Your search keyword '"J. Guilleux"' showing total 18 results

1. TRUST-DART: Land Surfaces Temperature and Emissivity Nonlinear Mapping from Nonisothermal Mixed Pixels of Satellite Images with the DART 3D Radiative Transfer Model

Author

Z. Zhen, J. León-Tavares, A. Kallel, Y. Wang, O. Regaieg, E. Chavanon, N. Lauret, J. Guilleux, J. Hedman, T. Yin, R. Demoulin, and J.-P. Gastellu-Etchegorry

Subjects

Technology, Engineering (General). Civil engineering (General), TA1-2040, Applied optics. Photonics, TA1501-1820

Abstract

Coarse spatial resolution of Thermal Infrared (TIR) satellites hampers measuring the temperature and emissivity of scene elements from space that improves our understanding of land surfaces' thermal behavior. The stringent conditions of current TIR unmixing methods hinder the production of extensive component temperature and emissivity products. To address this, we designed a gradient-based multi-pixel physical model, TRUST-DART, to derive the temperature and emissivity of urban features from non-isothermal mixed pixels of satellite images using the DART 3D radiative transfer model. Unlike traditional TIR unmixing methods, TRUSTDART is not constrained by issues related to spatial, spectral, temporal resolution, angular, scene, field measurement requirements, or manual operations. Its inputs include an at-surface radiance image, downwelling sky irradiance, a 3D urban mock-up with feature information, and DART input parameters such as spatial resolution. It generates maps of emissivity and temperature per urban feature. Its accuracy is validated for two vegetation and urban scenes and two types of images (DART simulated pseudo satellite and ASTER observed images). The accuracy of the TRUST-DART depends heavily on the fraction of components. TRUST-DART proves robust for high-fraction components. However, its accuracy decreases with decreasing fractions. TRUST-DART is distributed with DART and is available for education and research via Toulouse III University (https://dart.omp.eu).

Published

2024

2. Simulation of Solar-Induced Chlorophyll Fluorescence from 3D Canopies with the Dart Model

Author

O. Regaieg, Wang Y, Z. Malenovský, T. Yin, A. Kallel4, J. Duran N, Delavois A, J. Qi, E. Chavanon, N. Lauret, J. Guilleux, B Cook, D Morton, and Gastellu-Etchegorry J.P

Subjects

Earth Resources And Remote Sensing

Abstract

The potential of solar-induced chlorophyll fluorescence (SIF) to monitor photosynthesis and plant stress has attracted considerable interest in SIF remote sensing (RS). However, canopy SIF and RS observations are impacted by topography, vegetation three dimension (3D) structure, leaf orientation, non foliar elements (e.g., tree woody skeleton), ... Physically based downscaling of canopy SIF RS data to leaf-level (i.e., to leaf photosynthesis) requires 3D radiative transfer (RT) models simulating canopy SIF and its observation. These models are necessary to better exploit the potential of SIF, by linking leaf SIF and SIF in RS observations as a function of canopy 3D architecture and experimental configurations (sun and viewing directions, etc.). The Discrete Anisotropic Radiative Transfer (DART) model is a comprehensive 3D radiative transfer (RT) model for urban and natural landscapes. This paper presents its SIF modeling for vegetation simulated with facets, its validation with the SCOPE/mSCOPE 1D models, and its recent extension to SIF modelling for landscapes simulated with 3D turbid medium.

