Acoustic theory

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Acoustic theory is the field relating to mathematical description of sound waves. It is derived from fluid dynamics. See acoustics for the engineering approach.

The propagation of sound waves in a fluid (such as water) can be modeled by an equation of motion (conservation of momentum) and an equation of continuity (conservation of mass). With some simplifications, in particular constant density, they can be given as follows:

ρ0βˆ‚π―βˆ‚t+βˆ‡p=0(Momentum balance)βˆ‚pβˆ‚t+ΞΊβˆ‡β‹…π―=0(Mass balance)

where p(𝐱,t) is the acoustic pressure and 𝐯(𝐱,t) is the acoustic fluid velocity vector, 𝐱 is the vector of spatial coordinates x,y,z, t is the time, ρ0 is the static mass density of the medium and κ is the bulk modulus of the medium. The bulk modulus can be expressed in terms of the density and the speed of sound in the medium (c0) as

κ=ρ0c02.

If the acoustic fluid velocity field is irrotational, βˆ‡Γ—π―=𝟎, then the acoustic wave equation is a combination of these two sets of balance equations and can be expressed as [1]

βˆ‚2π―βˆ‚t2βˆ’c02βˆ‡2𝐯=0orβˆ‚2pβˆ‚t2βˆ’c02βˆ‡2p=0,

where we have used the vector Laplacian, βˆ‡2𝐯=βˆ‡(βˆ‡β‹…π―)βˆ’βˆ‡Γ—(βˆ‡Γ—π―) . The acoustic wave equation (and the mass and momentum balance equations) are often expressed in terms of a scalar potential Ο† where 𝐯=βˆ‡Ο†. In that case the acoustic wave equation is written as

βˆ‚2Ο†βˆ‚t2βˆ’c02βˆ‡2Ο†=0

and the momentum balance and mass balance are expressed as

p+ρ0βˆ‚Ο†βˆ‚t=0;ρ+ρ0c02βˆ‚Ο†βˆ‚t=0.

Derivation of the governing equations

The derivations of the above equations for waves in an acoustic medium are given below.

Conservation of momentum

The equations for the conservation of linear momentum for a fluid medium are

ρ(βˆ‚π―βˆ‚t+π―β‹…βˆ‡π―)=βˆ’βˆ‡p+βˆ‡β‹…π’”+ρ𝐛

where 𝐛 is the body force per unit mass, p is the pressure, and 𝒔 is the deviatoric stress. If 𝝈 is the Cauchy stress, then

p:=βˆ’13tr(𝝈);𝒔:=𝝈+p1

where 1 is the rank-2 identity tensor.

We make several assumptions to derive the momentum balance equation for an acoustic medium. These assumptions and the resulting forms of the momentum equations are outlined below.

Assumption 1: Newtonian fluid

In acoustics, the fluid medium is assumed to be Newtonian. For a Newtonian fluid, the deviatoric stress tensor is related to the velocity by

𝒔=ΞΌ[βˆ‡π―+(βˆ‡π―)T]+Ξ»(βˆ‡β‹…π―)1

where ΞΌ is the shear viscosity and Ξ» is the bulk viscosity.

Therefore, the divergence of 𝒔 is given by

βˆ‡β‹…π’”β‰‘βˆ‚sijβˆ‚xi=ΞΌ[βˆ‚βˆ‚xi(βˆ‚viβˆ‚xj+βˆ‚vjβˆ‚xi)]+Ξ»[βˆ‚βˆ‚xi(βˆ‚vkβˆ‚xk)]Ξ΄ij=ΞΌβˆ‚2viβˆ‚xiβˆ‚xj+ΞΌβˆ‚2vjβˆ‚xiβˆ‚xi+Ξ»βˆ‚2vkβˆ‚xkβˆ‚xj=(ΞΌ+Ξ»)βˆ‚2viβˆ‚xiβˆ‚xj+ΞΌβˆ‚2vjβˆ‚xi2≑(ΞΌ+Ξ»)βˆ‡(βˆ‡β‹…π―)+ΞΌβˆ‡2𝐯.

