One-dimensional models of radiation transfer in heterogeneouscanopies: A review, re-evaluation, and improved model
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[1] Hervé Sinoquet,et al. RATP: a model for simulating the spatial distribution of radiation absorption, transpiration and photosynthesis within canopies: application to an isolated tree crown , 2001 .
[2] T. A. Black,et al. Characteristics of shortwave and longwave irradiances under a Douglas-fir forest stand , 1991 .
[3] R. Leuning,et al. A two-leaf model for canopy conductance, photosynthesis and partitioning of available energy I:: Model description and comparison with a multi-layered model , 1998 .
[4] Murugesu Sivapalan,et al. Ecohydrological responses of dense canopies to environmental variability: 1. Interplay between vertical structure and photosynthetic pathway , 2010 .
[5] M. Monsi. Uber den Lichtfaktor in den Pflanzengesellschaften und seine Bedeutung fur die Stoffproduktion , 1953 .
[6] Jason Weber,et al. Creation and rendering of realistic trees , 1995, SIGGRAPH.
[7] J. Goudriaan,et al. Modelling Potential Crop Growth Processes: Textbook with Exercises , 1994 .
[8] K. Stadt,et al. MIXLIGHT: a flexible light transmission model for mixed-species forest stands. , 2000 .
[9] Adam Trendowicz,et al. Model Development and Validation , 2013 .
[10] Bruno Andrieu,et al. The nested radiosity model for the distribution of light within plant canopies , 1998 .
[11] H. Mooney,et al. Plant Physiological Ecology-Field Methods and Instrumentation. , 1990 .
[12] C. Stöckle,et al. CropSyst, a cropping systems simulation model , 2003 .
[13] J. M. Chen,et al. Effects of clumping on estimates of stand leaf area index using the LI-COR LAI-2000 , 1993 .
[14] P. Cox,et al. The Joint UK Land Environment Simulator (JULES), model description – Part 2: Carbon fluxes and vegetation dynamics , 2011 .
[15] D. Pury,et al. Simple scaling of photosynthesis from leaves to canopies without the errors of big‐leaf models , 1997 .
[16] M. Katz. Validation of models , 2006 .
[17] A. Strahler,et al. A clumped-foliage canopy radiative transfer model for a Global Dynamic Terrestrial Ecosystem Model II: Comparison to measurements. , 2010 .
[18] D S Kimes,et al. Radiative transfer model for heterogeneous 3-D scenes. , 1982, Applied optics.
[19] E. S. Krayenhoff,et al. A Multi-layer Radiation Model for Urban Neighbourhoods with Trees , 2014, Boundary-Layer Meteorology.
[20] D. Hodáňová. An introduction to environmental biophysics , 1979, Biologia Plantarum.
[21] William P. Kustas,et al. Effects of Vegetation Clumping on Two–Source Model Estimates of Surface Energy Fluxes from an Agricultural Landscape during SMACEX , 2005 .
[22] Afshin Soltani,et al. Modeling Physiology of Crop Development, Growth and Yield , 2012 .
[23] S. Liang,et al. Estimation of fraction of absorbed photosynthetically active radiation from multiple satellite data: Model development and validation , 2016 .
[24] F. Villalobos,et al. Radiation interception, radiation-use efficiency and dry matter partitioning in garlic (Allium sativum L.) , 2002 .
[25] H. Franssen,et al. H. (2015). Correction of systematic model forcing bias of CLM using assimilation of cosmic-ray Neutrons and land surface temperature: a study in the Heihe Catchment, China. Hydrology and Earth System , 2015 .
[26] E. Schulze,et al. Leaf nitrogen, photosynthesis, conductance and transpiration : scaling from leaves to canopies , 1995 .
[27] David T. Tissue,et al. Radiative transfer and carbon assimilation in relation to canopy architecture, foliage area distribution and clumping in a mature temperate rainforest canopy in New Zealand , 2005 .
[28] Raoul Lemeur,et al. A critical review of light models for estimating the shortwave radiation regime of plant canopies , 1974 .
[29] D. Randall,et al. A Revised Land Surface Parameterization (SiB2) for Atmospheric GCMS. Part I: Model Formulation , 1996 .
[30] O. Kull,et al. Modelling canopy growth and steady-state leaf area index in an aspen stand , 2000 .
[31] I. C. Prentice,et al. A dynamic global vegetation model for studies of the coupled atmosphere‐biosphere system , 2005 .
[32] R. W. Pearcy. Radiation and light measurements , 2000 .
[33] T. Pukkala,et al. Effect of crown shape and tree distribution on the spatial distribution of shade , 1987 .
[34] H. Jones. Plants and Microclimate: Other environmental factors: wind, altitude, climate change and atmospheric pollutants , 2013 .
[35] James W. Jones,et al. The DSSAT cropping system model , 2003 .
[36] E. Kowalczyk,et al. The CSIRO Atmosphere Biosphere Land Exchange (CABLE) model for use in climate models and as an offline model , 2006 .
[37] A. Rango,et al. An object-based image analysis approach for determining fractional cover of senescent and green vegetation with digital plot photography , 2007 .
[38] M. Modest. Inverse Radiative Heat Transfer , 2022, Radiative Heat Transfer.
[39] Mark A. Friedl,et al. Parameterization of shortwave radiation fluxes for nonuniform vegetation canopies in land surface models , 2001 .
[40] B. Bailey,et al. Evaluating the use of Beer's law for estimating light interception in canopy architectures with varying heterogeneity and anisotropy , 2019, Ecological Modelling.