Published

2021

3. Recent Improvements in the Dart Model for Atmosphere, Topography, Large Landscape, Chlorophyll Fluorescence, Satellite Image Inversion

Author

J. P. Gastellu-Etchegorry, Y. Wang, O. Regaieg, T. Yin, Z. Malenovsky, Z. Zhen, X. Yang, Z. Tao, L. Landier, A. Al Bitar, Deschamps, N. Lauret, J. Guilleux, E. Chavanon, B. Cao, J. Qi, A. Kallel, Z. Mitraka, N. Chrysoulakis, B Cook, and D Morton

Subjects

Earth Resources And Remote Sensing

Abstract

Physical models simulating the radiative budget (RB) and remote sensing (RS) observation of three-dimensional (3D) landscapes are critical to better understand human and natural components of the Earth system and further develop RS technology. DART is one of the most comprehensive 3D models of Earth-atmosphere optical radiative transfer (RT), from ultraviolet (UV) to thermal infrared (TIR). It simulates the optical signal of proximal, aerial and satellite imaging spectrometers and laser scanners, the 3D RB and solar induced chlorophyll fluorescence (SIF) signal, for any urban or natural landscape and any experimental or instrument configuration. It is freely available for research and teaching activities (https://dart.omp.eu). Here, five recent advances are presented. 1) Atmosphere RT. 2) RT in non repetitive topography. 3) Monte Carlo modelling for fast RS image simulation of large landscapes. 4) SIF modelling for vegetation simulated as facets and turbid cells. 5) RS image inversion for mapping the optical properties of urban material and the urban radiative budget.

Published

2021

4. Correction of Directional Effects in Sentinel-2 and -3 Images with Sentinel-3 Time Series and Dart 3D Radiative Transfer Model

Author

J.P., Gastellu-Etchegorry, primary, N., Lauret, additional, L., Tavares, additional, N., Lamquin, additional, V., Bruniquel, additional, J.L., Roujean, additional, O., Hagolle, additional, Z., Zhen, additional, Y., Wang, additional, O., Regaieg, additional, J., Guilleux, additional, E., Chavanon, additional, and P., Goryl, additional

Published

2022

5. Quantitative Analysis of DART Calibration Accuracy for Retrieving Spectral Signatures Over Urban Area

Author

E. Chavanon, Shengbo Chen, Tiangang Yin, Nicolas Lauret, J. Guilleux, Jean-Philippe Gastellu-Etchegorry, and Zhijun Zhen

Subjects

Atmospheric Science, Dart, Spectral signature, reflectance, QC801-809, spectral mixed model, Geophysics. Cosmic physics, Solar zenith angle, urban meteorology, Ocean engineering, Approximation error, Radiative transfer, DART, Satellite, spectral confusion, Computers in Earth Sciences, TC1501-1800, Image resolution, Shortwave, computer, Geology, Remote sensing, computer.programming_language

Abstract

Discrete anisotropic radiative transfer (DART) calibration is an iterative inversion method that is applied to shortwave (SW) satellite images to get maps of spectral signatures (SS) of city materials at the satellite spatial resolution. Therefore, it is potentially a handy spectral unmixing tool. However, up to now, it has only been validated by comparing the time series of SW radiative budget Q*SW from a flux tower in Basel to DART simulated Q*SW using maps of SS derived from satellite images. This article thoroughly assesses the DART calibration accuracy with two synthetic case studies, called “ideal” and “nonideal,” for short wavelengths. In both cases, the satellite image is a DART simulated image of an urban scene with ground, buildings with various structures, water, and shrubs. In the ideal case, SS maps are the only unknowns in the inversion process. The mean absolute value of the relative errors over all bands for ground, roof, water, tree, and shrub maps were 0.013, 0.005, 0.027, 0.297, and 0.250. In the nonideal case, we considered an uncertainty on parameters assumed to be known in the ideal case: solar zenith angle (SZA); satellite image spatial resolution; pixel-shift; inaccuracy of landscape modeling; and modulation transfer function (MTF). It led to larger errors: for ground, roof, water, tree, and shrubs, the mean absolute value of the relative error was 0.233, 0.507, 3.088, 0.834, and 1.256, respectively. By descending order of importance, the parameters that most affect the accuracy of the retrieved SS of urban material were SZA, satellite image spatial resolution, pixel-shift, inaccuracy of three-dimensional urban scene modeling, and MTF.

