Multi-source GNSS data and deep learning-driven RTK positioning error prediction for smartphones

doi:10.11947/j.AGCS.2026.20250355

Abstract

Abstract:

As the most widely used low-cost GNSS terminals at present, smartphones are limited by the physical characteristics of their built-in linearly polarized antennas. Their GNSS signal reception is vulnerable to occlusion interference from complex environments such as urban buildings and trees, leading to significant issues in observations including prominent multipath effects and poor carrier phase continuity, which in turn cause a substantial degradation in positioning accuracy. To address this problem, this study takes multi-source observation data opened by the Android system as the core input, including GNSS raw measurement information, attitude yaw angle and velocity derived from inertial sensors, as well as quality indicators such as pseudorange residuals and position dilution of precision (PDOP) during positioning calculation. Dynamic data collection was conducted in typical complex urban scenarios, and a prediction and correction framework for the 3D real-time kinematic (RTK) positioning error of smartphones was constructed. Considering the spatiotemporal correlation and multi-feature coupling characteristics of positioning errors, this paper proposes a convolutional long short-term memory (CNN-LSTM) neural network integrated with a channel-spatial dual attention mechanism: the convolutional layer extracts the spatial correlation of multi-source features, the LSTM layer captures the temporal dependence of error sequences, and the dual attention mechanism enhances the weights of key satellite channels and core observation features respectively, thereby achieving accurate modeling of error patterns in complex environments. Based on tests conducted with two smartphones of different hardware configurations, the Xiaomi Mi 8 and Google Pixel 6, under asymmetric transition occlusion environments and severe occlusion environments, the results indicate that the positioning accuracy of the Mi 8 was improved by approximately 49.3% and 63.9%, respectively, while the Pixel 6 achieved improvements of 37.5% and 47.1%, respectively. These results verify the universality and effectiveness of the method across different hardware terminals and complex scenarios, providing a lightweight algorithmic support for high-precision positioning of smartphones.

Key words: multi-source GNSS observation data, smartphone RTK, convolutional long short-term memory (CNN-LSTM) network, positioning error prediction

CLC Number:

P228

Chuang SHI, Xinxin CHEN, Jiale WANG, Ming XIA. Multi-source GNSS data and deep learning-driven RTK positioning error prediction for smartphones[J]. Acta Geodaetica et Cartographica Sinica, 2026, 55(5): 761-775.

