The exact theoretical expression describing the
probability distribution of nonlinear sea-surface elevations derived
from the second-order narrowband model has a cumbersome form
that requires numerical computations, not well-disposed to theoretical
or practical applications. Here, the same narrowband model is reexamined
to develop a simpler closed-form approximation suitable
for theoretical and practical applications. The salient features of the
approximate form are explored, and its relative validity is verified
with comparisons to other readily available approximations, and
oceanic data.
[1] M. A. Tayfun, “Narrow-band nonlinear sea waves,” J. Geophys. Res.,
vol. 85, pp. 1548–1552, 1980.
[2] H. Socquet-Juglard, K. Dysthe, K. Trulsen, H. Krogstad, and J. Liu,
“Probability distributions of surface gravity waves during spectral
changes,” J. Fluid Mech., vol. 542, 195–216, 2005.
[3] M. S. Longuet-Higgins, “The effects of nonlinearities on statistical
distributions in the theory of sea waves,” J. Fluid Mech. vol. 17, pp.
459–480, 1963.
[4] M. A. Tayfun, and J-M. Lo, “Envelope, phase, and narrowband models
of sea waves,” J. Waterw. Port, Coast. Ocean Eng., vol. 115, pp. 594-
613, 1990.
[5] M. A. Tayfun, “Statistics of nonlinear wave crests and groups,” Ocean
Eng., vol. 33, 1589–1622, 2006.
[6] M. A. Tayfun, and F. Fedele, “Wave-height distributions and nonlinear
effects,” Ocean Eng., vol. 34, 1631 – 1649, 2007.
[7] M. A. Tayfun, and F. Fedele, “Expected shape of extreme waves in
storm seas,” in Proc. 26th Inter. Conf. on Offshore Mech.& Arctic Eng.,
San Diego, paper no. OMAE2007-29073, pp. 1-8, 2007.
[8] M. A. Tayfun, “Distributions of envelope and phase in wind waves,” J.
Phys. Oceanogr., vol. 38, pp. 2784–2800, 2008.
[9] A. Toffoli, E. Bitner-Gregersen, M. Onorato, A. R. Osborne, and A. V.
Babanin, “Surface gravity waves from direct numerical simulations of
the Euler equations: A comparison with second-order theory,” Ocean
Eng., vol. 35, 367– 379, 2008.
[10] Z. Cherneva, M. A. Tayfun, and C. Guedes-Soares, “Statistics of
nonlinear waves generated in an offshore wave basin”, J. Geophys. Res.,
vol. 114, C08005, 2009.
[11] F. Fedele, and M. A. Tayfun, “On nonlinear wave groups and crest
statistics,” J. Fluid Mech., vol. 620, 221–239, 2009.
[12] F. Fedele, Z. Cherneva, M. A. Tayfun, and C. Guedes-Soares,
“Nonlinear Schrödinger invariants and wave statistics,” Phys. Fluids,
vol. 22, 2010.
[13] F. Arena, and F. Fedele, “A family of narrow-band nonlinear stochastic
processes for the mechanics of sea waves,” Eur. J. Mech. B/Fluids, vol.
21, pp. 125–137, 2005.
[14] A. K. Jha, and S. R. Winterstein,”Non-linear random ocean waves:
prediction and comparison with data,” in Proc. ETCE/OMAE2000 Joint
Conference Energy for the New Millenium, vol. 1, paper OMAE2000-
6125, 2000, ISBN: 0791819949, 9780791819944.
[15] M. Prevosto, H. E. Krogstad, and A. Robin, “Probability distributions
for maximum wave and crest heights,” Coastal Eng., vol. 40, 329–360,
2000.
[16] M. Abramowitz, and I. A. Stegun, Handbook of Mathematical
Functions, Dover Publications, New York, 1968, p. 932.
[1] M. A. Tayfun, “Narrow-band nonlinear sea waves,” J. Geophys. Res.,
vol. 85, pp. 1548–1552, 1980.
