Abstract
Topographic correction can reduce the influences of topographic factors and improve the accuracy of forest tree species classification when using remote-sensing data to investigate forest resources. In this study, the Mount Taishan forest farm is the research area. Based on Landsat 8 OLI data and field survey subcompartment data, four topographic correction models (cosine model, C model, solar-canopy-sensor (SCS)+C model and empirical rotation model) were used on the Google Earth Engine (GEE) platform to carry out algorithmic data correction. Then, the tree species in the study area were classified by the random forest method. Combined with the tree species classification process, the topographic correction effects were analyzed, and the effects, advantages and disadvantages of each correction model were evaluated. The results showed that the SCS+C model and empirical rotation model were the best models in terms of visual effect, reducing the band standard deviation and adjusting the reflectance distribution. When we used the SCS+C model to correct the remote-sensing image, the total accuracy increased by 4% when using the full-coverage training areas to classify tree species and by nearly 13% when using the shadowless training area. In the illumination condition interval of 0.4–0.6, the inconsistency rate decreased significantly; however, the inconsistency rate increased with increasing illumination condition values. Topographic correction can enhance reflectance information in shaded areas and can significantly improve the image quality. Topographic correction can be used as a pretreatment method for forest species classification when the study area’s dominant tree species are in a low light intensity area.
Highlights
Forests are among the important components of the global terrestrial ecosystem
Based on Landsat 8 data, we developed four topographic correction models on the Google Earth Engine (GEE) platform, and their effectiveness on forest tree species classification were compared in detail
The SCS+C model and empirical rotation model were the best models in terms of visual effects, reducing band standard deviation (SD) and adjusting the reflectance distribution
Summary
Forests are among the important components of the global terrestrial ecosystem. Whether from the perspective of forest ecology or from a service perspective in which the function of a forest is to provide wood and other products, it is necessary to obtain information on forest resources over time. Spectral information from satellite imagery can be used to effectively identify forest tree species [5,6,7,8] Such information is widely used in the investigation of forest species resources because of its effectiveness in species classification and low-cost advantages. Remote-sensing technology reduces manpower and material resource consumption, improves the quantitative description of resource information and improves survey timeliness better than traditional field investigations. The key to such forest tree resource investigation work is the analysis of spectral information from remote-sensing images and the determination of the tree species category according to the different spectral characteristics of tree resources
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