Format des notes

Numérique sur 20

Littérale/grade américain

Programme détaillé

Syllabus I. Characterizing ocean waves and sea states - Description of waves - Sea state characterization (wave-by-wave, spectral analysis) - Wave observation techniques and databases II. Linear wave theory - Linearization of the water wave problem - Dispersion relation - Wave kinematics and approximations in shallow and deep water - Nonlinear wave theories (Stokes, Cnoidal, stream function) *Exercise: Using wave buoy measurements to generate scatter diagrams and to characterize* *wave variability at an offshore study site.* III. Nearshore wave propagation - Wave energy flux conservation - Bathymetric refraction - Wave shoaling *Exercise: Using a one-line model to calculate wave transformation in the surf zone (and* *comparison to wave tank experiments).* IV. Coastal hydrodynamics - Characterization of wave breaking - Wave breaking impacts (undertow, setup, alongshore currents) - Surf zone circulation (rip currents, eddies) - Infragravity waves and impacts - Wave-current interactions V. Numerical modeling of wave propagation 1 - Review of important physical processes to model - Differentiating phase-averaged and phase-resolving models - Presentatin of phase-averaged (spectral) models *Exercise: Running TOMAWAC spectral wave propagation model to simulate wave propagation* *in the nearshore zone.* VI. Numerical modeling of wave propagation 2 - Review of the Navier-Stokes equations - Mild-slope equations - Boussinesq-type models - Fully nonlinear potential flow theory models - Navier-Stokes models (Eulerian and Lagrangian approaches) *Class presentations: Students work in groups to present the different families of deterministic* *wave propagation models.* VII. Dynamics of a body in waves - Nondimensional numbers (Re, Fr, KC) and similitude - Added mass, drag, lift, buoyancy - Morison equation (small bodies) - Diffraction-radiation problem (large bodies) - Second and higher-order effects *Exercise: Use of wave scatter diagrams to calculate absorbed wave energy at the selected study* *site for selected wave energy converters.* VIII. Modeling wave-body interactions - Industrial codes and open research questions - Experimental approaches - Academic models: - Linear theory - Fully nonlinear potential flow theory - Navier-Stokes equations *Exercise: Use of wave scatter diagrams to calculate wave forces on a floating body at the* *selected offshore study site.* IX. Seminar about wave-structure interactions (presented by a representative from a company working in the field of marine renewable energy): Subject: - fixed and floating offshore wind turbines or - wave energy converters Objectives: - present pilot project, study site, or existing installation - discuss design criteria, challenges, current needs for research X. Exam