Sound power

Sound measurements
Sound measurements
Characteristic	Symbols
Sound pressure	p, SPL, LPA
Particle velocity	v, SVL
Particle displacement	δ
Sound intensity	I, SIL
Sound power	P, SWL, LWA
Sound energy	W
Sound energy density	w
Sound exposure	E, SEL
Acoustic impedance	Z
Audio frequency	AF
Transmission loss	TL
	v; t; e;

Sound power or acoustic power is the rate at which sound energy is emitted, reflected, transmitted or received, per unit time.^[1] It is defined^[2] as "through a surface, the product of the sound pressure, and the component of the particle velocity, at a point on the surface in the direction normal to the surface, integrated over that surface." The SI unit of sound power is the watt (W).^[1] It relates to the power of the sound force on a surface enclosing a sound source, in air.

Quick Facts Characteristic, Particle velocity ...

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For a sound source, unlike sound pressure, sound power is neither room-dependent nor distance-dependent. Sound pressure is a property of the field at a point in space, while sound power is a property of a sound source, equal to the total power emitted by that source in all directions. Sound power passing through an area is sometimes called sound flux or acoustic flux through that area.

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Sound power level LWA

Regulations often specify a method for measurement^[3] that integrates sound pressure over a surface enclosing the source. L_WA specifies the power delivered to that surface in decibels relative to one picowatt. Devices (e.g., a vacuum cleaner) often have labeling requirements and maximum amounts they are allowed to produce. The A-weighting scale is used in the calculation as the metric is concerned with the loudness as perceived by the human ear. Measurements^[4] in accordance with ISO 3744 are taken at 6 to 12 defined points around the device in a hemi-anechoic space. The test environment can be located indoors or outdoors. The required environment is on hard ground in a large open space or hemi-anechoic chamber (free-field over a reflecting plane.)

Table of selected sound sources

Here is a table of some examples, from an on-line source.^[5] For omnidirectional sources in free space, sound power in L_wA is equal to sound pressure level in dB above 20 micropascals at a distance of 0.2821 m^[6]

More information Situation and, Sound power (W) ...

Situation and sound source	Sound power (W)	Sound power level (dB ref 10⁻¹² W)
Saturn V rocket^[7]	100000000	200
Project Artemis Sonar	1000000	180
Turbojet engine	100000	170
Turbofan aircraft at take-off	1000	150
Turboprop aircraft at take-off	100	140
Machine gun Large pipe organ	10	130
Symphony orchestra Heavy thunder Sonic boom	1	120
Rock concert (1970s) Chain saw Accelerating motorcycle	0.1	110
Lawn mower Car at highway speed Subway steel wheels	0.01	100
Large diesel vehicle	0.001	90
Loud alarm clock	0.0001	80
Relatively quiet vacuum cleaner	10⁻⁵	70
Hair dryer	10⁻⁶	60
Radio or TV	10⁻⁷	50
Refrigerator Low voice	10⁻⁸	40
Quiet conversation	10⁻⁹	30
Whisper of one person Wristwatch ticking	10⁻¹⁰	20
Human breath of one person	10⁻¹¹	10
Reference value	10⁻¹²	0

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Mathematical definition

Sound power, denoted P, is defined by^[8]

P=\mathbf {f} \cdot \mathbf {v} =Ap\,\mathbf {u} \cdot \mathbf {v} =Apv

where

f is the sound force of unit vector u;
v is the particle velocity of projection v along u;
A is the area;
p is the sound pressure.

In a medium, the sound power is given by

P={\frac {Ap^{2}}{\rho c}}\cos \theta ,

where

A is the area of the surface;
ρ is the mass density;
c is the sound velocity;
θ is the angle between the direction of propagation of the sound and the normal to the surface.
p is the sound pressure.

For example, a sound at SPL = 85 dB or p = 0.356 Pa in air (ρ = 1.2 kg⋅m⁻³ and c = 343 m⋅s⁻¹) through a surface of area A = 1 m² normal to the direction of propagation (θ = 0°) has a sound energy flux P = 0.3 mW.

This is the parameter one would be interested in when converting noise back into usable energy, along with any losses in the capturing device.

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Relationships with other quantities

Sound power is related to sound intensity:

P=AI,

where

A stands for the area;
I stands for the sound intensity.

