350 rub
Journal Radioengineering №6 for 2016 г.
Article in number:
Alternative methods of receiver autonomous integrity monitoring in jamming environment
Keywords: Receiver Autonomous Integrity Monitoring global navigation satellite systems - user equipment jamming navigation signals pre-processing user positioning error
Authors:
A.V. Zhuravlev - Ph. D. (Eng.), Senior Research Scientist, Main Designer - Deputy General Director, JSC «SPE «PROTEK» (Voronezh). E-mail: protek@protek-vrn.ru V.M. Bezmaga - Ph. D. (Eng.), Senior Research Scientist, Leading Research Scientist, JSC «SPE «PROTEK» (Voronezh). E-mail: protek@protek-vrn.ru A.V. Smolin - Deputy Head of Department, JSC «SPE «PROTEK» (Voronezh). E-mail: smolinalexe@yandex.ru
Abstract:
The paper presents suggestions on how to carry out receiver autonomous integrity monitoring with global navigation satellite systems - user equipment in jamming environment by employing 3 alternative methods with the use of indirect measuring techniques during pre-processing and subsequent comparison with threshold values that correspond in a one-to-one manner to user position error, i.e. the ratio of the received signal energy to radio interference power spectral density estimate (the first method), the received signal and its pattern cross-correlation coefficient (the second method), and difference between observable and extrapolated pseudorange estimation (the third method).
Pages: 66-73
References
  1. Radionavigacionnyjj plan Rossijjskojj Federacii. Utverzhden prikazom Minpromtorga Rossii ot 02.09.2008 g. № 118. V redakcii prikaza Minpromtorga Rossii ot 31.08. 2011 g. № 1177.
  2. 2014 FederalRadionavigationPlan. Rezhim dostupa: http://www.navcen.uscg.gov/pdf/FederalRadionavigationPlan2014.pdf. - Data obrashhenija: 25.12.2015.
  3. Doc 9613 AN/937. Rukovodstvo po trebuemym navigacionnym kharakteristikam (RNP). Izd-e 2‑e. Monreal: Mezhdunar. organizacija grazhdanskojj aviacii. 1999. 68 s.
  4. Globalnaja navigacionnaja sputnikovaja sistema GLONASS. Interfejjsnyjj kontrolnyjj dokument. Navigacionnyjj radiosignal v diapazonakh L1, L2 s otkrytym dostupom i chastotnym razdeleniem (redakcija 5.1). M.: RNII KP. 2008. 74 s.
  5. RTCASC-159, MinimumOperationalPerformanceStandardforGlobalPositioningsystem/WideAreaAugmentationSystemAirborneEquipment. RTCA/DO-229B. October6. 1999.
  6. CD-GPS-200C, NAVSTARGPSSpaceSegment/ NavigationUserInterface, ArincResearchCorporation, ElSegundo. CA. October 10.1993. andsubsequentIRNs 1 through4. April 12. 2000.
  7. Sturza M.A.NavigationSystemIntegrityMonitoringUsingRedundantMeasurements // Navigation. Winter 1988-89. V. 35. № 4.
  8. GIRAWP3-NAV-DEL-313-v10, GIRASOLE, GalileoSafetyofLifeReceiversDevelopment «MultisystemGNSSIntegrity».
  9. SHebshaevich V.S., Dmitriev P.P., Ivancevich N.V., Kalugin A.V., Kovalevskijj EH.G., Kutikov V.JU., Maksjutenko JU.A., Molchanov JU.B. Setevye sputnikovye radionavigacionnye sistemy / Pod red. V.S. SHebshaevicha. Izd. 2-e, pererab. i dop. M.: Radiosvjaz. 1993. 408 s.
  10. Nerovnyjj V.V., ZHuravlev A.V., Zemljanukhin V.A. Pomekhoustojjchivost sistemy slezhenija za fazojj apparatury potrebitelejj globalnykh navigacionnykh sputnikovykh sistem pri vozdejjstvii uzkopolosnojj pomekhi // EHlektromagnitnye volny i ehlektronnye sistemy. 2014. № 141. S. 49−52.
  11. Ilin V.A., Poznjak EH.G. Analiticheskaja geometrija: Uchebnik dlja vuzov. Izd. 7-e, ster. M.: FIZMATLIT. 2004. 224 s.