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Page

184

254

Version

6.3

Rev

r012

Date

05-11-2022

Part No. 96000001

12.3.4

Reverberation and Scattering

The sea is not homogenous in nature. Everything from suspended dust particles to fish, from the sea
surface to the seafloor, will scatter, that is reradiate the acoustic energy. All of the effects of
individual scattering can be termed reverberation. The effect of reverberation is to lessen the
acoustic energy, and this leads to transmission losses.

Reverberation is divided into three main areas: sea surface reverberation, bottom reverberation,
and volume reverberation (the body of water that the energy is passing through).

Both the sea surface and the sea bottom will reflect and scatter sound, thus affecting the
propagation of sound. Sea surface scattering is influenced by how rough the sea is (which is related
to wind velocity) and also the trapped air bubbles in the near-surface region. The sea surface is also
a good reflector of acoustic energy; this can lead to second and even tertiary bottom returns as the
bottom return acoustic energy is reflected by the sea surface and is then reflected once more by the
sea bottom.

In the case of the seafloor, the strength of the scattering depends on the type of bottom
(composition and roughness), the grazing angle of the acoustic pulse, and the operating frequency of
the sonar.

There is also bottom absorption based on the seafloor terrain and composition.  Bottom absorption
is also dependent on the operating frequency of the sonar and the angle of incidence. Bottom
absorption will be greater for a higher frequency and a large angle of incidence.  It is more or less
intuitive that a mud bottom will absorb more of the acoustic energy than a rocky bottom.  When the
acoustic energy is absorbed, it means there is less that will be reflected back to the receivers. The
surveyor must be aware of the bottom composition as adjustments can be made to the Sonic
Multibeam Echosounder’s operating parameters to help compensate for the bottom absorption.

In waters with a large sediment load, the suspended particles will scatter the sound wave, thus
leading to transmission loss.  In the scattering process, there is also a degree of energy that is
reflected (backscatter); this can be a cause for ‘noise’ in the sonar data.  Again, the surveyor should
be aware of this condition and, if need be, change the operating parameters of the Sonic MBES.
When discussing the changing of the operating parameters, it is generally a matter of increasing
transmit power or pulse length to get more total power into the water. In some circumstances,
increasing the Absorption value will allow the system to rapidly increase the gain to capture the
reflected energy that has been dissipated by seafloor absorption or scattering in the water column.

As noted above, many of the effects of absorption, scattering, and bottom absorption are frequency
dependent. With the Sonic MBES, the operator can adjust the sonar frequency to optimise the
system for the survey conditions. This will take some trial and error; however, lower frequencies
tend to do best in areas of an absorbent bottom and high sediment load (scatter).