Arc-Tangent Algorithm for anti-jamming of the GALILEO signals

Authors

  • Yamuna Sharma* School of Electronics Engineering KIIT, Bhubaneswar 751024, India Author
  • Tamesh Halder Dept. of Mining Engineering IIT Kharagpur, Kharagpur-721302, India. Author
  • Arindam Basak School of Electronics Engineering KIIT, Bhubaneswar 751024, India Author
  • Sarita Nanda School of Electronics Engineering KIIT, Bhubaneswar 751024, India Author
  • Debashish Chakravarty Dept. of Mining Engineering IIT Kharagpur, Kharagpur-721302, India. Author

Keywords:

ATSA, ATLMS, Arc-Tangent, Galileo, Anti-Jamming.

Abstract

Due to the diversified applications, GPS i.e Global Positioning System is the most widely used navigation system till date. However, in itself it consumes a number of flaws in terms of accuracy. Later on, with the development of the Global Navigation Satellite System (GLONASS) was designed to overcome these issues, however it failed to meet expectations. Galileo GNSS was the most current and sophisticated development in 2016, and it was released in 2016. It is the most recent satellite navigation system, with higher tracking speed and accuracy superior to both the earlier systems, GPS and GLONASS. This study aims to construct chirp jamming to jam the acquisition signal, then anti-jamming the Galileo GNSS signal using ATSA and ATLMS algorithm to recover the signal that is being provided as an input, which is unavailable in any of the navigation literatures till now. Basically, the objective of the paper is to describe the two arc tangent algorithms, i.e, Arc-tangent Sign Algorithm and Arc-tangent Least Mean Square Algorithm. It is the MATLAB-based simulation for supervising the mitigation techniques using the arc Arc-tangent algorithms. GALILEO signals, their transmission, and reception techniques are also described in the paper.

 

References

[1] Alkan, R. M., Karaman, H., & Sahin, M. GPS, GALILEO and GLONASS satellite navigation systems & amp; GPS modernization.

[2] Dutta, P., Halder, T., Banerjee, S., Basak, A., Nanda, S., & Chakravarty, D. (2022). Analysis of jamming and anti jamming techniques for Galileo GNSS. Materials Today: Proceedings, 58, 489-495.

[3] Hu, H., & Wei, N. (2009, December). A study of GPS jamming and anti-jamming. In 2009 2nd international conference on power electronics and intelligent transportation system (PEITS) (Vol. 1, pp. 388-391). IEEE.

[4] Yao, Z., Lu, M., & Feng, Z. (2009). Unambiguous technique for multiplexed binary offset carrier modulated signals tracking. IEEE Signal Processing Letters, 16(7), 608-611.

[5] Tom, S. Perspective on GNSS compatibility and interoperability. In Second meeting of the International Committee on Global Navigation Satellite System (pp. 1025-1056).

[6] Julien, O., Macabiau, C., Cannon, M. E., & Lachapelle, G. (2007). ASPeCT: Unambiguous sine-BOC (n, n) acquisition/tracking technique for navigation applications. IEEE Transactions on Aerospace and Electronic Systems, 43(1), 150-162.

[7] Yao, Z. (2008, September). A new unambiguous tracking technique for sine-BOC (2n, n) signals. In Proceedings of the 21st International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS 2008) (pp. 1490-1496).

[8] Heiries, V., Àvila-Rodriguez, J. À., Irsigler, M., Hein, G. W., Rebeyrol, E., & Roviras, D. (2005, September). Acquisition performance analysis of composite signals for the L1 OS optimized signal. In Proceedings of the 18th International Technical Meeting of the Satellite Division of the Institute of Navigation (ION GNSS 2005) (pp. 877-889).

[9] Lee, Y., Chong, D., Song, I., Kim, S. Y., Jee, G. I., & Yoon, S. (2012). Cancellation of correlation side-peaks for unambiguous BOC signal tracking. IEEE Communications Letters, 16(5), 569-572.

[10] Hein, G. W., Avila-Rodriguez, J. A., Wallner, S., Pratt, A. R., Owen, J., Issler, J. L., ... & Stansell, T. A. (2006, April). MBOC: the new optimized spreading modulation recommended for GALILEO L1 OS and GPS L1C. In Proceedings of IEEE/ION PLANS 2006 (pp. 883-892).

[11] Kaplan, E. D., & Hegarty, C. (Eds.). (2017). Understanding GPS/GNSS: principles and applications. Artech house.

[12] Hein, G. W., Avila-Rodriguez, J. A., Wallner, S., Pratt, A. R., Owen, J., Issler, J. L., ... & Stansell, T. A. (2006, April). MBOC: the new optimized spreading modulation recommended for GALILEO L1 OS and GPS L1C. In Proceedings of IEEE/ION PLANS 2006 (pp. 883-892).

[13] Arvizu, J. M. C., & Cruz, A. J. A. (2011, November). GNSS receiver based on a SDR architecture using FPGA devices. In 2011 IEEE Electronics, Robotics and Automotive Mechanics Conference (pp. 383-388). IEEE.

[14] Samama, N. (2008). Global positioning: Technologies and performance. John Wiley & Sons.

[15] Brown, A.K., and Thompson, N., (2010). Dynamically reconfigurable software defifined radio for gnss applications. Technical report, DTIC Document.

