Your search keyword '"Leaf angle distribution"' showing total 13 results

1. A new approach to retrieve leaf normal distribution using terrestrial laser scanners

Author

Masayuki Tamura, Junichi Susaki, and Shengye Jin

Subjects

Tree canopy, 010504 meteorology & atmospheric sciences, Correlation coefficient, 0211 other engineering and technologies, Point cloud, Forestry, 02 engineering and technology, computer.software_genre, 01 natural sciences, Normal distribution, Voxel, Principal component analysis, Botany, Leaf angle distribution, computer, Normal, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, Mathematics

Abstract

Leaf normal distribution is an important structural characteristic of the forest canopy. Although terrestrial laser scanners (TLS) have potential for estimating canopy structural parameters, distinguishing between leaves and nonphotosynthetic structures to retrieve the leaf normal has been challenging. We used here an approach to accurately retrieve the leaf normals of camphorwood (Cinnamomum camphora) using TLS point cloud data. First, nonphotosynthetic structures were filtered by using the curvature threshold of each point. Then, the point cloud data were segmented by a voxel method and clustered by a Gaussian mixture model in each voxel. Finally, the normal vector of each cluster was computed by principal component analysis to obtain the leaf normal distribution. We collected leaf inclination angles and estimated the distribution, which we compared with the retrieved leaf normal distribution. The correlation coefficient between measurements and obtained results was 0.96, indicating a good coincidence.

Published

2015

2. Asymmetric competition increases leaf inclination effect on light absorption in mixed canopies

Author

Marion Durand-Gillmann, Roland Huc, Guillaume Simioni, INRA, and GENCI-CINES [2011-c2011016613]

Subjects

0106 biological sciences, Ecology, Leaf angle distribution, Mixed forests, Forest management, 3D modelling, Radiation absorption, CARBON GAIN, RADIATION ABSORPTION, ANGLE DISTRIBUTION, PLANT CANOPIES, QUERCUS-ILEX, AREA INDEX, MODEL, FOLIAGE, INTERCEPTION, FOREST, Forestry, Context (language use), 15. Life on land, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Water balance, [SDV.SA.SF]Life Sciences [q-bio]/Agricultural sciences/Silviculture, forestry, Asymmetric competition, Environmental science, 010606 plant biology & botany

Abstract

International audience; The effects of leaf inclination on plant light capture, growth, and water balance of monospecific canopies are well documented, but we still lack information on such effects in the case of multispecific canopies. We investigated the effects of leaf inclination on the absorption of photosynthetically active radiation (PAR) of a mixed forest. We ran a 3D mechanistic radiation transfer model for a Mediterranean forest where Pinus halepensis makes the upper strata while Quercus ilex occupies the lower strata. As factors, we included (1) the distributions of leaf inclinations that ranged from vertical to horizontal (including the actual inclinations), (2) the fraction of diffuse light, sun position, and leaf area index (LAI), and (3) the Pinus/Quercus LAI ratio. Simulated PAR absorption was more than twice as sensitive to leaf inclination in oaks than in pines because oaks depended on PAR transmitted below the pine layer. The extent of the effect depended on season, fraction of diffuse light, LAI, and vegetation spatial structure. None of the observed inclinations maximized PAR absorption, suggesting a trade-off with water economy. Erroneous assumptions about leaf inclination lead to larger errors when modelling heterogeneous, mixed canopies. This also highlights potential caveats when using models that do not account for the spatial structure of canopies.

Published

2012

3. Estimating leaf inclination and G-function from leveled digital camera photography in broadleaf canopies

Author

Krista Alikas, Youngryel Ryu, and Jan Pisek

Subjects

business.product_category, 010504 meteorology & atmospheric sciences, Ecology, Physiology, Orientation (computer vision), Photography, Digital photography, Forestry, 04 agricultural and veterinary sciences, Plant Science, Function (mathematics), 15. Life on land, 01 natural sciences, Botany, 040103 agronomy & agriculture, Leaf angle distribution, 0401 agriculture, forestry, and fisheries, Leaf area index, business, Tree species, 0105 earth and related environmental sciences, Remote sensing, Digital camera, Mathematics

Abstract

The effectiveness of using leveled digital camera for measuring leaf inclination angles was investigated in this study as an inexpensive and convenient alternative to existing approaches. The new method is validated with manual leaf angle measurements for various broadleaf tree species common to hemi-boreal region of Estonia and the tropical forests of Hawai’i Islands. The acquired leaf angle distributions suggest that planophile case might be more appropriate than the commonly assumed spherical as the general approximation of leaf orientation while modeling the radiation transmission through the canopies of (hemi)-boreal broadleaf stands. However, direct leaf inclination measurements should be obtained whenever possible, as there will always exist a large variety of leaf orientation, both among different species and in the space–time domain within a single species. The camera method tested in this study provides a new robust and affordable tool to obtain this information.

