio i svyaz`" Publ., 272 p.
Konin V. V., Kharchenko V. P. (2010) Sistemy sputnikovoi radionavigatsii [Systems of satellite radio navigation], Kiev, "Kholtekh" Publ., 520 p.