研究目的
To advance the state of the art on hyperspectral image exploitation algorithms by addressing the challenges of retrieving re?ectance spectra from observed radiance spectra under complex illumination conditions typical of urban settings.
研究成果
The study successfully conducted an airborne measurement experiment to advance hyperspectral imaging exploitation algorithms, demonstrating the potential of combining hyperspectral data with three-dimensional imaging modalities. The development of a compact imaging spectrometer was also highlighted as a key enabler for future missions requiring high-performance, low-SWaP solutions.
研究不足
The study acknowledges the computational expense of solving the full 3-dimensional radiative transfer equation and the potential for calibration drift in ground truth measurements. Additionally, the atmospheric model's assumptions about the vertical distribution of scattering centers may introduce mismatches with observations.
1:Experimental Design and Method Selection:
The study involved an airborne data collection experiment using hyperspectral, laser radar, and pan-chromatic modalities to collect data over a light urban environment.
2:Sample Selection and Data Sources:
A comprehensive ground truth data set was collected, including re?ectance measurements of tarps under various illumination conditions.
3:List of Experimental Equipment and Materials:
The experiment utilized a hyperspectral imager, a LADAR system, and a pan-chromatic camera co-mounted on MITLL's airborne optical systems testbed (AOSTB).
4:Experimental Procedures and Operational Workflow:
The sensors were flown on a Twin Otter aircraft over an office park in Eastern Massachusetts, with ground teams collecting in-situ re?ectance measurements.
5:Data Analysis Methods:
The data was analyzed using MODTRAN? for atmospheric modeling and Mitsuba for solving the light transport equation.
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