基于PROSPECT＋SAIL模型的遥感叶面积指数反演   总被引：4，自引：1，他引：4  

蔡博峰  绍霞 《国土资源遥感》2007,18(2):39-43

以PROSPECT+SAIL模型为基础，从物理机理角度反演植被叶面积指数(LAI)。首先，通过FLAASH模型进行大气校正，使得图像像元值表达植被冠层反射率； 然后，根据LOPEX 93数据库和JHU光谱数据库选择植物生化参数和光谱数据，以PROSPECT模型模拟出的植物叶片反射率和透射率作为SAIL模型的输入参数，得到植被冠层反射率，将结果与遥感影像的植被冠层反射率对应，回归出植被LAI； 最后，以地面实测数据对遥感反演数据进行验证，并分析了误差的可能来源。  相似文献   

栎树氮碳含量反演叶片与冠层尺度差异分析     

《地理空间信息》2017,(1)

在叶片和冠层两个尺度上,分析了栎树叶片氮碳两种生化组分含量与其反射率特性的统计关系;采用逐步回归法,分别利用地面光谱和航空高光谱曲线对叶片和冠层尺度进行了反演,选择进入回归方程的波段分别为719 nm、1 854 nm/1 861 nm、359 nm和767.9 nm/1 319.0 nm。研究表明,叶片尺度由于受到干扰较小,反演结果明显优于冠层尺度;冠层尺度的反演受大气水汽、冠层结构、植被下垫面等诸多因素影响较大,因此在进行冠层尺度生化组分反演时,必须充分考虑上述因素的影响。  相似文献   

基于Hyperion影像的水稻冠层生化参量反演   总被引：5，自引：0，他引：5       下载免费PDF全文

陈君颖  田庆久  亓雪勇  刘晓臣  管仲 《遥感学报》2009,13(6):1114-1129

采用小区实验与大田应用相结合的方法, 依据扬州实验小区地面实测拔节期、抽穗期及灌浆期的水稻叶片、冠层光谱及氮和叶绿素含量, 采用光谱吸收特征和植被指数分析方法, 得到估算水稻氮和叶绿素含量的最佳光谱特征参数; 结合覆盖江苏姜堰地区大田的Hyperion高光谱遥感影像, 建立反演水稻冠层氮和叶绿素含量的模型, 对研究区大田水稻冠层氮和叶绿素含量进行了反演及制图。结果表明: 经波深中心归一化方法分析, 发现以670nm为中心的光谱吸收特征面积与水稻氮含量呈显著相关性; 基于反转归一化光谱, 结合560nm和670nm两个波段, 建立的植被指数NDVI560_670能很好地反演水稻叶绿素含量。  相似文献   

一种三江平原湿地的植被冠层叶绿素反演     

张冬冬  孙永华  田杰  黄锦  李明超 《测绘科学》2018,(5):50-54,73

针对三江平原洪河湿地保护区内主要特征植被冠层的叶绿素含量,采用PROSAIL模型从物理角度进行反演。首先将叶面积指数、叶片结构参数、等价水厚度、叶绿素实测含量等一些植被理化参数的实测值输入模型得到模拟光谱数据,然后与实测光谱数据对比验证其准确性。在模型中,通过固定其他参量不变,取叶绿素含量为唯一值时,考察在不同叶面积指数下叶绿素含量对冠层反射率的影响。结果显示,植被冠层叶绿素含量的敏感波段为555nm和720nm。基于PROSAIL模型的叶绿素反演方法较传统的统计模型相比是较好且稳健的方法。  相似文献   

植被冠层光谱和叶片光谱的尺度转换          下载免费PDF全文

于颖  宋张亮  范文义  杨曦光 《武汉大学学报(信息科学版)》2018,43(10):1560

叶片光谱是估算植被生化参数的重要依据。然而,遥感影像获取的光谱为像元及冠层光谱,因此,在进行植被生化参数的遥感定量估算时,需将冠层光谱转化到叶片尺度。根据几何光学模型原理,推导出植被冠层光谱和叶片光谱的尺度转换函数,将冠层光谱转换到叶片尺度。首先,采用叶片光谱模拟模型PROSPECT模拟出叶片水平的光谱;其次,在几何光学模型4-scale模型中,通过改变叶片光谱和叶面积指数（leaf area index,LAI）,模拟出不同叶片特征下的冠层光谱。最后,通过LAI建立两个查找表,一个是传感器观测到树冠光照面和背景光照面概率的查找表,另一个是多次散射因子M的查找表,从而实现冠层光谱和叶片光谱的转化。结果表明,利用4-scale模型能实现冠层光谱与叶片光谱的尺度转换,此方法有很好的适用性。  相似文献   

