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Abstract

The traditional Gauss-Newton iterative method is highly dependent on the initial value when locating the multimode GNSS receiver. If the difference between the initial value and the true value is higher, the algorithm has the problem of increasing number of iterations, and the algorithm lacks the self main monitoring process of the GNSS receiver, which leads to a great reduction in the positioning accuracy. A high precision multi-mode GNSS positioning algorithm is proposed. It is based on the composition and working principle of multimode GNSS multimode receiver, and the pseudo distance positioning distance is obtained by using GNSS multi constellation combined location algorithm. It uses a direct algorithm without initial value and iteration through the new algorithm of high precision positioning. After linearizing the pseudo range location distance equation, the user’s general position is calculated. After the pseudo range location distance equation is carried out in the general position of the user, the user’s position correction is calculated by weighted least squares, and the exact location of the user is obtained. The receiver autonomous integrity monitoring (RAIM) algorithm based on the least square residual method of GNSS receiver is used to realize the self-improvement monitoring of GNSS, and to further improve the precision of the multi-mode GNSS positioning algorithm. Experimental results show that the proposed location algorithm has high location accuracy and stability.

Keywords

High accuracy multimode GNSS positioning algorithm receiver pseudo range fusion RAIM algorithm perfection

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References

Garcia

J.G.

, Roncagliolo

P.A.

and Muravchik

C.H.

, A bayesian technique for real and integer parameters estimation in linear models and its application to GNSS high precision positioning, IEEE Transactions on Signal Processing64(4) (2016), 923–933.

Dong

, Wang

, Chen

et al., Mitigation of multipath effect in GNSS short baseline positioning by the multipath hemispherical map, Journal of Geodesy90(3) (2016), 255–262.

Chen

, Zhang

, Wang

et al., A simplified and unified model of multi-GNSS precise point positioning, Advances in Space Research55(1) (2015), 125–134.

Shen

, Li

, Xu

et al., Spatiotemporal filtering of regional GNSS network’s position time series with missing data using principle component analysis, Journal of Geodesy88(1) (2014), 1–12.

Huang

, Yao

, Cui

et al., Dilution of precision analysis for GNSS collaborative positioning, IEEE Transactions on Vehicular Technology65(5) (2016), 3401–3415.

, Li

X.C.

and Zhang

R.F.

, Research on algorithm of time delay estimation in satellite positioning systems, Computer Simulation32(4) (2015), 61–65.

, Ge

, Dai

et al., Accuracy and reliability of multi-GNSS real-time precise positioning: GPS, GLONASS, BeiDou, and Galileo, Journal of Geodesy89(6) (2015), 607–635.

Paziewski

and Wielgosz

, Investigation of some selected strategies for multi-GNSS instantaneous RTK positioning, Advances in Space Research59(1) (2017), 12–23.

Shu

, Shi

, Xu

et al., Error analysis of high-rate GNSS precise point positioning for seismic wave measurement, Advances in Space Research59(11) (2017), 2691–2713.

10.

Liu

, Xu

, Shu

et al., A new method to improve the performance of multi-GNSS pseudorange positioning in signal-degraded environment, Advances in Space Research58(4) (2016), 577–586.

11.

, Ding

, Dai

et al., Systematic error mitigation in multi-GNSS positioning based on semiparametric estimation, Journal of Geodesy91(12) (2017), 1491–1502.

12.

Liang

, Walter

, Enge

et al., GNSS multipath and jamming mitigation using high-mask-angle antennas and multiple constellations, IEEE Transactions on Intelligent Transportation Systems16(2) (2015), 741–750.

13.

Kashcheyev

, Nava

and Radicella

S.M.

, Estimation of higher-order ionospheric errors in GNSS positioning using a realistic 3-D electron density model, Radio Science47(4) (2016), 1–7.

14.

Chen

, Huang

, Liu

et al., Feasibility analysis of GNSS multi-constellation positioning for lunar spacecraft, Advances in Space Research32(6) (2015), 1155–1159.

15.

Gorni

and Zampieri

, Nonlocal and nonvariational extensions of killing-type equations, Discrete and Continuous Dynamical Systems-Series S11(4SI) (2018), 675–689.

16.

Cheng

, He

and Hu

, Quantitative risk analysis method of information security-Combining fuzzy comprehensive analysis with information entropy, Journal of Discrete Mathematical Sciences and Cryptography20(1) (2017), 149–165.

17.

Xue

, Jiang

and Sun

, Modeling of safety evaluation of super-large deep-water group pile foundation, Journal of Interdisciplinary Mathematics20(1) (2017), 101–111.

18.

Butt

, Ahmad

S.S.

, Shabbir

and Erum

, GIS based surveillance of road traffic accidents (RTA) risk for Rawalpindi city: A geo-statistical approach, Kuwait Journal of Science44(4) (2017), 129–134.

19.

Gao

, Farahani

M.R.

, Aslam

and Hosamani

, Distance learning techniques for ontology similarity measuring and ontology mapping, Cluster Computing-The Journal of Networks Software Tools and Applications20(2SI) (2017), 959–968.

20.

, Liu

, Furuta

and Peng

, Adsorption characteristics of sulfur solution by acticarbon against drinking-water toxicosis, Saudi Journal of Biological Sciences24(6) (2017), 1355–1360.

Simulation research on high precision multimode GNSS positioning algorithm

Abstract

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