[41] K. Oleson,et al. A dynamic global vegetation model for use with climate models: concepts and description of simulated vegetation dynamics , 2003 .
[42] Peter Willemsen,et al. A scalable plant-resolving radiative transfer model based on optimized GPU ray tracing , 2014 .
[43] J. Norman,et al. Radiative Transfer in an Array of Canopies1 , 1983 .
[44] T. Nilson. A theoretical analysis of the frequency of gaps in plant stands , 1971 .
[45] Bruce E. Gorham,et al. Using digital photographs and object-based image analysis to estimate percent ground cover in vegetation plots , 2006 .
[46] Nadine Gobron,et al. Radiation transfer model intercomparison (RAMI) exercise , 2001 .
[47] Mitsuru Tsubo,et al. A MODEL OF RADIATION INTERCEPTION AND USE BY A MAIZE–BEAN INTERCROP CANOPY , 2002 .
[48] J. Chen,et al. Measuring leaf area index of plant canopies with branch architecture , 1991 .
[49] Brian N. Bailey,et al. A reverse ray-tracing method for modelling the net radiative flux in leaf-resolving plant canopy simulations , 2018 .
[50] Jean-Philippe Gastellu-Etchegorry,et al. DART: a 3D model for simulating satellite images and studying surface radiation budget , 2004 .
[51] C. Justice,et al. A Revised Land Surface Parameterization (SiB2) for Atmospheric GCMS. Part II: The Generation of Global Fields of Terrestrial Biophysical Parameters from Satellite Data , 1996 .
[52] Tiit Nilson,et al. Inversion of gap frequency data in forest stands , 1999 .
[53] S. T. Gower,et al. Characterizing canopy nonrandomness with a multiband vegetation imager (MVI) , 1997 .
[54] Phillipp Kaestner. Ray Tracing From The Ground Up , 2016 .
[55] A. Kuusk,et al. A Directional Multispectral Forest Reflectance Model , 2000 .
[56] Michael Henke,et al. Using a Full Spectral Raytracer for Calculating Light Microclimate in Functional-Structural Plant Modelling , 2017, Comput. Informatics.
[57] Jean-Luc Widlowski,et al. Third Radiation Transfer Model Intercomparison (RAMI) exercise: Documenting progress in canopy reflectance models , 2007 .
[58] John M. Norman,et al. Characterization of radiation regimes in nonrandom forest canopies: theory, measurements, and a simplified modeling approach. , 1999, Tree physiology.
[59] Lu Su,et al. Radiation Transfer Model Intercomparison (RAMI) exercise: Results from the second phase , 2004 .
[60] Brian N. Bailey,et al. Helios: A Scalable 3D Plant and Environmental Biophysical Modeling Framework , 2019, Front. Plant Sci..
[61] J. Cuevas,et al. Radiative Heat Transfer , 2018, ACS Photonics.
[62] G. Mohren,et al. Simulation of competition for light in even-aged stands of Douglas Fir , 1987 .
[63] Alan H. Strahler,et al. Modeling the gap probability of a discontinuous vegetation canopy , 1988 .
[64] Senthold Asseng,et al. An overview of APSIM, a model designed for farming systems simulation , 2003 .
[65] A. Cescatti. Modelling the radiative transfer in discontinuous canopies of asymmetric crowns. I. Model structure and algorithms , 1997 .
[66] Tilden P. Meyers,et al. Modelling the plant canopy micrometeorology with higher-order closure principles , 1987 .
[67] Jindi Wang,et al. Improvement of spatially and temporally continuous crop leaf area index by integration of CERES-Maize model and MODIS data , 2016 .
[68] Tiit Nilson,et al. Radiative Transfer in Nonhomogeneous Plant Canopies , 1992 .
[69] F. Gougeon. A Crown-Following Approach to the Automatic Delineation of Individual Tree Crowns in High Spatial Resolution Aerial Images , 1995 .
[70] Robert W. Pearcy,et al. A three-dimensional crown architecture model for assessment of light capture and carbon gain by understory plants , 1996, Oecologia.
[71] Philip Lewis,et al. The fourth radiation transfer model intercomparison (RAMI‐IV): Proficiency testing of canopy reflectance models with ISO‐13528 , 2013 .
[72] Peng Gong,et al. Modeling radiation and photosynthesis of a heterogeneous savanna woodland landscape with a hierarchy of model complexities , 2007 .
[73] Harrie-Jan Hendricks Franssen,et al. Correction of systematic model forcing bias of CLM using assimilation of cosmic-ray Neutrons and land surface temperature: a study in the Heihe Catchment, China , 2014 .
[74] J. Goudriaan,et al. Modelling Potential Crop Growth Processes , 1994, Current Issues in Production Ecology.
[75] John G. Annandale,et al. Two-dimensional solar radiation interception model for hedgerow fruit trees , 2004 .
[76] Paul G. Jarvis,et al. Description and validation of an array model - MAESTRO. , 1990 .
[77] N. Kiang,et al. A clumped-foliage canopy radiative transfer model for a global dynamic terrestrial ecosystem model. I: Theory , 2010 .
[78] Gil Bohrer,et al. Exploring the Effects of Microscale Structural Heterogeneity of Forest Canopies Using Large-Eddy Simulations , 2009 .
[79] C. Gueymard. Direct solar transmittance and irradiance predictions with broadband models. Part I: detailed theoretical performance assessment , 2003 .
[80] Jing M. Chen,et al. Daily canopy photosynthesis model through temporal and spatial scaling for remote sensing applications , 1999 .