Optimising Satellite-Derived Bathymetry using Optical Satellite Imagery over the Adelaide Metropolitan Coast

This study enhances the accuracy of optical satellite-derived bathymetric datasets in a shallow, mixed benthic, low wave energy coastal environment by identifying the optimal combination of input satellite imagery, spectral bands, and empirical derivation techniques. A total of 109 unique derivations were performed based on an exhaustive combination of these variables. These deri-vations were calibrated and validated using 1,064,536 ground truth observations. Results revealed that the multiband linear technique consistently outperformed the band ratio technique, achieving the best results with input bands from PlanetScope SuperDove imagery. The top-performing derivation attained an R² value of 0.94 and an RMSE of 0.41m when compared with ground truth data, surpassing published RMSE values in similar environments. Further validation beyond the calibration site confirmed its effectiveness within depths of 0.5m to 5m, demonstrating an RMSE of 0.51m, albeit with a gradual reduction in accuracy with increasing depth. This research not only identifies the optimal combination of variables but also provides valuable insights into how the number of input bands, their spatial resolution, and their specific spectral properties (central wavelength and bandwidth) influence the quality of satellite-derived bathymetry datasets. Challenges remain in accounting for mixed benthic types and their variable albedos.