akamatsu: Water tank minimum resonant and cutoff frequencies
In seewave: Sound Analysis and Synthesis
akamatsu R Documentation
Water tank minimum resonant and cutoff frequencies
Description
This function computes the resonant and cutoff frequencies when
recording in a given aquarium according to the criteria explained in Akamatsu et al. (2002)
Usage
akamatsu(Lx, Ly, Lz, mode = c(1,1,1),
c = 148000, plot = FALSE, xlab = "Frequency (kHz)",
ylab = "Attenuation distance (cm)", ...)
Arguments
Lx
watertank length (in cm).
Ly
watertank width (in cm).
Lz
watertank height (in cm).
mode
mode, see details.
c
sound velocity in cm/s (by default 148000 cm/s in water).
plot
logical, if TRUE plots the attenuation distance in function of frequency.
xlab
title of the x axis if plot is TRUE.
ylab
title of the y axis if plot is TRUE.
...
other plot graphical parameters.
Details
From Akamatsu et al. (2002):
1. Resonant frequency
The calculated resonant frequencies of a rectangular glass tank with the dimension of Lx , Ly , and Lz (in centimeters) can
be described by the following equation:
f^{rectangular}_{lmn} = \frac{c}{2} \times \sqrt{\left(\frac{l}{L_{x}}\right)^2 +
\left(\frac{m}{L_{y}}\right)^2 + \left(\frac{n}{L_{z}}\right)^2}
where c is the sound velocity (cm/s) and each l, m, n reprents an
integer, and the combination of these paramameters designates the
'mode number'. The mode (1, 1, 1) represents the resonance wave of minimum
frequency. The mode (2, 1, 1) represents one of the higher order of
resonant component and has additional node of the soundpressure level
at the middle of the X axis, i.e., Lx/2.
2. Cutoff frequency
The cutoff frequency can be calculated as follows:
f^{rectangular}_{cutoff} = \frac{c}{2} \times \sqrt{
\left(\frac{1}{L_{y}}\right)^2 + \left(\frac{1}{L_{z}}\right)^2}
3. Attenuation distance
The theoretical attenuation distance D can be expressed in function of the
cutoff frequency and the projected frequency following:
D^{rectangular}(f) = 2 \times log_{10} \times \frac{c}{4 \pi
f^{rectangular}_{cutoff}} \times \frac{1}{\sqrt{1-\left(\frac{f}{f^{rectangular}_{cutoff}}\right)^2}}
Value
A list of two items:
res
Resonant frequency (in Hz). See Details
cut
Cut frequency (in Hz). See Details
Author(s)
Camille Desjonqueres
References
Akamatsu T, Okumura T, Novarini N, Yan HY (2002) Emprical refinements applicable to the recording of fish sounds in small tanks. Journal of the Acoustical Society of America, 112, 3073-3082.
Examples
akamatsu(60, 30, 40)
seewave documentation built on Oct. 19, 2023, 5:07 p.m.
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| akamatsu | R Documentation |
Water tank minimum resonant and cutoff frequencies
Description
This function computes the resonant and cutoff frequencies when recording in a given aquarium according to the criteria explained in Akamatsu et al. (2002)
Usage
akamatsu(Lx, Ly, Lz, mode = c(1,1,1),
c = 148000, plot = FALSE, xlab = "Frequency (kHz)",
ylab = "Attenuation distance (cm)", ...)
Arguments
Lx |
watertank length (in cm). |
Ly |
watertank width (in cm). |
Lz |
watertank height (in cm). |
mode |
mode, see details. |
c |
sound velocity in cm/s (by default 148000 cm/s in water). |
plot |
logical, if |
xlab |
title of the x axis if |
ylab |
title of the y axis if |
... |
other |
Details
From Akamatsu et al. (2002):
1. Resonant frequency
The calculated resonant frequencies of a rectangular glass tank with the dimension of Lx , Ly , and Lz (in centimeters) can
be described by the following equation:
f^{rectangular}_{lmn} = \frac{c}{2} \times \sqrt{\left(\frac{l}{L_{x}}\right)^2 +
\left(\frac{m}{L_{y}}\right)^2 + \left(\frac{n}{L_{z}}\right)^2}
where c is the sound velocity (cm/s) and each l, m, n reprents an
integer, and the combination of these paramameters designates the
'mode number'. The mode (1, 1, 1) represents the resonance wave of minimum
frequency. The mode (2, 1, 1) represents one of the higher order of
resonant component and has additional node of the soundpressure level
at the middle of the X axis, i.e., Lx/2.
2. Cutoff frequency
The cutoff frequency can be calculated as follows:
f^{rectangular}_{cutoff} = \frac{c}{2} \times \sqrt{
\left(\frac{1}{L_{y}}\right)^2 + \left(\frac{1}{L_{z}}\right)^2}
3. Attenuation distance
The theoretical attenuation distance D can be expressed in function of the
cutoff frequency and the projected frequency following:
D^{rectangular}(f) = 2 \times log_{10} \times \frac{c}{4 \pi
f^{rectangular}_{cutoff}} \times \frac{1}{\sqrt{1-\left(\frac{f}{f^{rectangular}_{cutoff}}\right)^2}}
Value
A list of two items:
res |
Resonant frequency (in Hz). See |
cut |
Cut frequency (in Hz). See |
Author(s)
Camille Desjonqueres
References
Akamatsu T, Okumura T, Novarini N, Yan HY (2002) Emprical refinements applicable to the recording of fish sounds in small tanks. Journal of the Acoustical Society of America, 112, 3073-3082.
Examples
akamatsu(60, 30, 40)
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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