<title>Reduction of the topographic effects in SPOT imagery: an examination of the Minnaert model</title>

Studying spatial patterns and habitat association of plant communities may provide understanding of the ecological mechanisms and processes that maintain species coexistence. To conduct assessments of correlation between community compositions and habitat association, we used data from two topographically different plots with 2 ha area in tropical evergreen forests with the variables recorded via grid systems of 10 × 10 m subplots in Northern-Central Vietnam. First, we tested the relationship between community composition and species diversity indices considering the topographical variables. We then assessed the interspecific interactions of 20 dominant plant species using the nearest-neighbor distribution function, Dij(r), and Ripley’s K-function, Kij(r). Based on the significant spatial association of species pairs, indices of interspecific interaction were calculated by the quantitative amounts of the summary statistics. The results showed that (i) community compositions were significantly influenced by the topographic variables and (ii) almost 50% significant pairs of species interactions were increased with increasing spatial scales up to 10–15 m, then declined and disappeared at scales of 30–40 m. Segregation and partial overlap were the dominant association types and disappeared at larger spatial scales. Spatial segregation, mixing, and partial overlap revealed the important species interactions in maintaining species coexistence under habitat heterogeneity in diverse forest communities.

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Modeling topographic effects on net ecosystem productivity of boreal black spruce forests

Tree Physiology ◽

10.1093/treephys/24.1.1 ◽

2004 ◽

Vol 24 (1) ◽

pp. 1-18 ◽

Cited By ~ 57

Author(s):

R. F. Grant

Keyword(s):

Black Spruce ◽

Topographic Effects ◽

Net Ecosystem Productivity ◽

Ecosystem Productivity ◽

Spruce Forests

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The Behavior of Jet Currents over a Continental Slope Topography with a Possible Application to the Northern Current

Journal of Physical Oceanography ◽

10.1175/jpo2705.1 ◽

2005 ◽

Vol 35 (5) ◽

pp. 790-810 ◽

Cited By ~ 14

Author(s):

M. M. Flexas ◽

G. J. F. van Heijst ◽

R. R. Trieling

Keyword(s):

High Speed ◽

Bottom Topography ◽

Laboratory Model ◽

Topographic Effects ◽

Topographic Slope ◽

Eddy Formation ◽

Slow Flows ◽

Bottom Depth ◽

Source Sink ◽

Northern Current

Abstract The Northern Current is a slope current in the northwest Mediterranean that shows high mesoscale variability, generally associated with meander and eddy formation. A barotropic laboratory model of this current is used here to study the role of the bottom topography on the current variability. For this purpose, a source–sink setup in a cylindrical tank placed on a rotating table is used to generate an axisymmetric barotropic current. To study inviscid topographic effects, experiments are performed over a topographic slope and also over a constant-depth setup, the latter being used as a reference for the former. With the aim of obtaining a fully comprehensive view of the vorticity balance at play, the flow may be forced in either azimuthal direction, leading to a “westward” prograde current (similar to the Northern Current) or an “eastward” retrograde current. For slow flows, eastward and westward currents showed similar patterns, dominated by Kelvin–Helmholtz-type instabilities. For high-speed flows, eastward and westward currents showed very different behavior. In eastward currents, the variability is observed to concentrate toward the center of the jet and shows strong meandering formation. Westward currents, instead, showed major variability toward the edges of the jet, together with a strong variability over the uppermost slope, which has been associated here with a topographic Rossby wave trapped over the shelf break. The differences between eastward and westward jets are explained through the balance between shear-induced and topographically induced vorticity at play in each case. Moreover, a model of jets over a beta plane is successfully applied here, allowing its extension to any ambient potential vorticity gradient caused either by latitudinal or bottom depth changes.

