The Sound Stops with the Passive Sonar
Equation
Matthew Duggan
The bioSNR package is an open-source SONAR equation calculator. The
calculator is capable of handling simple to intermediate level acoustic
problems associated with bioacoustics and passive acoustic monitoring
(PAM) systems.
This document gives quick examples of bioSNR’s capabilities with the
commonly utilized passive sonar equation.
#Stable - Install package from CRAN
install.packages("bioSNR")
#Unstable - Install package from Github repository
devtools::install_github("MattyD797/bioSNR")
#Attach package namespace to active libraries in Rstudio
library(bioSNR)
The Passive Sonar Equation
The passive sonar equation describes the relationship, or
sound-to-noise ratio (SNR), of an underwater sound from
a source to receiver. This equation is useful for determining detection
ranges of recording units, as well as acoustic active space, that is the
distance from the sourcce over which the signal’s amplitude renains
above the detection threshold of potential listeners (Marten and Marlet,
1977). It terms of bioacoustics, the equation can be outlined as
follows:
\[SL-TL-(NL-PG)\geq DT\]
- \(SL\) is the source level
of the signal of interest, as measured in dBs.
- \(TL\) is the transmission
loss or propagation loss (e.g., absorption, reflection, and
diffusion).
- \(NL\) is the noise level
or background ambient noise in the recorder’s local environment.
- \(PG\) is the processing
gain or directivity index which reduces the noise level.
- \(DT\) is the detection
threshold, or the additional dBs the signal of interest must
achieve above ambient noise conditions in order to be detected by the
receiver.
Source Level
Before we start applying the passive sonal equation, let’s further
decompose its parts. The \(SL\) is
typically measured 1 meter away from the source (~3 wavelengths). This
also means that \(SL\) is the ratio
between the transmitted intensity from the source and the reference
intensity. Refer to the vignette decibels for
a refresher on dBs or the introduction vignette for more information on
intensity, power, and pressure.
If we take a simulated sound source, such as a clown fish called
Nemo, we can better understand the physics! Let’s say for simplicity
that Nemo emits a perfect omni-directional sound. We refer to this
uniform prorogation of sound power as spherical spreading.
Referring to the definition of \(SL\),
we can form this equation:
\[SL=10log\frac{I_s}{I_{ref}}\]
- \(I_s\) is the intensity of the
transmitted signal from 1 meter or approximately 3 wavelengths
away.
- \(I_{ref}\) is the intensity of a
sound with a root mean square pressure of \(1\;\mu Pa\). Note that in bioacoustics
pressure is typically referred to as the root-mean-square pressure
because of the sinusoidal nature of sound waves.
- \(SL\) is the source level in \(dB \:re\: 1\;\mu Pa\), but also maintains
the intensity of a \(1\;\mu Pa\)
signal.
By referring to the equation for intensity, we can easily identify
the relationship between pressure and intensity (\(I = \frac{P_{rms}^2}{z}\)). Just in case, a
similar relationship between intensity and power can also be expressed
as \(I = \frac{P}{4\pi r^2}\). The
\(SL\) can then be expressed in power
or pressure as well:
\[ SL=10log_{10}\frac{I_s}{I_{ref}} =
10log_{10}\frac{P}{4\pi I_{ref}} = 10log_{10}P-10log_{10}(4\pi I_{ref})
= 10log_{10}P+170.8\]
\[ ...= 10log_{10}\frac{P_{rms}^2}{\rho c
I_{ref}} = 10log_{10}P_{rms}^2-10log_{10}(\rho c *
6.7*10^{-19})\]
- Where \(I_{ref}\) is equal to \(1 \mu Pa\) (as documented in the decibels
vignette: \(1 \mu Pa = 6.7*10^{-19}\:
\frac{W}{m^2}\))
Transmission Loss
Nemo’s sound will eventually soften as the sound wave moves through
the water. This propagation loss is caused by resistance of water
particles to move and the properties of the water itself. The exact
definition is the ratio of sound intensity at 1 m from a source to the
sound intensity at distance \(r\).
Thus, transmission loss can be represented as the following:
\[TL = 10log\frac{I_s}{I_sR}\]
\(TL\) is the most complicated
parameter in the passive sonar equation, but in an idealized ocean
environment transmission loss has two components: 1) geometric spreading
and 2) absorption of the sound as it propagates. Geometric spreading (1)
is the primary contributor to transmission loss. As the signal of
interest’s energy geometrically spreads over a larger area, the
intensity of the sound lowers over the increasing distance. Absorption
(2) involves the absorption coefficient which we provide a function to
calculate in the introduction vignette. We discuss in greater depth what
factors are considered in calculating this measurement.