Sound power is related sound energy density:

P=Acw,

where

c stands for the speed of sound;
w stands for the sound energy density.

Sound power level

Sound power level (SWL) or acoustic power level is a logarithmic measure of the power of a sound relative to a reference value.
Sound power level, denoted L_W and measured in dB,^[9] is defined by:^[10]

L_{W}={\frac {1}{2}}\ln \!\left({\frac {P}{P_{0}}}\right)\!~\mathrm {Np} =\log _{10}\!\left({\frac {P}{P_{0}}}\right)\!~\mathrm {B} =10\log _{10}\!\left({\frac {P}{P_{0}}}\right)\!~\mathrm {dB} ,

where

P is the sound power;
P₀ is the reference sound power;
1 Np = 1 is the neper;
1 B = ⁠1/2⁠ ln 10 is the bel;
1 dB = ⁠1/20⁠ ln 10 is the decibel.

The commonly used reference sound power in air is^[11]

P_{0}=1~\mathrm {pW} .

The proper notations for sound power level using this reference are L_{W/(1 pW)} or L_W (re 1 pW), but the suffix notations dB SWL, dB(SWL), dBSWL, or dB_SWL are very common, even if they are not accepted by the SI.^[12]

The reference sound power P₀ is defined as the sound power with the reference sound intensity I₀ = 1 pW/m² passing through a surface of area A₀ = 1 m²:

P_{0}=A_{0}I_{0},

hence the reference value P₀ = 1 pW.

Relationship with sound pressure level

The generic calculation of sound power from sound pressure is as follows:

L_{W}=L_{p}+10\log _{10}\!\left({\frac {A_{S}}{A_{0}}}\right)\!~\mathrm {dB} ,

where: ${A_{S}}$ defines the area of a surface that wholly encompasses the source. This surface may be any shape, but it must fully enclose the source.

In the case of a sound source located in free field positioned over a reflecting plane (i.e. the ground), in air at ambient temperature, the sound power level at distance r from the sound source is approximately related to sound pressure level (SPL) by^[13]

L_{W}=L_{p}+10\log _{10}\!\left({\frac {2\pi r^{2}}{A_{0}}}\right)\!~\mathrm {dB} ,

where

L_p is the sound pressure level;
A₀ = 1 m²;
${2\pi r^{2}},$ defines the surface area of a hemisphere; and
r must be sufficient that the hemisphere fully encloses the source.

Derivation of this equation:

{\begin{aligned}L_{W}&={\frac {1}{2}}\ln \!\left({\frac {P}{P_{0}}}\right)\\&={\frac {1}{2}}\ln \!\left({\frac {AI}{A_{0}I_{0}}}\right)\\&={\frac {1}{2}}\ln \!\left({\frac {I}{I_{0}}}\right)+{\frac {1}{2}}\ln \!\left({\frac {A}{A_{0}}}\right)\!.\end{aligned}}

For a progressive spherical wave,

z_{0}={\frac {p}{v}},

A=4\pi r^{2},

(the surface area of sphere)

where z₀ is the characteristic specific acoustic impedance.

Consequently,

I=pv={\frac {p^{2}}{z_{0}}},

and since by definition I₀ = p₀²/z₀, where p₀ = 20 μPa is the reference sound pressure,

{\begin{aligned}L_{W}&={\frac {1}{2}}\ln \!\left({\frac {p^{2}}{p_{0}^{2}}}\right)+{\frac {1}{2}}\ln \!\left({\frac {4\pi r^{2}}{A_{0}}}\right)\\&=\ln \!\left({\frac {p}{p_{0}}}\right)+{\frac {1}{2}}\ln \!\left({\frac {4\pi r^{2}}{A_{0}}}\right)\\&=L_{p}+10\log _{10}\!\left({\frac {4\pi r^{2}}{A_{0}}}\right)\!~\mathrm {dB} .\end{aligned}}

The sound power estimated practically does not depend on distance. The sound pressure used in the calculation may be affected by distance due to viscous effects in the propagation of sound unless this is accounted for.