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Quasi-3-D model to describe topographic effects on non-spherical comet nucleus evolution

Planetary and Space Science ◽

10.1016/j.pss.2008.08.020 ◽

2008 ◽

Vol 56 (15) ◽

pp. 1977-1991 ◽

Cited By ~ 16

Author(s):

J. Lasue ◽

M.C. De Sanctis ◽

A. Coradini ◽

G. Magni ◽

M.T. Capria ◽

...

Keyword(s):

Topographic Effects ◽

Comet Nucleus ◽

D Model

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Precise computation of the direct and indirect topographic effects of Helmert's 2nd method of condensation using SRTM30 digital elevation model

Journal of Geodetic Science ◽

10.2478/v10156-011-0009-8 ◽

2011 ◽

Vol 1 (4) ◽

pp. 305-312 ◽

Cited By ~ 2

Author(s):

Y. Wang

Keyword(s):

Standard Deviation ◽

Digital Elevation Model ◽

Outer Zone ◽

Mean Value ◽

Constant Density ◽

Topographic Effects ◽

Topographic Effect ◽

Digital Elevation ◽

The Mean ◽

Elevation Model

Precise computation of the direct and indirect topographic effects of Helmert's 2nd method of condensation using SRTM30 digital elevation modelThe direct topographic effect (DTE) and indirect topographic effect (ITE) of Helmert's 2nd method of condensation are computed using the digital elevation model (DEM) SRTM30 in 30 arc-seconds globally. The computations assume a constant density of the topographic masses. Closed formulas are used in the inner zone of half degree, and Nagy's formulas are used in the innermost column to treat the singularity of integrals. To speed up the computations, 1-dimensional fast Fourier transform (1D FFT) is applied in outer zone computations. The computation accuracy is limited to 0.1 mGal and 0.1cm for the direct and indirect effect, respectively.The mean value and standard deviation of the DTE are -0.8 and ±7.6 mGal over land areas. The extreme value -274.3 mGal is located at latitude -13.579° and longitude 289.496°, at the height of 1426 meter in the Andes Mountains. The ITE is negative everywhere and has its minimum of -235.9 cm at the peak of Himalayas (8685 meter). The standard deviation and mean value over land areas are ±15.6 cm and -6.4 cm, respectively. Because the Stokes kernel does not contain the zero and first degree spherical harmonics, the mean value of the ITE can't be compensated through the remove-restore procedure under the Stokes-Helmert scheme, and careful treatment of the mean value in the ITE is required.

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A Numerical Study on the Seismic Site Response of Rocky Valleys with Irregular Topographic Conditions

Journal of Multiscale Modelling ◽

10.1142/s1756973718500117 ◽

2019 ◽

Vol 10 (04) ◽

pp. 1850011 ◽

Cited By ~ 1

Author(s):

Mohammad Katebi ◽

Behrouz Gatmiri ◽

Pooneh Maghoul

Keyword(s):

Seismic Analysis ◽

Numerical Study ◽

Site Response ◽

Slope Angle ◽

Response Spectra ◽

Topographic Effects ◽

Combined Effects ◽

Acceleration Response ◽

Vertically Propagating ◽

Maximum Amplification

This paper investigates topographic effects of rocky valleys with irregular topographic conditions subjected to vertically propagating SV waves of Ricker type using a boundary element code. Valleys with two intersecting slopes, [Formula: see text] and [Formula: see text], are modelled in order to study their combined effects on ground motion. Presented in the form of pseudo-acceleration response spectra, results of this work can be extended to similar topographies. The main findings are: (i) [Formula: see text] (the first slope angle) and [Formula: see text] (L is the half width of the valley and [Formula: see text] is its corresponding height) have amplifying effects, and [Formula: see text] (the second slope angle) has de-amplifying effects on the site response. (ii) [Formula: see text] has a straight effect on intensifying the effects of both [Formula: see text] and [Formula: see text]. (iii) The combined effects of slope angles have been found to be important in modifying the response so more than a single slope should be considered for seismic analysis. (iv) Engineers should use the maximum amplification of 2.4 in case of valleys with the first and second slope angles below [Formula: see text].

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