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Sound speed profile

From Wikipedia, the free encyclopedia

A sound speed profile shows the speed of sound in water at different vertical levels. It has two general representations:

  1. tabular form, with pairs of columns corresponding to ocean depth and the speed of sound at that depth, respectively.
  2. a plot of the speed of sound in the ocean as a function of depth, where the vertical axis corresponds to the depth and the horizontal axis corresponds to the sound speed. By convention, the horizontal axis is placed at the top of the plot, and the vertical axis is labeled with values that increase from top to bottom, thus reproducing visually the ocean from its surface downward.

Table 1[1] shows an example of the first representation; figure 1 shows the same information using the second representation.

Table 1. A sound speed profile in tabular form.
Depth (m) Sound speed (m/s) Depth (m) Sound speed (m/s)
0 1540.4 500 1517.2
10 1540.5 600 1518.2
20 1540.7 700 1519.5
30 1534.4 800 1521.0
50 1523.3 900 1522.6
75 1519.6 1000 1524.1
100 1518.5 1100 1525.7
125 1517.9 1200 1527.3
150 1517.3 1300 1529.0
200 1516.6 1400 1530.7
250 1516.5 1500 1532.4
300 1516.2 1750 1536.7
400 1516.4 2000 1541.0
Figure 1. Table 1's data in graphical format.

Although given as a function of depth[note 1], the speed of sound in the ocean does not depend solely on depth. Rather, for a given depth, the speed of sound depends on the temperature at that depth, the depth itself, and the salinity at that depth, in that order.[3]

The speed of sound in the ocean at different depths can be measured directly, e.g., by using a velocimeter, or, using measurements of temperature and salinity at different depths, it can be calculated using a number of different sound speed formulae which have been developed. Examples of such formulae include those by Wilson,[4] Chen and Millero[5] ,and Mackenzie.[6] Each such formulation applies within specific limits of the independent variables.[7]

From the shape of the sound speed profile in figure 1, one can see the effect of the order of importance of temperature and depth on sound speed. Near the surface, where temperatures are generally highest, the sound speed is often highest because the effect of temperature on sound speed dominates. Further down the water column, sound speed also decreases as temperature decreases in the ocean thermocline, and sound speed also decreases. At a certain point, however, the effect of depth, i.e., pressure, begins to dominate, and the sound speed increases to the ocean floor.[8] Also visible in figure 1 is a common feature in sound speed profiles: the SOFAR channel. The axis of this channel is found at the depth of minimum sound speed. Sounds emitted at or near the axis of this channel propagate for very long horizontal distances, owing to the refraction of the sound back to the channel's center.[2]

Sound speed profile data are necessary for underwater acoustic propagation models, especially those based on ray tracing theory.

Notes

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  1. ^ Technically, depth isn't the physical variable which influences the sound speed. Rather, it is pressure. However, given the near linear relationship between the two,[2] depth is used more often when presenting sound speed profiles.

References

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  1. ^ John J. Audet, Jr. & Gregory G. Vega, (1974) AESD Sound-Speed Profile Retrieval System (RSVP), AESD Technical Note TN-74-03, 14.
  2. ^ a b Caruthers, Jerald W. (1977) Fundamentals of Marine Acoustics. Amsterdam: Elsevier Scientific Publishing Company.
  3. ^ Stewart, Robert H. (2008) Introduction to Physical Oceanography. College Station: Texas A&M University.
  4. ^ Wilson, W.D. (1960) Equation for the speed of sound in sea water. J. Acoust. Soc. Amer., 32, 1357.
  5. ^ Chen, C.-T. and Millero, F.J. (1977) Speed of sound in seawater at high pressures. J. Acoust. Soc. Amer., 62, 1129-35.
  6. ^ Mackenzie, K.V. (1981) Nine-term equation for sound speed in the oceans. J. Acoust. Soc. Amer., 70, 807-12.
  7. ^ Etter, Paul C. (1996) Underwater Acoustic Modeling: Principles, techniques and applications. Cambridge: University Press.
  8. ^ Talley, L.D et al. (2011) Descriptive Physical Oceanography: An Introduction. Academic Press.