Using the identity βˆ‡2𝐯=βˆ‡(βˆ‡β‹…π―)βˆ’βˆ‡Γ—βˆ‡Γ—π―, we have

βˆ‡β‹…π’”=(2ΞΌ+Ξ»)βˆ‡(βˆ‡β‹…π―)βˆ’ΞΌβˆ‡Γ—βˆ‡Γ—π―.

The equations for the conservation of momentum may then be written as

ρ(βˆ‚π―βˆ‚t+π―β‹…βˆ‡π―)=βˆ’βˆ‡p+(2ΞΌ+Ξ»)βˆ‡(βˆ‡β‹…π―)βˆ’ΞΌβˆ‡Γ—βˆ‡Γ—π―+ρ𝐛

Assumption 2: Irrotational flow

For most acoustics problems we assume that the flow is irrotational, that is, the vorticity is zero. In that case

βˆ‡Γ—π―=0

and the momentum equation reduces to

ρ(βˆ‚π―βˆ‚t+π―β‹…βˆ‡π―)=βˆ’βˆ‡p+(2ΞΌ+Ξ»)βˆ‡(βˆ‡β‹…π―)+ρ𝐛

Assumption 3: No body forces

Another frequently made assumption is that effect of body forces on the fluid medium is negligible. The momentum equation then further simplifies to

ρ(βˆ‚π―βˆ‚t+π―β‹…βˆ‡π―)=βˆ’βˆ‡p+(2ΞΌ+Ξ»)βˆ‡(βˆ‡β‹…π―)

Assumption 4: No viscous forces

Additionally, if we assume that there are no viscous forces in the medium (the bulk and shear viscosities are zero), the momentum equation takes the form

ρ(βˆ‚π―βˆ‚t+π―β‹…βˆ‡π―)=βˆ’βˆ‡p

Assumption 5: Small disturbances

An important simplifying assumption for acoustic waves is that the amplitude of the disturbance of the field quantities is small. This assumption leads to the linear or small signal acoustic wave equation. Then we can express the variables as the sum of the (time averaged) mean field (βŸ¨β‹…βŸ©) that varies in space and a small fluctuating field (β‹…~) that varies in space and time. That is

p=⟨p⟩+p~;ρ=⟨ρ⟩+ρ~;𝐯=⟨𝐯⟩+𝐯~

and

βˆ‚βŸ¨pβŸ©βˆ‚t=0;βˆ‚βŸ¨ΟβŸ©βˆ‚t=0;βˆ‚βŸ¨π―βŸ©βˆ‚t=𝟎.

Then the momentum equation can be expressed as

[⟨ρ⟩+ρ~][βˆ‚π―~βˆ‚t+[⟨𝐯⟩+𝐯~]β‹…βˆ‡[⟨𝐯⟩+𝐯~]]=βˆ’βˆ‡[⟨p⟩+p~]

Since the fluctuations are assumed to be small, products of the fluctuation terms can be neglected (to first order) and we have

βŸ¨ΟβŸ©βˆ‚π―~βˆ‚t+[⟨ρ⟩+ρ~][βŸ¨π―βŸ©β‹…βˆ‡βŸ¨π―βŸ©]+⟨ρ⟩[βŸ¨π―βŸ©β‹…βˆ‡π―~+𝐯~β‹…βˆ‡βŸ¨π―βŸ©]=βˆ’βˆ‡[⟨p⟩+p~]

Assumption 6: Homogeneous medium

Next we assume that the medium is homogeneous; in the sense that the time averaged variables ⟨p⟩ and ⟨ρ⟩ have zero gradients, i.e.,

βˆ‡βŸ¨p⟩=0;βˆ‡βŸ¨ΟβŸ©=0.

The momentum equation then becomes

βŸ¨ΟβŸ©βˆ‚π―~βˆ‚t+[⟨ρ⟩+ρ~][βŸ¨π―βŸ©β‹…βˆ‡βŸ¨π―βŸ©]+⟨ρ⟩[βŸ¨π―βŸ©β‹…βˆ‡π―~+𝐯~β‹…βˆ‡βŸ¨π―βŸ©]=βˆ’βˆ‡p~

Assumption 7: Medium at rest

At this stage we assume that the medium is at rest which implies that the mean velocity is zero, i.e. ⟨𝐯⟩=0. Then the balance of momentum reduces to

βŸ¨ΟβŸ©βˆ‚π―~βˆ‚t=βˆ’βˆ‡p~

Dropping the tildes and using ρ0:=⟨ρ⟩, we get the commonly used form of the acoustic momentum equation

ρ0βˆ‚π―βˆ‚t+βˆ‡p=0.

