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Sea state

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Title: Sea state  
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Subject: Wind wave model, Fetch (geography), Rogue wave, Wind wave, Seakeeping
Collection: Basic Meteorological Concepts and Phenomena, Marine Meteorology and Sailing, Oceanography
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Sea state

Georges Bank.

In oceanography, a sea state is the general condition of the free surface on a large body of water—with respect to wind waves and swell—at a certain location and moment. A sea state is characterized by statistics, including the wave height, period, and power spectrum. The sea state varies with time, as the wind conditions or swell conditions change. The sea state can either be assessed by an experienced observer, like a trained mariner, or through instruments like weather buoys, wave radar or remote sensing satellites.

In case of buoy measurements, the statistics are determined for a time interval in which the sea state can be considered to be constant. This duration has to be much longer than the individual wave period, but smaller than the period in which the wind and swell conditions vary significantly. Typically, records of one hundred to one thousand wave-periods are used to determine the wave statistics.

The large number of variables involved in creating the sea state cannot be quickly and easily summarized, so simpler scales are used to give an approximate but concise description of conditions for reporting in a ship's log or similar record.


  • World Meteorological Organization sea state code 1
  • Sea states in marine engineering 2
  • See also 3
  • Footnotes 4
  • References 5

World Meteorological Organization sea state code

Winter, North Atlantic – Water over deck and hatches, storm with huge waves (1958)

The WMO sea state code largely adopts the 'wind sea' definition of the Douglas Sea Scale.

WMO Sea State Code Wave height Characteristics
0 0 metres (0 ft) Calm (glassy)
1 0 to 0.1 metres (0.00 to 0.33 ft) Calm (rippled)
2 0.1 to 0.5 metres (3.9 in to 1 ft 7.7 in) Smooth (wavelets)
3 0.5 to 1.25 metres (1 ft 8 in to 4 ft 1 in) Slight
4 1.25 to 2.5 metres (4 ft 1 in to 8 ft 2 in) Moderate
5 2.5 to 4 metres (8 ft 2 in to 13 ft 1 in) Rough
6 4 to 6 metres (13 to 20 ft) Very rough
7 6 to 9 metres (20 to 30 ft) High
8 9 to 14 metres (30 to 46 ft) Very high
9 Over 14 metres (46 ft) Phenomenal
Character of the sea swell
  0. None
Low 1. Short or average
2. Long
Moderate 3. Short
4. Average
5. Long
Heavy 6. Short
7. Average
8. Long
  9. Confused
The direction from which the swell is coming should be recorded.

Sea states in marine engineering

In engineering applications, sea states are often characterized by the following two parameters:

The sea state is in addition to these two parameters (or variation of the two) also described by the wave spectrum S(\omega, \Theta) which is the product of a wave height spectrum S(\omega) and a wave direction spectrum f(\Theta). Some wave height spectra are listed below. The dimension of the wave spectrum is \{S(\omega)\} = \^2\cdot\text{time}\}, and many interesting properties about the sea state can be found from the spectrum.

The relationship between the spectrum S(\omega_j) and the wave amplitude A_j for a wave component j is:

\frac{1}{2} A_j^2 = S(\omega_j)\, \Delta \omega
\frac{S(\omega)}{H_{1/3}^2 T_1} = \frac{0.11}{2\pi} \left(\frac{\omega T_1}{2\pi}\right)^{-5} \mathrm{exp} \left[-0.44 \left(\frac{\omega T_1}{2\pi}\right)^{-4} \right]
S(\omega) = 155 \frac{H_{1/3}^2}{T_1^4 \omega^5} \mathrm{exp} \left(\frac{-944}{T_1^4 \omega^4}\right)(3.3)^Y,


Y = \exp \left[-\left(\frac{0.191 \omega T_1 -1}{2^{1/2}\sigma}\right)^2\right]


\sigma = \begin{cases} 0.07 & \text{if }\omega \le 5.24 / T_1, \\ 0.09 & \text{if }\omega > 5.24 / T_1. \end{cases}

(The latter model has since its creation improved based on the work of Phillips and Kitaigorodskii to better model the wave height spectrum for high wavenumbers.[4])

An example function f(\Theta) might be:

f(\Theta) = \frac{2}{\pi}\cos^2\Theta, \qquad -\pi/2 \le \Theta \le \pi/2

Thus the sea state is fully determined and can be recreated by the following function where \zeta is the wave elevation, \epsilon_{j} is uniformly distributed between 0 and 2\pi, and \Theta_j is randomly drawn from the directional distribution function \sqrt{f(\Theta)}:[5]

\zeta = \sum_{j=1}^N \sqrt{2 S(\omega_j) \Delta \omega_j}\; \sin(\omega_j t - k_j x \cos \Theta_j - k_j y \sin \Theta_j + \epsilon_{j}).

In addition to the short term wave statistics presented above, long term sea state statistics are often given as a joint frequency table of the significant wave height and the mean wave period. From the long and short term statistical distributions it is possible to find the extreme values expected in the operating life of a ship. A ship designer can find the most extreme sea states (extreme values of H1/3 and T1) from the joint frequency table, and from the wave spectrum the designer can find the most likely highest wave elevation in the most extreme sea states and predict the most likely highest loads on individual parts of the ship from the response amplitude operators of the ship. Surviving the once in 100 years or once in 1000 years sea state is a normal demand for design of ships and offshore structures.

See also


  1. ^ International Towing Tank Conference (ITTC), retrieved 11 November 2010 
  2. ^ International Ship and Offshore Structures Congress
  3. ^ Pierson, W. J.; Moscowitz, L. (1964), "A proposed spectral form for fully developed wind seas based on the similarity theory of S A Kitaigorodskii", Journal of Geophysical Research 69 (24): 5181–5190,  
  4. ^ Elfouhaily, T.; Chapron, B.; Katsaros, K.; Vandemark, D. (July 15, 1997). "A unified directional spectrum for long and short wind-driven waves" (PDF).  
  5. ^ Jefferys, E. R. (1987), "Directional seas should be ergodic", Applied Ocean Research 9 (4): 186–191,  


  • Faltinsen, O. M. (1990), Sea Loads on Ships and Offshore Structures, [Cambridge University Press],  
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