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Wave-current interaction in the presence of a reflective wave fieldRogers, Jonathan Robert January 1998 (has links)
No description available.
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Cross-shore modelling of short-crested wind wave transformation and wave-induced circulation in the near-shore zoneKitou, Matilda January 1999 (has links)
No description available.
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Internal wave wakes in stratified shear flowsMoroney, Gerard January 1999 (has links)
No description available.
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Air entrainment, splash and energy dissipation in breaking wavesBlenkinsopp, Christopher Edwin January 2007 (has links)
No description available.
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Using artificial neural networks to predict storm surge in the North Sea and Thames EstuaryProuty, Daniel Bruce January 2007 (has links)
An artificial neural network (ANN) was developed to predict storm surge magnitudes and arrival times at selected locations in the North Sea. The model predicts storm surges based solely on past measured water level residuals at one or more tidal stations. The research focuses on the performance of the model at the Sheerness tide station near the entrance of the River Thames in the UK. To take advantage of the specificity of surge propagation in the North Sea, the ANN uses input from both the target station and an additional station located where the peak of the storm surge has just passed. The ANN is trained to relate surge at the primary station from measured surge at a secondary station. The optimal secondary location is correlated to the forecast interval and the storm surge’s propagation time between the secondary and primary station. This research further explores new forecasting methods using ANN ensembles to reduce variance and minimize error. The ensemble forecasting method averages results from multiple ANN models trained based on different model initializations. A significant result of this research is the ANN’s ability to accurately predict maximum water elevations. A single ANN model had a 4-hour forecast error of 0.017 m, while a simple [1,1] ensemble model using 20 repetitions performed better with an average 4-hour forecast error of 0.008 m. When over-training is included to reduce the model bias, the error is further reduced to 0.004 m. ANN ensemble model performances for predicting maximum storm surge were however less impressive. Best results were obtained for ensembles of [30,1] models with an average 4-hour forecast error of 0.68 m.
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Wave interactions and wave statistics in directional seasGibson, Richard Stewart January 2005 (has links)
No description available.
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Walls of water on the open oceanGibbs, Richard Harvey January 2004 (has links)
No description available.
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Modelling storm surges in the Irish and Celtic seas using a finite element model (TELEMAC)Maskell, John Henry January 2011 (has links)
A finite element model (a configuration of TELEMAC) of the Irish and Celtic seas was forced with Met Office 'rnesoscale meteorological data to investigate storm surges in the region. This is the first time that output from the Met Office meteorological model (NAE) has been used to force a finite element model of the region so that a comparison to the current UK operational storm surge forecasting model (CS3X) could be carried out. Finite element models allow hydrodynamic simulations to be carried out on a graded mesh permitting fine resolution in shallow water regions, thus removing the need for nesting whilst remaining computation ally efficient. A hindcast simulation of la typical storm surge season was carried out for October 2007 to March 2008 and the simulated surge elevations compared to observations at tide gauge stations and to those simulated by the operational model to investigate any advantage of enhanced grid resolution in shallow coastal regions for storm surge prediction. It was found that including external surge generated in regions outside the boundary of the model was important in simulating the magnitude of the observed surge at the coast. External surge generated in the wider area operational model was successfully implemented at the open boundary of the TELEMAC model so that a like-for-like comparison of the surge at the coast simulated by both models could be carried out. The results show that TELEMAC performs as well as the operational model in simulating the observed residual and skew surge elevations at various tide gauge locations at the coast. However, there is no evidence that increasing the resolution in shallow water regions increases the accuracy of the storm surge prediction based on the same meteorological forcing. Both models simulate the observed residual elevations reasonably accurately with an average RMS error of 0.14 m with respect to observations at all the tide gauges used in the study. However, both models often severely under-predict the largest observed residuals, particularly at locations in the Bristol Channel and at Liverpool. It is evident that both models fail to capture the true dynamics of surge generation in these regions and that increasing the grid resolution in shallow water regions eventually becomes limited by the resolution of the forcing meteorology and/or the bathymetry. Examining the meteorological situation it was found that model performance in both models was better at Liverpool when the surge is generated by wind stress events that are not local to the region. Increasing the wind stress by 10% showed that some of the error in predicting the largest residuals could be explained by under-prediction of the peak wind stresses. However, the largest residuals at Liverpool were still under-predicted. Therefore, to simulate local wind-generated surge residuals it is important to have increased accuracy and detail of the forcing meteorology. To investigate the factors limiting performance of enhanced resolution in shallow water regions two further seasonal simulations were carried out with a more accurate representation of the Mersey estuary, with increased bathymetric resolution, and forcing the model with the Met Office's UK4 model providing a three-fold increase in the resolution of the forcing meteorology. It was found that the bathymetry of the Mersey estuary region was not the limiting factor in accurately simulating the observed residual and skew surge elevations at Liverpool. It is evident that main channel in the Mersey estuary adjacent to Liverpool (present in both model grids of the region) is the main feature in controlling the surge distribution, and the accuracy of the simulated surge at Liverpool is more dependent on the accuracy of the increased water levels and the effect of the wind on the tide outside of the Mersey estuary in Liverpool Bay. In a further seasonal simulation using meteorological
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A global perspective of wind-wave interaction and the distribution of wave momentumHanley, Kirsty January 2008 (has links)
The interaction between ocean surface waves and the overlying wind leads to a transfer of momentum across the air-sea interface. Generally, ocean waves are thought to act as a drag on the surface wind so that the air-sea momentum flux is directed downward, from the atmosphere into the waves. Recent observations have suggested that momentum can also be transferred upwards when long wavelength waves, characteristic of remotely generated swell, propagaite faster than the wind speed. This upwarad momentum transfer acts to accelerate the near-surface wind, resulting in a low-level wave-driven wind jet. Idealised models are used here to investigate the effect of upward momentum transfer on the marine boundary layer and to determine the dynamics of these wave-driven jets.
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Measurement and analysis of wave overtoppingBay, Ibrahim January 2005 (has links)
No description available.
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