To improve the positioning accuracy of the GPS system, the differential technology based on real time kinematic is utilized. Comparing with the conventional differential technology, the differential technology based on the virtual reference station can minimize the size of the rover station which is of great significance for the small system such as the mini-type unmanned vehicle, smart ammunitions and so on. Due to the high cost of the GPS receivers in the market which can’t be redeveloped and the limitation of their interface, it is not suitable for the application of the embedded system. In this paper, the receiver based on the aforementioned method is proposed to realize the real time differential positioning. Firstly, the concept of differential positioning based on real time kinematic is explained. Next, the composition of the virtual reference system and its working principle are introduced. And then, the design of differential GPS receiver based on the virtual reference system for rover station is illustrated. Finally, from the repeatability test, the result shows that by means of getting the differential corrections from the virtual reference station, the designed differential GPS receiver can correct the errors caused by ionosphere, troposphere and atmospheric refraction. Moreover, it can improve the positioning accuracy to centimeter-level. With low cost, small size and convertibility of the interface of the designed differential GPS receiver according to the embedded system, it will be popular in the future market. Copyright © 2014 IFSA Publishing, S. L.
[1]
Mosbeh R. Kaloop,et al.
Talkha steel highway bridge monitoring and movement identification using RTK-GPS technique
,
2013
.
[2]
Jing-nan Liu,et al.
Algorithms for Sparse Network-based RTK GPS Positioning and Performance Assessment
,
2013
.
[3]
Chris Rizos,et al.
Alternatives to current GPS-RTK services and some implications for CORS infrastructure and operations
,
2007
.
[4]
L. Wanninger.
Virtual reference stations (VRS)
,
2003
.
[5]
Denise Dettmering,et al.
Networked Transport of RTCM via Internet Protocol (NTRIP)
,
2005
.
[6]
David C. Slaughter,et al.
Tractor-based Real-time Kinematic-Global Positioning System (RTK-GPS) guidance system for geospatial mapping of row crop transplant
,
2012
.
[7]
Jeongho Cho,et al.
Development of an RTK-GPS Positioning Application with an Improved Position Error Model for Smartphones
,
2012,
Sensors.
[8]
David C. Slaughter,et al.
RTK GPS mapping of transplanted row crops
,
2010
.
[9]
Esmond Mok,et al.
ZigBee network positioning with support of Real-Time Kinematic GPS and terrestrial measurements
,
2013
.
[10]
Christophe Cariou,et al.
Automatic guidance of an off-road mobile robot with a trailer: Application to the control of agricultural passive towed implements
,
2012
.