Published

2011

4. A generalized layered radiative transfer model in the vegetation canopy

Author

Sun Shufen and Dai Qiudan

Subjects

Canopy, Surface (mathematics), Atmospheric Science, business.industry, Layered model, Geometry, Vegetation canopy, Physics::Geophysics, Optics, Radiation transfer, Atmospheric radiative transfer codes, Leaf angle distribution, Astrophysics::Solar and Stellar Astrophysics, Leaf area index, business, Geology

Abstract

In this paper, a generalized layered model for radiation transfer in canopy with high vertical resolution is developed. Differing from the two-stream approximate radiation transfer model commonly used in the land surface models, the generalized model takes into account the effect of complicated canopy morphology and inhomogeneous optical properties of leaves on radiation transfer within the canopy. In the model, the total leaf area index (LAI) of the canopy is divided into many layers. At a given layer, the influences of diffuse radiation angle distributions and leaf angle distributions on radiation transfer within the canopy are considered. The derivation of equations serving the model are described in detail, and these can deal with various diffuse radiation transfers in quite broad categories of canopy with quite inhomogeneous vertical structures and uneven leaves with substantially different optical properties of adaxial and abaxial faces of the leaves. The model is used to simulate the radiation transfer for canopies with horizontal leaves to validate the generalized model. Results from the model are compared with those from the two-stream scheme, and differences between these two models are discussed.

Published

2006

5. Principal component inversion technique for the retrieval of leaf area index

Author

Sasmita Satapathy and Vinay Kumar Dadhwal

Subjects

Geography, Mean squared error, Geography, Planning and Development, Principal component analysis, Earth and Planetary Sciences (miscellaneous), Leaf angle distribution, Inversion (meteorology), Leaf area index, Soil type, Reflectivity, Canopy reflectance, Remote sensing

Abstract

A simulation study has been carried out to investigate the Principal Component Inversion (PCI) technique for the retrieval of leaf area index (LAI). The PROSAIL model has been used for the forward analysis, i.e., estimation of reflectance for various combinations of LAI, soil reflectance, leaf angle distribution (o1), chlorophyll a+b concentration (Cab), etc. Independent test on sample with LAI range 0.1-7.0 indicated that the retrieved LAI from PCI has higher accuracy (RMSE=0.137) than the classical NDVI-LAI empirical approach (RMSE=1.139). The study needs to be extended to cover retrieval from different types of soil and simultaneous retrieval of different biophysical parameters viz., LAI, Cab, o1 to test the wider applicability of the PCI technique.

Published

2005

6. Modeling the light interception and carbon gain of individual fluttering aspen (Populus tremuloides Michx) leaves

Author

John S. Roden

Subjects

Canopy, Ecology, Physiology, Forestry, Plant Science, Spatial distribution, Atmospheric sciences, Photosynthesis, Petiole (botany), Latitude, Botany, Leaf angle distribution, Environmental science, Flutter, Interception

Abstract

Poplars (Populus spp.) have a particular petiole morphology that enhances leaf flutter even in light winds. Previous studies have shown that this trait enhances whole canopy carbon gain through changes in the temporal dynamics and spatial distribution of light in the lower canopy. However, less is known about the effects of flutter for leaves at the top of the canopy ("sun leaves"). A computer simulation model was developed that uses latitude, time of day, day of year, azimuth and a slope component, which was varied at a 3 Hz frequency over an arc of rotation to create the flutter motion, and generate data on light interception for both surfaces of a fixed or fluttering leaf. The light files generated (10 Hz) were input into a dynamic model of photosynthesis to estimate the carbon gain for both fluttering and fixed leaves. As compared to leaves fixed at various angles and azimuths, fluttering leaves had a more uniform light interception. Depending on their angle and azimuth, fixed leaves may not always be intercepting high photon flux density (PFD) even when exposed to full sun. Leaf flutter continuously randomizes leaf angles creating uniform PFD inputs for photosynthetic reactions regardless of variation in leaf orientation and solar position. These effects on light interception could have positive impacts on carbon gain for leaves at the top of the canopy.