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References 33

[1]	毕京学, 甄杰, 郭英. Android手机GPS和A-GPS定位精度分析[J]. 测绘通报, 2016(7): 10-13.
	BI Jingxue, ZHEN Jie, GUO Ying. Android phone GPS and A-GPS positioning accuracy analysis[J]. Bulletin of Surveying and Mapping, 2016(7): 10-13.
[2]	王颖喆, 陶贤露, 朱锋, 等. 利用智能手机实现GNSS原始观测值的高精度差分定位[J]. 武汉大学学报(信息科学版), 2021, 46(12): 1941-1950.
	WANG Yingzhe, TAO Xianlu, ZHU Feng, et al. High-precision differential positioning with GNSS raw observations from smartphones[J]. Geomatics and Information Science of Wuhan University, 2021, 46(12): 1941-1950.
[3]	袁良雄, 王浩, 申志恒. 基于扩展天线的智能手机GNSS RTK定位性能研究[J]. 全球定位系统, 2023, 48(3): 77-84.
	YUAN Liangxiong, WANG Hao, SHEN Zhiheng. Research on the GNSS RTK positioning performance of smartphones based on extended antenna[J]. Global Positioning System, 2023, 48(3): 77-84.
[4]	潘宇明, 丁乐乐, 王震. 安卓手机GNSS信号增强对定位精度的影响分析[J]. 测绘通报, 2022(S2): 43-47.
	PAN Yuming, DING Lele, WANG Zhen. Analysis of the influence of GNSS signal enhancement on positioning accuracy of Android phones[J]. Bulletin of Surveying and Mapping, 2022(S2): 43-47.
[5]	高成发, 陈波, 刘永胜. Android智能手机GNSS高精度实时动态定位[J]. 测绘学报, 2021, 50(1): 18-26. DOI: . doi: 10.11947/j.AGCS.2020.20200107
	GAO Chengfa, CHEN Bo, LIU Yongsheng. Android smartphone GNSS high-precision real-time kinematic positioning[J]. Acta Geodaetica et Cartographica Sinica, 2021, 50(1): 18-26. DOI: . doi: 10.11947/j.AGCS.2020.20200107
[6]	TAO X, LIU W, WANG Y, et al. Smartphone RTK positioning with multi-frequency and multi-constellation raw observations: GPS L1/L5, Galileo E1/E5a, BDS B1I/B1C/B2a[J]. Journal of Geodesy, 2023, 97(5): 43.
[7]	李仕辉, 王虎, 马宏阳, 等. 城市环境手机GNSS定位随机模型自适应构建方法[J]. 测绘科学, 2024, 49(3): 8-18.
	LI Shihui, WANG Hu, MA Hongyang, et al. An adaptive stochastic model construction method for smartphone GNSS positioning in urban environments[J]. Science of Surveying and Mapping, 2024, 49(3): 8-18.
[8]	DENG J, WANG H, WEI S, et al. A stochastic model based on optimal satellite subset selection strategy for smartphone pseudorange relative positioning[J]. Sensors, 2024, 24(8): 2598.
[9]	WANG J L, XIA M, ZHANG D, et al. Urban GNSS positioning for consumer electronics: 3D mapping and advanced signal processing[J]. IEEE Transactions on Consumer Electronics, 2025, 71(2): 7059-7072.
[10]	王式太, 张博宇, 殷敏. 基于动态阈值的移动终端GNSS定位阴影匹配算法[J]. 大地测量与地球动力学, 2021, 41(11): 1101-1105.
	WANG Shitai, ZHANG Boyu, YIN Min. A shadow matching algorithm for GNSS positioning of mobile terminals based on dynamic threshold[J]. Journal of Geodesy and Geodynamics, 2021, 41(11): 1101-1105.
[11]	KIM D, JANG M, LEE K, et al. Application of shadow matching technique to improve smartphone-based global navigation satellite system positioning accuracy[J]. Sensors and Materials, 2022, 34: 383.
[12]	GROVES P D. Shadow matching: a new GNSS positioning technique for urban canyons[J]. Journal of Navigation, 2011, 64(3): 417-430.
[13]	冯家昊, 任晓东, 张小红, 等. 一种智能手机GNSS精密定位随机模型构建方法及定位性能分析[J]. 导航定位与授时, 2024, 11(5): 136-144.
	FENG Jiahao, REN Xiaodong, ZHANG Xiaohong, et al. A method for constructing a stochastic model for smartphone GNSS precise positioning and its performance analysis[J]. Navigation, Positioning and Timing, 2024, 11(5): 136-144.
[14]	HUANG X, LI W, DAI Z, et al. Improving smartphone GNSS positioning in challenging urban environments using GA-BPNN[J]. GPS Solutions, 2024, 29(1): 3.
[15]	LIU W, SHI X, ZHU F, et al. Quality analysis of multi-GNSS raw observations and a velocity-aided positioning approach based on smartphones[J]. Advances in Space Research, 2019, 63(8): 2358-2377.
[16]	冷宏宇, 秘金钟, 徐彦田, 等. 智能手机终端RTK定位性能分析[J]. 测绘科学, 2020, 45(12): 15-21.
	LENG Hongyu, MI Jinzhong, XU Yantian, et al. Performance analysis of smartphone RTK positioning[J]. Science of Surveying and Mapping, 2020, 45(12): 15-21.
