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Monitoring of the sediment dynamics along a sandy shoreline by means of airborne hyperspectral remote sensing and LIDAR: a case study in Belgium
Deronde, B.; Houthuys, R.; Henriet, J.-P.; Van Lancker, V. (2008). Monitoring of the sediment dynamics along a sandy shoreline by means of airborne hyperspectral remote sensing and LIDAR: a case study in Belgium. Earth Surf. Process. Landforms 33(2): 280-294. dx.doi.org/10.1002/esp.1545
In: Earth Surface Processes and Landforms: the Journal of the British Geomorphological Research Group. John Wiley/Wiley: Chichester, Sussex; New York. ISSN 0197-9337; e-ISSN 1096-9837, more
Peer reviewed article  

Available in  Authors | Dataset 

Keywords
    Accretion > Beach accretion > Beach nourishment
    Acquisition > Data acquisition
    Earth sciences > Geology > Geomorphology > Coastal morphology > Beach morphology
    Lidar
    Monitoring
    Remote sensing
    Remote sensing > Geosensing > Airborne sensing
    Shorelines
    Statistics
    Topographic features > Landforms > Coastal landforms > Beaches
    Transport > Sediment transport
    ANE, Belgium, Knokke-Heist [Marine Regions]; ANE, Belgium, Koksijde [Marine Regions]; Belgium, Zeebrugge [Marine Regions]
    Marine/Coastal
Author keywords
    airborne hyperspectral remote sensing; LIDAR; beach morphodynamics;sediment transport; sandy shoreline; Belgium

Authors  Top | Dataset 
  • Deronde, B., more
  • Houthuys, R., more
  • Henriet, J.-P., more
  • Van Lancker, V., more

Abstract
    Airborne hyperspectral data and airborne laserscan or LIDAR data were applied to analyse the sediment transport and the beach morphodynamics along the Belgian shoreline. Between 2000 and 2004, four airborne acquisitions were performed with both types of sensor. The hyperspectral data were classified into seven sand type classes following a supervised classification approach, in which feature selection served to reduce the number of bands in the hyperspectral data. The seven classes allowed us to analyse the spatial dynamics of specific sediment volumes. The technique made it possible to distinguish the sand used for berm replenishment works or for beach nourishments from the sand naturally found on the backshore and the foreshore. Subtracting sequential DTMs (digital terrain models) resulted in height difference maps indicating the erosion and accretion zones. The combination of both data types, hyperspectral data and LIDAR data, provides a powerful tool, suited to analyse the dynamics of sandy shorelines. The technique was demonstrated on three sites along the Belgian shoreline: Koksijde, located on the West Coast and characterized by wide accretional beaches, influenced by dry berm replenishment works and the construction of groins; Zeebrugge, on the Middle Coast, where a beach nourishment was executed one year before the acquisitions started and where the dams of the harbour of Zeebrugge are responsible for the formation of a large accretional beach, and Knokke-Heist, located on the East Coast and characterized by narrow, locally reflective, beaches, heavily influenced by nourishment activities. The methodology applied allowed retrieval of the main sediment transport directions as well as the amount of sediment transported. It proved to be specifically suited to follow up the redistribution and the re-sorting of the fill in beach nourishment areas.

Dataset
  • Hyperspectrale vliegtuigopnamen strand Vlaamse kust, geïntegreerd met LIDAR, more

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