[2] H. Socquet-Juglard, K. Dysthe, K. Trulsen, H. Krogstad, and J. Liu,
“Probability distributions of surface gravity waves during spectral
changes,” J. Fluid Mech., vol. 542, 195–216, 2005.
[3] M. S. Longuet-Higgins, “The effects of nonlinearities on statistical
distributions in the theory of sea waves,” J. Fluid Mech. vol. 17, pp.
459–480, 1963.
[4] M. A. Tayfun, and J-M. Lo, “Envelope, phase, and narrowband models
of sea waves,” J. Waterw. Port, Coast. Ocean Eng., vol. 115, pp. 594-
613, 1990.
[5] M. A. Tayfun, “Statistics of nonlinear wave crests and groups,” Ocean
Eng., vol. 33, 1589–1622, 2006.
[6] M. A. Tayfun, and F. Fedele, “Wave-height distributions and nonlinear
effects,” Ocean Eng., vol. 34, 1631 – 1649, 2007.
[7] M. A. Tayfun, and F. Fedele, “Expected shape of extreme waves in
storm seas,” in Proc. 26th Inter. Conf. on Offshore Mech.& Arctic Eng.,
San Diego, paper no. OMAE2007-29073, pp. 1-8, 2007.
[8] M. A. Tayfun, “Distributions of envelope and phase in wind waves,” J.
Phys. Oceanogr., vol. 38, pp. 2784–2800, 2008.
[9] A. Toffoli, E. Bitner-Gregersen, M. Onorato, A. R. Osborne, and A. V.
Babanin, “Surface gravity waves from direct numerical simulations of
the Euler equations: A comparison with second-order theory,” Ocean
Eng., vol. 35, 367– 379, 2008.
[10] Z. Cherneva, M. A. Tayfun, and C. Guedes-Soares, “Statistics of
nonlinear waves generated in an offshore wave basin”, J. Geophys. Res.,
vol. 114, C08005, 2009.
[11] F. Fedele, and M. A. Tayfun, “On nonlinear wave groups and crest
statistics,” J. Fluid Mech., vol. 620, 221–239, 2009.
[12] F. Fedele, Z. Cherneva, M. A. Tayfun, and C. Guedes-Soares,
“Nonlinear Schrödinger invariants and wave statistics,” Phys. Fluids,
vol. 22, 2010.
[13] F. Arena, and F. Fedele, “A family of narrow-band nonlinear stochastic
processes for the mechanics of sea waves,” Eur. J. Mech. B/Fluids, vol.
21, pp. 125–137, 2005.
[14] A. K. Jha, and S. R. Winterstein,”Non-linear random ocean waves:
prediction and comparison with data,” in Proc. ETCE/OMAE2000 Joint
Conference Energy for the New Millenium, vol. 1, paper OMAE2000-
6125, 2000, ISBN: 0791819949, 9780791819944.
[15] M. Prevosto, H. E. Krogstad, and A. Robin, “Probability distributions
for maximum wave and crest heights,” Coastal Eng., vol. 40, 329–360,
2000.
[16] M. Abramowitz, and I. A. Stegun, Handbook of Mathematical
Functions, Dover Publications, New York, 1968, p. 932.
@article{"International Journal of Engineering, Mathematical and Physical Sciences:68797", author = "M. A. Tayfun and M. A. Alkhalidi", title = "A Simplified Distribution for Nonlinear Seas", abstract = "The exact theoretical expression describing the
probability distribution of nonlinear sea-surface elevations derived
from the second-order narrowband model has a cumbersome form
that requires numerical computations, not well-disposed to theoretical
or practical applications. Here, the same narrowband model is reexamined
to develop a simpler closed-form approximation suitable
for theoretical and practical applications. The salient features of the
approximate form are explored, and its relative validity is verified
with comparisons to other readily available approximations, and
oceanic data.
", keywords = "Ocean waves, probability distributions, second-order nonlinearities, skewness coefficient, wave steepness.", volume = "9", number = "1", pages = "34-4", }
