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EM Technical Note
Date:
September 20, 2005
Author:
Erik Hammerstad
Subject: Sound Levels from Kongsberg Multibeams
The power output level of an echo sounder is normally specified by giving
its source level in dB relative to 1 μPa at a distance of 1 m from the
transmit transducer. However this is really a measure of the pressure
level of the output sound wave and is only directly applicable in the
farfield. The intensity (power per unit area) of a sound wave can be found
from the pressure level by the relation I = p
density and c the speed of sound. The quantity c is the acoustic
impedance of water and for sea water is nominally taken to be 1.5x10
kg/m
s. Thus a pressure level in sea water of 1 μPa is nominally equal to
2
an energy intensity of 0.667x10
example 210 dB corresponds to an intensity of 667 W/m
In the farfield the pressure level of a sound wave will fall off with the
square of the distance, this because of spherical spreading of the wave,
and the wave will be further attenuated due to absorption loss. In the
nearfield the pressure level will be nominally constant as there is no
spreading. If the transmit transducer generating the sound wave is
rectangular, there will be a transition region in which the pressure will
fall of proportionally to the distance due to cylindrical spreading in the
direction parallel to the shortest side of the transducer. It may be noted
that in the nearfield the pressure level will have large variations, with
peaks up to about twice the nominal level and also deep nulls, this effect
will however be ignored in this note.
The source level is given by SL = 170.8 + 10lgP
power which is typically half the electric power applied to the transmit
transducer. DI is the transducer's directivity index which for a rectangular
flat transducer can be approximated by DI = 46.2 – 10lg
are the transmit beamwidths in degrees along and across respectively.
y
The relation between beamwidth and transducer array length, L, depends
upon the applied shading and the number of elements in the array,
typically it would be
limit is conventionally given by R = L
To derive the pressure levels in the nearfield from the source level of an
echo sounder one must first calculate the pressure level at the largest
farfield limit assuming spherical spreading from the 1 meter reference
level used in defining the source level. From the largest to the smallest
nearfield limit the pressure level will increase linearly with distance, and
W/m
, and a pressure level of for
-18
2
= 65 /L where
is the wavelength. The nearfield
/ .
2
1
/ c where
is the water
2
.
2
+ DI. P
is the acoustic
Ac
Ac
where
x
y
6
and
x
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Summary of Contents for Kongsberg EM - TECHNICAL NOTE 2005
- Page 1 EM Technical Note Date: September 20, 2005 Author: Erik Hammerstad Subject: Sound Levels from Kongsberg Multibeams The power output level of an echo sounder is normally specified by giving its source level in dB relative to 1 μPa at a distance of 1 m from the transmit transducer.
- Page 2 from the smallest nearfield limit in to the transducer level the pressure level will be constant. If the source level of the echo sounder is not known, but both beamwidths or transducer array lengths or even just area are, the maximum possible pressure level may still to a good degree be estimated.
- Page 3 System PL@NF1 PL@NF2 SBP 120 3° 0.8m 140m SBP 120 6° 0.8m SBP 120 12° 0.8m EM 122 0.5° 2.8m 1840m EM 120/122 1° 2.8m 460m EM 120/122 2° 2.8m 115m EM 302 0.5° 720m EM 300/302 1° 180m EM 300/302 2° EM 710 0.5°...
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