Your search keyword '"Ionospheric effect"' showing total 2 results

1. Cycle Slip Detection during High Ionospheric Activities Based on Combined Triple-Frequency GNSS Signals

Author

Shuanggen Jin, Dongsheng Zhao, Gethin Wyn Roberts, and Craig M. Hancock

Subjects

cycle slip, 010504 meteorology & atmospheric sciences, Computer science, Science, Cycle slip, Satellite system, 010502 geochemistry & geophysics, Geodesy, 01 natural sciences, Physics::Geophysics, GNSS applications, Physics::Space Physics, Ionospheric effect, combined signals, General Earth and Planetary Sciences, Ionosphere, Triple frequency, GNSS ionospheric bias mitigation, Smoothing, 0105 earth and related environmental sciences, HMW combination

Abstract

The current cycle slip detection methods of Global Navigation Satellite System (GNSS) were mostly proposed on the basis of assuming the ionospheric delay varying smoothly over time. However, these methods can be invalid during active ionospheric periods, e.g., high Kp index value and scintillations, due to the significant increase of the ionospheric delay. In order to detect cycle slips during high ionospheric activities successfully, this paper proposes a method based on two modified Hatch⁻Melbourne⁻Wübbena combinations. The measurement noise in the Hatch⁻Melbourne⁻Wübbena combination is minimized by employing the optimally selected combined signals, while the ionospheric delay is detrended using a smoothing technique. The difference between the time-differenced ambiguity of the combined signal and this estimated ionospheric trend is adopted as the detection value, which can be free from ionospheric effect and hold the high precision of the combined signal. Five threshold determination methods are proposed and compared to decide the cycle slip from the magnitude aspect. This proposed method is tested with triple-frequency Global Navigation Satellite System observations collected under high ionospheric activities. Results show that the proposed method can correctly detect and fix cycle slips under disturbed ionosphere.

Published

2019

2. Glacier Surface Velocity Retrieval Using D-InSAR and Offset Tracking Techniques Applied to Ascending and Descending Passes of Sentinel-1 Data for Southern Ellesmere Ice Caps, Canadian Arctic

Author

Francisco Navarro and Pablo Sánchez-Gámez

Subjects

geography, Sentinel-1, SAR, offset tracking, D-InSAR, ionospheric effect, Nunavut, Canada, Offset (computer science), geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, Terrain, Glacier, 02 engineering and technology, TOPS, Geodesy, 01 natural sciences, Azimuth, Arctic, Interferometric synthetic aperture radar, General Earth and Planetary Sciences, Geology, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Tidewater

Abstract

The Terrain Observation by Progressive Scans (TOPS) acquisition mode of the Sentinel-1 mission provides a wide coverage per acquisition with resolutions of 5 m in range and 20 m in azimuth, which makes this acquisition mode attractive for glacier velocity monitoring. Here, we retrieve surface velocities from the southern Ellesmere Island ice caps (Canadian Arctic) using both offset tracking and Differential Interferometric Synthetic Aperture Radar (D-InSAR) techniques and combining ascending and descending passes. We optimise the offset tracking technique by omitting the azimuth offsets. By doing so, we are able to improve the final resolution of the velocity product, as Sentinel-1 shows a lower resolution in the azimuth direction. Simultaneously, we avoid the undesired ionospheric effect manifested in the data as azimuth streaks. The D-InSAR technique shows its merits when applied to slow-moving areas, while offset tracking is more suitable for fast-moving areas. This research shows that the methods used here are complementary and the use of both to determine glacier velocities is better than only using one or the other. We observe glacier surface velocities of up to 1200 m year − 1 for the fastest tidewater glaciers. The land-terminating glaciers show typical velocities between 12 and 33 m year − 1 , though with peaks up to 150 m year − 1 in narrowing zones of the confining valleys.

Published

2017