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References

[1]
Ronald J. Baken, Robert F. Orlikoff (2000). Clinical Measurement of Speech and Voice. Cengage Learning. p. 94. ISBN 9781565938694.
[2]
"ISO 80000-8(en) Quantities and Units - Acoustics". [ISO].
[3]
"ISO 3744:2010(en) Acoustics — Determination of sound power levels and sound energy levels of noise sources using sound pressure — Engineering methods for an essentially free field over a reflecting plane". [ISO]. Retrieved 22 December 2017.
[4]
"EU Sound Power Regulation for Vacuum Cleaners". [NTi Audio]. 19 December 2017. Retrieved 22 December 2017.
[5]
"Sound Power". The Engineering Toolbox. Retrieved 28 November 2013.
[6]
"Sound Power Level".
[7]
Allgood, Daniel C. (15 February 2012). "NASA Technical Reports Server (NTRS)". NASA. Retrieved 2021-03-24. the largest sound power levels ever experienced at NASA Stennis was approximately 204dB, which corresponded to the Saturn S‐IC stage on the B‐2 test stand.
[8]
Landau & Lifshitz, "Fluid Mechanics", Course of Theoretical Physics, Vol. 6
[9]
"Letter symbols to be used in electrical technology – Part 3: Logarithmic and related quantities, and their units", IEC 60027-3 Ed. 3.0, International Electrotechnical Commission, 19 July 2002.
[10]
Attenborough K, Postema M (2008). A pocket-sized introduction to acoustics. Kingston upon Hull: University of Hull. doi:10.5281/zenodo.7504060. ISBN 978-90-812588-2-1.
[11]
Ross Roeser, Michael Valente, Audiology: Diagnosis (Thieme 2007), p. 240.
[12]
Thompson, A. and Taylor, B. N. sec 8.7, "Logarithmic quantities and units: level, neper, bel", Guide for the Use of the International System of Units (SI) 2008 Edition, NIST Special Publication 811, 2nd printing (November 2008), SP811 PDF
[13]
Chadderton, David V. Building services engineering, pp. 301, 306, 309, 322. Taylor & Francis, 2004. ISBN 0-415-31535-2

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External links

[clinical-1] [1]
Ronald J. Baken, Robert F. Orlikoff (2000). Clinical Measurement of Speech and Voice. Cengage Learning. p. 94. ISBN 9781565938694.

[2] [2]
"ISO 80000-8(en) Quantities and Units - Acoustics". [ISO].

[3] [3]
"ISO 3744:2010(en) Acoustics — Determination of sound power levels and sound energy levels of noise sources using sound pressure — Engineering methods for an essentially free field over a reflecting plane". [ISO]. Retrieved 22 December 2017.

[4] [4]
"EU Sound Power Regulation for Vacuum Cleaners". [NTi Audio]. 19 December 2017. Retrieved 22 December 2017.

[5] [5]
"Sound Power". The Engineering Toolbox. Retrieved 28 November 2013.

[6] [6]
"Sound Power Level".

[7] [7]
Allgood, Daniel C. (15 February 2012). "NASA Technical Reports Server (NTRS)". NASA. Retrieved 2021-03-24. the largest sound power levels ever experienced at NASA Stennis was approximately 204dB, which corresponded to the Saturn S‐IC stage on the B‐2 test stand.

[8] [8]
Landau & Lifshitz, "Fluid Mechanics", Course of Theoretical Physics, Vol. 6

[IEC60027-3-9] [9]
"Letter symbols to be used in electrical technology – Part 3: Logarithmic and related quantities, and their units", IEC 60027-3 Ed. 3.0, International Electrotechnical Commission, 19 July 2002.

[10] [10]
Attenborough K, Postema M (2008). A pocket-sized introduction to acoustics. Kingston upon Hull: University of Hull. doi:10.5281/zenodo.7504060. ISBN 978-90-812588-2-1.

[11] [11]
Ross Roeser, Michael Valente, Audiology: Diagnosis (Thieme 2007), p. 240.

[NIST2008-12] [12]
Thompson, A. and Taylor, B. N. sec 8.7, "Logarithmic quantities and units: level, neper, bel", Guide for the Use of the International System of Units (SI) 2008 Edition, NIST Special Publication 811, 2nd printing (November 2008), SP811 PDF

[Chadderton-13] [13]
Chadderton, David V. Building services engineering, pp. 301, 306, 309, 322. Taylor & Francis, 2004. ISBN 0-415-31535-2

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