Published

2021

6. Recent Improvements in the Dart Model for Atmosphere, Topography, Large Landscape, Chlorophyll Fluorescence, Satellite Image Inversion

Author

Ahmad Al Bitar, Jean-Philippe Gastellu-Etchegorry, Z. Tao, Biao Cao, Tiangang Yin, E. Chavanon, Lucas Landier, O. Regaieg, Deschamps, Nektarios Chrysoulakis, Zhijun Zhen, Bruce D. Cook, Zina Mitraka, Yingjie Wang, Z. Malenovsky, Jianbo Qi, J. Guilleux, Xue Yang, Abdelaziz Kallel, Douglas C. Morton, and Nicolas Lauret

Subjects

Dart, Physical model, 010504 meteorology & atmospheric sciences, Spectrometer, 0208 environmental biotechnology, Monte Carlo method, 02 engineering and technology, Atmospheric model, Laser, 01 natural sciences, 020801 environmental engineering, law.invention, Atmosphere, law, Radiative transfer, Environmental science, computer, 0105 earth and related environmental sciences, Remote sensing, computer.programming_language

Abstract

Physical models simulating the radiative budget (RB) and remote sensing (RS) observation of three-dimensional (3D) landscapes are critical to better understand human and natural components of the Earth system and further develop RS technology. DART is one of the most comprehensive 3D models of Earth-atmosphere optical radiative transfer (RT), from ultraviolet (UV) to thermal infrared (TIR). It simulates the optical signal of proximal, aerial and satellite imaging spectrometers and laser scanners, the 3D RB and solar induced chlorophyll fluorescence (SIF) signal, for any urban or natural landscape and any experimental or instrument configuration. It is freely available for research and teaching activities (https://dart.omp.eu). Here, five recent advances are presented. 1) Atmosphere RT. 2) RT in non repetitive topography. 3) Monte Carlo modelling for fast RS image simulation of large landscapes. 4) SIF modelling for vegetation simulated as facets and turbid cells. 5) RS image inversion for mapping the optical properties of urban material and the urban radiative budget.

Published

2020

7. Simulation of Solar-Induced Chlorophyll Fluorescence from 3D Canopies with the Dart Model

Author

O. Regaieg, Y. Wang, Z. Malenovsky, T. Yin, A. Kallel, J. Duran N., A. Delavois, J. Qi, E. Chavanon, N. Lauret, J. Guilleux, B. Cook, D. Morton, and J.P. Gastellu-Etchegorry

Subjects

Canopy, Dart, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, 02 engineering and technology, Atmospheric model, Vegetation, Atmospheric sciences, 01 natural sciences, Radiative transfer, Environmental science, Anisotropy, Chlorophyll fluorescence, computer, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Downscaling, computer.programming_language

Abstract

The potential of solar-induced chlorophyll fluorescence (SIF) to monitor photosynthesis and plant stress has attracted considerable interest in SIF remote sensing (RS). However, canopy SIF and RS observations are impacted by topography, vegetation three dimension (3D) structure, leaf orientation, non foliar elements (e.g., tree woody skeleton), … Physically based downscaling of canopy SIF RS data to leaf-level (i.e., to leaf photosynthesis) requires 3D radiative transfer (RT) models simulating canopy SIF and its observation. These models are necessary to better exploit the potential of SIF, by linking leaf SIF and SIF in RS observations as a function of canopy 3D architecture and experimental configurations (sun and viewing directions, etc.). The Discrete Anisotropic Radiative Transfer (DART) model is a comprehensive 3D radiative transfer (RT) model for urban and natural landscapes. This paper presents its SIF modeling for vegetation simulated with facets, its validation with the SCOPE/mSCOPE 1D models, and its recent extension to SIF modelling for landscapes simulated with 3D turbid medium.

