[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.11003/JPNT.2020.9.3.191

Investigation on Figures-of-Merit of Signal Performance for Next Generation RNSS Signal Design

Han, Kahee (Autonomous Navigation Lab., Inha University)
Won, Jong-Hoon (Department of Electrical Engineering, Inha University)

Publication Information

Journal of Positioning, Navigation, and Timing / v.9, no.3, 2020 , pp. 191-205 More about this Journal

Abstract

Designing a new signal is essential in the development of a new Radio Navigation Satellite Service (RNSS) system. This paper introduces the signal design parameters and the figures of merit (FoMs) to be considered in designing a new RNSS signal, and then reviews their relationship in details. In addition, we show examples of the trade-off analysis between FoMs according to the signal design scenarios using an analytical simulation tool based on the relationship between the signal design parameters and the FoMs.

Keywords

RNSS; GNSS; figure of merit; signal design parameters; analytical simulation;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	Anghileri, M., Paonni, M., Wallner, S., Avila-Rodriguez, J.-A., & Eissfeller, B. 2008, Estimating the time-to-first-fix for GNSS signals theory and simulation results, European Navigation Conference (ENCGNSS)-Proceedings, Toulouse, France, pp.23-25.
2	Betz, J. W. 1999, The Offset Carrier Modulation for GPS Modernization, Proceedings of ION 1999, January 25-27, 1999, San Diego, CA, pp.639-648.
3	Betz, J. W. 2001, Effect of Partial-Band Interference on Receiver Estimation of C/N0: Theory, Proceedings of ION NTM 2001, Jan. 22-24, 2001, Long Beach, CA, pp.817-828.
4	Betz, J. W. & Goldstein, D. B. 2002, Candidate Designs for an Additional Civil Signal in GPS Spectral Bands, in Proceeding of The Institute of Navigation National Technical Meeting, San Diego, CA, 28-30 Jan 2002, pp.622-631.
5	Conley, R., Cosentino, R., Hegarty, C. J., Kaplan, E. D., Leva, J. L., et al. 2006, Performance of Stand-Alone GPS, Chapter 7 in Kaplan, E. D. & Hegarty, C. J. (eds), Understanding GPS: Principles and Applications. 2nd ed. (Boston: Artech House Inc.)
6	Esper, M., Chao, E. L., & Wolf, C. F. 2020, 2019 Federal Radionavigation Plan (No. DOT-VNTSC-OST-R-15-01), United States. Dept. of Defense
7	Fine, P. & Wilson, W. 1999, Tracking Algorithm for GPS Offset Carrier Signals, Proceeding of ION 1999, January 25-27, 1999, San Diego, CA, pp.671-676.
8	Foucras, M., Ekambi, B., Bacard, F., Julien, O., & Macabiau, C. 2014, Optimal GNSS acquisition parameters when considering bit transitions, 2014 IEEE/ION Position, Location and Navigation Symposium-PLANS 2014, 5-8 May 2014, Monterey, CA, USA, pp.804-817. https://doi.org/10.1109/PLANS.2014.6851445
9	Han, K. & Won, J.-H. 2018, Investigation on the Relationship between GNSS Signal Design Parameters and its Navigation Performance for the Next Generation GNSS Signal Design, Proceedings of the 31st International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS+ 2018), September 24-28, 2018, Miami, Florida, pp.868-875. https://doi.org/10.33012/2018.15887
10	Han, K. & Won, J.-H. 2019, Development of MATLAB-based Signal Performance Analysis Software for New RNSS Signal Design, Journal of Positioning, Navigation, and Timing, 8, 139-152. https://doi.org/10.11003/JPNT.2019.8.4.139 DOI
11	Hegarty, C. J. 2011, Analytical Model for GNSS Receiver Implementation Losses, Navigation: Journal of The Institute of Navigation, 58, 29-44. https://doi.org/10.1002/j.2161-4296.2011.tb01790.x DOI
12	Holmes, J. K. & Raghavan, S. 2009, The mean cycle slip time for first-, second-, and third-order PLLs, 2009 IEEE Transactions on Aerospace and Electronic Systems, 7-14 March 2009, Big Sky, MT, USA, pp.1-8. https://doi.org/10.1109/AERO.2009.4839416
13	Hoque, M. M. & Jakowski, N. 2012, Ionospheric Propagation Effects on GNSS Signals and New Correction Approaches, Chapter 16 in Jin, S. (ed), Global Navigation Satellite Systems-Signal, Theory and Applications (Rijeka, Croatia: InTech)