[16] Jin, T., Wang, Y., Shi, L., & Zhang, H. (2008, October). Software defined radio GNSS receiver design over single DSP platform. In 2008 4th International Conference on Wireless Communications, Networking and Mobile Computing (pp. 1-4). IEEE.

[17] Hurskainen, H., Simona Lohan, E., Hu, X., Raasakka, J., & Nurmi, J. (2008). Multiple gate delay tracking structures for GNSS signals and their evaluation with Simulink, SystemC, and VHDL. International Journal of Navigation and Observation, 2008(1), 785695.

[18] Ries, L., Issler, J. L., Julien, O., & Macabiau, C. (2012). U.S. Patent No. 8,094,071. Washington, DC: U.S. Patent and Trademark Office.

[19] Betz, J. W., Hegarty, C. J., & Rushanan, J. J. (2008). U.S. Patent Application No. 11/785,571.

[20] Lohan, E. S., Burian, A., & Renfors, M. (2008). Low‐complexity unambiguous acquisition methods for BOC‐modulated CDMA signals. International Journal of Satellite Communications and Networking, 26(6), 503-522.

[21] P.S. Diniz, Adaptive Filtering. Springer, 2020.

[22] Peng, S., Ser, W., Chen, B., Sun, L., & Lin, Z. (2018). Robust constrained adaptive filtering under minimum error entropy criterion. IEEE Transactions on Circuits and Systems II: Express Briefs, 65(8), 1119-1123.

[23] Chen, B., Xing, L., Zhao, H., Zheng, N., & Prı, J. C. (2016). Generalized correntropy for robust adaptive filtering. IEEE Transactions on Signal Processing, 64(13), 3376-3387.

[24] He, H., Chen, J., Benesty, J., & Yu, Y. (2021, June). Robust recursive least M-estimate adaptive filter for the identification of low-rank acoustic systems. In ICASSP 2021-2021 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP) (pp. 940-944). IEEE.

[25] Shi, L., & Lin, Y. (2014). Convex combination of adaptive filters under the maximum correntropy criterion in impulsive interference. IEEE Signal Processing Letters, 21(11), 1385-1388.

[26] Sayin, M. O., Vanli, N. D., & Kozat, S. S. (2014). A novel family of adaptive filtering algorithms based on the logarithmic cost. IEEE Transactions on signal processing, 62(17), 4411-4424.

[27] Xiong, K., & Wang, S. (2019). Robust least mean logarithmic square adaptive filtering algorithms. Journal of the Franklin Institute, 356(1), 654-674.

[28] Huang, Y., Zhang, Y., Shi, P., Wu, Z., Qian, J., & Chambers, J. A. (2017). Robust Kalman filters based on Gaussian scale mixture distributions with application to target tracking. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 49(10), 2082-2096.

[29] Wang, S., Wang, W., Xiong, K., Iu, H. H., & Tse, C. K. (2019). Logarithmic hyperbolic cosine adaptive filter and its performance analysis. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 51(4), 2512-2524.

[30] Benesty, J., Paleologu, C., & Ciochina, S. (2010). On regularization in adaptive filtering. IEEE Transactions on audio, speech, and language processing, 19(6), 1734-1742.

[31] Chen, B., Xing, L., Zhao, H., Zheng, N., & Prı, J. C. (2016). Generalized correntropy for robust adaptive filtering. IEEE Transactions on Signal Processing, 64(13), 3376-3387.

[32] Kumar, K., Pandey, R., Bora, S. S., & George, N. V. (2021). A robust family of algorithms for adaptive filtering based on the arctangent framework. IEEE Transactions on Circuits and Systems II: Express Briefs, 69(3), 1967-1971.

[33] Gao, W., & Liu, S. (2011). Improved artificial bee colony algorithm for global optimization. Information Processing Letters, 111(17), 871-882.

[34] Pajala, E., Lohan, E. S., & Renfors, M. (2005, July). CFAR detectors for hybrid-search acquisition of Galileo signals. In CDROM Proc. of ENC-GNSS.

[35] Brahim, F., Chonavel, T., & Rabaste, O. (2008, May). An MCMC algorithm for BOC and AltBOC signaling acquisition in multipath environments. In 2008 IEEE/ION Position, Location and Navigation Symposium (pp. 424-432). IEEE.

[36] Bastide, F., Julien, O., Macabiau, C., & Roturier, B. (2002, September). Analysis of L5/E5 acquisition, tracking and data demodulation thresholds. In Proceedings of the 15th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GPS 2002) (pp. 2196-2207).

[37] De Wilde, W., Sleewaegen, J. M., Simsky, A., Vandewiele, C., Peeters, E., Grauwen, J., & Boon, F. (2006, May). New fast signal acquisition unit for GPS/Galileo receivers. In Proceedings of ENC GNSS.

[38] Dai, L., Wang, Z., Wang, J., & Song, J. (2010, September). Joint code acquisition and Doppler frequency shift estimation for GPS signals. In 2010 IEEE 72nd Vehicular Technology Conference-Fall (pp. 1-5). IEEE.

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Published

2026-03-21

Issue

Vol. 3 No. 3 (2026)

Section

Articles

How to Cite

Arc-Tangent Algorithm for anti-jamming of the GALILEO signals. (2026). World Journal of Multidisciplinary Studies, 3(3), 40-47. https://wasrpublication.com/index.php/wjms/article/view/273

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