The optimal route selection of airborne remote sensing by simulating radiative transfer

Qiankun Zhu; Xianqiang He; Delu Pan; Zhihua Mao

doi:10.1117/12.619693

12 May 2005 The optimal route selection of airborne remote sensing by simulating radiative transfer

Qiankun Zhu, Xianqiang He, Delu Pan, Zhihua Mao

Proceedings Volume 5832, Optical Technologies for Atmospheric, Ocean, and Environmental Studies; (2005) https://doi.org/10.1117/12.619693
Event: Optical Technologies for Atmospheric, Ocean, and Environmental Studies, 2004, Beijing, China

Abstract

The airborne test experiment validates the function of remote sensor before on-oribt which has important meaning for satellite remote sensing. The sun glint is the most important factor that affects the data quality of airborne test experiment. In order to avoid the sun glint and improve the data quality it needs to select the optimal fly route before the airborne test experiment. This paper simulates the sun glint radiative image with inputed the in-remote sensor atmosphere and water parameters using the radiative transfer theory in atmosphere and ocean. Based on the generated sun glint radiative images can select the optimal fly route will improve the data availability significantly in the airborne test experiment and reduce the waste of manpower and material resources in the airborne test experiment.

Citation Download Citation

Qiankun Zhu, Xianqiang He, Delu Pan, and Zhihua Mao "The optimal route selection of airborne remote sensing by simulating radiative transfer", Proc. SPIE 5832, Optical Technologies for Atmospheric, Ocean, and Environmental Studies, (12 May 2005); https://doi.org/10.1117/12.619693

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