14	ITU 2015, Recommendation ITU-R SM.1541-6, Unwanted emissions in the out-of-band domain, International Telecommunication Union.
15	ITU 2016a, Radio Regulations, Vol. 1, International Telecommunication Union.
16	ITU 2016b, Radio Regulations, Vol. 3, International Telecommunication Union.
17	Klobuchar, J. A. 1996, Ionospheric Effects on GPS, Chapter 12 in Parkinson, B. W. & Spilker Jr., J. J. (eds), Global Positioning System: Theory and applications, Volume I (Washington, D.C.: AIAA)
18	Liu, W., Li, S., Liu, L., Niu, M., & Zhan, X. 2010 A Comprehensive Methodology for Assessing Radio Frequency Compatibility for GPS, Galileo and Compass, Proceedings of the 23rd International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS 2010), Portland, OR, September 21-24 2010, pp.943-954.
19	Misra, P. & Enge, P. 2012, Global Positioning System: signals, measurements and performance, Revised 2nd ed. (Lincoln MA: Ganga-Jamuna Press.)
20	Matas, A. 2018, ITU Radio Regulation & Space Traffic Management, 4th Annual Space Traffic Management Conference Embry-Riddle Aeronautical University's College of Aviation 15-19 January 2018, Daytona Beach, Florida USA. https://commons.erau.edu/stm/2018/presentations/18
21	NAVSTAR GPS User Equipment Introduction 1996, Public Release Version, DOD Joint Program Office, September 1996.
22	Park, J. U. & Heo, M. B. 2019, Korea PNT Update, 59th Meeting of the Civil GPS Service Interface Committee, Miami, Florida, 16-17 Sep 2019
23	Rebeyrol, E., Macabiau, C., Julien, O., Ries, L., Issler, J. L., et al. 2006, Signal distortions at GNSS payload level, In: Proceedings od ION GNSS 2006, Institute of Navigation, Fort Worth, Texas, USA, September 26-29 2006, Fort Worth, TX, pp.1595-1605
24	Shin, H., Han, K., & Won, J.-H. 2019, Development of Endto-end Numerical Simulator for Next Generation GNSS Signal Design, Journal of Positioning, Navigation, and Timing, 8, 153-164. https://doi.org/10.11003/JPNT.2019.8.4.153 DOI
25	Spilker Jr, J. J. 1996a, GPS Signal Structure and Theoretical Performance, Chapter 3 in Parkinson, B. W. & Spilker Jr., J. J. (eds), Global Positioning System: Theory and applications, Volume I (Washington, D.C.: AIAA)
26	Spilker Jr, J. J. 1996b, Tropospheric Effects on GPS, Chapter 13 in Parkinson, B. W. & Spilker Jr., J. J. (eds), Global Positioning System: Theory and applications, Volume I (Washington, D.C.: AIAA)
27	Wallner, S., Avila-Rodriguez, J.-A., & Hein, G. W. 2011, Codes: The PRN Family Grows Again, Inside GNSS, September/October 2011, pp.83-92. https://insidegnss.com/codes-the-prn-family-grows-again/
28	Weill, L. R. & Petovello, M. G. 2011, GNSS Solutions: Differences Between Signal Acquisition and Tracking, Inside GNSS, January/February 2011, pp.22-27. https://insidegnss.com/differences-between-signalacquisition-and-tracking/
29	Ward, P. W. & Betz, J. W. 2006a, Satellite Signal Acquisition, Tracking, and Data Demodulation, Chapter 5 in Kaplan, E. D. & Hegarty, C. J. (eds), Understanding GPS: Principles and Applications. 2nd ed. (Boston: Artech House Inc.)
30	Ward, P. W. & Betz, J. W. 2006b, Interference, Multipath, and Scintillation, Chapter 6 in Kaplan, E. D. & Hegarty, C. J. (eds), Understanding GPS: Principles and Applications. 2nd ed. (Boston: Artech House Inc.)
31	Xue, R., Sun, Y., & Zhao, D. 2015, CPM signals for satellite navigation in the S and C bands, Sensors, 15, 13184-13200. https://doi.org/10.3390/s150613184 DOI
32	Won, J.-H., Eissfeller, B., Schmitz-Peiffer, A., & Colzi, E. 2008, C-Band User Terminal Tracking Loop Stability Analysis for European GNSS Evolution Programme, Proceedings of the 21st International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS 2008), Savannah, GA, September 16-19 2008, pp.1706-1718.
33	Won, J.-H., Paonni, M., Fontanella, D., & Eissfeller, B. 2011, Receiver Performance Analysis of Advanced Signal-In-Space Modulation Techniques for Next Generation GNSS, Proceedings of the 18th GNSS Workshop, Jeju, S. Korea, 3-4 Nov. 2011.