A scalable plant-resolving radiative transfer model based on optimized GPU ray tracing
暂无分享,去创建一个
Peter Willemsen | Brian N. Bailey | Matthew Overby | Eric R. Pardyjak | Rob Stoll | Walter F. Mahaffee | P. Willemsen | E. Pardyjak | R. Stoll | B. Bailey | W. Mahaffee | Matthew Overby
[1] A. Kuusk,et al. A reflectance model for the homogeneous plant canopy and its inversion , 1989 .
[2] F. Baret,et al. 2D approximation of realistic 3D vineyard row canopy representation for light interception (fIPAR) and light intensity distribution on leaves (LIDIL) , 2011 .
[3] J. Roujean,et al. A bidirectional reflectance model of the Earth's surface for the correction of remote sensing data , 1992 .
[4] J. Norman,et al. Radiative Transfer in an Array of Canopies1 , 1983 .
[5] Jens H. Krüger,et al. A Survey of General‐Purpose Computation on Graphics Hardware , 2007, Eurographics.
[6] Pradeep Dubey,et al. Debunking the 100X GPU vs. CPU myth: an evaluation of throughput computing on CPU and GPU , 2010, ISCA.
[7] S. T. Henderson. Daylight and Its Spectrum , 1977 .
[8] K. Stadt,et al. MIXLIGHT: a flexible light transmission model for mixed-species forest stands. , 2000 .
[9] Peter R. J. North,et al. Three-dimensional forest light interaction model using a Monte Carlo method , 1996, IEEE Trans. Geosci. Remote. Sens..
[10] Ranga B. Myneni,et al. Photon transport in vegetation canopies with anisotropic scattering Part I. Scattering phase functions in one angle , 1988 .
[11] Ana L. Scopel,et al. Far-Red Radiation Reflected from Adjacent Leaves: An Early Signal of Competition in Plant Canopies , 1990, Science.
[12] J. M. Norman,et al. Partitioning solar radiation into direct and diffuse, visible and near-infrared components , 1985 .
[13] Y. Iwasa,et al. Tree height and crown shape, as results of competitive games , 1985 .
[14] V. Vanderbilt,et al. Plant Canopy Specular Reflectance Model , 1985, IEEE Transactions on Geoscience and Remote Sensing.
[15] Gautam Badhwar,et al. Inclusion of Specular Reflectance in Vegetative Canopy Models , 1985, IEEE Transactions on Geoscience and Remote Sensing.
[16] John R. Miller,et al. Assessing vineyard condition with hyperspectral indices: Leaf and canopy reflectance simulation in a row-structured discontinuous canopy , 2005 .
[17] E. C. Flowers,et al. Atmospheric Turbidity over the United States, 1961–1966 , 1969 .
[18] M. Katz. Validation of models , 2006 .
[19] D S Kimes,et al. Radiative transfer model for heterogeneous 3-D scenes. , 1982, Applied optics.
[20] D. Smart,et al. Evaluation of Hyperspectral Reflectance Indexes to Detect Grapevine Water Status in Vineyards , 2007, American Journal of Enology and Viticulture.
[21] David K. McAllister,et al. GPU ray tracing , 2013, CACM.
[22] H. S. Horn. The adaptive geometry of trees , 1971 .
[23] B. Choudhury,et al. Spatial heterogeneity in vegetation canopies and remote sensing of absorbed photosynthetically active radiation: A modeling study , 1992 .
[24] A. Tarrant,et al. Daylight and its Spectrum (2nd edn) , 1978 .
[25] Paul G. Jarvis,et al. Description and validation of an array model - MAESTRO. , 1990 .
[26] R. Myneni,et al. Radiative transfer in vegetation canopies with anisotropic scattering , 1988 .
[27] J. Ledent. The physiology of crop yield, 2nd edn , 2007 .
[28] Nadine Gobron,et al. Radiation transfer model intercomparison (RAMI) exercise , 2001 .
[29] J. Ross. The radiation regime and architecture of plant stands , 1981, Tasks for vegetation sciences 3.
[30] D. Kimes. Dynamics of directional reflectance factor distributions for vegetation canopies. , 1983, Applied optics.
[31] J. Meseguer,et al. Thermal radiation heat transfer , 2012 .
