4.7 Article

Vegetation Types Mapping Using Multi-Temporal Landsat Images in the Google Earth Engine Platform

Journal

REMOTE SENSING
Volume 13, Issue 22, Pages -

Publisher

MDPI
DOI: 10.3390/rs13224683

Keywords

vegetation types classification; multi-temporal images; machine learning; Google Earth Engine; NDVI

Funding

  1. Shahrekord University
  2. European Research Council (ERC) [ERC-2017-STGSENTIFLEX, 755617]

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This study utilized multi-temporal datasets to improve the accuracy of VTs classification in Central Zagros, Iran, with results showing that multi-temporal datasets favored accurate VTs classification. The research highlights the importance of open access cloud-computing platforms like the Google Earth Engine for identifying optimal periods and multi-temporal imagery for VTs classification.
Vegetation Types (VTs) are important managerial units, and their identification serves as essential tools for the conservation of land covers. Despite a long history of Earth observation applications to assess and monitor land covers, the quantitative detection of sparse VTs remains problematic, especially in arid and semiarid areas. This research aimed to identify appropriate multi-temporal datasets to improve the accuracy of VTs classification in a heterogeneous landscape in Central Zagros, Iran. To do so, first the Normalized Difference Vegetation Index (NDVI) temporal profile of each VT was identified in the study area for the period of 2018, 2019, and 2020. This data revealed strong seasonal phenological patterns and key periods of VTs separation. It led us to select the optimal time series images to be used in the VTs classification. We then compared single-date and multi-temporal datasets of Landsat 8 images within the Google Earth Engine (GEE) platform as the input to the Random Forest classifier for VTs detection. The single-date classification gave a median Overall Kappa (OK) and Overall Accuracy (OA) of 51% and 64%, respectively. Instead, using multi-temporal images led to an overall kappa accuracy of 74% and an overall accuracy of 81%. Thus, the exploitation of multi-temporal datasets favored accurate VTs classification. In addition, the presented results underline that available open access cloud-computing platforms such as the GEE facilitates identifying optimal periods and multitemporal imagery for VTs classification.

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