FIELD MEASUREMENTS OF VERY OBLIQUE WAVE RUN-UP AND OVERTOPPING WITH LASER SCANNERS
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How to Cite

Oosterlo, P., Hofland, B., Meer, J. W. van der, Overduin, M., & Steendam, G. J. (2020). FIELD MEASUREMENTS OF VERY OBLIQUE WAVE RUN-UP AND OVERTOPPING WITH LASER SCANNERS. Coastal Engineering Proceedings, (36v), waves.20. https://doi.org/10.9753/icce.v36v.waves.20

Abstract

Oosterlo et al. (2019) developed a system using two terrestrial laser scanners, which can measure run-up heights, depths and velocities of waves on a dike in field situations. The system has now been placed next to two overtopping tanks on a dike in the Eems-Dollard estuary in the Netherlands to measure during actual severe winter storms. The goal of the present paper is to further validate this innovative system with data obtained during storm Ciara (10 - 12 February 2020), a severe winter storm with very oblique wave attack. Furthermore, the data gathered during storm Ciara will be compared to the current knowledge on wave overtopping, to possibly gain new insights in the influence of very oblique wave attack on wave overtopping.

Recorded Presentation from the vICCE (YouTube Link): https://youtu.be/TwSwJuxb-Yo
https://doi.org/10.9753/icce.v36v.waves.20
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References

Brodie, K. L., Slocum, R. K., & McNinch, J. E. (2012). New insights into the physical drivers of wave runup from a continuously operating terrestrial laser scanner. In Oceans (pp. 1–8). IEEE.

De Rouck, J., Verhaeghe, H., & Geeraerts, J. (2009). Crest level assessment of coastal structures - General overview. Coastal Engineering, 56(2), 99–107.

De Vries, S., Hill, D. F., De Schipper, M. A., & Stive, M. J. F. (2011). Remote sensing of surf zone waves using stereo imaging. Coastal Engineering, 58(3), 239–250.

Matias, A., Blenkinsopp, C. E., & Masselink, G. (2014). Detailed investigation of overwash on a gravel barrier. Marine Geology, 350, 27–38.

Hanna, S. R., & Heinold, D. W. (1985). Development and application of a simple method for evaluating air quality models. Washington, D.C.: American Petroleum Institute.

Oosterlo, P., Hofland, B., Van der Meer, J. W., Overduin, M., Steendam, G. J., Nieuwenhuis, J.-W., … Reneerkens, M. (2019). Measuring (Oblique) Wave Run-Up and Overtopping with Laser Scanners. In Proc. Coastal Structures (pp. 442–452). Hannover, Germany: Bundesanstalt für Wasserbau.

Vousdoukas, M I, Kirupakaramoorthy, T., Oumeraci, H., De La Torre, M., Wübbold, F., Wagner, B., & Schimmels, S. (2014). The role of combined laser scanning and video techniques in monitoring wave-by-wave swash zone processes. Coastal Engineering, 83, 150–165.

Vousdoukas, Michalis Ioannis, Wziatek, D., & Almeida, L. P. (2012). Coastal vulnerability assessment based on video wave run-up observations at a mesotidal, steep-sloped beach. Ocean Dynamics, 62(1), 123–137.

Wenneker, I., Spelt, B., Peters, H., & de Ronde, J. (2016). Overview of 20 years of field measurements in the coastal zone and at the Petten sea dike in the Netherlands. Coastal Engineering, 109, 96–113.

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