Published

2020

8. Why To Model Remote Sensing Measurements In 3d? Recent Advances In Dart: Atmosphere, Topography, Large Landscape, Chlorophyll Fluorescence And Satellite Image Inversion

Author

Z. Mitraka, Ahmad Al Bitar, Bruce D. Cook, B. Cao, Douglas C. Morton, Tiangang Yin, N. Chrysoulakis, Z. Tao, Abdelaziz Kallel, Jianbo Qi, Z. Malenovsky, Jean-Philippe Gastellu-Etchegorry, O. Regaieg, Yingjie Wang, Zhijun Zhen, X. Yang, Lucas Landier, Nicolas Lauret, J. Guilleux, E. Chavanon, and Deschamps

Subjects

Dart, Physical model, Spectrometer, Inversion (meteorology), Laser, law.invention, law, Satellite image, Radiative transfer, Environmental science, computer, Chlorophyll fluorescence, computer.programming_language, Remote sensing

Abstract

Remote sensing (RS) dedicated to the study of land surfaces benefits from more and more advanced sensors. However, the interpretation of RS data is often is often inaccurate due to the complexity of the observed land surfaces. Therefore, RS models, in particular physical models, that simulate RS observations of the three-dimensional (3D) landscapes are critical to correctly interpret RS data. DART is one of the most comprehensive 3D models of Earthatmosphere optical radiative transfer (RT), from ultraviolet (UV) to thermal infrared (TIR). It simulates the optical signal of proximal, aerial and satellite imaging spectrometers and laser scanners, the 3D RB and solar-induced chlorophyll fluorescence (SIF) signal, for any urban or natural landscape and any experimental or instrument configuration. It is freely available for research and teaching activities (dart.omp.eu). After illustrating three significant sources of inaccuracy in RS interpretation, five recent DART advances are presented: RT in the atmosphere and topography, fast RS image simulation of large landscapes, SIF modelling, and satellite image inversion.

Published

2020

9. Discrete anisotropic radiative transfer modelling of solar-induced chlorophyll fluorescence: Structural impacts in geometrically explicit vegetation canopies

Author

Tiangang Yin, O. Regaieg, Ghania Medjdoub, Bruce D. Cook, Jean-Philippe Gastellu-Etchegorry, Zbyněk Malenovský, Douglas C. Morton, Jean Meynier, J. Guilleux, Christiaan van der Tol, Nicolas Lauret, Růžena Janoutová, E. Chavanon, Antony Delavois, Nuria Duran, Peiqi Yang, UT-I-ITC-WCC, Faculty of Geo-Information Science and Earth Observation, and Department of Water Resources

Subjects

Canopy, Dart, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, 22/2 OA procedure, Soil Science, Geology, 02 engineering and technology, Vegetation, 01 natural sciences, Signal, 020801 environmental engineering, Homogeneous, ITC-ISI-JOURNAL-ARTICLE, Radiative transfer, Environmental science, Computers in Earth Sciences, Anisotropy, Chlorophyll fluorescence, computer, 0105 earth and related environmental sciences, computer.programming_language, Remote sensing

Abstract

Solar-induced fluorescence (SIF) is a subtle but informative optical signal of vegetation photosynthesis. Remotely sensed SIF integrates environmental, physiological and structural changes that alter photosynthesis at leaf, plant and canopy scales. Radiative transfer models are ideally suited to investigate the complex sources of variability in the SIF signal to guide the interpretation of SIF retrievals from airborne and space-borne platforms. Here, we coupled the Fluspect-Cx model of leaf optical properties and chlorophyll-a fluorescence with the Discrete Anisotropic Radiative Transfer (DART) model to upscale SIF from individual leaves to three-dimensional (3D) structurally explicit canopies. For one-dimensional homogeneous (turbid-like) canopies, DART-SIF was nearly identical to SIF simulated in two existing models, SCOPE and mSCOPE (RMSE

Published

2021

10. Atmospheric and emissivity corrections for ground-based thermography using 3D radiative transfer modelling

Author

Jean-Philippe Gastellu-Etchegorry, Nicolas Lauret, Tiangang Yin, Leslie K. Norford, William Morrison, Sue Grimmond, J. Guilleux, and Simone Kotthaus

