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学术论文


ADHHI airborne hyperspectral imager: camera structure and geometric correction

浏览: 时间:2022-11-17 15:29 发布人:段延松


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Jieke Dong, Yansong Duan, Qi Zhou, and Xinbo Zhao "ADHHI airborne hyperspectral imager: camera structure and geometric correction", Proc. SPIE 12267, Image and Signal Processing for Remote Sensing XXVIII, 1226717 (26 October 2022); https://doi.org/10.1117/12.2643771


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Poster + Presentation + Paper          
26 October 2022 ADHHI airborne hyperspectral imager: camera structure and geometric correction
Jieke Dong,                             Yansong Duan,                             Qi Zhou,                             Xinbo Zhao          
Author Affiliations +          
Proceedings Volume 12267, Image and Signal Processing for Remote Sensing XXVIII; 1226717 (2022)                                   https://doi.org/10.1117/12.2643771                                  
Event:                                   SPIE Remote Sensing, 2022, Berlin, Germany







Abstract


For decades, the design of remote sensors has to make trade-offs among many characteristics such as the field of view (FOV), spatial resolution, spectral resolution, radiometric resolution, and the number of bands. It’s inevitable to weaken some characteristics to enhance others. Moreover, these problems lead to using multi-sources of remote sensing data in practical projects where a single sensor can’t meet the relevant requirements. The Airborne Dual-mode High-resolution Hyperspectral Imager (ADHHI) provides a new solution to the above limitations by the technology of multi-camera stitching. In this way, many excellent but conflicting characteristics can be separated into different imaging sub-systems, and are combined together during data processing. Supported by related processing algorithms and software, ADHHI embeds many excellent characteristics into one system, such as high spatial resolution, high spectral resolution, and high radiometric resolution. Firstly, this paper picks some common imaging sensors to illustrate the problem of conflicting characteristics. Secondly, we introduce the camera structure and sensor parameters of ADHHI. Then, we sketch out the data processing workflow and elaborate on relevant principles and results of the whole geometric correction, such as homo-spectral stitching and hetero-spectral registration. Finally, this airborne hyperspectral imager’s advantages and application prospects are concluded.