Skip to main content Accessibility help
×
Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-25T09:17:08.942Z Has data issue: false hasContentIssue false

Bibliography

Published online by Cambridge University Press:  12 May 2020

Johannes Falnes
Affiliation:
NTNU, Norwegian University of Science and Technology, Trondheim
Adi Kurniawan
Affiliation:
University of Western Australia, Albany
Get access

Summary

Image of the first page of this content. For PDF version, please use the ‘Save PDF’ preceeding this image.'
Type
Chapter
Information
Ocean Waves and Oscillating Systems
Linear Interactions Including Wave-Energy Extraction
, pp. 293 - 300
Publisher: Cambridge University Press
Print publication year: 2020

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. Mei, Chiang C., Stiassnie, Michael and Yue, Dick K.-P.. Theory and Applications of Ocean Surface Waves. World Scientific, 2005.Google Scholar
2. Faltinsen, O. M.. Sea Loads on Ships and Offshore Structures. Cambridge University Press, 1990.Google Scholar
3. Sarpkaya, Turgut. Wave Forces on Offshore Structures. Cambridge University Press, 2010.Google Scholar
4. Chakrabarti, S. K.. Hydrodynamics of Offshore Structures. WIT Press, 1987.Google Scholar
5. Salter, S. H.. World progress in wave energy – 1988. International Journal of Ambient Energy, 10(1):324, 1989.CrossRefGoogle Scholar
6. Carmichael, A. D. and Falnes, J.. State of the art in wave power recovery. In Seymour, Richard J., editor, Ocean Energy Recovery, chapter 8, pages 182–212. American Society of Civil Engineers, 1992.Google Scholar
7. Brooke, John. Wave Energy Conversion, volume 6. Elsevier, 2003.Google Scholar
8. Cruz, J., editor. Ocean Wave Energy: Current Status and Future Perspectives. Green Energy and Technology. Springer-Verlag, 2008.Google Scholar
9. de, A. F. Falcão, O.. Wave energy utilization: A review of the technologies. Renewable and Sustainable Energy Reviews, 14:899918, 2010.Google Scholar
10. Umesh, A. Korde and John Ringwood. Hydrodynamic Control of Wave Energy Devices. Cambridge University Press, 2016.Google Scholar
11. Babarit, Aurélien. Ocean Wave Energy Conversion: Resource, Technologies and Performance. ISTE, 2017.Google Scholar
12. Bode, H. W.. Network Analysis and Feedback Amplifier Design. Van Nostrand, 1945.Google Scholar
13. Friedland, B.. Control System Design: An Introduction to State-Space Methods. McGraw-Hill, 1986.Google Scholar
14. Moler, C. and Van Loan, C.. Nineteen dubious ways to compute the exponential of a matrix. Society for Industrial and Applied Mathematics Review, 20:801836, 1978.Google Scholar
15. Petkov, P. Hr., Christov, N. D. and Konstantinov, M. M.. Computational Methods for Linear Control Systems. Prentice Hall, 1991.Google Scholar
16. Pease, M. C.. Methods of Matrix Algebra. Academic Press, 1965.Google Scholar
17. Papoulis, A.. The Fourier Integral and Its Applications. McGraw-Hill, 1962.Google Scholar
18. Bracewell, R. N.. The Fourier Transform and Its Applications. McGraw-Hill, 1986.Google Scholar
19. Kramers, H. A.. La diffusion de la lumière par les atomes. In Atti del Congresso Internazionale dei Fisici, volume II, pages 545–557, Como, settembre 1927. Nicola Zanichelli, Bologna, 1928.Google Scholar
20. de, R. Kronig, L.. On the theory of dispersion of X-rays. Journal of the Optical Society of America, 12(6):547557, 1926.Google Scholar
21. Kinsler, L. E. and Frey, A. R.. Fundamentals of Acoustics, 3rd edition. Wiley, 1982.Google Scholar
22. Panofsky, K. H. and Phillips, M.. Classical Electricity and Magnetism. Addison-Wesley, 1955.Google Scholar
