Publications

Fang, HL; Liu, WW; Li, WJ; Wei, SS (2018). Estimation of the directional and whole apparent clumping index (ACI) from indirect optical measurements. ISPRS JOURNAL OF PHOTOGRAMMETRY AND REMOTE SENSING, 144, 1-13.

Abstract
Canopy clumping index (CI) indicates the non-random distribution of foliage components in space, and is an important structural parameter for better understanding the radiative transfer process in a canopy. The apparent clumping index (ACI), calculated using the logarithmic gap fraction averaging method, is reported by the LAI-2200 Plant Canopy Analyzer. While LAI-2200 calculates the gap fraction and ACI from different conical rings, calculation of ACI for other geometric units (e.g., an angular cell or an azimuth sector) and instruments has been lacked. Building upon the LAI-2200 ACI, this study compares the ACIs calculated for different geometric spaces from different optical instruments. The field data obtained from seasonal continuous measurements with LAI-2200, digital hemispheric photography (DHP), and AccuPAR at a paddy rice field in northeast China were used to calculate the directional ACIs at different levels-a directional cell (Omega(A)(theta,phi)), a concentric ring (Omega(A)(theta)), an azimuth sector (Omega(A)(phi)), and over the horizontal landscape (Omega(A)(nu)). The whole ACIs were calculated from the directional ACIs with an angular integration method, a simple averaging method, a non-linear correction method, and a variance-to-mean ratio method. The directional ACIs for paddy rice generally follow the ord er of Omega(A)(theta,phi) < Omega(A)(theta) and Omega(A)(phi) < Omega(A)(nu), displaying an increase of foliage randomness with the segment size. The Omega(A)(theta,phi) estimated from DHP indicates canopy clumping at the finest level and is consistent with the CIs estimated from the logarithmic averaging method (Omega(LX)) and the ratio method (the effective leaf area index (LAI(e)) divided by the LAI). The ACI metrics expand the current CI metrics and can be obtained with different optical instruments. The expanded metrics can be applied in the canopy radiative transfer modeling and in the estimation of canopy biophysical parameters for other vegetation ecosystems.

DOI:
10.1016/j.isprsjprs.2018.06.022

ISSN:
0924-2716