Wave refraction over complex nearshore bathymetry

Peak, Scott Douglas

12 1900

Approved for public release, distribution is unlimited / Accurate predictions of nearshore wave conditions are critical to the success of military operations in the littoral environment. Although linear spectral-refraction theory is used by the main operational forecasting centers in the world for these predictions, owing to a lack of field studies its accuracy in regions of complex bathymetry such as steep shoals and submarine canyons is unknown. This study examines the accuracy of linear spectral-refraction theory in areas of complex nearshore bathymetry with three months of extensive wave data collected during the Nearshore Canyon Experiment (NCEX) held in the fall of 2003. The field site, off La Jolla California, is characterized by two submarine canyons that strongly affect the propagation of long period Pacific swell. Data from 7 directional waverider buoys, 17 bottom pressure recorders, and 12 pressure-velocity sensors, were examined and compared to predictions made by a high resolution spectral-refraction model. Analysis reveals large spatial variation in wave heights over the area especially in the vicinity of the canyon heads, where wave heights vary by as much as an order of magnitude over a few hundred meters. This extreme variation in wave conditions across the canyons is surprisingly well described by refraction theory with typical errors of nearshore wave height predictions of about 20 percent. / Lieutenant, Royal Australian Navy

Refraction

Ocean waves

Refraction

Swell transformation

Scripps Canyon

NCEX

Nearshore wave model

Examining the Effects of Directional Wave Spectra on a Nearshore Wave Model

Dillon, Sally Catherine Davis

10 August 2018

Wave models are an integral part of coastal engineering due to their ability to quantify information that is either unobtainable or unavailable. However, these models rely heavily on the input of a directional wave spectrum that describes the variation of energy with frequency and direction. This study investigated how five methods for computing the directional wave spectrum perform within the nearshore spectral wave model, STWAVE. The results of the five experimental runs showed that overall, the greatest differences between spectra were observed in the significant wave height parameter. The mean wave direction showed greater differences at the offshore model domain boundary and lesser differences as the wave enters the nearshore; and the peak period had fewer differences at the boundary, but at the nearshore the differences were dependent upon the presence of wind forcing. Winds had a significant impact on observed differences between the spectra in the domain by dominating the wave field variation.

spreading function

STWAVE

frequency spectra

directional wave spectra

nearshore wave model