TY - JOUR
T1 - On the feasibility of ionosphere-modeled satellite positioning by a hierarchical ambiguity function methodology
AU - Wu, Joz
AU - Yang, Ming
AU - Tsai, Lung Chih
AU - Chen, Kuan Hung
N1 - Publisher Copyright:
© 2015 The Chinese Institute of Engineers.
PY - 2015/11/17
Y1 - 2015/11/17
N2 - The ambiguity function that is connected with global navigation satellite systems is subjected to a least-squares parameter estimation. A novel algorithm that is applicable to phase data either on the Russian frequency division or the American code division multiple access L-band signals is reported in detail. The positioning technology relies only on pseudoranges and carrier phases measured at one single epoch. The method involves techniques such as wide-lane combination, atmospheric delay correction, variance component estimation, and ambiguity functions in hierarchy. Preliminary experiments showed methodological feasibility in time-dependent relative satellite positioning. In the collocation case study of a 56.6-km baseline, it is also shown that the incorporation of a numerical model epoch-by-epoch for the ionosphere is of great benefit. For the Russian navigation system, 9.5 cm in the northsouth, 11.5 cm in the eastwest, and 22.9 cm in the vertical direction are achieved as root mean square errors. For the American counterpart, there are 7.4, 7.3, and 17.6 cm in positioning accuracy, respectively. Concluding remarks are made to raise some issues that warrant future research efforts.
AB - The ambiguity function that is connected with global navigation satellite systems is subjected to a least-squares parameter estimation. A novel algorithm that is applicable to phase data either on the Russian frequency division or the American code division multiple access L-band signals is reported in detail. The positioning technology relies only on pseudoranges and carrier phases measured at one single epoch. The method involves techniques such as wide-lane combination, atmospheric delay correction, variance component estimation, and ambiguity functions in hierarchy. Preliminary experiments showed methodological feasibility in time-dependent relative satellite positioning. In the collocation case study of a 56.6-km baseline, it is also shown that the incorporation of a numerical model epoch-by-epoch for the ionosphere is of great benefit. For the Russian navigation system, 9.5 cm in the northsouth, 11.5 cm in the eastwest, and 22.9 cm in the vertical direction are achieved as root mean square errors. For the American counterpart, there are 7.4, 7.3, and 17.6 cm in positioning accuracy, respectively. Concluding remarks are made to raise some issues that warrant future research efforts.
KW - ambiguity function
KW - GLONASS
KW - GPS
KW - single-epoch positioning
KW - Taiwan ionospheric model
UR - http://www.scopus.com/inward/record.url?scp=84944279015&partnerID=8YFLogxK
U2 - 10.1080/02533839.2015.1056556
DO - 10.1080/02533839.2015.1056556
M3 - 期刊論文
AN - SCOPUS:84944279015
SN - 0253-3839
VL - 38
SP - 1002
EP - 1009
JO - Journal of the Chinese Institute of Engineers, Transactions of the Chinese Institute of Engineers,Series A/Chung-kuo Kung Ch'eng Hsuch K'an
JF - Journal of the Chinese Institute of Engineers, Transactions of the Chinese Institute of Engineers,Series A/Chung-kuo Kung Ch'eng Hsuch K'an
IS - 8
ER -