Conservation of mass

The equation for the conservation of mass in a fluid volume (without any mass sources or sinks) is given by

βˆ‚Οβˆ‚t+βˆ‡β‹…(ρ𝐯)=0

where ρ(𝐱,t) is the mass density of the fluid and 𝐯(𝐱,t) is the fluid velocity.

The equation for the conservation of mass for an acoustic medium can also be derived in a manner similar to that used for the conservation of momentum.

Assumption 1: Small disturbances

From the assumption of small disturbances we have

p=⟨p⟩+p~;ρ=⟨ρ⟩+ρ~;𝐯=⟨𝐯⟩+𝐯~

and

βˆ‚βŸ¨pβŸ©βˆ‚t=0;βˆ‚βŸ¨ΟβŸ©βˆ‚t=0;βˆ‚βŸ¨π―βŸ©βˆ‚t=𝟎.

Then the mass balance equation can be written as

βˆ‚Ο~βˆ‚t+[⟨ρ⟩+ρ~]βˆ‡β‹…[⟨𝐯⟩+𝐯~]+βˆ‡[⟨ρ⟩+ρ~]β‹…[⟨𝐯⟩+𝐯~]=0

If we neglect higher than first order terms in the fluctuations, the mass balance equation becomes

βˆ‚Ο~βˆ‚t+[⟨ρ⟩+ρ~]βˆ‡β‹…βŸ¨π―βŸ©+βŸ¨ΟβŸ©βˆ‡β‹…π―~+βˆ‡[⟨ρ⟩+ρ~]β‹…βŸ¨π―βŸ©+βˆ‡βŸ¨ΟβŸ©β‹…π―~=0

Assumption 2: Homogeneous medium

Next we assume that the medium is homogeneous, i.e.,

βˆ‡βŸ¨ΟβŸ©=0.

Then the mass balance equation takes the form

βˆ‚Ο~βˆ‚t+[⟨ρ⟩+ρ~]βˆ‡β‹…βŸ¨π―βŸ©+βŸ¨ΟβŸ©βˆ‡β‹…π―~+βˆ‡Ο~β‹…βŸ¨π―βŸ©=0

Assumption 3: Medium at rest

At this stage we assume that the medium is at rest, i.e., ⟨𝐯⟩=0. Then the mass balance equation can be expressed as

βˆ‚Ο~βˆ‚t+βŸ¨ΟβŸ©βˆ‡β‹…π―~=0

Assumption 4: Ideal gas, adiabatic, reversible

In order to close the system of equations we need an equation of state for the pressure. To do that we assume that the medium is an ideal gas and all acoustic waves compress the medium in an adiabatic and reversible manner. The equation of state can then be expressed in the form of the differential equation:

dpdρ=γpρ;γ:=cpcv;c2=γpρ.

where cp is the specific heat at constant pressure, cv is the specific heat at constant volume, and c is the wave speed. The value of Ξ³ is 1.4 if the acoustic medium is air.

For small disturbances

dpdΟβ‰ˆp~ρ~;pΟβ‰ˆβŸ¨p⟩⟨ρ⟩;c2β‰ˆc02=γ⟨p⟩⟨ρ⟩.

where c0 is the speed of sound in the medium.

Therefore,

p~ρ~=γ⟨p⟩⟨ρ⟩=c02βˆ‚p~βˆ‚t=c02βˆ‚Ο~βˆ‚t

The balance of mass can then be written as

1c02βˆ‚p~βˆ‚t+βŸ¨ΟβŸ©βˆ‡β‹…π―~=0

Dropping the tildes and defining ρ0:=⟨ρ⟩ gives us the commonly used expression for the balance of mass in an acoustic medium:

βˆ‚pβˆ‚t+ρ0c02βˆ‡β‹…π―=0.