冠层反射光谱对植被理化参数的全局敏感性分析   总被引：1，自引：0，他引：1  

肖艳芳  周德民  宫辉力  赵文吉 《遥感学报》2015,19(3):368-374

植被理化参数与许多有关植物物质能量交换的生态过程密切相关,定量分析植被反射光谱对理化参数的敏感性是遥感反演理化参数含量的前提。本文采用EFAST(Extended Fourier Amplitude Sensitivity Test)全局敏感性分析方法,利用PROSAIL辐射传输模型分析了冠层疏密程度对叶片生化组分含量、冠层结构以及土壤背景等多种参数敏感性的影响,并对植被理化参数反演所需先验知识的精度问题进行了初步探讨。研究表明:(1)对于较为稠密的冠层,可见光波段的冠层反射率主要受叶绿素含量的影响,近红外和中红外波段的冠层反射率主要受干物质量和含水量的影响;(2)对于稀疏的冠层,LAI是影响400—2500 nm波段范围内冠层反射率的最重要参数,土壤湿度次之,叶片生化参数对冠层反射率的敏感性较低;(3)在已知稀疏冠层LAI的情况下进一步确定土壤的干湿状态,可显著提高冠层反射率对叶绿素含量的敏感度,有助于稀疏冠层叶绿素含量的反演。  相似文献   

利用光谱反射率估算叶片生化组分和籽粒品质指标研究   总被引：2，自引：0，他引：2  

王纪华  黄文江  赵春江  杨敏华  王之杰 《遥感学报》2003,7(3):277-284

对可见光至短波红外波段(350—2500nm)冬小麦田间冠层光谱反射率与叶片含氮量间的关系进行了相关分析。结果表明，820—1100nm波段的光谱反射率与叶片含氮量极显著正相关；1150—1300hm波段的光谱反射率与叶片含氮量显著正相关，以上两波段为叶片全氮的敏感波段。对各生育时期叶片全氮与其他生化组分的关系进行了回归分析，并建立了相关的回归方程，显著性检验结果表明，方程具有较高的可靠性。小麦的叶片含氮量可以估算其它生化组分及干物质指标含量，开花期叶片含氮量可用来估测籽粒蛋白质和干面筋等品质指标含量。  相似文献   

利用光谱反射率估算叶片生化组分和籽粒品质指标研究   总被引：55，自引：2，他引：55  

王纪华  黄文江  赵春江  杨敏华  王之杰 《遥感学报》2003,7(4):277-284

对可见光至短波红外波段(350—2500nm)冬小麦田间冠层光谱反射率与叶片含氮量间的关系进行了相关分析。结果表明，820—1100nm波段的光谱反射率与叶片含氮量极显著正相关；1150—1300hm波段的光谱反射率与叶片含氮量显著正相关，以上两波段为叶片全氮的敏感波段。对各生育时期叶片全氮与其他生化组分的关系进行了回归分析，并建立了相关的回归方程，显著性检验结果表明，方程具有较高的可靠性。小麦的叶片含氮量可以估算其它生化组分及干物质指标含量，开花期叶片含氮量可用来估测籽粒蛋白质和干面筋等品质指标含量。  相似文献   

基于高光谱曲线峰度、偏度的植被叶绿素含量反演模型研究     

姚付启  张振华  杨润亚  冯雪  张燕  王海江 《测绘科学》2009,34(5)

本文分析了高光谱反射率及红边位置与叶片绿度的相关性,建立了基于敏感波段和红边位置的叶绿素估算模型。通过对不同叶绿素含量高光谱曲线特征的分析,提出了基于高光谱曲线峰度和偏度的叶绿素估算新思路,并分别建立基于原始光谱560-760nm波段和一阶导数光谱660-760nm波段对应峰度、偏度的叶绿素反演模型。结果表明,法国梧桐、无花果和白毛杨基于敏感波段的叶绿素含量反演模型的拟合度,与传统估算模型相比,本文提出的新估算模型可以明显提高高光谱反演叶绿素含量的能力。  相似文献   

植物叶片生化组分遥感反演的波段选择     

马维维  张连蓬  马向华  陈士城  郭洋洋 《测绘学院学报》2011,(3)

遥感模型PROSPECT可以反演植物叶片生化组分,不同的波段组合将会导致不同的反演结果。提出了一种带约束波段相关性最小原则的波段选择算法,并用模拟数据和实测数据对所选波段的效果进行了验证。结果表明:对于模拟数据,反演准确率超过99%;对于实测数据,叶绿素和水分的反演精度稍有提高,干物质的反演精度提高较明显。  相似文献   

植被生化组分的遥感反演方法研究   总被引：10，自引：2，他引：10  

颜春燕  刘强  牛铮  王长耀 《遥感学报》2004,8(4):300-308

从反演物理模型提取植被生化组分含量的角度 ,分别在叶片和冠层水平探讨了反演生化参量的方法。在叶片水平 ,利用实验室测量光谱数据 ,较为准确地提取了水分和叶绿素含量 ,通过比较真实光谱数据与利用模型和真实参数模拟的光谱数据 ,得出如下结论 :模型能否准确描述某个参数的作用是能否真正准确反演该参数的关键。在模拟的冠层水平 ,基于多阶段反演思想 ,采用了分步反演策略 ,最终较为准确地反演了生化参数。  相似文献   

Inversion of PROSAIL Model for Retrieval of Plant Biophysical Parameters     

Rahul Tripathi  Rabi N. Sahoo  Vinay K. Sehgal  R. K. Tomar  Debashish Chakraborty  S. Nagarajan 《Journal of the Indian Society of Remote Sensing》2012,40(1):19-28

The current development of satellite technology particularly in the sensors like POLDER and MISR, has emphasized more on directional reflectance measurements (i.e. spectral reflectance of the target measured from different view zenith and azimuth angles) of the earth surface features mainly the vegetation for retrieval of biophysical parameters at regional scale using radiative transfer models. This approach being physical process based and uses directional reflectance measurement has been found to better and more reliable compared to the conventional statistical approach used till date and takes care of anisotropic nature (i.e. reflectance from the target is different if measured from different view angles) of the target. Keeping this in view a field experiment was conducted in mustard crop to evaluate the radiative transfer model for biophysical parameter retrieval through its inversion with the objectives set as (i) to relate canopy biophysical parameters and geometry to its bidirectional reflectance, (ii) to evaluate a canopy reflectance model to best represent the radiative transfer within the canopy for its inversion and (iii) to retrieve crop biophysical parameters through inversion of the model. Two varieties of the mustard crop (Brassica juncea L) were grown with two nitrogen treatments. The bidirectional reflectance data obtained at 5 nm interval for a range of 400–1100 nm were integrated to IRS LISS–II sensor’s four band values using Newton Cotes Integration technique. Biophysical parameters like leaf area index, leaf chlorophyll content, leaf length, plant height and average leaf inclination angle, biomass etc were estimated synchronizing with the bi-directional reflectance measurements. Radiative transfer model PROSAIL model was validated and its inversion was done to retrieve LAI and ALA. Look Up Table (LUT) of Bidirectional reflectance distribution function (BRDF) was prepared simulating through PROSAIL model varying only LAI (0.2 interval from 1.2 to 5.4 ) and ALA (5° interval from 40° to 55°) parameters and inversion was done using a merit function and numerical optimization technique given by Press et al. (1986). The derived LAI and ALA values from inversion were well matched with observed one with RMSE 0.521 and 5.57, respectively.  相似文献   

Relationship of bidirectional reflectance of wheat with biophysical parameters and its radiative transfer modeling using PROSAIL     

D. Barman  V. K. Sehgal  R. N. Sahoo  S. Nagarajan 《Journal of the Indian Society of Remote Sensing》2010,38(1):35-44

The algorithms for deriving vegetation biophysical parameters rely on the understanding of bi-directional interaction of radiation and its subsequent linkages with canopy radiative transfer models and their inversion. In this study, an attempt has been made to define the geometry of sensor and source position to best relate plant biophysical parameters with bidirectional reflectance of wheat varieties varying in canopy architecture and to validate the performance of PROSAIL (PROSPECT+SAIL) canopy radiative transfer model. A field experiment was conducted with two wheat cultivars varying in canopy geometry and phenology. The bidirectional measurements between 400nm–1100nm at 5nm interval were recorded every week at six view azimuth and four view zenith positions using spectro-radiometer. Canopy biophysical parameters were recorded synchronous to bi-directional reflectance measurements. The broadband reflectances were used to compute the NDVIs which were subsequently related to leaf area index and biomass. Results showed that the bidirectional reflectance increased with increase in view zenith from 20⁰ to 60⁰ irrespective of the sensor azimuth. For a given view zenith, the reflectance was observed to be maximum at 150⁰ azimuth where the difference between the sun and sensor azimuth was least. For sun azimuth of 160⁰ and zenith of 52⁰, the view geometry defined by 150⁰ azimuth and 50⁰ zenith corresponded to hotspot position. The measured bidirectional NDVI had significant logarithmic relationship with LAI and linear relationship with biomass for both the varieties of wheat and maximum correlation of NDVI with LAI and with biomass was obtained at the hotspot position. The PROSAIL validation results showed that the model simulated well the overall shape of spectra for all combination of view zenith and azimuth position for both wheat varieties with overall RMSE less than 5 per cent. The hotspot and dark spot positions were also well simulated and hence model performance may be suitable for deriving wheat biophysical parameters using satellite derived reflectances.  相似文献   

Estimation of forest LAI by inverting canopy reflectance models and multi-angle imagery     

X. Y. Wang  W. H. Qin  G.Q. Sun  J. Zhu 《国际地球制图》2019,34(9):959-976

Computer simulation models have seldom been applied for estimating the structural and biophysical variables of forest canopy. In this study, an approach for the estimation of leaf area index (LAI) using the information contained in hyperspectral, multi-angle images and the inversion of a computer simulation model are explored. For this purpose, L-systems combined with forest growth model ZELIG were applied to render 3-D forest architectural scenarios. The Radiosity-graphics combined model (RGM) was used to estimate forest LAI from the Compact High-Resolution Imaging Spectrometer/Project for On-Board Autonomy (CHRIS/PROBA) data. LAI inversion was performed using the look-up table (LUT) method. The estimated LAI was evaluated against in situ LAI measurement and compared against the LAI predictions from CHRIS data obtained using the Li-Strahler geometric-optical canopy reflectance model (GOMS). The results indicated that the method used in this study can be efficient strategy to estimate LAI by RGM model inversion.  相似文献   

Visualizing the ill-posedness of the inversion of a canopy radiative transfer model: A case study for Sentinel-2     

《International Journal of Applied Earth Observation and Geoinformation》2015

Monitoring biophysical and biochemical vegetation variables in space and time is key to understand the earth system. Operational approaches using remote sensing imagery rely on the inversion of radiative transfer models, which describe the interactions between light and vegetation canopies. The inversion required to estimate vegetation variables is, however, an ill-posed problem because of variable compensation effects that can cause different combinations of soil and canopy variables to yield extremely similar spectral responses. In this contribution, we present a novel approach to visualise the ill-posed problem using self-organizing maps (SOM), which are a type of unsupervised neural network. The approach is demonstrated with simulations for Sentinel-2 data (13 bands) made with the Soil-Leaf-Canopy (SLC) radiative transfer model. A look-up table of 100,000 entries was built by randomly sampling 14 SLC model input variables between their minimum and maximum allowed values while using both a dark and a bright soil. The Sentinel-2 spectral simulations were used to train a SOM of 200 × 125 neurons. The training projected similar spectral signatures onto either the same, or contiguous, neuron(s). Tracing back the inputs that generated each spectral signature, we created a 200 × 125 map for each of the SLC variables. The lack of spatial patterns and the variability in these maps indicate ill-posed situations, where similar spectral signatures correspond to different canopy variables. For Sentinel-2, our results showed that leaf area index, crown cover and leaf chlorophyll, water and brown pigment content are less confused in the inversion than variables with noisier maps like fraction of brown canopy area, leaf dry matter content and the PROSPECT mesophyll parameter. This study supports both educational and on-going research activities on inversion algorithms and might be useful to evaluate the uncertainties of retrieved canopy biophysical and biochemical state variables.  相似文献   

Retrieval of boreal forest LAI using a forest reflectance model and empirical regressions     

Janne Heiskanen  Miina Rautiainen  Lauri Korhonen  Matti Mõttus  Pauline Stenberg 《International Journal of Applied Earth Observation and Geoinformation》2011

Spectral invariants provide a novel approach for characterizing canopy structure in forest reflectance models and for mapping biophysical variables using satellite images. We applied a photon recollision probability (p) based forest reflectance model (PARAS) to retrieve leaf area index (LAI) from fine resolution SPOT HRVIR and Landsat ETM+ satellite data. First, PARAS was parameterized using an extensive database of LAI-2000 measurements from five conifer-dominated boreal forest sites in Finland, and mixtures of field-measured forest understory spectra. The selected vegetation indices (e.g. reduced simple ratio, RSR), neural networks and kNN method were used to retrieve effective LAI (L_e) based on reflectance model simulations. For comparison, we established empirical vegetation index-LAI regression models for our study sites. The empirical RSR–L_e regression performed best when applied to an independent test site in southern Finland [RMSE 0.57 (24.2%)]. However, the difference to the best reflectance model based retrievals produced by neural networks was only marginal [RMSE 0.59 (25.1%)]. According to this study, the PARAS model provides a simple and flexible modelling tool for calibrating algorithms for LAI retrieval in conifer-dominated boreal forests. The advantage of PARAS is that it directly uses field measurements to parameterize canopy structure (LAI-2000, hemispherical photographs) and optical properties of foliage and understory.  相似文献   

Leaf to canopy upscaling approach affects the estimation of canopy traits   总被引：1，自引：0，他引：1  

Tawanda W. Gara  Andrew K. Skidmore  Roshanak Darvishzadeh  Tiejun Wang 《地理信息系统科学与遥感》2019,56(4):554-575

In remote sensing applications, leaf traits are often upscaled to canopy level using sunlit leaf samples collected from the upper canopy. The implicit assumption is that the top of canopy foliage material dominates canopy reflectance and the variability in leaf traits across the canopy is very small. However, the effect of different approaches of upscaling leaf traits to canopy level on model performance and estimation accuracy remains poorly understood. This is especially important in short or sparse canopies where foliage material from the lower canopy potentially contributes to the canopy reflectance. The principal aim of this study is to examine the effect of different approaches when upscaling leaf traits to canopy level on model performance and estimation accuracy using spectral measurements (in-situ canopy hyperspectral and simulated Sentinel-2 data) in short woody vegetation. To achieve this, we measured foliar nitrogen (N), leaf mass per area (LMA), foliar chlorophyll and carbon together with leaf area index (LAI) at three vertical canopy layers (lower, middle and upper) along the plant stem in a controlled laboratory environment. We then upscaled the leaf traits to canopy level by multiplying leaf traits by LAI based on different combinations of the three canopy layers. Concurrently, in-situ canopy reflectance was measured using an ASD FieldSpec-3 Pro FR spectrometer, and the canopy traits were related to in-situ spectral measurements using partial least square regression (PLSR). The PLSR models were cross-validated based on repeated k-fold, and the normalized root mean square errors (nRMSE_cv) obtained from each upscaling approach were compared using one-way analysis of variance (ANOVA) followed by Tukey’s post hoc test. Results of the study showed that leaf-to-canopy upscaling approaches that consider the contribution of leaf traits from the exposed upper canopy layer together with the shaded middle canopy layer yield significantly (p < 0.05) lower error (nRMSE_cv < 0.2 for canopy N, LMA and carbon) as well as high explained variance (R² > 0.71) for both in-situ hyperspectral and simulated Sentinel-2 data. The widely-used upscaling approach that considers only leaf traits from the upper illuminated canopy layer yielded a relatively high error (nRMSE_cv>0.2) and lower explained variance (R² < 0.71) for canopy N, LMA and carbon. In contrast, canopy chlorophyll upscaled based on leaf samples collected from the upper canopy and total canopy LAI exhibited a more accurate relationship with spectral measurements compared with other upscaling approaches. Results of this study demonstrate that leaf to canopy upscaling approaches have a profound effect on canopy traits estimation for both in-situ hyperspectral measurements and simulated Sentinel-2 data in short woody vegetation. These findings have implications for field sampling protocols of leaf traits measurement as well as upscaling leaf traits to canopy level especially in short and less foliated vegetation where leaves from the lower canopy contribute to the canopy reflectance.  相似文献   

基于稳健估计的白桦叶片铜元素含量反演          下载免费PDF全文

王明常  应申  任福  陈圣波  张旭晴  王凤艳  牛雪峰 《武汉大学学报(信息科学版)》2017,42(5):637-642

根据阔叶叶片模型（a model of leaf optical properties spectra,PROSPECT）叶片辐射传输模型机理,利用一次范数稳健估计估算叶片结构参数N和铜元素的吸收系数k_Cu。选取黑龙江呼玛地区作为研究区,利用美国ASD公司的FieldSpec 3 Hi-Res光谱仪野外测定白桦叶片的反射光谱,实验室测定相应叶片的铜含量,利用改进的PROSPECT-Cu模型进行白桦叶片铜元素含量反演。通过与野外样品测定值和反演值进行比较分析,决定系数为0.963。研究结果表明,反演结果得到的叶片Cu含量是准确的,反演方法是可行的。  相似文献