Abstract
Coastal wetlands are a critical component of the coastal landscape that are increasingly threatened by sea level rise and other human disturbance. Periodically mapping wetland distribution is crucial to coastal ecosystem management. Ensemble algorithms (EL), such as random forest (RF) and gradient boosting machine (GBM) algorithms, are now commonly applied in the field of remote sensing. However, the performance and potential of other EL methods, such as extreme gradient boosting (XGBoost) and bagged trees, are rarely compared and tested for coastal wetland mapping. In this study, we applied the three most widely used EL techniques (i.e., bagging, boosting and stacking) to map wetland distribution in a highly modified coastal catchment, the Manning River Estuary, Australia. Our results demonstrated the advantages of using ensemble classifiers to accurately map wetland types in a coastal landscape. Enhanced bagging decision trees, i.e., classifiers with additional methods to increasing ensemble diversity such as RF and weighted subspace random forest, had comparably high predictive power. For the stacking method evaluated in this study, our results are inconclusive, and further comprehensive quantitative study is encouraged. Our findings also suggested that the ensemble methods were less effective at discriminating minority classes in comparison with more common classes. Finally, the variable importance results indicated that hydro-geomorphic factors, such as tidal depth and distance to water edge, were among the most influential variables across the top classifiers. However, vegetation indices derived from longer time series of remote sensing data that arrest the full features of land phenology are likely to improve wetland type separation in coastal areas.
Highlights
Coastal wetlands are a critical component of the coastal landscape, representing unique and important habitat for many species ranging from marine megafauna [1] to waterbirds to terrestrial mammals [3]
The rank of performance of the classifiers is consistent between the performance metrics kappa and overall accuracy (OAA) but not AUC and mean balanced accuracy (MBA) (Figure 2)
This study has demonstrated the advantages of using ensemble classifiers to accurately map wetland types in a coastal landscape
Summary
Coastal wetlands are a critical component of the coastal landscape, representing unique and important habitat for many species ranging from marine megafauna [1] to waterbirds ( shorebirds, [2]) to terrestrial mammals [3]. They provide several ecosystem services, including the removal of nutrients and other pollutants, stabilising the shoreline, and carbon sequestration [4,5,6]. The growing awareness of the rapid loss of coastal wetlands and the services we derive from them has resulted in extensive studies to quantify the problem, understand its underlying causes, and assess possible solutions [9]. Recent advances in sensor design and geospatial analysis techniques are making remote sensing systems practical and attractive to manage coastal landscapes through mapping and monitoring coastal wetland vegetation [17] as well as other applications [14,18]
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