Foliage clumping index of main vegetation types  in Daxing’an Mountains, Northeast China

doi:10.13287/j.1001-9332.201703.011

Abstract

Abstract: The foliage clumping index quantifies the cluster degree of the leaf spatial distribution under random canopy. It is of comparable importance for establishment of ecological models. MODIS BRDF model parameter products (MCD43A1 data) and land cover types (MCD12Q1 data) were used in this study to simulate the reflectivity of the hot spots and dark spots, and calculate the normalized difference between hotspot and darkspot (NDHD) based on the Ross-Li semi-empirical model. Least square method was then used to simulate the relationship between NDHD and the foliage clumping index and foliage clumping index products of 500-m resolution in August 2014 were retrieved. Measurements of the foliage clumping index in Daxing’an Mountains were conducted by using the TRAC (Tracing Radiation and Architecture of Canopies) sampling instrument for mo-del validation and analysis. Results showed that it was a feasible algorithm to retrieve clumping index from MCD43A1 product with the correlation of simulated data and the measured data of significance (R²=0.8879). The MODIS near infrared wave band was more sensitive than that on red band to foliage clumping index change. With the increase of the solar zenith angle, the clumping index retrieved by Ross-Li model had a linear increase (R²=0.9699), which indicated that the foliage clumping index related to the solar zenith angle.

HUANG Ting, FAN Wen-yi, MAO Xue-gang, YU Ying. Foliage clumping index of main vegetation types in Daxing’an Mountains, Northeast China[J]. Chinese Journal of Applied Ecology, 2017, 28(3): 757-762.

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Foliage clumping index of main vegetation types in Daxing’an Mountains, Northeast China

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