Leveraging Google Earth Engine platform to characterize and map small seasonal wetlands in the semi-arid environments of South Africa

https://doi.org/10.1016/j.scitotenv.2021.150139Get rights and content

Highlights

There is a great concern that small semi-arid wetlands are not routinely monitored.

Monitoring of small wetlands using optical data has remained a challenge.

Google Earth Engine platform was used to study small wetlands in Limpopo.

Google Earth Engine provides new opportunities to improve wetlands monitoring.

Findings underscore the relevance of GEE in studying small and seasonal wetlands.

Abstract

Although significant scientific research strides have been made in mapping the spatial extents and ecohydrological dynamics of wetlands in semi-arid environments, the focus on small wetlands remains a challenge. This is due to the sensing characteristics of remote sensing platforms and lack of robust data processing techniques. Advancements in data analytic tools, such as the introduction of Google Earth Engine (GEE) platform provides unique opportunities for improved assessment of small and scattered wetlands. This study thus assessed the capabilities of GEE cloud-computing platform in characterising small seasonal flooded wetlands, using the new generation Sentinel 2 data from 2016 to 2020. Specifically, the study assessed the spectral separability of different land cover classes for two different wetlands detected, using Sentinel-2 multi-year composite water and vegetation indices and to identify the most suitable GEE machine learning algorithm for accurately detecting and mapping semi-arid seasonal wetlands. This was achieved using the object based Random Forest (RF), Support Vector Machine (SVM), Classification and Regression Tree (CART) and Naïve Bayes (NB) advanced algorithms in GEE. The results demonstrated the capabilities of using the GEE platform to characterize wetlands with acceptable accuracy. All algorithms showed superiority, in mapping the two wetlands except for the NB method, which had lowest overall classification accuracy. These findings underscore the relevance of the GEE platform, Sentinel-2 data and advanced algorithms in characterizing small and seasonal semi-arid wetlands.

Abbreviations

GEE
Google Earth Engine
RF
Random Forest
SVM
Support Vector Machine
CART
Classification and Regression Tree
NB
Naïve Bayes
MODIS
Moderate Resolution Imaging Spectroradiometer
SPOT
Satellite Pour I'Obeservation de la Terre
MA
Microsoft Azure
AWS
Amazon Web Service
NOAA
National Oceanographic and Atmospheric Administration
AHRRRM
Advanced High-Resolution Rapid Refresh Model
NOAA AVHRR
National Oceanographic and Atmospheric Administration Advanced Very High-Resolution Radiometer
(ALOS)
Advanced Land Observing Satellite
NDVI
Normalised Difference Vegetation Index
EVI
Enhanced Vegetation Index
LTRB
Limpopo Transboundary River Basin
MAP
Mean Annual Precipitation
GPS
Geographical Positioning System
TOA
Top of the Atmosphere
NDWI
Normalised Difference Water Index
MSAVI
Modified Soil Adjusted Vegetation Index
OBIA
Object Based Image Analysis
SNIC
Simple Non-Iterative Clustering
NIR
Near Infrared
OA
overall accuracy
JM
Jeffries Matusita
WeMAST
Wetland Monitoring and Assessment Services for Transboundary Basins in Southern Africa
(EU Africa GMES)
European Union-Africa Global Monitoring for Environmental Security
SWIR
Short-wave infrared

Keywords

Limpopo River Basin
Object-based classification
Machine learning algorithm
Wetland mapping
Wetland condition
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