Multi-channel signal parameters joint optimization for GNSS terminals

doi:10.21629/JSEE.2018.01.04

Journal of Systems Engineering and Electronics ›› 2018, Vol. 29 ›› Issue (1): 39-47.doi: 10.21629/JSEE.2018.01.04

• Electronics Technology • Previous Articles Next Articles

Multi-channel signal parameters joint optimization for GNSS terminals

Qian WANG*(), Chuanding ZHANG(), Deyong XIAN()

Beijing Satellite Navigation Center, Beijing 100094, China

Received:2017-06-17 Online:2018-02-26 Published:2018-02-23
Contact: Qian WANG E-mail:wqaloha@139.com;13607665382@163.net;xi_an_yong@126.com
About author:WANG Qian was born in 1978. He received his Ph.D. degree in Computer Science Department of Beihang University. He is a researcher in Beijing Satellite Navigation Center. His research interests include the design of algorithms for signal tracking, integrated navigation and precision positioning. E-mail: wqaloha@139.com|ZHANG Chuanding was born in 1966. He received his Ph.D. degree in PLA Information Engineering University. He is a senior researcher in Beijing Satellite Navigation Center. His research interests include satellite gravity measure and precise orbit determination. E-mail: 13607665382@163.net|XIAN Deyong was born in 1982. He received his M.S. degree in National University of Defense Technology. He is a researcher in Beijing Satellite Navigation Center. His research interests include software receiver and ASIC design. E-mail: xi_an_yong@126.com
Supported by:
the National Natural Science Foundation of China(41474027);National Defense Basic Science Project of China(JCKY2016110B004);This work was supported by the National Natural Science Foundation of China (41474027) and National Defense Basic Science Project of China (JCKY2016110B004)

Abstract

Abstract:

Traditional global navigation satellite system (GNSS) terminals for satellite navigation adopt independent channels to track the signals from different satellites, which results in a lack of information interaction between the channels. Inspired by the vector tracking idea, and drawing lessons from the principle that in the position domain the Taylor expanded pseudorange observations can be used for positioning via the least squares method, this paper proposes a novel least squares-based multi-channel parameter joint estimation (MPJE) method in the signal domain, which not only retains the advantages of channel fusion, but also maintains the flexibility and diversity of the localization algorithm. With achieving optimal carrier to noise ratio as the goal, the proposed method obtains the required code loop and carrier loop parameters for signal tracking in the domain of whole channels. Experimental results indicate that this method fully achieves the assistant fusion advantages of frequency lock loop (FLL), phase lock loop (PLL) and delay lock loop (DLL), making good use of the robustness and dynamic properties of the FLL and the measurement accuracy of the DLL, and is helpful for achieving stable and accurate signal tracking under weak signals and high dynamic stress environments.

Key words: least squares method, signal parameter optimization, vector tracking, global navigation satellite system (GNSS), weight matrix

Qian WANG, Chuanding ZHANG, Deyong XIAN. Multi-channel signal parameters joint optimization for GNSS terminals[J]. Journal of Systems Engineering and Electronics, 2018, 29(1): 39-47.

Figures/Tables 9

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References 14

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Coherent integration time/ms	Ch1	Ch2	Ch3	Ch4	Ch5	Ch6	Ch7	Ch8	Unit
1	33	36	72	60	46	64	46	62	10$^{-4}$ chip
1	0.79	0.78	0.82	0.94	0.98	0.88	0.94	0.98	Hz
10	37	23	53	63	29	65	62	52	10$^{-4}$ chip
10	0.79	0.78	0.82	0.94	0.98	0.88	0.94	0.99	Hz
50	21	19	41	64	19	76	56	46	10$^{-4}$ chip
50	0.79	0.78	0.82	0.94	0.98	0.88	0.94	0.99	Hz
100	15	17	38	75	18	42	44	27	10$^{-4}$ chip
100	0.79	0.78	0.82	1.24	1.03	0.89	1.18	1.02	Hz

Scene	Ch1	Ch2	Ch3	Ch4	Ch5	Ch6	Ch7	Ch8	Average number	Method	Unit
Scene 1(45 dB-Hz)(40 m/s²)	41	31.8	37	32	46	37	40	50	39.35	MPJE	10$^{-4}$ chip
	0.96	1.35	1.42	3.44	3.39	2.66	3.75	3.9	2.61	MPJE	Hz
	89	106	77	150	98	89	210	187	125.75	Scalar	10$^{-4}$ chip
	23	36	38	33	35	77	80	34	44.5	Scalar	Hz
Scene 2(45 dB-Hz)(2 m/s²)	34	19	30	14	22	16	22	27	23	MPJE	10$^{-4}$ chip
	0.423	0.426	0.41	0.44	0.43	0.45	0.45	0.46	0.436	MPJE	Hz
	48	34	38	36	40	22	47	24	36.13	Scalar	10$^{-4}$ chip
	3.5	3.4	3.4	5.4	5.5	3.6	3	5.7	4.19	Scalar	Hz

[1]	Yangjun GAO, Guangyun LI, Zhiwei LYU, Lundong ZHANG, Zhongpan LI. Improved adaptively robust estimation algorithm for GNSS spoofer considering continuous observation error [J]. Journal of Systems Engineering and Electronics, 2022, 33(5): 1237-1248.
[2]	Qian WANG, Feng SHANG, Liming DU, Wenjia ZHOU. Influence of B1 code correlation loop for vector tracking structures under complicated environment [J]. Journal of Systems Engineering and Electronics, 2019, 30(6): 1053-1063.
[3]	Rongling Lang, Xinyue Li, Fei Gao, and Liang Yang. Re-scaling and adaptive stochastic resonance as a tool for weak GNSS signal acquisition [J]. Journal of Systems Engineering and Electronics, 2016, 27(2): 290-296.
[4]	Hongwei Zhao, Baowang Lian, and Juan Feng. Adaptive beamforming and phase bias compensation for GNSS receiver [J]. Journal of Systems Engineering and Electronics, 2015, 26(1): 10-.
[5]	Hong Zhou, Michail Antoniou, Zhangfan Zeng, Rui Zuo, et al.. Pre-processing for time domain image formation in SS-BSAR system [J]. Journal of Systems Engineering and Electronics, 2012, 23(6): 875-880.
[6]	Junfang Fan, Defu Lin, Zhong Su, and Qing Li. Control of static unstable airframes [J]. Journal of Systems Engineering and Electronics, 2010, 21(6): 1063-1071.
[7]	Liu Ming, Liu Yu & Su Baoku. Error model identification of inertial navigation platform based on errors-in-variables model [J]. Journal of Systems Engineering and Electronics, 2009, 20(2): 388-393.

Multi-channel signal parameters joint optimization for GNSS terminals

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Scene	Ch1	Ch2	Ch3	Ch4	Ch5	Ch6	Ch7	Ch8
Scene 1	47	26	26	14	29	26	24	33
Scene 2	38	24	32	11	30	26	25	36
Scene 3	40	38	36	38	60	56	34	48