Abstract
Fractional vegetation cover (FVC) is an essential land surface parameter for Earth surface process simulations and global change studies. The currently existing FVC products are mostly obtained from low or medium resolution remotely sensed data, while many applications require the fine spatial resolution FVC product. The availability of well-calibrated coverage of Landsat imagery over large areas offers an opportunity for the production of FVC at fine spatial resolution. Therefore, the objective of this study is to develop a general and reliable land surface FVC estimation algorithm for Landsat surface reflectance data under various land surface conditions. Two machine learning methods multivariate adaptive regression splines (MARS) model and back-propagation neural networks (BPNNs) were trained using samples from PROSPECT leaf optical properties model and the scattering by arbitrarily inclined leaves (SAIL) model simulations, which included Landsat reflectance and corresponding FVC values, and evaluated to choose the method which had better performance. Thereafter, the MARS model, which had better performance in the independent validation, was evaluated using ground FVC measurements from two case study areas. The direct validation of the FVC estimated using the proposed algorithm (Heihe: R2 = 0.8825, RMSE = 0.097; Chengde using Landsat 7 ETM+: R2 = 0.8571, RMSE = 0.078, Chengde using Landsat 8 OLI: R2 = 0.8598, RMSE = 0.078) showed the proposed method had good performance. Spatial-temporal assessment of the estimated FVC from Landsat 7 ETM+ and Landsat 8 OLI data confirmed the robustness and consistency of the proposed method. All these results indicated that the proposed algorithm could obtain satisfactory accuracy and had the potential for the production of high-quality FVC estimates from Landsat surface reflectance data.
Highlights
Fractional vegetation cover (FVC), which is defined as the percentage of the vertical projected area of green vegetation to the total ground area [1,2], is an important parameter for many environmental and climate-related modeling applications [3,4,5], such as dynamic global vegetation models [6], soil erosion models [7], and weather prediction models [3]
The performances of the multivariate adaptive regression splines (MARS) and back-propagation neural networks (BPNNs) were evaluated over the test dataset (2880 samples), corresponding to Landsat 7 ETM+ and Landsat 8
Consistently shows a slightly better result than that of BPNNs. These results indicated that MARS was consistently shows a slightly better result than that of BPNNs
Summary
Fractional vegetation cover (FVC), which is defined as the percentage of the vertical projected area of green vegetation to the total ground area [1,2], is an important parameter for many environmental and climate-related modeling applications [3,4,5], such as dynamic global vegetation models [6], soil erosion models [7], and weather prediction models [3]. The estimation of FVC from remote sensing data at the regional, even global scales is of great significance. From the methodological point of view, there are three main FVC estimation methods using remotely sensed data: empirical methods, pixel un-mixing modeling, and physical model-based methods [9,10,11]. The empirical methods are based on the statistical relationships between FVC and spectral band reflectance or vegetation indices from airborne or satellite spectra [8,12]. The normalized difference vegetation index (NDVI) derived from the reflectance of the red and near-infrared (NIR) bands is the most frequently used index for regression models development of FVC estimation [11].
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