李子申-尊龙登录

北斗精准导航定位

（1）学术论文

[1].liu, a., et al., shaking: adjusted spherical harmonics adding kriging method for near real-time ionospheric modeling with multi-gnss observations. advances in space research, 2023.71(1): p.67-79.

[2].wang, z., et al., real-time precise orbit determination for leo between kinematic and reduced-dynamic with ambiguity resolution. aerospace, 2022.9(1): p.25.

[3].wang, z., et al., comparison of the real-time precise orbit determination for leo between kinematic and reduced-dynamic modes. measurement, 2022.187: p.110224.

[4].wang, n., et al., a station-specific ionospheric modeling method for the estimation and analysis of beidou-3 differential code bias parameters. navigation: journal of the institute of navigation, 2022.69(1): p. navi.509.

[5].li, z., et al., real-time gnss precise point positioning with smartphones for vehicle navigation. satellite navigation, 2022.3(1): p.19.

[6].zhao, j., et al., integrity investigation of global ionospheric tec maps for high-precision positioning. journal of geodesy, 2021.95(3): p.35.

[7].wang, l., et al., real-time gnss precise point positioning for low-cost smart devices. gps solutions, 2021.25(2): p.69.

[8].wang, n., et al., beidou global ionospheric delay correction model (bdgim): performance analysis during different levels of solar conditions. gps solutions, 2021.25(3): p.97.

[9].li, z., et al., status of cas global ionospheric maps after the maximum of solar cycle 24. satellite navigation, 2021.2(1): p.19.

[10].zhang, w., et al., algorithm research using gnss-tec data to calibrate tec calculated by the iri-2016 model over china. remotesensing,2021.13(19): p.4002.

[11].li, w., et al., a satellite-based method for modeling ionospheric slant tec from gnss observations: algorithm and validation. gps solutions, 2021. 26(1): p.14.

[12].li, r., et al., considering inter-receiver pseudorange biases for bds-2 precise orbit determination. measurement, 2021.177: p.109251.

[13].liu, a., et al., analysis of the short-term temporal variation of differential code bias in gnss receiver. measurement, 2020: p.107448.

[14].li, z., et al., igs real-time service for global ionospheric total electron content modeling. journal of geodesy, 2020.94(3): p.32.

[15].zhao, j., et al., high-rate doppler-aided cycle slip detection and repair method for low-cost single-frequency receivers. gps solutions, 2020.24(3): p. 80.

[16].zhang, y., et al., orbital design of leo navigation constellations and assessment of their augmentation to bds. advances in space research, 2020.

[17].wang, n., et al., gps and glonass observable-specific code bias estimation: comparison of solutions from the igs and mgex networks. journal of geodesy, 2020.94(8): p.74.

[18].李子申, 王宁波与袁运斌, 多模多频卫星导航系统码偏差统一定义与处理方法. 导航定位与授时, 2020. 2020(5): 第10-20页.

[19].li, w., et al., adaptation of the nequick2 model for gnss wide-area ionospheric delay correction in china and the surrounding areas. advances in space research, 2020.

[20].汪亮等, 面向android智能终端的多模gnss实时非差精密定位. 导航定位与授时, 2019. 6(3): 第p1-10页.

[21].wang, l., et al., investigation of the performance of real-time bds-only precise point positioning using the igs real-time service. gps solutions, 2019. 23(3): p.66.

[22].wang, n., et al., refinement of global ionospheric coefficients for gnss applications: methodology and results. advances in space research, 2019. 63(1): p. 343-358.

[23].li, z., et al., regional ionospheric tec modeling based on a two-layer spherical harmonic approximation for real-time single-frequency ppp. journal of geodesy, 2019.93(9): p.1659-1671.

[24].wang, l., et al., validation and assessment of multi-gnss real-time precise point positioning in simulated kinematic mode using igs real-time service. remote sensing, 2018.10(2): p.337.

[25].wang, z., et al., assessment of multiple gnss real-time ssr products from different analysis centers. isprs international journal of geo-information, 2018.7(3): p.85.

[26].zhao, j., et al., the first result of relative positioning and velocity estimation based on caps. sensors, 2018.18(5): p.1528.

[27].liu, a., et al., validation of cas’s final global ionospheric maps during different geomagnetic activities from 2015 to 2017. results in physics, 2018.

[28].wang, n., et al., ionospheric correction using gps klobuchar coefficients with an empirical night-time delay model. advances in space research, 2018.

[29].wang, n., et al., gps, bds and galileo ionospheric correction models: an evaluation in range delay and position domain. journal of atmospheric and solar-terrestrial physics, 2018: p.s1364682617303358.

[30].li, l., et al., integrity monitoring-based ambiguity validation for triple-carrier ambiguity resolution. gps solutions, 2017.21(2): p.797-810.

[31].李子申等, 国际gnss服务组织全球电离层tec格网精度比较与分析. 地球物理学报, 2017(10).

[32].wang, n., et al., an examination of the galileo nequick model: comparison with gps and jason tec. gps solutions, 2017.21(2): p.605-615.

[33].王宁波等, 不同nequick电离层模型参数的应用精度分析. 测绘学报, 2017. 46(4): 第421-429页.

[34].li, l., et al., integrity monitoring-based ratio test for gnss integer ambiguity validation. gps solutions, 2016.20(3): p.573-585.

[35].wang, l., et al., smart device-supported bds/gnss real-time kinematic positioning for sub-meter-level accuracy in urban location-based services. sensors, 2016. 16(12): p. 2201-2215.

[36].汪亮等, bds/gps/glonass组合的双频单历元相对定位性能对比分析. 科学通报, 2015. 60(9): 第857-868页.

[37].li, z., et al., shpts: towards a new method for generating precise global ionospheric tec map based on spherical harmonic and generalized trigonometric series functions. journal of geodesy, 2015.89(4): p.331-345.

[38].zishen, l., et al., determination of the differential code bias for current bds satellites. ieee transactions on geoscience and remote sensing, 2014. 52(7): p.3968-3979.

[39].li, z., et al., two-step method for the determination of the differential code biases of compass satellites. journal of geodesy, 2012.86(11): p.1059-1076.

（2）专著（参与编写）

卫星导航电离层建模与应用,袁运斌、李子申、王宁波、霍星亮，国防工业出版社，2021