Subjects

010504 meteorology & atmospheric sciences, Infrared, 0208 environmental biotechnology, Atmospheric correction, Longwave, Soil Science, Geology, 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Atmosphere, Thermography, Emissivity, Radiative transfer, Environmental science, Computers in Earth Sciences, Absorption (electromagnetic radiation), 0105 earth and related environmental sciences, Remote sensing

Abstract

Methods to retrieve urban surface temperature (Ts) from remote sensing observations with sub-building scale resolution are developed using the Discrete Anisotropic Radiative Transfer (DART, Gastellu-Etchegorry et al., 2012) model. Corrections account for the emission and absorption of radiation by air between the surface and instrument (atmospheric correction), and for the reflected longwave infrared (LWIR) radiation from non-black-body surfaces (“emissivity” correction) within a single modelling framework. The atmospheric correction a) can use horizontally and vertically variable distributions of atmosphere properties at high resolution ( The atmospheric correction method evaluation, with simultaneous “near” (~15 m) and “far” (~155 m) observations, has a mean absolute error of 0.39 K. Using broadband approximations, the emissivity correction has clear diurnal variability, particularly when a cool and shaded surface (e.g. north facing) is irradiated by warmer (up to 17.0 K) surfaces (e.g. south facing). Varying the material emissivity with bulk values common for dark building materials (e = 0.89 → 0.97) alters the corrected roof (south facing) surface temperatures by ~3 (1.5) K, and the corrected cooler north facing surfaces by less than 0.1 K. Corrected observations, assuming a homogeneous radiation distribution from surfaces (analogous to a sky view factor correction), differ from a heterogeneous distribution by up to 0.25 K. Our proposed correction provides more accurate Ts observations with improved uncertainty estimates. Potential applications include ground-truthing airborne or space-borne surface temperatures and evaluation of urban energy balance models.

Published

2020

11. Simulation of Chlorophyll Fluorescence for Sun- and Shade-Adapted Leaves of 3D Canopies with the Dart Model

Author

Jianbo Qi, Douglas C. Morton, Bruce D. Cook, Jean-Philippe Gastellu-Etchegorry, Z. Malenovsky, J. Guilleux, E. Chavanon, N. Duran Gomez, J. Meynier, Tiangang Yin, and Nicolas Lauret

Subjects

Canopy, Dart, Physical model, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, Irradiance, 02 engineering and technology, Atmospheric model, Vegetation, 01 natural sciences, Radiative transfer, Environmental science, computer, Chlorophyll fluorescence, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, computer.programming_language, Remote sensing

Abstract

Potential of solar-induced chlorophyll fluorescence (SIF) to track time variable environmental stress of vegetation explains high interest in SIF remote sensing. There is an increasing need for physical models that consider the 3D structure of Earth surfaces, in order to better understand the relationships between SIF, vegetation three-dimensional (3D) architecture, irradiance and remote sensing configuration at canopy level. The Discrete Anisotropic Radiative Transfer (DART) model is one of the most comprehensive physically based 3D models of Earth-atmosphere radiative transfer (RT), covering the spectral domain from ultraviolet to thermal infrared wavelengths. This paper presents the determination of the sun and shade adapted leaf elements of a 3D vegetation canopy in DART, which is required for accurate RT simulations of SIF in geometrically explicit 3D canopy representations.

Published

2018

12. Dart: A Tool For Studying Earth Surfaces - Time Series of Urban Radiative Budget From Eo Satellites

Author

Jianbo Qi, Christian Feigenwinter, Tiangang Yin, Nicolas Lauret, E. Chavanon, J. Guilleux, Nektarios Chrysoulakis, Lucas Landier, Ahmad Al Bitar, Jean-Philippe Gastellu-Etchegorry, and Z. Mitraka

Subjects

Dart, 010504 meteorology & atmospheric sciences, Spectrometer, 0211 other engineering and technologies, Inversion (meteorology), 02 engineering and technology, Atmospheric model, Solid modeling, 01 natural sciences, Planet, Radiative transfer, Environmental science, Satellite, computer, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, computer.programming_language