[17]	WANG Jiale, ZHEN Fu, HU Yong, et al. Instantaneous sub-meter level precise point positioning of low-cost smartphones[J]. NAVIGATION: Journal of the Institute of Navigation, 2023, 70(4): 597.
[18]	ZHANG X, TAO X, ZHU F, et al. Quality assessment of GNSS observations from an Android N smartphone and positioning performance analysis using time-differenced filtering approach[J]. GPS Solutions, 2018, 22(3): 70.
[19]	HÅKANSSON M. Characterization of GNSS observations from a Nexus 9 Android tablet[J]. GPS Solutions, 2018, 23(1): 21.
[20]	王家乐, 郑福, 施闯, 等. 智能手机GNSS数据质量分析及大气增强PPP精度评估[C]//第十三届中国卫星导航年会论文集. 北京: 中国卫星导航系统管理办公室, 2022: 1-9.
	WANG Jiale, ZHENG Fu, SHI Chuang, et al. Analysis of smartphone GNSS data quality and accuracy assessment of atmospheric-augmented PPP[C]//Proceedings of the 13th China Satellite Navigation Conference. Beijing: China Satellite Navigation Office, 2022: 1-9.
[21]	VAZQUEZ-ONTIVEROS J R, MARTINEZ-FELIX C A, MELGAREJO-MORALES A, et al. Assessing the quality of raw GNSS observations and 3D positioning performance using the Xiaomi Mi 8 dual-frequency smartphone in Northwest Mexico[J]. Earth Science Informatics, 2024, 17(1): 21-35.
[22]	赵兴旺, 陶安迪, 陈健, 等. 智能手机GNSS数据质量分析与随机模型建立[J]. 大地测量与地球动力学, 2024, 44(7): 661-666.
	ZHAO Xingwang, TAO Andi, CHEN Jian, et al. Analysis of smartphone GNSS data quality and stochastic model establishment[J]. Journal of Geodesy and Geodynamics, 2024, 44(7): 661-666.
[23]	徐彦田, 刘巍峰, 李玉星, 等. BDS/GPS/GAL智能手机RTK动态定位算法[J]. 无线电工程, 2023, 53(5): 1061-1067.
	XU Yantian, LIU Weifeng, LI Yuxing, et al. BDS/GPS/GAL smartphone RTK dynamic positioning algorithm[J]. Radio Engineering, 2023, 53(5): 1061-1067.
[24]	姚子扬, 尚俊娜, 孙建强, 等. 一种多源融合室内外无缝定位方法[J]. 传感技术学报, 2022, 35(1): 72-83.
	YAO Ziyang, SHANG Junna, SUN Jianqiang, et al. A multi-source fusion seamless indoor and outdoor positioning method[J]. Journal of Transducer Technology, 2022, 35(1): 72-83.
[25]	WANG J L, XIA M, XIE Y, et al. Multimodal sensor fusion-based lightweight pedestrian wearable system for continuous health monitoring and location tracking[J]. IEEE Sensors Journal, 2025, 26(10): 14558-14575.
[26]	PAZIEWSKI J, FORTUNATO M, MAZZONI A, et al. An analysis of multi-GNSS observations tracked by recent Android smartphones and smartphone-only relative positioning results[J]. Measurement. 2021, 175: 109162.
[27]	LI Xingxing, ZHANG Xiaohong, NIU Xiaoji, et al. Progress and achievements of multi-sensor fusion navigation in China during 2019—2023[J]. Journal of Geodesy and Geoinformation Science, 2023, 6(3): 102-114.
[28]	JADERBERG M, SIMONYAN K, ZISSERMAN A. Spatial transformer networks[J]. Advances in Neural Information Processing Systems, 2015, 28.
[29]	ZHU X, CHENG D, ZHANG Z, et al. An empirical study of spatial attention mechanisms in deep networks[C]//Proceedings of 2019 IEEE/CVF International Conference on Computer Vision. Seoul: IEEE, 2019: 6688-6697.
[30]	WANG Jiale, SHI Chuang, ZHENG Fu, et al. Multi-frequency smartphone positioning performance evaluation: insights into A-GNSS PPP-B2b services and beyond[J]. Satellite Navigation, 2024, 5(1): 25.
[31]	YAN D, LI T, JIANG H, et al. PS-VINS: a visual-inertial SLAM system with pedestrian gait and structural constraints using smartphone sensors[J]. IEEE Sensors Journal, 2024, 24(5): 6777-6791.
[32]	WANG Jiale, SHI Chuang, XIA Ming, et al. Seamless indoor-outdoor foot-mounted inertial pedestrian positioning system enhanced by smartphone PPP/3-D Map/Barometer[J]. IEEE Internet of Things Journal, 2024, 11(7): 13051-13069.
[33]	LI Guangcai, GENG Jianghui. Characteristics of raw multi-GNSS measurement error from Google Android smart devices[J]. GPS solutions, 2019, 23(3): 90.