Published

2003

7. [Untitled]

Author

V. A. Dlugunovich, O. V. Tsaryuk, and V. A. Zaitseva

Subjects

Physics, Linear polarization, business.industry, Plane of incidence, Quantitative Biology::Tissues and Organs, Radiation, Elliptical polarization, Condensed Matter Physics, Polarization (waves), Laser, law.invention, symbols.namesake, Optics, law, Leaf angle distribution, symbols, Stokes parameters, business, Spectroscopy

Abstract

It is shown that the widest differences in the values and angular distributions of the polarization characteristics of the radiation reflected from the leaves of different kinds of plants are observed when a leaf is illuminated at an angle of 55° by He–Ne laser radiation (λ = 0.63 μm) linearly polarized in the plane of incidence. It has been found that the radiation reflected from a leaf becomes elliptically polarized at observation angles of 55° ± 10°. The ellipticity of the radiation reflected from a leaf depends on the thickness of the leaf plate and the position of the top or undersurface of the leaf relative to the direction of illumination.

Published

2001

8. The gap probability model for canopy thermal infrared emission with non-scattering approximation

Author

Qingyuan Zhang, Changyao Wang, Qinhuo Liu, Yanchun Gao, and Zheng Niu

Subjects

Canopy, Daytime, Scattering, Thermal, Leaf angle distribution, Radiance, Environmental science, Hot spot (veterinary medicine), Leaf area index, Remote sensing

Abstract

To describe canopy emitting thermal radiance precisely and physically is one of the key researches in retrieving land surface temperature (LST) over vegetation-covered regions by remote sensing technology. This work is aimed at establishing gap probability models to describe the thermal emission characteristics in continuous plant, including the basic model and the sunlit model. They are suitable respectively in the nighttime and in the daytime. The sunlit model is the basic model plus a sunlit correcting item which takes the hot spot effect into account. The researches on the directional distribution of radiance and its relationship to canopy structural parameters, such as the leaf area index (LAI) and leaf angle distribution (LAD), were focused. The characteristics of directional radiance caused by temperature differences among components in canopy, such as those between leaf and soil, and between sunlit leaf or soil and shadowed leaf or soil, were analyzed. A well fitting between experimental data and the theoretical calculations shows that the models are able to illustrate the canopy thermal emission generally.

Published

2000

9. The reflection and scattering of light by a plant leaf

Author

V. V. Sikorskii, G. F. Stel’makh, A. V. Sikorskii, and Yu. I. Atrashevskii

Subjects

Maple, Brightness, Materials science, business.industry, Scattering, Quantitative Biology::Tissues and Organs, Radiation, engineering.material, Condensed Matter Physics, Polarization (waves), Light scattering, Azimuth, Optics, engineering, Leaf angle distribution, business, Spectroscopy

Abstract

The spectral polarization characteristics of the visible radiation reflected and scattered by a plant leaf were investigated. Measurements of the spectral brightness coefficient, the directed reflection coefficients, and the degree and azimuth of polarization of radiation reflected from a leaf were performed at different angles of incidence of radiation on the leaf and different angles of observation. More than 500 measurements were performed for 36 samples. Maple (Acer platanoides) leaves from different trees were used as objects of investigation. Peculiarities of the mechanism of formation of the flux of radiation reflected from a plant leaf have been revealed.

Published

1999

10. Leaf orientation and light interception by juvenile Pseudopanax crassifolius(Cunn.) C. Koch in a partially shaded forest environment

Author

Michael J. Clearwater and Kevin S. Gould

Subjects

Canopy, Agronomy, Hemispherical photography, Photosynthetically active radiation, Botany, Leaf angle distribution, Secondary forest, Shading, Biology, Interception, Pseudopanax crassifolius, biology.organism_classification, Ecology, Evolution, Behavior and Systematics

