Automated Landmark Matching of FY-2 Visible Imagery with Its Applications to the On-Orbit Image Navigation Performance Analysis and Improvements

YANG Lei; FENG Xiaohu; LV Ke; SHANG Jian

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Article Navigation > Chinese Journal of Electronics > 2014 > 23(3): 649-654

YANG Lei, FENG Xiaohu, LV Ke, et al., “Automated Landmark Matching of FY-2 Visible Imagery with Its Applications to the On-Orbit Image Navigation Performance Analysis and Improvements,” Chinese Journal of Electronics, vol. 23, no. 3, pp. 649-654, 2014,

Citation:

YANG Lei, FENG Xiaohu, LV Ke, et al., “Automated Landmark Matching of FY-2 Visible Imagery with Its Applications to the On-Orbit Image Navigation Performance Analysis and Improvements,” Chinese Journal of Electronics, vol. 23, no. 3, pp. 649-654, 2014,

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Automated Landmark Matching of FY-2 Visible Imagery with Its Applications to the On-Orbit Image Navigation Performance Analysis and Improvements

YANG Lei^1,2,
FENG Xiaohu^1,2,
LV Ke³,
SHANG Jian^1,2

1.
National Satellite Meteorological Center, China Meteorological Administration, Beijing 100081, China;
2.
Key Laboratory of Radiometric Calibration and Validation for Environmental Satellite, Beijing 100081, China;
3.
Graduate University of Chinese Academy of Sciences, Beijing 100080, China

Funds: This work is supported by the National Natural Science Foundations of China (No.61172113, No.91338109 and No.40975017).

Received Date: 2013-02-01
Rev Recd Date: 2013-04-01
Publish Date: 2014-07-05

Abstract

Abstract

To analysis and improve China Fengyun-2 (FY-2, spin-stabilized geosynchronous meteorological satellite) on-orbit Image navigation (IN) performance, an automated landmark matching algorithm(FY-2 automated landmark matching, FALM) for the Visible and infrared spin scan radiometer (VISSR) visible channel has been developed at China National satellite meteorological center (NSMC). FALM is based on a correlation algorithm used to match the observed landmark to the corresponding landmark extracted from the template. FALM can overcome the previous methods' shortcomings, such as the dependency on ten-year long satellite data and US Defense Mapping Agency data. Each step of FALM, generation of the landmark templates, binarization processing for observed images, image matching between observed images and landmark templates are described. Exclusion of false matching is done by several strict quality measures including cloud contamination detection, prior knowledge check, neighborhood filter and Hypothesis test. 400 days of FY-2 data have been processed by FALM and the results have showed that mainly five factors which can influence the FY-2 on-orbit IN performance: orbit control, the integrity of the known IN parameters, the satellite viewing zone adjustment, beta angle computation and the moment of sunshine pressure. Because of FALM's high processing speed and accuracy, it is ready to put into operation for the FY-2 IN improvement, as well as for operational monitoring purposes, and will be further developed for FY-4.
- Automated landmark matching,
- FY-2,
- On-orbit image navigation performance analysis

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References(11)

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