Núm. 37 (2022), Sediment Transport and Morphology
Núm. 37 (2022)

S2SHORES: A PYTHON LIBRARY FOR ESTIMATING COASTAL BATHYMETRY

Sediment Transport and Morphology
Publicado 2023-09-01
  • Erwin W. J. Bergsma
  • Rafael Almar
  • Alain Giros
  • Solange Lemai-Chenevier
  • Gregoire Thoumyre
  • Stephanie Artigues
  • Thierry Garlan
  • Romain Degoul
Erwin W. J. Bergsma
Rafael Almar
Alain Giros
Solange Lemai-Chenevier
Gregoire Thoumyre
Stephanie Artigues
Thierry Garlan
Romain Degoul
ICCE 2022
DOC (Inglés)

Cómo citar

S2SHORES: A PYTHON LIBRARY FOR ESTIMATING COASTAL BATHYMETRY. (2023). Coastal Engineering Proceedings, 37, sediment.36. https://doi.org/10.9753/icce.v37.sediment.36
ACM ACS APA ABNT Chicago Harvard IEEE MLA Turabian Vancouver AMA

Descargar cita

Endnote/Zotero/Mendeley (RIS) BibTeX

Resumen

Understanding coastal zone dynamics covering large spatial and dense temporal scales is paramount to understand and mitigate emerging coastal issues relating to climatological changes. However, the uncertainties on the coastal zone risks are still too large to predict effectively impacts on an overall increasing coastal population. Prediction, by deploying numerical models for waves, tide, and currents in the coastal zone, requires accurate and up-to-date bottom boundary conditions (bathymetry) to simulate coastal hydrodynamics accurately, let alone predict morphological change. There are three main approaches for estimating coastal bathymetry using satellite sensors: 1) linking water depth to a spectral response (colour), 2) underwater photogrammetry and 3) linking wave kinematics to a water depth. Here, we present S2Shores (Satellite to Shores), a python library that detects and extracts local wave parameters (geometry and kinematics) to derive coastal bathymetry.
DOC (Inglés)

Referencias

Abileah, (2013). Mapping near shore bathymetry using wave kinematics in a time series of worldview-2 satellite images. In: 2013 IEEE International Geoscience and Remote Sensing Symposium - IGARSS. pp. 2274–2277.

Almar et al. (2019). Wave-derived coastal bathymetry from satellite video imagery: A showcase with Pleiades persistent mode. Remote Sensing of Environment, 231, 111263

Almar et al. (2022). Coastal Topo-Bathymetry from a Single-Pass Satellite Video: Insights in Space-Videos for Coastal Monitoring at Duck Beach (NC, USA). Remote Sens., 14(7), 1529

Almar et al. (2021). Global satellite-based coastal bathymetry from waves. Remote Sensing, 13(22), 4628

Bergsma et al. (2019). Radon-Augmented Sentinel-2 Satellite Imagery to Derive Wave-Patterns and Regional Bathymetry. Remote Sens. 2019, 11, 1918.

Bergsma and Almar (2020). Coastal coverage of ESA' Sentinel 2 mission. Advances in Space Research.

Bergsma et al. (2021). Coastal morphology from space: A showcase of monitoring the topography-bathymetry continuum. Remote Sensing of Environment, 261, 112469.

Bergsma et al. (2022). Wave variability along the world’s continental shelves and coasts: monitoring opportunities from satellite Earth observation. Advances in Space Research.

Binet et al. (2022). Accurate Sentinel-2 inter-band time delays. ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences, -1-2022, 57-66.

Caballero et al. (2019). Preliminary assessment of turbidity and chlorophyll impact on bathymetry derived from sentinel-2a and sentinel-3a satellites in south Florida. Remote Sensing 11 (6).

Daly et al. (2022) The New Era of Regional Coastal Bathymetry from Space: A Showcase for West Africa using Sentinel-2 Imagery. Remote Sensing of Environment.

van Dongeren et al. (2008). Beach wizard: Nearshore bathymetry estimation through assimilation of model computations and remote observations, CoastalEng., 55, 1016–1027

Gawehn et al. (2022). Depth Inversion from Wave Frequencies in Temporally Augmented Satellite Video. Remote Sens. 2022, 14, 1847

Hodul et al. (2018). Satellite derived photogrammetric bathymetry. ISPRS Journal of Photogrammetry and Remote Sensing. Vol 142, pp. 268-277.

Holman et al. (2013). cBathy: A robust algorithm for estimating nearshore bathymetry. J. Geophys. Res. 118, 1–15.

International Hydrographic Organization (2020) IHO Standards for Hydrographic Surveys, Edition 6.0.0, September 2020. Monaco, International Hydrographic Organization, 41pp.

Lyzenga (1978). Passive remote sensing techniques for mapping water depth and bottom features. Appl. Opt. 17 (3), 379–383

Melet et al. (2020). Earth observations for monitoring marine coastal hazards and their drivers. Surveys in Geophysics, 41(6), 1489-1534.

Turner et al. (2021). Coastal Engineering in the satellite era. Coastal Engineering, 167, 103919

International Hydrographic Organization (2020) IHO Standards for Hydrographic Surveys, Edition 6.0.0, September 2020. Monaco, International Hydrographic Organization, 41pp.

Rocklin, M. (2015). Dask: Parallel computation with blocked algorithms and task scheduling. In Proceedings of the 14th python in science conference.

Creative Commons License

Esta obra está bajo una licencia internacional Creative Commons Atribución 4.0.

Derechos de autor 2023 Erwin W. J. Bergsma, Rafael Almar, Alain Giros, Solange Lemai-Chenevier, Gregoire Thoumyre, Stephanie Artigues, Thierry Garlan, Romain Degoul