Abstract

Models that simulate the radiative budget (RB) and remote sensing (RS) observation of landscapes with physical approaches and consideration of the three-dimensional (3-D) architecture of Earth surfaces are increasingly needed to better understand the life-essential cycles and processes of our planet and to further develop RS technology. DART (Discrete Anisotropic Radiative Transfer) is one of the most comprehensive physically based 3-D models of Earth-atmosphere optical radiative transfer (RT), from ultraviolet to thermal infrared. It simulates the optical 3-D RB and signal of proximal, aerial and satellite imaging spectrometers and laser scanners, for any urban and/ or natural landscapes and for any experimental and instrumental configurations. It is freely available for research and teaching activities. Here, an application is presented after a summary of its theory and recent advances: inversion of Sentinel 2 images for simulating time series of urban radiative budget ‘Q* sw ’ maps through the determination of maps of urban surface material. Results are very encouraging: satellite and in-situ Q* sw are very close (RMSE ≈ 15W/m2; i.e., 2.7% mean relative difference).

Published

2018

13. Dart: Radiative Transfer modeling for simulating terrain, airborne and satellite spectroradiometer and LIDAR acquisitions and 3D radiative budget of natural and urban landscapes

Author

Jean-Philippe Gastellu-Etchegorry, Nicolas Lauret, Josselin Aval, C. Jan, J. Guilleux, Lucas Landier, Tiangang Yin, E. Chavanon, Ahmad Al Bitar, Centre d'études spatiales de la biosphère (CESBIO), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), and Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[PHYS]Physics [physics], Dart, Radiometer, 010504 meteorology & atmospheric sciences, Meteorology, 0211 other engineering and technologies, Terrain, 02 engineering and technology, Atmospheric model, 01 natural sciences, Lidar, Spectroradiometer, [SDE]Environmental Sciences, Radiative transfer, Environmental science, Satellite, computer, ComputingMilieux_MISCELLANEOUS, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, computer.programming_language

Abstract

The need of better accuracy for analyzing remote sensing (RS) data of complex Earth surfaces explains the increasing need of models that simulate RS data with physical approaches. Similarly, the study of Earth surfaces functioning requires physical models that simulate the 3D radiative budget (RB) of these surfaces. DART (Discrete Anisotropic Radiative Transfer is one of the most comprehensive physically based 3D models that model the Earth-atmosphere radiation interaction from visible to thermal infrared wavelengths. It simulates optical signals at the entrance of terrain / airborne / satellite imaging radiometers and laser scanners, as well as the 3D RB, of urban / natural landscapes for any experimental and instrumental configurations. Its licenses are free for research and teaching activities. Here, we present its major recent advances.

Published

2016

14. Modeling specular reflectance and polarization in DART model for simulating remote sensing images of natural and urban landscapes

Author

C. Jan, E. Chavanon, J. Guilleux, Josselin Aval, Tiangang Yin, Abdelaziz Kallel, Nicolas Lauret, Jean-Philippe Gastellu-Etchegorry, Lucas Landier, Ahmad Al Bitar, Centre d'études spatiales de la biosphère (CESBIO), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), and Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[PHYS]Physics [physics], Dart, Radiometer, 010504 meteorology & atmospheric sciences, business.industry, Monte Carlo method, 0211 other engineering and technologies, Terrain, 02 engineering and technology, Atmospheric model, 01 natural sciences, Optics, Lidar, [SDE]Environmental Sciences, Radiative transfer, Environmental science, Specular reflection, business, computer, ComputingMilieux_MISCELLANEOUS, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, computer.programming_language

Abstract

The need of better accuracy to analyze remote sensing (RS) data and radiative budget (RB) of Earth surfaces explains the demand of physical models of RS and RB data. DART (Discrete Anisotropic Radiative Transfer) model is probably the most comprehensive three-dimensional (3D) physical model. Indeed, with original ray tracking and Monte Carlo methods for tracking radiation in the Earth and atmosphere from visible to thermal infrared wavelengths, it simulates the 3D RB and acquisitions of terrain / RS imaging radiometers and laser scanners, for any urban / natural landscape and any experimental / instrumental configuration. Paul Sabatier delivers free licenses for research and teaching activities. After introducing DART theory, we present recent advances: simulation of LiDAR and airborne sensors, and modeling of specular interaction and polarization.