23. McIver, P. and Evans, D. V.. The occurrence of negative added mass in free-surface problems involving submerged oscillating bodies. Journal of Engineering Mathematics, 18:722, 1984.CrossRefGoogle Scholar
24. Miles, J. N.. Resonant response of harbours: An equivalent circuit analysis. Journal of Fluid Mechanics, 46:241265, 1971.Google Scholar
25. Falnes, J.. Radiation impedance matrix and optimum power absorption for interacting oscillators in surface waves. Applied Ocean Research, 2(2):7580, 1980.CrossRefGoogle Scholar
26. Meyer, E. and Neumann, E. G.. Physikalische und technische Akustik, pages 180–182. Vierweg, 1967.Google Scholar
27. Titchmarsh, E.. Eigenfunction Expansion Associated with Second-Order Differential Equations. Oxford University Press, 1946.Google Scholar
28. Newman, J. N.. Marine Hydrodynamics, 40th anniversary edition. MIT Press, 2017.Google Scholar
29. Longuet-Higgins, M. S.. The mean forces exerted by waves on floating or submerged bodies, with application to sand bars and wave power machines. Proceedings of the Royal Society of London A, 352(1671):463480, 1977.Google Scholar
30. Goda, Yoshimi. Random Seas and Design of Maritime Structures, 3rd edition. World Scientific, 2010.Google Scholar
31. Tucker, M. J. and Pitt, E. G.. Waves in Ocean Engineering, 1st edition. Elsevier, 2001.Google Scholar
32. Abramowitz, M. and Stegun, I. A.. Handbook of Mathematical Functions. Dover Publications, 1965.Google Scholar
33. Wehausen, J. V. and Laitone, E. V.. Surface waves. In Flügge, S., editor, Encyclopedia of Physics, volume IX, pages 446–778. Springer-Verlag, 1960.Google Scholar
34. Newman, J. N.. The interaction of stationary vessels with regular waves. In Proceedings of the 11th Symposium on Naval Hydrodynamics, pages 491–501, London, 1976.Google Scholar
35. King, B.. Time-Domain Analysis of Wave Exciting Forces on Ships and Bodies. PhD thesis, Department of Naval Architecture and Marine Engineering, University of Michigan, 1987.Google Scholar
36. Korsmeyer, F. T.. The time domain diffraction problem. In The Sixth International Workshop on Water Waves and Floating Bodies, Woods Hole, MA, 1991.Google Scholar
37. Falnes, J.. On non-causal impulse response functions related to propagating water waves. Applied Ocean Research, 17(6):379389, 1995.CrossRefGoogle Scholar
38. Erdélyi, A., editor. Tables of Integral Transforms. McGraw-Hill, 1954.Google Scholar
39. Naito, S. and Nakamura, S.. Wave energy absorption in irregular waves by feed-forward control system. In Evans, D. V. and de, A. F. Falcão, O., editors, Hydrodynamics of Ocean Wave-Energy Utilization, pages 169–280. Springer-Verlag, 1986. IUTAM Symposium, Lisbon 1985.Google Scholar
40. Morris, E. L., Zienkiewich, H. K., Pourzanjani, M. M. A., Flower, J. O. and Belmont, M. R.. Techniques for sea state prediction. In Second International Conference on Manoeuvring and Control of Marine Craft, pages 547–569, Southampton, UK, 1992.Google Scholar
41. Sand, S. E.. Three-Dimensional Deterministic Structure of Ocean Waves. Technical Report 24, Institute of Hydrodynamics and Hydraulic Engineering (ISVA), Technical University of Denmark (DTH), 1979.Google Scholar
42. Greenhow, M. J. L.. The hydrodynamic interactions of spherical wave-power devices in surface waves. In Count, B., editor, Power from Sea Waves, pages 287– 343. Academic Press, 1980.Google Scholar
43. Kyllingstad, Å.. Approximate Analysis Concerning Wave-Power Absorption by Hydrodynamically Interacting Buoys. PhD thesis, Institutt for eksperimentalfysikk, NTH, Trondheim, Norway, 1982.Google Scholar
