Tidal Energy Chapter | 3 81


             which simply shows that the power generated is proportional to the area between
             the time series of water elevation inside and outside a tidal lagoon. Eq. (5.58)
             can also be applied to the study of hydropower, in a similar way.

             REFERENCES

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              [3] R. Pawlowicz, B. Beardsley, S. Lentz, Classical tidal harmonic analysis including error
                 estimates in MATLAB using T_TIDE, Comput. Geosci. 28 (2002) 929–937.
              [4] D.T. Pugh, Tides, Surges and Mean Sea-Level: A Handbook for Engineers and Scientists, John
                 Wiley, Chichester, UK, 1987, 472 pp.
              [5] S.D. Hicks, R.L. Sillcox, C.R. Nichols, B. Via, E.C. McCray, Tide and current glossary, in:
                 Center for Operational Oceanographic Products and Services, NOAA National Ocean Service,
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              [6] C. Le Provost, Generation of over-tides and compound tides (review), in: Tidal
                 Hydrodynamics, John Wiley & Sons, Inc., New York, NY, 1991, pp. 269–295.
              [7] S.P. Neill, E.J. Litt, S.J. Couch, A.G. Davies, The impact of tidal stream turbines on large-scale
                 sediment dynamics, Renew. Energy 34 (2009) 2803–2812.
              [8] S.P. Neill, M.R. Hashemi, M.J. Lewis, The role of tidal asymmetry in characterizing the tidal
                 energy resource of Orkney, Renew. Energy 68 (2014) 337–350.
              [9] M.N. Gallo, S.B. Vinzon, Generation of overtides and compound tides in Amazon estuary,
                 Ocean Dyn. 55 (5–6) (2005) 441–448.
             [10] R. Soulsby, Dynamics of Marine Sands: A Manual for Practical Applications, Thomas Telford,
                 London, 1997.
             [11] F.O. Rourke, F. Boyle, A. Reynolds, Tidal energy update 2009, Appl. Energy 87 (2) (2010)
                 398–409.
             [12] Y.L. Young, M.R. Motley, R.W. Yeung, Three-dimensional numerical modeling of the
                 transient fluid-structural interaction response of tidal turbines, J. Offshore Mech. Arct. Eng.
                 132 (1) (2010) 011101.
             [13] M.E. Harrison, W.M.J. Batten, L.E. Myers, A.S. Bahaj, Comparison between CFD simulations
                 and experiments for predicting the far wake of horizontal axis tidal turbines, IET Renew. Power
                 Gen. 4 (6) (2010) 613–627.
             [14] J.P. Frau, Tidal energy: promising projects: La Rance, a successful industrial-scale experiment,
                 IEEE Trans. Energy Convers. 8 (3) (1993) 552–558.
             [15] R.H. Clark, Elements of Tidal-Electric Engineering, vol. 33, John Wiley & Sons, New York,
                 NY, 2007.

             FURTHER READING
             [1] S.P. Neill, J.D. Scourse, K. Uehara, Evolution of bed shear stress distribution over the northwest
                European shelf seas during the last 12,000 years, Ocean Dyn. 60 (2010) 1139–1156.