| 模型ID: | M00003 | ||||||
| 模型名称: | PROSPECT+SAIL 模型 | ||||||
| 模型编码者: |
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| 模型关键字: | null | ||||||
| 模型类型: | 机理模型 | ||||||
| 模型最后修改日期: | 2012/11/1 0:00:00 | ||||||
| 模型提交日期: | 2012/11/7 0:00:00 | ||||||
| 模型摘要: | PROSPECT模型是在Allen的平板模型基础上发展起来的。它通过模拟叶片从400 nm到2500 nm的上行和下行辐射通量而得到叶片的光学特性。 PROSPECT模型把叶片看做为一个表面粗糙的均匀平板,把非致密型叶片当做由N层平板和N-1层空气组成。现在N已经被扩展到实数范围内,N实际描述的是叶片内部的结构。 光线入射到叶片上时看似垂直,实际上从微观的角度看,入射光线是以一定的角度入射到叶片上的。PROSPECT模型考虑到了这个现象,引入了立体角Ω,Ω由相对于叶平面法线的最大入射角α来确定,假定光线都是从这个立体角里穿过叶片的。 SAIL( Scattering by Arbitrarily Inclined Leaves)模型是一个冠层二向反射率模型,它假设植物冠层是由方位随机分布的水平、均一及无限扩展的各向同性叶片组成的混合体,并且叶子的反射、散射均具有漫反射性质。 SAIL模型则是在Suits模型的基础上,以接近现实的任意取向的叶子去代替Suits模型的水平投影与垂直投影,所以比Suits模型更接近观测数据。当给定冠层结构参数和环境参数时,就可以计算任何太阳角度和观测方向的冠层反射率和透射率。 | ||||||
| 公式: |
| 1 |
名称:Fraction Direct Solar
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参数类型:double
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物理意义:太阳入射辐射中太阳直射光所占的份额
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| 2 |
名称:Solar Declination
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参数类型:double
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物理意义:太阳赤纬
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| 3 |
名称:Latitude
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参数类型:double
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物理意义:纬度
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| 4 |
名称:View Azimuth Angle
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参数类型:double
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物理意义:观测方位角
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| 5 |
名称:View Zenith Angle
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参数类型:double
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物理意义:观测天顶角
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| 6 |
名称:Time of Day
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参数类型:string
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物理意义:用于计算太阳天顶角的时间
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| 7 |
名称:Calculate APAR
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参数类型:bool
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物理意义:是否计算太阳天顶角
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| 标题: | Inversion of the PROSPECT + SAIL canopy reflectance model from AVIRIS equivalent spectra: Theoretical study | ||||||
| 文献作者: |
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| 文献引用: | Remote Sensing of Environment Volume 44, Issues 2–3, May–June 1993, Pages 281–292 | ||||||
| 文献摘要: | The potentials and limits of estimating canopy parameters are investigated using only a reflectance spectrum in the optical domain, and the PROSPECT + SAIL model. Simulations are performed on AVIRIS (Airborne Visible / Infrared Imaging Spectrometer) equivalent spectra, corrected for the atmospheric effects. It is established that this model is numerically invertible. The sensitivity analysis of reflectance spectral features to changes in the values of canopy parameters (leaf mesophyll structure N, chlorophyll a + b concentration Cab, water depth Cw, leaf area index, LAI, and average leaf inclination angle θ1) suggests that the accuracy of the inversion procedure needs some constraints. The Cab and Cw parameters, which describe the leaf physiological status, can be generally retrieved with a reasonable accuracy; it is somewhat difficult to estimate the canopy geometrical parameters (LAI and θ1) separately. Determining the fraction of absorbed photosynthetic active radiation (APAR) with parameters derived from the inversion procedure is discussed. |
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