Precise GNSS Positioning Using Smart Devices

The recent access to GNSS (Global Navigation Satellite System) phase observations on smart devices, enabled by Google through its Android operating system, opens the possibility to apply precise positioning techniques using off-the-shelf, mass-market devices. The target of this work is to evaluate whether this is feasible, and which positioning accuracy can be achieved by relative positioning of the smart device with respect to a base station. Positioning of a Google/HTC Nexus 9 tablet was performed by means of batch least-squares adjustment of L1 phase double-differenced observations, using the open source goGPS software, over baselines ranging from approximately 10 m to 8 km, with respect to both physical (geodetic or low-cost) and virtual base stations. The same positioning procedure was applied also to a co-located u-blox low-cost receiver, to compare the performance between the receiver and antenna embedded in the Nexus 9 and a standard low-cost single-frequency receiver with external patch antenna. The results demonstrate that with a smart device providing raw GNSS phase observations, like the Nexus 9, it is possible to reach decimeter-level accuracy through rapid-static surveys, without phase ambiguity resolution. It is expected that sub-centimeter accuracy could be achieved, as demonstrated for the u-blox case, if integer phase ambiguities were correctly resolved.

[1]  Michael P. Sama,et al.  Mobile Device-Based Location Services Accuracy , 2016 .

[2]  Eugenio Realini,et al.  Geoguard - An Innovative Technology Based on Low-cost GNSS Receivers to Monitor Surface Deformations , 2017 .

[3]  M. Piras,et al.  Performance of low-cost GNSS receiver for landslides monitoring: test and results , 2015 .

[4]  Lionel Benoit,et al.  Real-time deformation monitoring by a wireless network of low-cost GPS , 2014 .

[5]  J. Saastamoinen Atmospheric Correction for the Troposphere and Stratosphere in Radio Ranging Satellites , 2013 .

[6]  Venkatesh Raghavan,et al.  Enhanced satellite positioning as a web service with goGPS open source software , 2012 .

[7]  Robert W. Heath,et al.  Centimeter Positioning with a Smartphone-Quality GNSS Antenna , 2014 .

[8]  Jan Beutel,et al.  GPS-Equipped Wireless Sensor Network Node for High-Accuracy Positioning Applications , 2012, EWSN.

[9]  Mirko Reguzzoni,et al.  goGPS: open-source MATLAB software , 2015, GPS Solutions.

[10]  Venkatesh Raghavan,et al.  Development of track log and point of interest management system using Free and Open Source Software , 2010 .

[11]  Mirko Reguzzoni,et al.  goGPS: open source software for enhancing the accuracy of low-cost receivers by single-frequency relative kinematic positioning , 2013 .

[12]  Ahmed Hamdi Mansi,et al.  Gravity for Detecting Caves: Airborne and Terrestrial Simulations Based on a Comprehensive Karstic Cave Benchmark , 2016, Pure and Applied Geophysics.

[13]  Ludovico Biagi,et al.  Low-Cost GNSS Receivers for Local Monitoring: Experimental Simulation, and Analysis of Displacements , 2016, Sensors.

[14]  Giulio Magli,et al.  HIGH-PRECISION GPS SURVEY OF VIA APPIA : ARCHAEOASTRONOMY-RELATED ASPECTS , 2014 .

[15]  J. Klobuchar Ionospheric Time-Delay Algorithm for Single-Frequency GPS Users , 1987, IEEE Transactions on Aerospace and Electronic Systems.

[16]  Giulio Magli,et al.  Topographical and astronomical analysis on the Neolithic “Altar” Of Monte D’accoddi In Sardinia , 2009 .

[17]  Maria Antonia Brovelli,et al.  Public participation in GIS via mobile applications , 2016 .

[18]  Jessica,et al.  Landslide Monitoring Using Low Cost GNSS Equipment - Experiences from Two Alpine Testing Sites , 2011 .

[19]  Fernando Sansò,et al.  Experimental Study on Low-Cost Satellite-Based Geodetic Monitoring over Short Baselines , 2016 .