Published

2016

15. L 'enceinte romaine du Mans

Author

Jason Wood and J. Guilleux

Subjects

Archeology, History, Classics

Abstract

L'enceinte romaine de la ville du mans reste l'un des monuments les plus prestigieux du bus-empire en gaule. Son etude comporte un repertoire des sources ecrites et une bibliographie permettant de se familiariser avec le theme, suivi d'un inventaire bibliographique portant sur les autres enceintes de la gaule. Apres une presentation du site urbain et de ses transformations jusqu'a la fin du troisieme siecle, les elements de tophographie, le plan et la description de cette enceinte font l'objet d'une analyse detaillee qui s'appuie sur tout un dossier de plans. Les techniques et les modes de construction ainsi que la decoration des parements demontrent l'evolution des travaux lois de leur mise en oeuvre. Le probleme de la datation de l'enceinte est aborde a partir d'une documentation archeologique propre au site. Pour chacun des themes traites, il est toujours fait appel a des comparaisons nombreuses avec les autres enceintes romaines. Elles permettent de comprendre la complexite de ces constructions qui se rapportent au grand probleme du temps : celui de la defense de la gaule.

Published

2004

16. DART: Recent Advances in Remote Sensing Data Modeling With Atmosphere, Polarization, and Chlorophyll Fluorescence

Author

Abdelaziz Kallel, E. Chavanon, Jianbo Qi, Bruce D. Cook, Jean-Philippe Gastellu-Etchegorry, Nicolas Lauret, Tiangang Yin, Ahmad Al Bitar, Ghania Medjdoub, Josselin Aval, J. Guilleux, Lucas Landier, Douglas C. Morton, Zina Mitraka, Z. Malenovsky, Nektarios Chrysoulakis, Sahar Benhmida, Centre d'études spatiales de la biosphère (CESBIO), Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), and Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[PHYS]Physics [physics], Atmospheric Science, Dart, 010504 meteorology & atmospheric sciences, Spectrometer, 0211 other engineering and technologies, 02 engineering and technology, Atmospheric model, Solid modeling, Polarization (waves), 01 natural sciences, Lidar, 13. Climate action, [SDE]Environmental Sciences, Radiative transfer, Environmental science, Specular reflection, Computers in Earth Sciences, computer, ComputingMilieux_MISCELLANEOUS, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, computer.programming_language

Abstract

To better understand the life-essential cycles and processes of our planet and to further develop remote sensing (RS) technology, there is an increasing need for models that simulate the radiative budget (RB) and RS acquisitions of urban and natural landscapes using physical approaches and considering the three-dimensional (3-D) architecture of Earth surfaces. Discrete anisotropic radiative transfer (DART) is one of the most comprehensive physically based 3-D models of Earth-atmosphere radiative transfer, covering the spectral domain from ultraviolet to thermal infrared wavelengths. It simulates the optical 3-D RB and optical signals of proximal, aerial, and satellite imaging spectrometers and laser scanners, for any urban and/or natural landscapes and for any experimental and instrumental configurations. It is freely available for research and teaching activities. In this paper, we briefly introduce DART theory and present recent advances in simulated sensors (LiDAR and cameras with finite field of view) and modeling mechanisms (atmosphere, specular reflectance with polarization and chlorophyll fluorescence). A case study demonstrating a novel application of DART to investigate urban landscapes is also presented.

17. Using the Negative Soil Adjustment Factor of Soil Adjusted Vegetation Index (SAVI) to Resist Saturation Effects and Estimate Leaf Area Index (LAI) in Dense Vegetation Areas.

