Forest Type Classification Based on Integrated Spectral-Spatial-Temporal Features and Random Forest Algorithm—A Case Study in the Qinling Mountains

• Published in: Forests Vol. 10; no. 7; p. 559
• Main Authors: Cheng, Kai, Wang, Juanle
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 04.07.2019
• Subjects: Accuracy; Algorithms; Biodiversity; Classification; Climate change; Coniferous forests; Correlation analysis; Deciduous forests; Discrimination; Evaluation; Forest management; forest type; Fourier analysis; Harmonic analysis; Land cover; Land use; Mountains; Optimization; Phenology; random forest; random forest-recursive feature elimination; Remote sensing; sentinel-2 time series; Shrubs; Spectra; spectral-spatial-temporal features; Sustainability management; Temporal variations; Time series; Topography; Vegetation; Vegetation index; Qinling Mountains; United States > US; China
• ISSN: 1999-4907; 1999-4907
• DOI: 10.3390/f10070559

Spectral, spatial, and temporal features play important roles in land cover classification. However, limitations still exist in the integrated application of spectral-spatial-temporal (SST) features for forest type discrimination. This paper proposes a forest type classification framework based on SST features and the random forest (RF) algorithm. The SST features were derived from time-series images using original bands, vegetation index, gray-level correlation matrix, and harmonic analysis. Random forest-recursive feature elimination (RF-RFE) was used to optimize high-dimensional and correlated feature space, and determine the optimal SST feature set. Then, the classification was carried out using an RF classifier and the optimized SST feature set. This method was applied in the Qinling Mountains using Sentinel-2 time-series images. A total of 21 SST features were obtained through the RF-RFE method, and their importance was evaluated using the Gini index. The results indicated that spectral features contribute the most to separating shrubs, spatial features are more suitable for discrimination among evergreen forest types, and temporal features are more useful for evergreen forest, deciduous forest, and shrub types. The forest type map was generated based on the optimal SST feature set and RF algorithm, and evaluated based on an agreement with the validation dataset. The results showed that this integrated method is reliable, with an overall accuracy of 86.88% and kappa coefficient of 0.86, and can support forest type sustainable management and mapping at the local scale.