Governing equations in cylindrical coordinates

If we use a cylindrical coordinate system (r,θ,z) with basis vectors 𝐞r,𝐞θ,𝐞z, then the gradient of p and the divergence of 𝐯 are given by

βˆ‡p=βˆ‚pβˆ‚r𝐞r+1rβˆ‚pβˆ‚ΞΈπžΞΈ+βˆ‚pβˆ‚z𝐞zβˆ‡β‹…π―=βˆ‚vrβˆ‚r+1r(βˆ‚vΞΈβˆ‚ΞΈ+vr)+βˆ‚vzβˆ‚z

where the velocity has been expressed as 𝐯=vr𝐞r+vθ𝐞θ+vz𝐞z.

The equations for the conservation of momentum may then be written as

ρ0[βˆ‚vrβˆ‚t𝐞r+βˆ‚vΞΈβˆ‚t𝐞θ+βˆ‚vzβˆ‚t𝐞z]+βˆ‚pβˆ‚r𝐞r+1rβˆ‚pβˆ‚ΞΈπžΞΈ+βˆ‚pβˆ‚z𝐞z=0

In terms of components, these three equations for the conservation of momentum in cylindrical coordinates are

ρ0βˆ‚vrβˆ‚t+βˆ‚pβˆ‚r=0;ρ0βˆ‚vΞΈβˆ‚t+1rβˆ‚pβˆ‚ΞΈ=0;ρ0βˆ‚vzβˆ‚t+βˆ‚pβˆ‚z=0.

The equation for the conservation of mass can similarly be written in cylindrical coordinates as

βˆ‚pβˆ‚t+ΞΊ[βˆ‚vrβˆ‚r+1r(βˆ‚vΞΈβˆ‚ΞΈ+vr)+βˆ‚vzβˆ‚z]=0.

Time harmonic acoustic equations in cylindrical coordinates

The acoustic equations for the conservation of momentum and the conservation of mass are often expressed in time harmonic form (at fixed frequency). In that case, the pressures and the velocity are assumed to be time harmonic functions of the form

p(𝐱,t)=pΜ‚(𝐱)eβˆ’iΟ‰t;𝐯(𝐱,t)=𝐯̂(𝐱)eβˆ’iΟ‰t;i:=βˆ’1

where Ο‰ is the frequency. Substitution of these expressions into the governing equations in cylindrical coordinates gives us the fixed frequency form of the conservation of momentum

βˆ‚pΜ‚βˆ‚r=iωρ0vΜ‚r;1rβˆ‚pΜ‚βˆ‚ΞΈ=iωρ0vΜ‚ΞΈ;βˆ‚pΜ‚βˆ‚z=iωρ0vΜ‚z

and the fixed frequency form of the conservation of mass

iΟ‰pΜ‚ΞΊ=βˆ‚vΜ‚rβˆ‚r+1r(βˆ‚vΜ‚ΞΈβˆ‚ΞΈ+vΜ‚r)+βˆ‚vΜ‚zβˆ‚z.

Special case: No z-dependence

In the special case where the field quantities are independent of the z-coordinate we can eliminate vr,vΞΈ to get

βˆ‚2pβˆ‚r2+1rβˆ‚pβˆ‚r+1r2βˆ‚2pβˆ‚ΞΈ2+Ο‰2ρ0ΞΊp=0

Assuming that the solution of this equation can be written as

p(r,ΞΈ)=R(r)Q(ΞΈ)

we can write the partial differential equation as

r2Rd2Rdr2+rRdRdr+r2Ο‰2ρ0ΞΊ=βˆ’1Qd2QdΞΈ2

The left hand side is not a function of ΞΈ while the right hand side is not a function of r. Hence,

r2d2Rdr2+rdRdr+r2Ο‰2ρ0ΞΊR=Ξ±2R;d2QdΞΈ2=βˆ’Ξ±2Q

where Ξ±2 is a constant. Using the substitution

r~←(ωρ0ΞΊ)r=kr

we have

r~2d2Rdr~2+r~dRdr~+(r~2βˆ’Ξ±2)R=0;d2QdΞΈ2=βˆ’Ξ±2Q

The equation on the left is the Bessel equation which has the general solution

R(r)=AΞ±JΞ±(kr)+BΞ±Jβˆ’Ξ±(kr)

where JΞ± is the cylindrical Bessel function of the first kind and AΞ±,BΞ± are undetermined constants. The equation on the right has the general solution

Q(ΞΈ)=CