Retrieval of Leaf Area Index (LAI) and Soil Water Content (WC) Using Hyperspectral Remote Sensing under Controlled Glass House Conditions for Spring Barley and Sugar Beet

Leaf area index (LAI) and water content (WC) in the root zone are two major hydro-meteorological parameters that exhibit a dominant control on water, energy and carbon fluxes, and are therefore important for any regional eco-hydrological or climatological study. To investigate the potential for retrieving these parameter from hyperspectral remote sensing, we have investigated plant spectral reflectance (400-2,500 nm, ASD FieldSpec3) for two major agricultural crops (sugar beet and spring barley) in the mid-latitudes, treated under different water and nitrogen (N) conditions in a greenhouse experiment over the growing period of 2008. Along with the spectral response, we have measured soil water content and LAI for 15 intensive measurement campaigns spread over the growing season and could demonstrate a significant response of plant reflectance characteristics to variations in water content and nutrient conditions. Linear and non-linear dimensionality analysis suggests that the full band reflectance information is well represented by the set of 28 vegetation spectral indices (SI) and most of the variance is explained by three to a maximum of eight variables. Investigation of linear dependencies between LAI and soil WC and pre-selected SI's indicate that: (1) linear regression using single SI is not sufficient to describe plant/soil variables over the range of experimental conditions, however, some improvement can be seen knowing crop species beforehand; (2) the improvement is superior when applying multiple linear regression using three explanatory SI's approach. In addition to linear investigations, we applied the non-linear CART (Classification and Regression Trees) technique, which finally did not show the potential for any improvement in the retrieval process

Automatic retrieval of crop characteristics: an example for hyperspectral AHS data from the AgriSAR campaign.

This paper presents the results of automated extraction of crop characteristics from hyperspectral earth observation data. The data was acquired with an airborne AHS imaging spectrometer in the framework of the joint European AgriSAR 2006 campaign. The AgriSAR campaign was directed by the ESA and took place at the DEMMIN test site in northeast Germany, an agricultural area dominated by large monocultures. An important objective of this campaign was to establish to what degree novel radar and optical technologies are able to provide accurate agro-meteorological parameters for precision farming purposes. Parameter retrieval in this study was performed with the CRASh approach, a software module based on the inversion of radiative transfer models. CRASh was developed at DLR as part of an automated operative processing chain for future hyperspectral missions. Validation of the model inversion results was performed with field measurements of leaf area index and leaf chlorophyll content which were carried out for winter wheat, winter barley, winter rape, maize, and sugar beet at two time steps during the 2006 growing season. Although spatial patterns of the model results generally coincide with the trends observed in the field, absolute accuracy of the fully automatically extracted variables appeared insufficient for precision agriculture purposes. The unsatisfying results are ascribed to a combination of causes, including angular anisotropy across the swath-width of the flight lines, the configuration of the applied bands, and the large number of model inversion solutions inherent to an automated environment in which little additional information on the observed canopy is present. Employing the airborne version of CRASh and incorporating a priori information on land cover and variable distributions is expected to drastically increase the retrieval performance

Calibration of the AquaCrop model for winter wheat using MODIS LAI images

In semi-arid environments vegetation density and distribution is of considerable importance for the hydrological water balance. A number of hydrological models exploit Leaf Area Index (LAI) maps retrievedby remote sensing as a measure of the vegetation cover, in order to enhance the evaluation of evapotran-spiration and interception losses. On the other hand, actual evapotranspiration and vegetation development can be derived through crop growth models, such as AquaCrop, developed by FAO (Food and Agricultural Organization), which allows the simulation of the canopy development of the main field crops. We used MODIS LAI images to calibrate AquaCrop according to the canopy cover development of winter wheat. With this aim we exploited an empirical relationship between LAI and canopy cover. In detail Aquacrop was calibrated with MODIS LAI maps collected between 2008 and 2011, and validated with reference to MODIS LAI maps of 2013-2014 in Rocchetta Sant'Antonio and Sant'Agata, two test sites in the Carapelle watershed, Southern Italy. Results, in terms of evaluation of canopy cover, provided improvements. For example, for Rocchetta Sant'Antonio, the statistical indexes vary from r = 0.40, ER = 0.22, RMSE = 17.28 and KGE = 0.31 (using the model without calibration), to r = 0.86, ER = 0.08, RMSE = 6.01 and KGE 0.85 (after calibration). © 2015 Elsevier B.V

Estimating the crop leaf area index using hyperspectral remote sensing

AbstractThe leaf area index (LAI) is an important vegetation parameter, which is used widely in many applications. Remote sensing techniques are known to be effective but inexpensive methods for estimating the LAI of crop canopies. During the last two decades, hyperspectral remote sensing has been employed increasingly for crop LAI estimation, which requires unique technical procedures compared with conventional multispectral data, such as denoising and dimension reduction. Thus, we provide a comprehensive and intensive overview of crop LAI estimation based on hyperspectral remote sensing techniques. First, we compare hyperspectral data and multispectral data by highlighting their potential and limitations in LAI estimation. Second, we categorize the approaches used for crop LAI estimation based on hyperspectral data into three types: approaches based on statistical models, physical models (i.e., canopy reflectance models), and hybrid inversions. We summarize and evaluate the theoretical basis and different methods employed by these approaches (e.g., the characteristic parameters of LAI, regression methods for constructing statistical predictive models, commonly applied physical models, and inversion strategies for physical models). Thus, numerous models and inversion strategies are organized in a clear conceptual framework. Moreover, we highlight the technical difficulties that may hinder crop LAI estimation, such as the “curse of dimensionality” and the ill-posed problem. Finally, we discuss the prospects for future research based on the previous studies described in this review

A Mixed Data-Based Deep Neural Network to Estimate Leaf Area Index in Wheat Breeding Trials

Remote and non-destructive estimation of leaf area index (LAI) has been a challenge in the last few decades as the direct and indirect methods available are laborious and time-consuming. The recent emergence of high-throughput plant phenotyping platforms has increased the need to develop new phenotyping tools for better decision-making by breeders. In this paper, a novel model based on artificial intelligence algorithms and nadir-view red green blue (RGB) images taken from a terrestrial high throughput phenotyping platform is presented. The model mixes numerical data collected in a wheat breeding field and visual features extracted from the images to make rapid and accurate LAI estimations. Model-based LAI estimations were validated against LAI measurements determined non-destructively using an allometric relationship obtained in this study. The model performance was also compared with LAI estimates obtained by other classical indirect methods based on bottom-up hemispherical images and gaps fraction theory. Model-based LAI estimations were highly correlated with ground-truth LAI. The model performance was slightly better than that of the hemispherical image-based method, which tended to underestimate LAI. These results show the great potential of the developed model for near real-time LAI estimation, which can be further improved in the future by increasing the dataset used to train the model

Mapping within-field leaf chlorophyll content in agricultural crops for nitrogen management using Landsat-8 imagery

Spatial information on crop nutrient status is central for monitoring vegetation health, plant productivity and managing nutrient optimization programs in agricultural systems. This study maps the spatial variability of leaf chlorophyll content within felds with differing quantities of nitrogen fertilizer application, using multispectral Landsat-8 OLI data (30 m). Leaf chlorophyll content and leaf area index measurements were collected at 15 wheat (Triticum aestivum) sites and 13 corn (Zea mays) sites approximately every 10 days during the growing season between May and September 2013 near Stratford, Ontario. Of the 28 sites, 9 sites were within controlled areas of zero nitrogen fertilizer application. Hyperspectral leaf refectance measurements were also sampled using an Analytical Spectral Devices FieldSpecPro spectroradiometer (400–2500 nm). A two-step inversion process was developed to estimate leaf chlorophyll content from Landsat-8 satellite data at the subfeld scale, using linked canopy and leaf radiative transfer models. Firstly, at the leaf-level, leaf chlorophyll content was modelled using the PROSPECT model, using both hyperspectral and simulated mulitspectral Landsat-8 bands from the same leaf sample. Hyperspectral and multispectral validation results were both strong (R2=0.79, RMSE=13.62 μg/cm2 and R2=0.81, RMSE=9.45 μg/cm2, respectively). Secondly, leaf chlorophyll content was estimated from Landsat-8 satellite imagery for 7 dates within the growing season, using PROSPECT linked to the 4-Scale canopy model. The Landsat-8 derived estimates of leaf chlorophyll content demonstrated a strong relationship with measured leaf chlorophyll values (R2=0.64, RMSE=16.18 μg/cm2), and compared favourably to correlations between leaf chlorophyll and the best performing tested spectral vegetation index (Green Normalised Diference Vegetation Index, GNDVI; R2=0.59). This research provides an operational basis for modelling within-feld variations in leaf chlorophyll content as an indicator of plant nitrogen stress, using a physically-based modelling approach, and opens up the possibility of exploiting a wealth of multispectral satellite data and UAV-mounted multispectral imaging systems

Seasonal mapping of irrigated winter wheat traits in Argentina with a hybrid retrieval workflow using sentinel-2 imagery

Earth observation offers an unprecedented opportunity to monitor intensively cultivated areas providing key support to assess fertilizer needs and crop water uptake. Routinely, vegetation traits mapping can help farmers to monitor plant development along the crop’s phenological cycle, which is particularly relevant for irrigated agricultural areas. The high spatial and temporal resolution of the Sentinel-2 (S2) multispectral instrument leverages the possibility to estimate leaf area index (LAI), canopy chlorophyll content (CCC), and vegetation water content (VWC) from space. Therefore, our study presents a hybrid retrieval workflow combining a physically-based strategy with a machine learning regression algorithm, i.e., Gaussian processes regression, and an active learning technique to estimate LAI, CCC and VWC of irrigated winter wheat. The established hybrid models of the three traits were validated against in-situ data of a wheat campaign in the Bonaerense valley, South of the Buenos Aires Province, Argentina, in the year 2020. We obtained good to highly accurate validation results with LAI: R2 = 0.92, RMSE = 0.43 m2 m−2, CCC: R2 = 0.80, RMSE = 0.27 g m−2 and VWC: R2 = 0.75, RMSE = 416 g m−2. The retrieval models were also applied to a series of S2 images, producing time series along the seasonal cycle, which reflected the effects of fertilizer and irrigation on crop growth. The associated uncertainties along with the obtained maps underlined the robustness of the hybrid retrieval workflow. We conclude that processing S2 imagery with optimised hybrid models allows accurate space-based crop traits mapping over large irrigated areas and thus can support agricultural management decisions.Fil: Caballero, Gabriel. Technological University of Uruguay (UTEC). Agri-Environmental Engineering; Uruguay. University of Valencia. Image Processing Laboratory (IPL); EspañaFil: Pezzola, Alejandro. Instituto Nacional de Tecnología Agropecuaria (INTA). Estación Experimental Agropecuaria Hilario Ascasubi; ArgentinaFil: Winschel, Cristina Ines. Instituto Nacional de Tecnología Agropecuaria (INTA). Estación Experimental Agropecuaria Hilario Ascasubi; ArgentinaFil: Casella, Alejandra. Instituto Nacional de Tecnología Agropecuaria (INTA). Instituto de Clima y Agua; ArgentinaFil: Sanchez Angonova, Paolo Andres. Instituto Nacional de Tecnología Agropecuaria (INTA). Estación Experimental Agropecuaria Hilario Ascasubi; ArgentinaFil: Rivera Caicedo, Juan Pablo. CONACYT-UAN. Secretary of Research and Graduate Studies; MéxicoFil: Berger, Katja. University of Valencia. Image Processing Laboratory (IPL); España. Mantle Labs GmbH; AustriaFil: Verrelst, Jochem. University of Valencia. Image Processing Laboratory (IPL); EspañaFil: Delegido, Jesús. Universidad de Valencia. Image Processing Laboratory (IPL); Españ

Noise-Resistant Spectral Features for Retrieving Foliar Chemical Parameters

Foliar chemical constituents are important indicators for understanding vegetation growing status and ecosystem functionality. Provided the noncontact and nondestructive traits, the hyperspectral analysis is a superior and efficient method for deriving these parameters. In practice, thespectral noise issue significantly impacts the performance of the hyperspectral retrieving system. To systematically investigate this issue, by introducing varying levels of noise to spectral signals, an assessment on noiseresistant capability of spectral features and models for retrieving concentrations of chlorophyll, carotenoids, and leaf water content was conducted. Given the continuous waveletanalysis (CWA) showed superior performance in extracting critical information associating plants biophysical and biochemical status in recent years, both wavelet features (WFs) and some conventional features (CFs) were chosen for the test. Two datasets including a leaf optical properties experiment dataset (n = 330), and a corn leaf spectral experiment dataset (n = 213) were used for analysis and modeling. The results suggested that the WFs had stronger correlations with all leaf chemical parameters than the CFs. According to an evaluation by decay rate of retrieving error that indicates noise-resistant capability, both WFs and CFs exhibited strong resistance to spectral noise. Particularly for WFs, the noise-resistant capability is relevant to the scale of the features. Based on the identified spectral features, both univariate and multivariate retrieving models were established and achieved satisfactory accuracies. Synthesizing the retrieving accuracy, noise resistivity, and model’s complexity, the optimal univariate WF-models were recommended in practice for retrieving leaf chemical parameters

The EnMAP Managed Vegetation Scientific Processor

Nach jahrelanger wissenschaftlicher und technischer Vorbereitungszeit wird voraussichtlich Ende des Jahres 2020 der Start der orbitalen Phase einer unbemannten deutschen Weltraum-Mission initiiert. Das Environmental Mapping and Analysis Program (EnMAP) wird an Bord des gleichnamigen Satelliten einen hyperspektralen Sensor zur Erfassung terrestrischer Oberflächen tragen. In den Umweltdisziplinen zur Erforschung von Ökosystemen, landwirtschaftlicher, forstwirtschaftlicher und urbaner Flächen, im Bereich der Küsten- und Inlandsgewässer sowie der Geologie und Bodenkunde bereitete man sich im Vorfeld des Starts auf die kommenden Daten vor. Zwar existiert bereits eine Vielzahl an Algorithmen zur wissenschaftlichen Analyse von spektralen Daten, allerdings ergeben sich auch neue Herausforderungen, da die EnMAP-Mission bislang im weltweiten Kontext der Fernerkundung einzigartig ist. Die Abdeckung des vollen optischen Spektrums (420 nm – 2450 nm) in Verbindung mit einer moderaten räumlichen Auflösung von 30 m und einem hohen Signal-Rausch-Verhältnis von mindestens 180 im kurzwelligen Infrarot und über 400 im sichtbaren Spektrum, ermöglichen eine Aufnahmequalität, die bislang nur von flugzeuggestützten Systemen erreicht werden konnte. Die Bemühungen in dieser Dissertation umfassen Aktivitäten in der wissenschaftlichen Vorbereitungsphase zu agrargeographischen Fragestellungen. Algorithmen und Tools zur Analyse der hyperspektralen Daten werden kostenlos im QGIS-Plugin EnMAP-Box 3 zur Verfügung gestellt. Die drängenden Fragen im Agrarsektor drehen sich hierbei um die Ableitung biochemischer und biophysikalischer Parameter aus Fernerkundungsdaten, weshalb die übergeordnete Problemstellung des Promotionsvorhabens die Entwicklung eines wissenschaftsbasierten EnMAP-Tools für bewirtschaftete Vegetationsflächen (EnMAP Managed Vegetation Scientific Processor) darstellt. Zu Beginn wurde eine umfassende Feldkampagne geplant, welche ab April 2014 umgesetzt wurde. Neben der spektralen Erfassung von Blatt-, Bestands- und Bodensignaturen in einem Winterweizen- und einem Maisfeld erfolgte auch die Messung wesentlicher Pflanzenparameter an den exakt gleichen Positionen. Hierzu zählt die non-destruktive Ableitung des Blattflächenindex (LAI), des Blattchlorophyllgehalts (Ccab), des Blattwassergehalts (EWT oder Cw), des relativen Blatttrockengewichts (LMA oder Cm), des mittleren Blattneigungswinkels im Bestand (ALIA) sowie weiterer sekundärer Parameter wie Wuchshöhe, das phänologisches Stadium und der Sonnenvektor. Um die Fähigkeit des späteren EnMAP-Satelliten sich um bis zu 30° orthogonal zur Flugrichtung zu kippen nachzustellen, wurden die spektralen Aufnahmen aus verschiedenen Betrachtungswinkeln erstellt, die dieser Aufnahme-Geometrien nachempfunden sind. Ein gängiges Verfahren zur Ableitung der relevanten Pflanzenparameter ist die Verwendung des Strahlungstransfermodells PROSAIL, welches das spektrale Signal einer Vegetationsfläche auf Basis der zugrundeliegenden biophysikalischen und biochemischen Parameter simuliert. Bei der Umkehr dieses Prozesses können ebendiese Variablen von gemessenen spektralen Daten abgeleitet werden. Hierzu wurde eine Datenbank (Look-Up-Table, LUT) aus PROSAIL-Modellläufen aufgebaut und die in den Feldkampagnen gemessenen Spektren mit dieser abgeglichen. Mit dieser Methode der LUT-Invertierung aus unterschiedlichen Aufnahmewinkeln konnten Genauigkeiten bei der LAI-Schätzung von 18 % und bei Blattchlorophyll von 20 % erzielt werden. Eine starke Anisotropie, also eine Reflexionsabhängigkeit von der Beleuchtungs- und Aufnahmerichtung, wurde bei Winterweizen vor allem für frühe Entwicklungsstadien festgestellt. Bei einer anschließenden Studie zur Unsicherheitsanalyse des Spektralmodells wurden PROSAIL-Ergebnisse, bei denen real gemessene Pflanzenparameter als Input dienten, den zugehörigen Reflektanzspektren gegenübergestellt. Es zeigten sich hierbei mitunter starke Abweichungen zwischen gemessenen und modellierten Spektren, die im Falle des Winterweizens einen saisonalen Verlauf zeichneten. Vor allem während frühen Wachstumsstadien tendierte das Modell dazu die Reflektanz im nahen Infrarot zu überschätzen, während es gegen Ende der Wachstumsperiode eher eine Unterschätzung aufwies. Als Unsicherheitsfaktor wurde die Parametrisierung des Modells ausgemacht, wenn der ALIA-Parameter als echter physikalische Blattwinkel interpretiert wird. Es wurde geschlussfolgert, dass eine Separierung von LAI und ALIA bei der Invertierung von PROSAIL eine korrekte Abschätzung der weniger sensitiven Parameter behindert. Die Erstellung des Vegetations-Prozessors erforderte die Verwendung von Regressions-Algorithmen des maschinellen Lernens (MLRA), da eine Verteilung von großen LUTs an die User nicht praktikabel wäre. Die MLRAs wurden an synthetischen Datensätzen trainiert, wobei zunächst die Optimierung der Hyperparameter im Vordergrund stand, bevor die Anwendung an echten Spektraldaten unternommen wurde. Es konnten dabei erst aussagekräftige Ergebnisse produziert werden, als die Trainingsdaten mit einem künstlichen Rauschen belegt wurden, da die Algorithmen unter einer Überanpassung an die Modellumgebung litten. Mithilfe des Prozessors konnten schließlich LAI, ALIA, Ccab und Cw aus hyperspektralen Daten abgeleitet werden. Künstliche neuronale Netze dienen dabei als Blackbox-Modelle, die in kurzer Zeit große Datenmengen verarbeiten können und somit einen entscheidenden Beitrag zur modernen angewandten Fernerkundung für eine breite User-Community leisten.After years of scientific and technical preparation, the launch of an unmanned German space-mission is planned to be initiated in 2020. The Environmental Mapping and Analysis Program (EnMAP) is going to provide an equally named hyperspectral imager to map land surfaces. Scientists of environmental disciplines of monitoring of ecosystems, agricultural, forestry and urban areas as well as coastal and inland waters, geology and soils prepared themselves for the upcoming data prior to the actual launch. Although there already exists a variety of useful algorithms for a profound analysis of spectral data, new challenges will arise given the uniqueness of the EnMAP-mission in the global context of remote sensing; i.e. coverage of the full range of the optical spectrum (420 nm – 2450 nm) in combination with a moderate spatial resolution of 30 m and a high signal-to-noise ratio of at least 180 in the shortwave infrared and above 400 in the visible spectrum. This enables an imaging quality which to this date has only been reached by airborne systems. The efforts of this dissertation comprise activities in the scientific preparation phase for agro-geographical tasks. Algorithms and tools for an analysis of hyperspectral data are being provided for free in the QGIS-plugin EnMAP-Box 3. Urgent questions in the agricultural sector revolve around the derivation of biochemical and biophysical parameters from remote sensing data. For this reason, the overarching objective of this promotion is the development of a scientific EnMAP-tool for managed areas of vegetation (EnMAP Managed Vegetation Scientific Processor). At first, an extensive field campaign was planned and then started in April, 2014. Apart from spectral observations of leaves, canopies and soils in a winter wheat and a maize field, also relevant plant parameters were acquired at the exact same spots. Namely, they are the Leaf Area Index (LAI), leaf chlorophyll content (Ccab), leaf water content (EWT or Cw), relative dry leaf weight (LMA or Cm), Average Leaf Inclination Angle (ALIA) as well as other secondary parameters like canopy height, phenological stage and the solar vector. Spectral measurements were captured from different observation angles to match ground data with the sensing geometry of the future EnMAP-satellite, which can be tilted up to 30° orthogonal to its direction of flight. A common procedure to derive relevant crop parameters is to make use of the radiative transfer model PROSAIL, which simulates the spectral signal of a vegetated surface based on biophysical and biochemical input parameters. If this process is reverted, said parameters can be derived from measured spectral data. To do so, a Look-Up-Table (LUT) is built containing model runs of PROSAIL and then subsequently compared against spectra from the field campaigns. With this approach of LUT-inversions from different observation angles, an accuracy of 18 % could be achieved for LAI and 20 % for Ccab. Strong anisotropic effects, i.e. dependence on illumination geometry and sensor orientation, were identified for winter wheat mainly in the early stages of plant development. In a consecutive study about uncertainties of the spectral model, PROSAIL results fed with in situ measured crop parameters as input, were opposed to their associated reflectance signatures. A strong deviation between measured and modelled spectra was observed, which – in the case of winter wheat – showed a seasonal behavior. The model tended to overestimate reflectances in the near infrared for early phenological stages and to underestimate them at end of the growing period. The parametrization of the model was identified as an uncertainty factor if the ALIA parameter is interpreted as true physical leaf inclinations. It was concluded that a separation of LAI and ALIA at inversion of PROSAIL prevents an adequate estimation of the less sensitive parameters. The development of the vegetation processor required the use of Machine Learning Regression Algorithms (MLRA), since distribution of large LUTs to the user would be impracticable. The MLRAs were trained with synthetic datasets with primary importance to optimize their hyperparameters, before attempting to apply the algorithms to real spectral data. Significant results could not be obtained until training data were altered with artificial noise, because algorithms suffered from overfitting to the model environment. Executing the processor allowed to derive LAI, ALIA, Ccab and Cw from hyperspectral data. Artificial neural networks served as black box models, which digest great amount of data in a short period of time and thus make a decisive contribution to modern applied remote sensing with relevance for a broad user-community