Author

Zhen Z, Chen S, Yin T, Chavanon E, Lauret N, Guilleux J, Henke M, Qin W, Cao L, Li J, Lu P, and Gastellu-Etchegorry JP

Subjects

Linear Models, Satellite Imagery, Plant Leaves, Soil

Abstract

Saturation effects limit the application of vegetation indices (VIs) in dense vegetation areas. The possibility to mitigate them by adopting a negative soil adjustment factor X is addressed. Two leaf area index (LAI) data sets are analyzed using the Google Earth Engine (GEE) for validation. The first one is derived from observations of MODerate resolution Imaging Spectroradiometer (MODIS) from 16 April 2013, to 21 October 2020, in the Apiacás area. Its corresponding VIs are calculated from a combination of Sentinel-2 and Landsat-8 surface reflectance products. The second one is a global LAI dataset with VIs calculated from Landsat-5 surface reflectance products. A linear regression model is applied to both datasets to evaluate four VIs that are commonly used to estimate LAI: normalized difference vegetation index (NDVI), soil adjusted vegetation index (SAVI), transformed SAVI (TSAVI), and enhanced vegetation index (EVI). The optimal soil adjustment factor of SAVI for LAI estimation is determined using an exhaustive search. The Dickey-Fuller test indicates that the time series of LAI data are stable with a confidence level of 99%. The linear regression results stress significant saturation effects in all VIs. Finally, the exhaustive searching results show that a negative soil adjustment factor of SAVI can mitigate the SAVIs' saturation in the Apiacás area (i.e., X = -0.148 for mean LAI = 5.35), and more generally in areas with large LAI values (e.g., X = -0.183 for mean LAI = 6.72). Our study further confirms that the lower boundary of the soil adjustment factor can be negative and that using a negative soil adjustment factor improves the computation of time series of LAI.

Published

2021

18. Comparison of early development of three grasses: Lolium perenne, Agrostis stolonifera and Poa pratensis.

Author

Fustec J, Guilleux J, Le Corff J, and Maitre JP

Subjects

Agrostis growth & development, Biomass, Lolium growth & development, Models, Biological, Poa growth & development, Regression Analysis, Seeds growth & development, Time Factors, Plant Leaves growth & development, Poaceae growth & development

Abstract

Background and Aims: To improve the management of grass communities, early plant development was compared in three species with contrasting growth forms, a caespitose (Lolium perenne), a rhizomatous (Poa pratensis) and a caespitose-stoloniferous species (Agrostis stolonifera)., Methods: Isolated seedlings were grown in a glasshouse without trophic constraints for 37 d (761 degrees Cd). The appearance of leaves and their location on tillers were recorded. Leaf appearance rate (LAR) on the tillers and site-filling were calculated. Tillering was modelled based on the assumption that tiller number increases with the number of leaves produced on the seedling main stem. Above- and below-ground parts were harvested to compare biomass., Key Results: Lolium perenne and A. stolonifera expressed similar bunch-type developments. However, root biomass was approx. 30 % lower in A. stolonifera than in L. perenne. Poa pratensis was rhizomatous. Nevertheless, the ratio of above-ground : below-ground biomass of P. pratensis was similar to that of L. perenne. LAR was approximately equal to 0.30 leaf d(-1) in L. perenne, and on the main stem and first primary tillers of A. stolonifera. LAR on the other tillers of A. stolonifera was 30 % higher than on L. perenne. For P. pratensis, LAR was 30 % lower than on L. perenne, but the interval between the appearance of two successive shoots from rhizomes was 30 % higher than the interval between two successive leaf stages on the main stem. Above-ground parts of P. pratensis first grew slower than in the other species to the benefit of the rhizomes, whose development enhanced tiller production., Conclusions: Lolium perenne had the fastest tiller production at the earliest stages of seedling development. Agrostis stolonifera and P. pratensis compensated almost completely for the delay due to higher LAR on tillers or ramets compared with L. perenne. This study provides a basis for modelling plant development.

Published

2005