44. Srokosz, M. A.. Some relations for bodies in a canal, with application to wave-power absorption. Journal of Fluid Mechanics, 99:145162, 1980.CrossRefGoogle Scholar
45. Falnes, J. and Budal, K.. Wave-power absorption by parallel rows of interacting oscillating bodies. Applied Ocean Research, 4(4):194207, 1982.CrossRefGoogle Scholar
46. Havelock, T. H.. Waves due to a floating sphere making periodic heaving oscillations. Proceedings of the Royal Society of London A, 231(1184):17, 1955.Google Scholar
47. Hulme, A.. The wave forces acting on a floating hemisphere undergoing forced periodic oscillations. Journal of Fluid Mechanics, 121:443463, 1982.Google Scholar
48. Eidsmoen, Håvard. Hydrodynamic parameters for a two-body axisymmetric system. Applied Ocean Research, 17(2):103115, 1995.Google Scholar
49. Eatock Taylor, R. and Jeffreys, E. R.. Variability of hydrodynamic load predictions for a tension leg platform. Ocean Engineering, 13(5):449490, 1986.Google Scholar
50. WAMIT User Manual. www.wamit.com.Google Scholar
51. Korsmeyer, F. T., Lee, C. H., Newman, J. N. and Sclavounos, P. D.. The analysis of wave effects on tension-leg platforms. In Proceedings of the Seventh International Conference on Offshore Mechanics and Arctic Engineering, volume 2, pages 1–14, Houston, TX, 1988.Google Scholar
52. Cummins, W. E.. The impulse response function and ship motions. Schiffstechnik, 9:101109, 1962.Google Scholar
53. Kotik, J. and Mangulis, V.. On the Kramers-Kronig relations for ship motions. International Shipbuilding Progress, 9(97):361368, 1962.Google Scholar
54. Greenhow, Martin. A note on the high-frequency limits of a floating body. Journal of Ship Research, 28:226228, 1984.Google Scholar
55. Count, B. M. and Jefferys, E. R. Wave power, the primary interface. In Proceedings of the 13th Symposium on Naval Hydrodynamics, pages 1–10, Tokyo, 1980.Google Scholar
56. Tick, L. J.. Differential equations with frequency-dependent coefficients. Journal of Ship Research, 3(3):4546, 1959.Google Scholar
57. Goldman, S.. Transformation Calculus and Electric Transients. Constable and Co., London, 1949.Google Scholar
58. Timoshenko, S. P. and Gere, J. M.. Mechanics of Materials. Van Nostrand, 1973.Google Scholar
59. Haskind, M. D.. The exciting forces and wetting of ships (in Russian). Izvestyia Akademii Nauk SSSR, OtdelenieTekhnicheskikh Nauk, 7:6579, 1957.Google Scholar
60. Newman, J. N.. The exciting forces on fixed bodies in waves. Journal of Ship Research, 6(3):1017, 1962.Google Scholar
61. Evans, D. V.. Some analytic results for two and three dimensional wave-energy absorbers. In Count, B., editor, Power from Sea Waves, pages 213–249. Academic Press, 1980.Google Scholar
62. Budal, K.. Theory of absorption of wave power by a system of interacting bodies. Journal of Ship Research, 21:248253, 1977.Google Scholar
63. Falnes, J. and Kurniawan, A.. Fundamental formulae for wave-energy conversion. Royal Society Open Science, 2(3):140305, 2015.CrossRefGoogle ScholarPubMed
64. Kyllingstad, Å.. A low-scattering approximation for the hydrodynamic interactions of small wave-power devices. Applied Ocean Research, 6:132139, 1984.Google Scholar
65. Arzel, T., Bjarte-Larsson, T. and Falnes, J.. Hydrodynamic parameters for a floating WEC force-reacting against a submerged body. In Proceedings of the Fourth European Wave Energy Conference, Aalborg, Denmark, December 2000.Google Scholar
