TY - JOUR
T1 - Feasibility of precise navigation in high and low latitude regions under scintillation conditions
AU - Juan, José Miguel
AU - Sanz, Jaume
AU - González-Casado, Guillermo
AU - Rovira-Garcia, Adrià
AU - Camps, Adriano
AU - Riba, Jaume
AU - Barbosa, José
AU - Blanch, Estefania
AU - Altadill, David
AU - Orus, Raul
N1 - Funding Information:
Acknowledgements. This work was supported in part by the Spanish Ministry of Science and Innovation project CGL2015-66410-P and in part by the European Space Agency project SCIONAV (ESA-ITT 1-8214/15/NL/LvH). Authors acknowledge the use of data from the International GNSS Service. The editor thanks Eurico Rodrigues de Paula and an anonymous referee for their assistance in evaluating this paper.
Publisher Copyright:
© J.M. Juan et al., Published by EDP Sciences 2018.
PY - 2018
Y1 - 2018
N2 - Scintillation is one of the most challenging problems in Global Navigation Satellite Systems (GNSS) navigation. This phenomenon appears when the radio signal passes through ionospheric irregularities. These irregularities represent rapid changes on the refraction index and, depending on their size, they can produce also diffractive effects affecting the signal amplitude and, eventually producing cycle slips. In this work, we show that the scintillation effects on the GNSS signal are quite different in low and high latitudes. For low latitude receivers, the main effects, from the point of view of precise navigation, are the increase of the carrier phase noise (measured by σI) and the fade on the signal intensity (measured by S4) that can produce cycle slips in the GNSS signal. With several examples, we show that the detection of these cycle slips is the most challenging problem for precise navigation, in such a way that, if these cycle slips are detected, precise navigation can be achieved in these regions under scintillation conditions. For high-latitude receivers the situation differs. In this region the size of the irregularities is typically larger than the Fresnel length, so the main effects are related with the fast change on the refractive index associated to the fast movement of the irregularities (which can reach velocities up to several km/s). Consequently, the main effect on the GNSS signals is a fast fluctuation of the carrier phase (large σI), but with a moderate fade in the amplitude (moderate S4). Therefore, as shown through several examples, fluctuations at high-latitude usually do not produce cycle slips, being the effect quite limited on the ionosphere-free combination and, in general, precise navigation can be achieved also during strong scintillation conditions.
AB - Scintillation is one of the most challenging problems in Global Navigation Satellite Systems (GNSS) navigation. This phenomenon appears when the radio signal passes through ionospheric irregularities. These irregularities represent rapid changes on the refraction index and, depending on their size, they can produce also diffractive effects affecting the signal amplitude and, eventually producing cycle slips. In this work, we show that the scintillation effects on the GNSS signal are quite different in low and high latitudes. For low latitude receivers, the main effects, from the point of view of precise navigation, are the increase of the carrier phase noise (measured by σI) and the fade on the signal intensity (measured by S4) that can produce cycle slips in the GNSS signal. With several examples, we show that the detection of these cycle slips is the most challenging problem for precise navigation, in such a way that, if these cycle slips are detected, precise navigation can be achieved in these regions under scintillation conditions. For high-latitude receivers the situation differs. In this region the size of the irregularities is typically larger than the Fresnel length, so the main effects are related with the fast change on the refractive index associated to the fast movement of the irregularities (which can reach velocities up to several km/s). Consequently, the main effect on the GNSS signals is a fast fluctuation of the carrier phase (large σI), but with a moderate fade in the amplitude (moderate S4). Therefore, as shown through several examples, fluctuations at high-latitude usually do not produce cycle slips, being the effect quite limited on the ionosphere-free combination and, in general, precise navigation can be achieved also during strong scintillation conditions.
KW - Algorithm
KW - Ionosphere (aurora)
KW - Ionosphere (equatorial)
KW - Irregularities
KW - Positioning system
UR - http://www.scopus.com/inward/record.url?scp=85042023745&partnerID=8YFLogxK
U2 - 10.1051/swsc/2017047
DO - 10.1051/swsc/2017047
M3 - Article
AN - SCOPUS:85042023745
SN - 2115-7251
VL - 8
JO - Journal of Space Weather and Space Climate
JF - Journal of Space Weather and Space Climate
M1 - 8
ER -