Abstract
With the widespread availability of satellite data, a single region can be described using multi-source and multi-temporal remote sensing data, such as high-resolution (HR) optical imagery, synthetic aperture radar (SAR) imagery, and space-borne laser altimetry data. These have become the main source of data for geopositioning. However, due to the limitation of the direct geometric accuracy of HR optical imagery and the effect of the small intersection angle of HR optical imagery in stereo pair orientation, the geometric accuracy of HR optical imagery cannot meet the requirements for geopositioning without ground control points (GCPs), especially in uninhabited areas, such as forests, plateaus, or deserts. Without satellite attitude error, SAR usually provides higher geometric accuracy than optical satellites. Space-borne laser altimetry technology can collect global laser footprints with high altitude accuracy. Therefore, this paper presents a geometric accuracy improvement method for HR optical satellite remote sensing imagery combining multi-temporal SAR Imagery and GLAS data without GCPs. Based on the imaging mechanism, the differences in the weight matrix determination of the HR optical imagery and SAR imagery were analyzed. The laser altimetry data with high altitude accuracy were selected and applied as height control point in combined geopositioning. To validate the combined geopositioning approach, GaoFen2 (GF2) optical imagery, GaoFen6 (GF6) optical imagery, GaoFen3 (GF3) SAR imagery, and the Geoscience Laser Altimeter System (GLAS) footprint were tested. The experimental results show that the proposed model can be effectively applied to combined geopositioning to improve the geometric accuracy of HR optical imagery. Moreover, we found that the distribution and weight matrix determination of SAR images and the distribution of GLAS footprints are the crucial factors influencing geometric accuracy. Combined geopositioning using multi-source remote sensing data can achieve a plane accuracy of 1.587 m and an altitude accuracy of 1.985 m, which is similar to the geometric accuracy of geopositioning of GF2 with GCPs.
Highlights
High-resolution (HR) optical satellite imagery has become an important data source for geopositioning due to the wide coverage, short return period, and good image interpretation [1]
The GF6 satellite is characterized by high resolution and wide coverage, and was launched on 2 June 2018 [39]
We presented a geometric accuracy improvement method for HR optical satellite remote sensing imagery combining multi-temporal synthetic aperture radar (SAR) Imagery and Geoscience Laser Altimeter System (GLAS) data
Summary
High-resolution (HR) optical satellite imagery has become an important data source for geopositioning due to the wide coverage, short return period, and good image interpretation [1]. Due to the limitation of the direct geometric accuracy of HR optical imagery, some ground control points (GCPs) are usually adopted to compensate for geometric errors in HR optical imagery to meet the geometric accuracy requirements of geopositioning [2,3,4,5,6]. Given the widespread availability of satellite data, a single region can be described by multi-source and multi-temporal remote sensing data, such as SAR imagery and laser altimetry data. SAR satellite images usually have a small coverage area and cannot meet the needs of large-area geopositioning. Space-borne laser altimetry technology can collect global laser footprints with high altitude accuracy [9].
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