The EnMAP Managed Vegetation Scientific Processor

Nach jahrelanger wissenschaftlicher und technischer Vorbereitungszeit wird voraussichtlich Ende des Jahres 2020 der Start der orbitalen Phase einer unbemannten deutschen Weltraum-Mission initiiert. Das Environmental Mapping and Analysis Program (EnMAP) wird an Bord des gleichnamigen Satelliten einen hyperspektralen Sensor zur Erfassung terrestrischer Oberflächen tragen. In den Umweltdisziplinen zur Erforschung von Ökosystemen, landwirtschaftlicher, forstwirtschaftlicher und urbaner Flächen, im Bereich der Küsten- und Inlandsgewässer sowie der Geologie und Bodenkunde bereitete man sich im Vorfeld des Starts auf die kommenden Daten vor. Zwar existiert bereits eine Vielzahl an Algorithmen zur wissenschaftlichen Analyse von spektralen Daten, allerdings ergeben sich auch neue Herausforderungen, da die EnMAP-Mission bislang im weltweiten Kontext der Fernerkundung einzigartig ist. Die Abdeckung des vollen optischen Spektrums (420 nm – 2450 nm) in Verbindung mit einer moderaten räumlichen Auflösung von 30 m und einem hohen Signal-Rausch-Verhältnis von mindestens 180 im kurzwelligen Infrarot und über 400 im sichtbaren Spektrum, ermöglichen eine Aufnahmequalität, die bislang nur von flugzeuggestützten Systemen erreicht werden konnte. Die Bemühungen in dieser Dissertation umfassen Aktivitäten in der wissenschaftlichen Vorbereitungsphase zu agrargeographischen Fragestellungen. Algorithmen und Tools zur Analyse der hyperspektralen Daten werden kostenlos im QGIS-Plugin EnMAP-Box 3 zur Verfügung gestellt. Die drängenden Fragen im Agrarsektor drehen sich hierbei um die Ableitung biochemischer und biophysikalischer Parameter aus Fernerkundungsdaten, weshalb die übergeordnete Problemstellung des Promotionsvorhabens die Entwicklung eines wissenschaftsbasierten EnMAP-Tools für bewirtschaftete Vegetationsflächen (EnMAP Managed Vegetation Scientific Processor) darstellt. Zu Beginn wurde eine umfassende Feldkampagne geplant, welche ab April 2014 umgesetzt wurde. Neben der spektralen Erfassung von Blatt-, Bestands- und Bodensignaturen in einem Winterweizen- und einem Maisfeld erfolgte auch die Messung wesentlicher Pflanzenparameter an den exakt gleichen Positionen. Hierzu zählt die non-destruktive Ableitung des Blattflächenindex (LAI), des Blattchlorophyllgehalts (Ccab), des Blattwassergehalts (EWT oder Cw), des relativen Blatttrockengewichts (LMA oder Cm), des mittleren Blattneigungswinkels im Bestand (ALIA) sowie weiterer sekundärer Parameter wie Wuchshöhe, das phänologisches Stadium und der Sonnenvektor. Um die Fähigkeit des späteren EnMAP-Satelliten sich um bis zu 30° orthogonal zur Flugrichtung zu kippen nachzustellen, wurden die spektralen Aufnahmen aus verschiedenen Betrachtungswinkeln erstellt, die dieser Aufnahme-Geometrien nachempfunden sind. Ein gängiges Verfahren zur Ableitung der relevanten Pflanzenparameter ist die Verwendung des Strahlungstransfermodells PROSAIL, welches das spektrale Signal einer Vegetationsfläche auf Basis der zugrundeliegenden biophysikalischen und biochemischen Parameter simuliert. Bei der Umkehr dieses Prozesses können ebendiese Variablen von gemessenen spektralen Daten abgeleitet werden. Hierzu wurde eine Datenbank (Look-Up-Table, LUT) aus PROSAIL-Modellläufen aufgebaut und die in den Feldkampagnen gemessenen Spektren mit dieser abgeglichen. Mit dieser Methode der LUT-Invertierung aus unterschiedlichen Aufnahmewinkeln konnten Genauigkeiten bei der LAI-Schätzung von 18 % und bei Blattchlorophyll von 20 % erzielt werden. Eine starke Anisotropie, also eine Reflexionsabhängigkeit von der Beleuchtungs- und Aufnahmerichtung, wurde bei Winterweizen vor allem für frühe Entwicklungsstadien festgestellt. Bei einer anschließenden Studie zur Unsicherheitsanalyse des Spektralmodells wurden PROSAIL-Ergebnisse, bei denen real gemessene Pflanzenparameter als Input dienten, den zugehörigen Reflektanzspektren gegenübergestellt. Es zeigten sich hierbei mitunter starke Abweichungen zwischen gemessenen und modellierten Spektren, die im Falle des Winterweizens einen saisonalen Verlauf zeichneten. Vor allem während frühen Wachstumsstadien tendierte das Modell dazu die Reflektanz im nahen Infrarot zu überschätzen, während es gegen Ende der Wachstumsperiode eher eine Unterschätzung aufwies. Als Unsicherheitsfaktor wurde die Parametrisierung des Modells ausgemacht, wenn der ALIA-Parameter als echter physikalische Blattwinkel interpretiert wird. Es wurde geschlussfolgert, dass eine Separierung von LAI und ALIA bei der Invertierung von PROSAIL eine korrekte Abschätzung der weniger sensitiven Parameter behindert. Die Erstellung des Vegetations-Prozessors erforderte die Verwendung von Regressions-Algorithmen des maschinellen Lernens (MLRA), da eine Verteilung von großen LUTs an die User nicht praktikabel wäre. Die MLRAs wurden an synthetischen Datensätzen trainiert, wobei zunächst die Optimierung der Hyperparameter im Vordergrund stand, bevor die Anwendung an echten Spektraldaten unternommen wurde. Es konnten dabei erst aussagekräftige Ergebnisse produziert werden, als die Trainingsdaten mit einem künstlichen Rauschen belegt wurden, da die