[32] I. Seginer,et al. Leaf temperature error from heat conduction along thermocouple wires , 1999 .
[33] G. Campbell,et al. An Introduction to Environmental Biophysics , 1977 .
[34] John R. Howell,et al. Comparison of Monte Carlo Strategies for Radiative Transfer in Participating Media , 1998 .
[35] C. A. Coombes,et al. Angular distribution of clear sky short wavelength radiance , 1988 .
[36] H. Gausman,et al. Interaction of Isotropic Light with a Compact Plant Leaf , 1969 .
[37] C. Gueymard. REST2: High-performance solar radiation model for cloudless-sky irradiance, illuminance, and photosynthetically active radiation – Validation with a benchmark dataset , 2008 .
[38] Baker,et al. Ultraviolet-B radiation effects on water relations, leaf development, and photosynthesis in droughted pea plants , 1998, Plant physiology.
[39] G. Russell,et al. Plant Canopies: Their Growth, Form and Function: Absorption of radiation by canopies and stand growth , 1989 .
[40] G. Rybicki. Radiative transfer , 2019, Climate Change and Terrestrial Ecosystem Modeling.
[41] Hans R. Schultz,et al. Leaf absorptance of visible radiation in Vitis vinifera L.: estimates of age and shade effects with a simple field method , 1996 .
[42] M. Modest. Radiative heat transfer , 1993 .
[43] J. Porter,et al. The Physiology of Crop Yield , 2006 .
[44] J. Jeans,et al. The Equations of Radiative Transfer of Energy , 1917 .
[45] E. Pardyjak,et al. An experimental study of momentum and heavy particle transport in a trellised agricultural canopy , 2015 .
[46] M. Adams,et al. Simple models for stomatal conductance derived from a process model: cross-validation against sap flux data. , 2012, Plant, cell & environment.
[47] Y. Viswanadham. The Relationship between Total Precipitable Water and Surface Dew Point , 1981 .
[48] François X. Sillion,et al. An efficient instantiation algorithm for simulating radiant energy transfer in plant models , 2003, TOGS.
[49] H. Jones,et al. Remote Sensing of Vegetation: Principles, Techniques, and Applications , 2010 .
[50] V. N. Sridhar,et al. Linear polarization measurements of a wheat canopy , 1993 .
[51] M. Pinar Mengüç,et al. Thermal Radiation Heat Transfer , 2020 .
[52] E. Saff,et al. Distributing many points on a sphere , 1997 .
[53] Thomas K. Van Heuklon. Estimating atmospheric ozone for solar radiation models , 1979 .
[54] J. Monteith,et al. Principles of Environmental Physics , 2014 .
[55] J. Goudriaan,et al. SEPARATING THE DIFFUSE AND DIRECT COMPONENT OF GLOBAL RADIATION AND ITS IMPLICATIONS FOR MODELING CANOPY PHOTOSYNTHESIS PART I. COMPONENTS OF INCOMING RADIATION , 1986 .
[56] Philippe Martin,et al. A Model of Light Scattering in Three-Dimensional Plant Canopies: a Monte Carlo Ray Tracing Approach , 2007 .
[57] A. Kuusk. The Hot Spot Effect in Plant Canopy Reflectance , 1991 .
[58] A. Groot. A model to estimate light interception by tree crowns, applied to black spruce , 2004 .
[59] H. C. Hottel,et al. Radiant heat exchange in a gas-filled enclosure: Allowance for nonuniformity of gas temperature , 1958 .
[60] A. Cescatti. Modelling the radiative transfer in discontinuous canopies of asymmetric crowns. I. Model structure and algorithms , 1997 .
[61] Frédéric Baret,et al. Review of methods for in situ leaf area index determination Part I. Theories, sensors and hemispherical photography , 2004 .
[62] A. R. Ennos,et al. Adapting cities for climate change: the role of the green infrastructure. , 2007 .
[63] 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 .
[64] T. Brakke,et al. Specular and diffuse components of radiation scattered by leaves , 1994 .
[65] Jean Dauzat,et al. Simulating light regime and intercrop yields in coconut based farming systems , 1997 .
[66] Marialena Nikolopoulou,et al. Vegetation in the urban environment: microclimatic analysis and benefits , 2003 .