Parameter Design for Time-Domain Optimization of the Fourth-Order Carrier Loop in a BDS Receiver

LI Na; ZHANG Shufang; ZHANG Jingbo; HUAI Shuaiheng; JIANG Yi

doi:10.1049/cje.2021.04.012

Volume 30 Issue 3

May 2021

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Article Navigation > Chinese Journal of Electronics > 2021 > 30(3): 584-594

LI Na, ZHANG Shufang, ZHANG Jingbo, et al., “Parameter Design for Time-Domain Optimization of the Fourth-Order Carrier Loop in a BDS Receiver,” Chinese Journal of Electronics, vol. 30, no. 3, pp. 584-594, 2021, doi: 10.1049/cje.2021.04.012

Citation:

LI Na, ZHANG Shufang, ZHANG Jingbo, et al., “Parameter Design for Time-Domain Optimization of the Fourth-Order Carrier Loop in a BDS Receiver,” Chinese Journal of Electronics, vol. 30, no. 3, pp. 584-594, 2021, doi: 10.1049/cje.2021.04.012

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Parameter Design for Time-Domain Optimization of the Fourth-Order Carrier Loop in a BDS Receiver

doi: 10.1049/cje.2021.04.012

1. Information Science and Technology College, Dalian Maritime University, Dalian 116026, China;
2. Physics and Electronic Information College, Hulunbuir University, Hulunbuir 021008, China

Funds:

This work is supported by the National Natural Science Foundation of China (No.61231006, No.61501078).

Received Date: 2020-12-04

Abstract

Abstract

In the design of a BeiDou navigation satellite system(BDS) receiver, the carrier loop is largely influenced by the loop filter, and the selection of loop filter parameters is crucial to the performance of the carrier loop. In this paper, by analyzing the relationship between the parameters of the loop filter transfer function of the BDS receiver’s fourth-order carrier loop system and the time-domain index of the system, the loop filter transfer function parameters of the fourth-order system are obtained when the dynamic performance is best optimized under the condition that the maximum steady-state error is limited. The relationship between the phase margin, magnitude margin of the system and the parameters of the system transfer function is obtained through simulation experiment and theoretical derivation. The simultaneous equations of deriving the loop system transfer function parameters are given under the following conditions: the optimal phase margin and magnitude margin of the system are settled. These research results have important reference significance for the design of a high-performance BDS receiver.
- BeiDou Navigation Satellite System(BDS) receiver,
- Carrier loop,
- Parameter optimization,
- Tracking,
- Loop filter

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References(26)

References

W. Guo, K. Yan, H. Zhang, X. Niu and C. Shi, “Double stage nco-based carrier tracking loop in gnss receivers for city environmental applications”, IEEE Communications Letters, Vol.18, No.10, pp.1747–1750, 2014.

C. Zeng and W. Li, “Application of extended kalman filter for tracking high dynamic gps signal”, 2016 IEEE International Conference on Signal and 28 Image Processing (ICSIP), Beijing, China, pp.503–507, 2016.

L. Hu and L. Jie, “Design and implementation of digital intelligent carrier synchronization loop”, 2010 International Conference on Computer Application and System Modeling (ICCASM 2010), Taiyuan, China, pp.V2-321-V2-323, 2010.

R. Yang, Y. Morton, K. Ling and E. Poh, “Generalized GNSS Signal Carrier Tracking—Part II: Optimization and Implementation”, IEEE Transactions on Aerospace and Electronic Systems, Vol.53, No.4, pp.1798–1811, 2017.

T. Zhuang, H. T. Chen and W. Cui, “High dynamic carrier tracking technology based on Kalman Filter”, IET International Radar Conference 2015, Hangzhou, China, pp.1–4, 2015.

X. Wang, P. Wu and X. Li, “Carrier tracking loop design for high-dynamic BeiDou receivers”, 20179th International Conference on Modelling, Identification and Control (ICMIC), Kunming, China, pp.296–301, 2017.

C. Yang, T. Nguyen, E. Blasch and M. Miller, “Postcorrelation semi-coherent integration for high-dynamic and weak GPS signal acquisition”, 2008 IEEE/ION Position, Location and Navigation Symposium, Monterey, CA, USA, pp.1341–1349, 2008.