Geometric spreading is characterized as either spherical or
cylindrical. Spreading begins as spherical, but as the signal of
interest continues to spread across larger disances, the surface of the
ocean contrains the rounded top of the sphere, forcing it into a
cylindrical shape. So spherical spreading transitions into cylindrical
once it hits the limiting factor of the ocean’s depth. The transition
from spherical to cylindrical is rarely uniform, but for the sake of
idealized equations, we will maintain a transition range of half the
ocean’s depth at the site of the sound source. Below is the geometric
transmission loss for spherical and then for cylindrical (before and
after transition range):
\[TL_{spherical}=20log_{10}r\]
\[TL_{cylindrical}=10log_{10}r +
10log_{10}r_{trans}\]
- \(r\) is the propagation
distance.
- \(r_{trans}\) is transition range
or half the depth.
The absorption coefficient computed using absorptionWater() is
calculated via the viscous absorption, boric acid relaxation, and
magnesium sulfate relaxation process. While these equations are
explained well in other literature, these explanations are beyond our
need of understanding absorption in the context of bioacoustics, so we
will not repeat them here. When we do factor teh abssorption coefficient
into geometrical spreading, the formula takes on the following form:
\[TL=TL_{spherical |
cylindrical}(r)+\alpha r\]
- \(\alpha\) is the absorption
coefficient calculated using the function bioSNR function
absorptionWater().
Noise Level and Processing Gain
Noise level (\(NL\)) is the ratio
between the average background noise intensity and reference intensity
that is the same as used in the \(SL\)
(typically \(I_{ref} = 6.7*10^{-19}\:
\frac{W}{m^2}\)). While the equation is the same as \(SL\) we can use a Wenz curve (Wenz 1962) to estimate spectrum levels, an
approach adapted into the function specLvlGraph(). Below is the
empirical Wenz curve for odontocetes (toothed whales), that describe
oceanic ambient noise as a function of frequency:
\(NL\) can then be found via the
following formula:
\[ NL=\text{SpectrumLvl} +
10log_{10}(\text{Bandwidth}) \]
- \(Bandwidth\) is equal to the
difference between the maximum to minimum frequency of the measured
frequency band.
An array of recorders can reduce overall noise level. By combining
their independently measurements of the soundscape the signal-to-noise
ratio is increased, which is referred to as propagation gain (\(PG\)) or array gain (\(AG\)). This is typically specified on the
recording array of use. A variety of formulas can also calculate the
\(PG\) value called (e.g.,
‘beamforming’) but this computation is currenltly beyond the scope of
this package. \(PG\) can be assumed to
be 1 \(dB\: re\: 1 \mu Pa\) unless
otherwise stated or known.
Examples
Each example will utilize the following information:
Nemo suddenly turned into a blue whale (Balaenoptera musculus
intermedia) and produced a call near a Rockhopper recording unit.
The call was made at 195 \(dB\: re\: 1 \mu
Pa\) at 1 meter and measured between [28,33] Hz frequency.
- Using a Wenz curve, what would be the noise level in the frequency
band of interest, considering noise from moderate shipping, a sea state
of 1, and a wind speed of 10 mph?
specLvlGraph(c(28,33), ship=4,seaState = 1, wSpeed = 10, boolR = T)[[2]]
#> The noise level (NL) is: 82.9896990174959 dB ref 1 µP
- The \(NL\) is 82.9897 \(dB\: re \: 1\mu Pa\).
- Given the above \(NL\), we want to
find the detection range of the call. We can neglect absorption at this
distance (a=0) in the function rmax(). Given we want a \(DT\) of 10 \(dB\:
re \: 1\mu Pa\), we can calculate \(NL\) by finding the propagation distance in
the formula for \(TL\) and rewriting
the passive sonar equation: \(TL=SL-NL-DT\). We can further break down
the equation of \(TL_{cylindrical}\):
\[TL_{cylindrical}=10log_{10}r +
10log_{10}r_{trans}+\alpha r\]
Into:
\[ 10log_{10}r + 10log_{10}r_{trans} +
\alpha r = SL-NL-DT\]
#Source Level
SL <- 195
#Noise Level - from above
NL <- 82.9897
#Detection Threshold
DT <- 10
#Transition Range <- depth/2
TR <- 2500
rmax(sl=SL,nl=NL,dt=DT,d=5000, xaxis=10000000)
#> [1] 6354626
The call has a detection range of 6354626 meters. Nemo has some
chords!
Wenz, Gordon M. 1962. “Acoustic Ambient Noise in the Ocean:
Spectra and Sources.” The Journal of the Acoustical Society
of America. Acoustical Society of America.