期刊名称:ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences
印刷版ISSN:2194-9042
电子版ISSN:2194-9050
出版年度:2010
卷号:XXXVIII - Part 7B
页码:103-106
出版社:Copernicus Publications
摘要:The Dual push-broom line-based hyperspectral sensors combine two different instruments that are usually mount on the same optical bench. This configuration leads to problems such as co-registration of pixels and squint of the field of view known as boresight effect. Image orientation parameters and sensor boresight of any sensor during data acquisition became possible by a combination of an inertial measurement system (IMU) and GPS. The different position of the IMU, the GPS antenna and the imaging sensors, causes an orientation and boresight effect. Any small change in the correction of internal orientation affects the co- registration between VNIR and SWIR region of hyperspectral images. Correcting the boresight effect is an almost automatically key mission taken by all Dual system users. This is because the boresight effect is considered as a noise in the system and a problem that needs to be corrected prior to any data analysis. We propose to use the boresight effect as a vehicle to monitor and detect some spectral phenomena in the image that can't be obtained in corrected images. The advantage of the sensors orientation and boresight effect was investigated based on the AISA-Dual sensor that combines EAGLE for the VIS -NIR (400-970nm) and HAWK for the SWIR (980-2450nm). An experience of more than six years with this sensor, we have found that the boresight effect have some positive outcomes on the analysis results of the hyperspectral remote sensing (HRS) data. This led us to generate an HRS processing protocol where this effect is examined for gaining the most from the data. Three applications were investigated as follow: 1) enhancing shadowing effect, 2) generating a 3-D view, and 3) performing a better detection of boarder anomaly. We will demonstrate these three options and suggest a possible use of this idea from orbit.