Abstract

Leaf orientations and light environments were recorded for 40 juvenile Pseudopanax crassifolius trees growing in New Zealand in a partially shaded, secondary forest environment. Efficiencies of interception of diffuse and direct light by the observed leaf arrangments were calculated relative to those of three hypothetical leaf arrangements. Canopy gaps above the study plants were unevenly distributed with respect to azimuth and elevation above the horizon. Our results indicate that photosynthetically active radiation (PAR) received from the sides is more important than that received from directly above. In 33 of the plants leaf orientation was found to be significantly clustered towards one azimuth. The mean azimuth and the mean angle of declination were different for each plant. Leaves were steeply declined, and oriented towards the largest canopy gap at each site. Steep leaf angles reduced interception of direct and diffuse PAR when compared to interception by plant with a hypothetical horizontal leaf arrangement. When compared to a hypothetical arrangement with steep leaf declination and a uniform azimuth distribution, the observed leaf arrangement increased the efficiency of interception of diffuse PAR, but had a variable effect on the interception of direct PAR. Results indicate that the developing leaves of juvenile P. crassifolius orient towards the strongest sources of diffuse light, regardless of their value as a source of direct light. By maximising diffuse light interception while reducing direct light interception, leaf orientation may be a partial determinant of the types of habitats exploited by this species. This study emphasises the importance of considering diffuse light interception for plants growing in partially shaded environments.

Published

1995

11. Dense canopy albedo as a function of illumination direction: Dependence on structure and leaf transmittance

Author

T. W. Brakke and J. Otterman

Subjects

Azimuth, Canopy, Physics, Atmospheric Science, Optics, business.industry, Solar zenith angle, Leaf angle distribution, Transmittance, Shading, Albedo, business, Zenith

Abstract

The dependence of the albedo on illumination direction is analyzed by constructing a canopy model in which the individual leaves are planar, Lambertian reflectors. Leaf transmission is treated separately, and is assumed to be proportional to the cosine of the zenith angle of the leaf normal. Effects of shading and obscuration are formulated assuming random distribution of the leaves with respect to the viewing and illumination directions. Variants of the model with different azimuthal leaf distributions are created and discussed as explicit expressions of the viewing/illumination geometry and the canopy characteristics.

Published

1991

12. Light distribution and foliage structure in an oak canopy

Author

Olevi Kull, Bart Kruijt, M. S. J. Broadmeadow, and Patrick Meir

Subjects

Canopy, Ecology, biology, Physiology, Forestry, Plant Science, Molar absorptivity, Spatial distribution, Atmospheric sciences, biology.organism_classification, Fagaceae, Quercus robur, Botany, Leaf angle distribution, Quercus petraea, Leaf area index, Mathematics

Abstract

Leaf angle distribution and shoot bifurcation ratio were measured and related to photon flux density (PFD) distribution in an oak canopy. Leaf angle distribution deviated substantially from random and changed markedly throughout the canopy. The observed leaf angle distribution was described by an ellipsoidal function with the single parameter of the distribution, x, changing from 1.6 at the top of the canopy to 3.2 in the lowest branches. In vertically homogeneous canopies, the extinction coefficient for diffuse radiation is expected to decline with increasing leaf area index (LAI). However, in the canopy studied here, the leaf angle distribution changed with height such that the effective extinction coefficient remained constant. Both shoot bifurcation ratio and leaf number per shoot declined with decreasing PFD inside the canopy. Based on these observed relationships, a simple canopy growth model that assumes horizontal homogeneity of the canopy was constructed. Calculations showed that a steady state, when growth in the upper of the canopy is in equilibrium with decline of lower canopy, the total canopy LAI should equal to 4.3. This predicted value of equilibrium LAI is larger than that estimated from measurements of PFD transmission (LAI=3.3), but smaller than that directly determined by litter collection (LAI=6.2 in 1998). Possible reasons for these discrepancies are discussed.

Published

1999

13. Penetration of sunlight into a canopy: Explicit models based on vertical and horizontal leaf projections

Author

J. Otterman and Thomas W. Brakke

Subjects

Canopy, Sunlight, Atmospheric Science, Planetary boundary layer, Leaf angle distribution, Environmental science, Vertical plane, Penetration (firestop), Horizontal plane, Atmospheric sciences, Zenith, Remote sensing

Abstract

The projections of leaf areas onto a horizontal plane and onto a vertical plane are examined for their utility in characterizing canopies for sunlight penetration (direct beam only) models. These projections exactly specify the penetration if the projections on the principal plane of the normals to the top surfaces of the leaves are in the same quadrant as the sun. Inferring the total leaf area from these projections (and therefore the penetration as a function of the total leaf area) is possible only with a large uncertainty (up to + or - 32 percent) because the projections are a specific measure of the total leaf area only if the leaf angle distribution is known. It is expected that this uncertainty could be reduced to more acceptable levels by making an approximate assessment of whether the zenith angle distribution is that of an extremophile canopy.

Published

1986