66. Budal, K.. Floating structure with heave motion reduced by force compensation. In Proceedings of the Fourth International Offshore Mechanics and Arctic Engineering Symposium, pages 92–101, Dallas, TX, February 1985.Google Scholar
67. Falnes, J.. Wave-energy conversion through relative motion between two single-mode oscillating bodies. Journal of Offshore Mechanics and Arctic Engineering, 121:3238, 1999.CrossRefGoogle Scholar
68. McCormick, M.. Ocean Wave Energy Conversion. Wiley, 1981.Google Scholar
69. Wehausen, J. V.. Causality and the radiation condition. Journal of Engineering Mathematics, 26:153158, 1992.Google Scholar
70. Budal, K. and Falnes, J.. A resonant point absorber of ocean waves. Nature, 256:478479, 1975. With Corrigendum in Vol. 257, p. 626.Google Scholar
71. Clare, R., Evans, D. V. and Shaw, T. L.. Harnessing sea wave energy by a submerged cylinder device. Proceedings of the Institution of Civil Engineers, 73(3):565585, 1982.Google Scholar
72. Evans, D. V., Jeffrey, D. C., Salter, S. H. and Taylor, J. R. M.. Submerged cylinder wave energy device: Theory and experiment. Applied Ocean Research, 1(1):312, 1979.Google Scholar
73. Salter, S. H.. Wave power. Nature, 249:720724, 1974.Google Scholar
74. Budal, K. and Falnes, J.. Optimum operation of improved wave-power converter. Marine Science Communications, 3(2):133150, 1977.Google Scholar
75. Evans, D. V.. A theory for wave-power absorption by oscillating bodies. Journal of Fluid Mechanics, 77:125, 1976.Google Scholar
76. Count, B. M.. Wave power: A problem searching for a solution. In Count, B. M., editor, Power from Sea Waves, pages 11–27. Academic Press, 1980.Google Scholar
77. Falnes, J. and Hals, J.. Heaving buoys, point absorbers and arrays. Philosophical Transactions of the Royal Society A, 370(1959):246277, 2012.Google Scholar
78. Falnes, J. and Budal, K.. Wave-power absorption by point absorbers. Norwegian Maritime Research, 6(4):211, 1978.Google Scholar
79. Salter, S. H.. Power conversion systems for ducks. In Proceedings of International Conference on Future Energy Concepts, pages 100–108, London, January 1979.Google Scholar
80. Nebel, P.. Maximizing the efficiency of wave-energy plants using complex-conjugate control. Journal of Systems and Control Engineering, 206(4):225236, 1992.Google Scholar
81. Salter, S. H., Jeffery, D. C. and Taylor, J. R. M.. The architecture of nodding duck wave power generators. The Naval Architect, pages 21–24, 1, 1976.Google Scholar
82. Milgram, J. H.. Active water-wave absorbers. Journal of Fluid Mechanics, 43:845859, 1970.Google Scholar
83. Budal, K. and Falnes, J.. Interacting point absorbers with controlled motion. In Count, B., editor, Power from Sea Waves, pages 381–399. Academic Press, 1980.Google Scholar
84. Budal, K., Falnes, J., Hals, T., Iversen, L. C. and Onshus, T.. Model experiment with a phase controlled point absorber. In Proceedings of Second International Symposium on Wave and Tidal Energy, pages 191–206, Cambridge, UK, 23–25 September 1981.Google Scholar
85. Budal, K., Falnes, J., Iversen, L. C., Lillebekken, P. M., Oltedal, G., Hals, T., Onshus, T. and Høy, A. S.. The Norwegian wave-power buoy project. In Berge, H., editor, Proceedings of the Second International Symposium on Wave Energy Utilization, pages 323344. Tapir, Trondheim, Norway, 1982.Google Scholar
86. Perdigão, J. N. B. A. and Sarmento, A. J. N. A.. A phase control strategy for OWC devices in irregular seas. In Grue, J., editor, The Fourth International Workshop on Water Waves and Floating Bodies, pages 205209, Deptartment of Mathematics, University of Oslo, 1989.Google Scholar
