Integration of ZiYuan-3 Multispectral and Stereo Data for Modeling Aboveground Biomass of Larch Plantations in North China

Guiying Li,Zhuli Xie,Dengsheng Lu,Xiandie Jiang,Erxue Chen

doi:10.3390/rs11192328

Abstract

Data saturation in optical sensor data has long been recognized as a major factor that causes underestimation of aboveground biomass (AGB) for forest sites having high AGB, but there is a lack of suitable approaches to solve this problem. The objective of this research was to understand how incorporation of forest canopy features into high spatial resolution optical sensor data improves forest AGB estimation. Therefore, we explored the use of ZiYuan-3 (ZY-3) satellite imagery, including multispectral and stereo data, for AGB estimation of larch plantations in North China. The relative canopy height (RCH) image was calculated from the difference of digital surface model (DSM) data at leaf-on and leaf-off seasons, which were extracted from the ZY-3 stereo images. Image segmentation was conducted using eCognition on the basis of the fused ZY-3 multispectral and panchromatic data. Spectral bands, vegetation indices, textural images, and RCH-based variables based on this segment image were extracted. Linear regression was used to develop forest AGB estimation models, where the dependent variable was AGB from sample plots, and explanatory variables were from the aforementioned remote-sensing variables. The results indicated that incorporation of RCH-based variables and spectral data considerably improved AGB estimation performance when compared with the use of spectral data alone. The RCH-variable successfully reduced the data saturation problem. This research indicated that the combined use of RCH-variables and spectral data provided more accurate AGB estimation for larch plantations than the use of spectral data alone. Specifically, the root mean squared error (RMSE), relative RMSE, and mean absolute error values were 33.89 Mg/ha, 29.57%, and 30.68 Mg/ha, respectively, when using the spectral-only model, but they become 24.49 Mg/ha, 21.37%, and 20.37 Mg/ha, respectively, when using the combined model with RCH variables and spectral band. This proposed approach provides a new insight in reducing the data saturation problem.

Highlights

Remote sensing-based aboveground biomass (AGB) estimation has obtained great attention in the past three decades because of the unique characteristics of remote sensing technologies in providing land surface features and the requirement of understanding the spatial patterns and dynamics of AGB
Previous studies have confirmed that a combination of spectral and spatial features is effective for forest AGB estimation, especially for the forest sites with complex forest stand structures [7,12], whereas for the forest sites with relatively simple forest stand structures, for instance, successional forest in the Brazilian Amazon, spectral signatures play more important roles than spatial features [13,14]
The relative canopy height (RCH) was developed from the difference of bi-temporal digital surface model (DSM) data that were extracted from leaf-on and leaf-off ZY-3 stereo images

Summary

Introduction

Remote sensing-based aboveground biomass (AGB) estimation has obtained great attention in the past three decades because of the unique characteristics of remote sensing technologies in providing land surface features and the requirement of understanding the spatial patterns and dynamics of AGB (see review papers [1,2,3,4,5,6]). Previous studies have confirmed that a combination of spectral and spatial features is effective for forest AGB estimation, especially for the forest sites with complex forest stand structures [7,12], whereas for the forest sites with relatively simple forest stand structures, for instance, successional forest in the Brazilian Amazon, spectral signatures play more important roles than spatial features [13,14]. Previous studies show that Landsat data are especially valuable for the AGB estimation of successional forests in the Amazon basin, but are not suitable for primary forests because spectral signatures cannot effectively reflect the small difference of forest stand structures, their AGB may be considerably different [12,15]. In order to reduce the data saturation problem, different approaches may be used, such as stratification of forest types and/or topographic factors, or incorporation of different kinds of data sources, such as optical and radar or lidar [7,8]

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Results

Discussion

Conclusion