| 模型ID: | M00027 | ||||||
| 模型名称: | 植被冠层光学二向反射特性模拟模型 | ||||||
| 模型编码者: |
|
||||||
| 模型关键字: | 植被、二向反射、三维模拟模型、面元、形状因子 | ||||||
| 模型类型: | 理论模型 | ||||||
| 模型最后修改日期: | 2014/6/15 0:00:00 | ||||||
| 模型提交日期: | 2014/6/15 0:00:00 | ||||||
| 模型摘要: | RGM模型(Qin and Gerstl 2000)是一种基于辐射度方法的植被冠层二向反射特性三维模拟模型,RGM一般由三个计算模块组成:场景的生成;场景中各组分辐射度的计算;以及场景的二向性反射率因子BRF 及其它感兴趣参量,如反照率(albedo),光合有效辐射吸收系数(fpar)等的计算。RGM模型适用于多角度遥感应用研究。RGM场景由多边形面元构成,通过给定面元的基本结构、几何特征及面元间的拓扑关系,可以生成虚拟的植被场景。 | ||||||
| 公式: |
| 1 |
名称:观测波段
|
参数类型:int
|
物理意义:可见光/近红外观测波段
|
| 2 |
名称:观测角度起始值
|
参数类型:double
|
物理意义:观测角度起始值,度
|
| 3 |
名称:观测角度终止值
|
参数类型:double
|
物理意义:观测角度终止值,度
|
| 4 |
名称:观测角度步长
|
参数类型:double
|
物理意义:观测角度步长,度
|
| 5 |
名称:太阳天顶角
|
参数类型:double
|
物理意义:太阳天顶角,度
|
| 6 |
名称:太阳方位角
|
参数类型:double
|
物理意义:太阳方位角,度
|
| 7 |
名称:天空光比例
|
参数类型:double
|
物理意义:天空光比例
|
| 8 |
名称:上半空间剖分角度个数
|
参数类型:int
|
物理意义:上半空间剖分角度个数
|
| 9 |
名称:场景长度
|
参数类型:double
|
物理意义:场景长度,米
|
| 10 |
名称:场景宽度
|
参数类型:double
|
物理意义:场景宽度,米
|
| 11 |
名称:场景高度
|
参数类型:double
|
物理意义:场景高度,米
|
| 12 |
名称:场景起点坐标
|
参数类型:double
|
物理意义:场景起点坐标(x,y,z)
|
| 13 |
名称:场景DEM
|
参数类型:double
|
物理意义:场景DEM
|
| 14 |
名称:植被类型
|
参数类型:String
|
物理意义:植被类型
|
| 15 |
名称:树冠类型
|
参数类型:String
|
物理意义:树冠类型
|
| 16 |
名称:树高
|
参数类型:double
|
物理意义:树高,m
|
| 17 |
名称:枝下高
|
参数类型:double
|
物理意义:枝下高,m
|
| 18 |
名称:冠幅
|
参数类型:double
|
物理意义:冠幅,m
|
| 19 |
名称:胸径
|
参数类型:double
|
物理意义:胸径,m
|
| 20 |
名称:叶片面元边长
|
参数类型:double
|
物理意义:叶片面元边长,m
|
| 21 |
名称:作物类型
|
参数类型:String
|
物理意义:作物类型
|
| 22 |
名称:株高
|
参数类型:double
|
物理意义:株高,m
|
| 23 |
名称:茎秆直径
|
参数类型:double
|
物理意义:茎秆直径,m
|
| 24 |
名称:叶分段宽度
|
参数类型:double
|
物理意义:叶分段宽度,m
|
| 25 |
名称:叶分段长度
|
参数类型:double
|
物理意义:叶分段长度,m
|
| 26 |
名称:节间距
|
参数类型:double
|
物理意义:节间距,m
|
| 27 |
名称:叶倾角起始角度
|
参数类型:int
|
物理意义:叶倾角起始角度, 度
|
| 28 |
名称:叶倾角终止角度
|
参数类型:int
|
物理意义:叶倾角终止角度, 度
|
| 29 |
名称:叶倾角角度步长
|
参数类型:int
|
物理意义:叶倾角角度步长
|
| 30 |
名称:叶倾角概率密度
|
参数类型:double
|
物理意义:叶倾角概率密度
|
| 31 |
名称:土壤面元边长
|
参数类型:double
|
物理意义:土壤面元边长,米
|
| 32 |
名称:场景LAI
|
参数类型:double
|
物理意义:场景LAI, m2/m2
|
| 33 |
名称:植株数目
|
参数类型:int
|
物理意义:植株数目
|
| 34 |
名称:植株位置
|
参数类型:double
|
物理意义:植株位置(x,y,z)
|
| 35 |
名称:叶片反射率
|
参数类型:double
|
物理意义:叶片反射率
|
| 36 |
名称:叶片透过率
|
参数类型:double
|
物理意义:叶片透过率
|
| 37 |
名称:茎杆反射率
|
参数类型:double
|
物理意义:茎杆反射率
|
| 38 |
名称:茎杆透过率
|
参数类型:double
|
物理意义:茎杆透过率
|
| 39 |
名称:土壤反射率
|
参数类型:double
|
物理意义:土壤反射率
|
| 40 |
名称:土壤透过率
|
参数类型:double
|
物理意义:土壤透过率
|
| 标题: | 3-D scene modeling of semidesert vegetation cover and its radiation regime | |||||||||
| 文献作者: |
|
|||||||||
| 文献引用: | Remote Sensing of Environment | |||||||||
| 文献摘要: | To explore the potential of multiangle remote sensing for estimating biophysical or ecological parameters over a variety of landscapes, a modeling tool that is capable of handling three-dimensional (3-D) heterogeneous structures, deriving ecological parameters from the vegetation structure, and effectively working on different scene scales is very desirable. A 3-D scene modeling approach for these purposes is presented in this paper. This 3-D model fulfills its goal by taking advantage of radiosity theory and computer graphics techniques. It consists of two major modules: a modified extended L-systems (MELS) method to generate a 3-D realistic scene and a radiosity-graphics combined method (RGM) to calculate the radiation regime based on the 3-D structures rendered with MELS. The 3-D simulation tool is then evaluated using field measurements of both plant structure and spectra collected during the NASA Earth Observing Satellite Prototype Validation Exercise Jornada field campaign near Las Cruces, NM. The modeled scene reflectance is compared with measurements from three platforms (ground, tower, and satellite) at various scales (from the size of individual shrub component to satellite pixels of kilometers). The agreement with measured reflectances is excellent at all sampling scales tested. As an example of the model's application, we use the model output to examine the validity of a linear mixture scheme over the Jornada semidesert scene. The result shows that the larger the sampling size (at least larger than the size of the shrub component), the better the hypothesis is satisfied because of the unique structure of the Jornada scene: dense plant clumps (shrub component) sparsely scattered on a predominantly bare soil background. A range of possible applications of this 3-D scene model is highlighted, and further work needed for 3-D modeling is also discussed. |
模型公式