数据源/类名	参数/接口名称	描述	单位
GnssClock类	BiasUncertaintyNanos	描述FullBiasNanos（手机内部时钟与GPST的总偏差）和BiasNanos（GNSS芯片时钟与GPST的亚纳秒级偏差）的不确定度	ns
GnssMeasurement类	ReceivedSvTimeUncertaintyNanos	接收到的卫星的发射时刻不确定度	ns
	AccumulatedDeltaRangeUncertaintyMeters	载波相位不确定度	m
	Cn0DbHz	载噪比	dB-Hz
惯导传感器^[27]	姿态偏航角	描述设备运动方向与正北方向的夹角	°
惯导传感器	平面运动速度	设备在北方向与东方向的运动速度	m/s
后处理	伪距残差	观测伪距与根据定位结果计算的理论伪距之间的差值，反映观测值的拟合程度	m
后处理	PDOP	描述卫星几何构型对定位精度的影响程度	—
后处理	历元间位置差分	相邻两个历元之间计算出的三维位置变化量	m

设备名称	天线	系统	GNSS芯片	星座	频率	载波相位
Mi 8	线极化	安卓12	博通BCM4775	G/R/C/E/J	L1，L5	支持
Pixel 6	线极化	安卓13	博通BCM4776	G/R/C/E/J	L1，L5	支持

设备	指标	模型误差			RTK误差
设备	指标	北向	东向	天向	北向	东向	天向
Mi 8	RMS	4.560 4	6.742 3	5.438 2	10.490 0	11.906 2	11.012 5
	AVE	2.742 5	1.065 1	－3.270 4	－8.680 5	－8.823 9	－9.829 4
	STD	3.665 0	6.696 7	4.370 4	5.924 1	8.040 4	4.994 7
	MAX	10.700 5	12.200 4	12.760 0	16.160 6	21.701 1	20.776 4
Pixel 6	RMS	1.460 1	7.807 1	2.162 7	5.423 1	4.487 8	11.139 5
	AVE	0.275 6	－0.436 4	－1.288 3	3.317 2	1.163 3	5.839 5
	STD	1.442 3	7.840 6	1.747 3	4.315 5	4.359 9	9.541 9
	MAX	4.960 7	19.192 4	5.187 4	11.559 0	11.098 5	19.844 0

设备	指标	模型误差			RTK误差
设备	指标	北向	东向	天向	北向	东向	天向
Mi 8	RMS	5.912 5	3.404 0	7.050 7	10.531 8	4.433 0	24.622 4
	AVE	－2.034 9	－2.229 1	2.426 6	1.014 2	－3.367 4	21.002 2
	STD	5.589 2	2.590 2	6.665 1	10.554 4	2.902 7	12.939 6
	MAX	24.639 9	11.563 4	29.383 3	23.696 6	13.401 8	46.614 2
Pixel 6	RMS	9.164 4	6.814 8	10.749 7	9.812 3	7.094 4	27.085 3
	AVE	－3.633 2	4.771 9	4.538 0	6.469 1	1.766 3	23.347 4
	STD	8.467 2	4.896 3	9.807 1	7.424 9	6.914 9	13.817 6
	MAX	29.094 4	18.462 4	33.214 6	22.139 8	17.663 8	66.107 3