87. Perdigão, J. N. B. A.. Reactive-Control Strategies for an Oscillating-Water-Column Device. PhD thesis, Universidade Técnica de Lisboa, Instituto Superior Técnico, 1998.Google Scholar
88. Clément, A. and Maisondieu, C.. Comparison of time-domain control laws for a piston wave absorber. In European Wave Energy Symposium, pages 117–122, Edinburgh, Scotland, 1993.Google Scholar
89. Chatry, G., Clément, A. and Gouraud, T.. Self-adaptive control of a piston wave absorber. In Proceedings of the Eighth International Offshore and Polar Engineering Conference, volume 1, pages 127–133, Montréal, Canada, May 1998.Google Scholar
90. Falnes, J.. Small is beautiful: How to make wave energy economic. In European Wave Energy Symposium, pages 367–372, Edinburgh, Scotland, 1993.Google Scholar
91. Rainey, Rod. Private communication, 2003.Google Scholar
92. Sergiienko, N. Y., Cazzolato, B. S., Ding, B., Hardy, P. and Arjomandi, M.. Performance comparison of the floating and fully submerged quasi-point absorber wave energy converters. Renewable Energy, 108:425437, 2017.Google Scholar
93. Todalshaug, Jørgen Hals. Practical limits to the power that can be captured from ocean waves by oscillating bodies. International Journal of Marine Energy, 3:e70–e81, 2013.Google Scholar
94. Shaw, Ronald. Wave energy: A Design Challenge. Ellis Horwood Ltd., 1982.Google Scholar
95. Budal, K., Falnes, J., Kyllingstad, A. and Oltedal, G.. Experiments with point absorbers. In Proceedings of the First Symposium on Wave Energy Utilization, pages 253–282. Chalmers University of Technology, Gothenburg, Sweden, 1979.Google Scholar
96. Keulegan, G. H. and Carpenter, L. H.. Forces on cylinders and plates in an oscillating fluid. Journal of Research of the National Bureau of Standards, 60(5):423440, 1958.Google Scholar
97. de, A. F. Falcão, O. and Sarmento, A. J. N. A.. Wave generation by a periodic surface pressure and its application in wave-energy extraction. In 15th International Congress of Theoretical and Applied Mechanics, Toronto, 1980.Google Scholar
98. Evans, D. V.. Wave-power absorption by systems of oscillating surface pressure distributions. Journal of Fluid Mechanics, 114:481499, 1982.Google Scholar
99. Alcorn, R. G., Beattie, W. C. and Douglas, R.. Turbine modelling and analysis using data obtained from the Islay wave-power plant. In Proceedings of the Ninth International Offshore and Polar Engineering Conference, Brest, 1999.Google Scholar
100. Lin, Chia-Po. Experimental Studies of the Hydrodynamic Characteristics of a Sloped Wave Energy Device. PhD thesis, University of Edinburgh, 1999.Google Scholar
101. Haren, P. and Mei, C. C.. Wave power extraction by a train of rafts: Hydrodynamic theory and optimum design. Applied Ocean Research, 1(3):147157, 1979.Google Scholar
102. Noad, I. F. and Porter, R.. Modelling an articulated raft wave energy converter. Renewable Energy, 114:11461159, 2017.Google Scholar
103. de Sousa Prado, M. G. F. Gardner, M. Damen, and Polinder, H.. Modelling and test results of the Archimedes Wave Swing. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 220(8):855868, 2006.Google Scholar
104. French, M. J.. The search for low cost wave energy and the flexible bag device. In Proceedings of the First Symposium of Wave Energy Utilization, pages 364–377, Gothenburg, Sweden, 1979.Google Scholar
105. Bellamy, N. W.. Development of the SEA Clam wave energy converter. In Proceedings of the Second International Symposium on Wave Energy Utilization, pages 175–190, Trondheim, Norway, 1982.Google Scholar