L. Hui and J. S. Yang, “Analysis and simulation of vector tracking algorithms for weak GPS signals”, 20102nd International Asia Conference on Informatics in Control, Automation and Robotics (CAR 2010), Wuhan, China, Vol.2, pp.215–218, 2010.

E. D. Kaplan and C. J. Hegarty, Understanding GPS: Principles and Applications, second edition, Artech House, Norwood, MA, USA, pp.164-190, 1996.

P. H. Lewis and W. E. Weingarten, “A comparison of second, third, and fourth order phase-locked loops”, IEEE Transactions on Aerospace and Electronic Systems, Vol.3, No.4, pp.720–727, 1967.

Y. Cheng, C. Wu, C. Chuang and Y. Wang, “A phase-locked-loop optimal parameter design by improved discrete particle swarm optimization”, 2017 International Conference on Applied System Innovation (ICASI), Sapporo, Japan, pp.227–230, 2017.

H. J. Jiang, C. M. He, D. G. Chen and G. Randall, “Optimal loop parameter design of charge pump PLLs for jitter transfer characteristic optimization”, The 200245th Midwest Symposium on Circuits and Systems, Tulsa, USA, pp.1–344, 2002.

R. Yang, D. Xu and Y. T. Morton, “Generalized multifrequency GPS carrier tracking architecture: Design and performance analysis”, IEEE Transactions on Aerospace and Electronic Systems, Vol.56, No.4, pp.2548–2563, 2020.

Z. Tu, T. Lu and B. Bi, “Research on satellite signal vector tracking based on prefilter under high dynamic conditions”, 2019 IEEE 4th International Conference on Signal and Image Processing (ICSIP), Wuxi, China, pp.626–630, 2019.

S. M. F. S. M. Dardin, A. A. Azid, Z. A. Rashid, A. S. Mokhtar and L. S. Supian, “The effect of contaminated channel in vector tracking loop for position estimation”, 20196th International Conference on Space Science and Communication (IconSpace), Johor Bahru, Malaysia, pp.63–67, 2019.

X. Gang, GPS Principle and receiver design, Electronic Industry Press, Beijing, China, pp.266-295, 2009. (in Chinese)

D. B. Yuan, H. Li, F. Wang and M. Q. Lu, “A GNSS acquisition method with the capability of spoofing detection and mitigation”, Chinese Journal of Electronics, Vol.27, No.1, pp.213–222, 2018.

S. Golestan, F. D. Freijedo and J. M. Guerrero, “A systematic approach to design high-order phase-locked loops”, IEEE Transactions on Power Electronics, Vol.30, No.6, pp.2885–2890, 2015.

G. C. Hsieh and J. C. Hung, “Phase-locked loop techniques: A survey”, IEEE Transactions on Industrial Electronics, Vol.43, No.6, pp.609–615, 1996.

H. W. ZHOU, T. JIN, F. Y. L, et al, “Time-domain approach to the performance analysis of GPS phase locked loop”, Chinese Journal of Electronics, Vol.26, No.2, pp.385–391, 2017.

S. Hu, Principle of Automatic Control, 5th ed, Science Press, BeiJing, China, pp.93-103, pp.201–204, 2007.

R. E. Best, Phase-Locked Loops: Design, Simulation, and Applications, 6th ed, McGraw-Hill Professional, New York, USA, pp.371–396, 1999.

R. L. LANG, Z. SU, K. ZHOU and S. X. MOU, ”A robust signal driven method for GNSS signals interference detection”, Chinese Journal of Electronics, Vol.27, No.2, pp.422–427, 2018.

V. A. Vilnrotter, S. Hinedi and R. Kumar, “Frequency estimation techniques for high dynamic trajectories”, IEEE Transactions on Aerospace and Electronic Systems, Vol.25, No.4, pp.559–577, 2002.

J. B. Zhang, S. F. Zhang, Y. Jiang, “A novel doppler parameter detection algorithm in the high dynamic carrier tracking loop”, Chinese Journal of Electronics, Vol.22, No.01, pp.187–191, 2013.

Y. Lu, Principle and Implementation Technology of Beidou/GPS Dual Mode Software Receiver, Electronic Industry Press, BeiJing, China, pp.126, 2016.

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