An Analysis of Spoofing Effects on a GNSS Receiver Using Real-Time GNSS Spoofing Simulator

Im, Sung-Hyuck;Im, Jun-Hyuck;Jee, Gyu-In;Heo, Mun-Beom;

doi:10.5302/J.ICROS.2013.19.2.113

Journal of Institute of Control, Robotics and Systems (제어로봇시스템학회논문지)

Volume 19 Issue 2
/
Pages.113-118
/
2013
/
1976-5622(pISSN)
/
2233-4335(eISSN)

Institute of Control, Robotics and Systems (제어로봇시스템학회)

DOI QR Code

An Analysis of Spoofing Effects on a GNSS Receiver Using Real-Time GNSS Spoofing Simulator

실시간 GNSS 기만 시뮬레이터를 이용한 위성항법수신기에서의 기만 영향 분석

Im, Sung-Hyuck (Korea Aerospace Research Institute) ;
Im, Jun-Hyuck (Konkuk University) ;
Jee, Gyu-In (Konkuk University) ;
Heo, Mun-Beom (Korea Aerospace Research Institute)

임성혁 (한국항공우주연구원) ;
임준혁 (건국대학교 전자정보통신공학과) ;
지규인 (건국대학교 전자정보통신공학과) ;
허문범 (한국항공우주연구원)

Received : 2012.12.03
Accepted : 2012.12.31
Published : 2013.02.01

https://doi.org/10.5302/J.ICROS.2013.19.2.113 Citation PDF KSCI

Download PDF

⟨ Previous Next ⟩

Abstract

In this paper, spoofing effects on a GNSS receiver were analyzed. The spoofer (spoofing device) was classified to two categories. One is an active spoofer and the other is a passive spoofer. The active spoofer was considered for analysis. For the analysis of spoofing effects on a GNSS receiver, a real-time GNSS spoofing simulator was developed. The simulator was consisted with two parts which are a baseband signal generation part and a RF up-conversion part. The first GNSS baseband signal was generated according to spoofing parameters such as range, range rate, GNSS navigation data, spoofing to GNSS signal ratio, and etc. The generated baseband signal was up-converted to GNSS L1 band. Then the signal transmitted to a GNSS signal. For a perfect spoofing, a spoofer knew an accurate position and velocity of a spoofing target. But, in real world, that is not nearly possible. Although uncertainty of position and velocity of the target was existed, the spoofer was operated as an efficient jammer.

Keywords

References

B. W. Parkinson and J. J. Spilker Jr, GPS Positioning System: Theory and Application, AIAA, 1996.
E. D. Kaplan, Understanding GPS: Principles and Applications, Artech House Publisher, Norwood, MA, 1996.
J. B.-Y. Tsui, Fundamentals of Global Positioning System Receivers : A Software Approach, John Willey&Sons INC., 2000.
T. E. Humphreys, B. M. Ledvina, M. L. Psiaki, B. W. O'Hanlon, and P. M. Kintner, Jr., "Assessing the spoofing threat: development of a portable GPS civilian spoofer," ION GNSS 2008, 2008.
S.-H. Im, G.-I. Jee, S.-D. Cho, and S.-J. Ko, "A novel software GPS receiver architecture using partial down conversion," ION 2007 National Technical Meeting, 2007.
J. S. Warner and R. G. Johnston, "GPS spoofing countermeasures," Homeland Security Journal, Dec. 2003.
S.-H. Im, J.-H. Im, G.-I. Jee, S.-W. Baek, Y.-W. Lee, and D.-Y. Lee, "Susceptibility of spoofing on a GPS L1 C/A signal tracking loop" Journal of The Korean Navigation Institute (in Korean), vol. 15, no. 1, pp. 32-38, 2011.
S.-H. Im and G.-I. Jee, "A GNSS signal correlation using mapbased partial-time common intermediate frequency removal method," Journal of Institute of Control, Robotics, and Systems (in Korean), vol. 14, no. 7, pp. 695-701, 2008. https://doi.org/10.5302/J.ICROS.2008.14.7.695
S.-H. Im and G.-I. Jee, "A implementation of software-based GNSS IF (Intermediate Frequency) signal and IMU (Inertial Measurement Unit) data generator," 12th GNSS Workshop (in Korean), 2005.

Cited by

Station Based Detection Algorithm using an Adaptive Fading Kalman Filter for Ramp Type GNSS Spoofing vol.21, pp.3, 2015, https://doi.org/10.5302/J.ICROS.2015.14.0091