Algorithmen unter einer Überanpassung an die Modellumgebung litten. Mithilfe des Prozessors konnten schließlich LAI, ALIA, Ccab und Cw aus hyperspektralen Daten abgeleitet werden. Künstliche neuronale Netze dienen dabei als Blackbox-Modelle, die in kurzer Zeit große Datenmengen verarbeiten können und somit einen entscheidenden Beitrag zur modernen angewandten Fernerkundung für eine breite User-Community leisten.After years of scientific and technical preparation, the launch of an unmanned German space-mission is planned to be initiated in 2020. The Environmental Mapping and Analysis Program (EnMAP) is going to provide an equally named hyperspectral imager to map land surfaces. Scientists of environmental disciplines of monitoring of ecosystems, agricultural, forestry and urban areas as well as coastal and inland waters, geology and soils prepared themselves for the upcoming data prior to the actual launch. Although there already exists a variety of useful algorithms for a profound analysis of spectral data, new challenges will arise given the uniqueness of the EnMAP-mission in the global context of remote sensing; i.e. coverage of the full range of the optical spectrum (420 nm – 2450 nm) in combination with a moderate spatial resolution of 30 m and a high signal-to-noise ratio of at least 180 in the shortwave infrared and above 400 in the visible spectrum. This enables an imaging quality which to this date has only been reached by airborne systems. The efforts of this dissertation comprise activities in the scientific preparation phase for agro-geographical tasks. Algorithms and tools for an analysis of hyperspectral data are being provided for free in the QGIS-plugin EnMAP-Box 3. Urgent questions in the agricultural sector revolve around the derivation of biochemical and biophysical parameters from remote sensing data. For this reason, the overarching objective of this promotion is the development of a scientific EnMAP-tool for managed areas of vegetation (EnMAP Managed Vegetation Scientific Processor). At first, an extensive field campaign was planned and then started in April, 2014. Apart from spectral observations of leaves, canopies and soils in a winter wheat and a maize field, also relevant plant parameters were acquired at the exact same spots. Namely, they are the Leaf Area Index (LAI), leaf chlorophyll content (Ccab), leaf water content (EWT or Cw), relative dry leaf weight (LMA or Cm), Average Leaf Inclination Angle (ALIA) as well as other secondary parameters like canopy height, phenological stage and the solar vector. Spectral measurements were captured from different observation angles to match ground data with the sensing geometry of the future EnMAP-satellite, which can be tilted up to 30° orthogonal to its direction of flight. A common procedure to derive relevant crop parameters is to make use of the radiative transfer model PROSAIL, which simulates the spectral signal of a vegetated surface based on biophysical and biochemical input parameters. If this process is reverted, said parameters can be derived from measured spectral data. To do so, a Look-Up-Table (LUT) is built containing model runs of PROSAIL and then subsequently compared against spectra from the field campaigns. With this approach of LUT-inversions from different observation angles, an accuracy of 18 % could be achieved for LAI and 20 % for Ccab. Strong anisotropic effects, i.e. dependence on illumination geometry and sensor orientation, were identified for winter wheat mainly in the early stages of plant development. In a consecutive study about uncertainties of the spectral model, PROSAIL results fed with in situ measured crop parameters as input, were opposed to their associated reflectance signatures. A strong deviation between measured and modelled spectra was observed, which – in the case of winter wheat – showed a seasonal behavior. The model tended to overestimate reflectances in the near infrared for early phenological stages and to underestimate them at end of the growing period. The parametrization of the model was identified as an uncertainty factor if the ALIA parameter is interpreted as true physical leaf inclinations. It was concluded that a separation of LAI and ALIA at inversion of PROSAIL prevents an adequate estimation of the less sensitive parameters. The development of the vegetation processor required the use of Machine Learning Regression Algorithms (MLRA), since distribution of large LUTs to the user would be impracticable. The MLRAs were trained with synthetic datasets with primary importance to optimize their hyperparameters, before attempting to apply the algorithms to real spectral data. Significant results could not be obtained until training data were altered with artificial noise, because algorithms suffered from overfitting to the model environment. Executing the processor allowed to derive LAI, ALIA, Ccab and Cw from hyperspectral data. Artificial neural networks served as black box models, which digest great amount of data in a short period of time and thus make a decisive contribution to modern applied remote sensing with relevance for a broad user-community