106. Kurniawan, A., Chaplin, J. R., Greaves, D. M. and Hann, M.. Wave energy absorption by a floating air bag. Journal of Fluid Mechanics, 812:294320, 2017.Google Scholar
107. Newman, J. N.. Wave effects on deformable bodies. Applied Ocean Research, 16:4759, 1994.Google Scholar
108. Falnes, J.. Budal’s 1978 Design of a Point Absorber with Hydraulic Machinery for Control and Power Take-Off. Technical report, Institutt for fysikk, NTH, Trondheim, 1993.Google Scholar
109. Falnes, J. and McIver, P.. Surface wave interactions with systems of oscillating bodies and pressure distributions. Applied Ocean Research, 7:225234, 1985.Google Scholar
110. Fernandes, A. C.. Reciprocity relations for the analysis of floating pneumatic bodies with application to wave power absorption. In Proceedings of the Fourth International Offshore Mechanics and Arctic Engineering Symposium, volume 1, pages 725–730, Dallas, Texas, 1985.Google Scholar
111. Thomas, G. P. and Evans, D. V.. Arrays of three-dimensional wave-energy absorbers. Journal of Fluid Mechanics, 108:6788, 1981.Google Scholar
112. Evans, D. V.. Maximum wave-power absorption under motion constraints. Applied Ocean Research, 3(4):200203, 1981.Google Scholar
113. Pizer, D. J.. Maximum wave-power absorption of point absorbers under motion constraints. Applied Ocean Research, 15:227234, 1993.Google Scholar
114. Masuda, Y., Kimura, H., Liang, X., Gao, X., Mogensen, R. M. and Anderson, T.. Regarding BBDB wave power generating plant. In Elliot, G. and Diamantaras, K., editors, Proceedings of the Second European Wave Power Conference, pages 6976, Lisbon, Portugal, 1995.Google Scholar
115. António, F. de O. Falcão and João C. C. Henriques. Oscillating-water-column wave energy converters and air turbines: A review. Renewable Energy, 85:13911424, 2016.Google Scholar
116. Falnes, J. and Lillebekken, P. M.. Budal’s latching-controlled-buoy type wave-power plant. In Lewis, A. and Thomas, G., editors, Proceedings of the Fifth European Wave Energy Conference, pages 233244, Cork, Ireland, 2003.Google Scholar
117. Mei, C. C.. Power extraction from water waves. Journal of Ship Research, 20:6366, 1976.Google Scholar
118. Falnes, J.. Wave-power absorption by an array of attenuators oscillating with unconstrained amplitudes. Applied Ocean Research, 6:1622, 1984.Google Scholar
119. Ogilvie, T. F.. First- and second-order forces on a cylinder submerged under a free surface. Journal of Fluid Mechanics, 16:451472, 1963.Google Scholar

Save book to Kindle

To save this book to your Kindle, first ensure [email protected] is added to your Approved Personal Document E-mail List under your Personal Document Settings on the Manage Your Content and Devices page of your Amazon account. Then enter the ‘name’ part of your Kindle email address below. Find out more about saving to your Kindle.

Note you can select to save to either the @free.kindle.com or @kindle.com variations. ‘@free.kindle.com’ emails are free but can only be saved to your device when it is connected to wi-fi. ‘@kindle.com’ emails can be delivered even when you are not connected to wi-fi, but note that service fees apply.

Find out more about the Kindle Personal Document Service.

Available formats
×

Save book to Dropbox

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Dropbox.

Available formats
×

Save book to Google Drive

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Google Drive.

Available formats
×