Satellite-Derived Topography and Morphometry for VHR Coastal Habitat Mapping: The Pleiades-1 Tri-Stereo Enhancement

The evolution of the coastal fringe is closely linked to the impact of climate change, specifically increases in sea level and storm intensity. The anthropic pressure that is inflicted on these fragile environments strengthens the risk. Therefore, numerous research projects look into the possibility of monitoring and understanding the coastal environment in order to better identify its dynamics and adaptation to the major changes that are currently taking place in the landscape. This new study aims to improve the habitat mapping/classification at Very High Resolution (VHR) using Pleiades-1-derived topography, its morphometric by-products, and Pleiades-1-derived imageries. A tri-stereo dataset was acquired and processed by image pairing to obtain nine digital surface models (DSM) that were 0.50 m pixel size using the free software RSP (RPC Stereo Processor) and that were calibrated and validated with the 2018-LiDAR dataset that was available for the study area: the Emerald Coast in Brittany (France). Four morphometric predictors that were derived from the best of the nine generated DSMs were calculated via a freely available software (SAGA GIS): slope, aspect, topographic position index (TPI), and TPI-based landform classification (TPILC). A maximum likelihood classification of the area was calculated using nine classes: the salt marsh, dune, rock, urban, field, forest, beach, road, and seawater classes. With an RMSE of 4 m, the DSM#2-3_1 (from images #2 and #3 with one ground control point) outperformed the other DSMs. The classification results that were computed from the DSM#2-3_1 demonstrate the importance of the contribution of the morphometric predictors that were added to the reference Red-Green-Blue (RGB, 76.37% in overall accuracy, OA). The best combination of TPILC that was added to the RGB + DSM provided a gain of 13% in the OA, reaching 89.37%. These findings will help scientists and managers who are tasked with coastal risks at VHR.

Automated summary

The study aims to enhance habitat mapping/classification at Very High Resolution (VHR) using Pleiades-1-derived topography and morphometric predictors, leading to a significant improvement in classification accuracy. The incorporation of morphometric predictors with RGB + DSM yielded a substantial increase in overall accuracy, providing valuable support for coastal risk management at VHR.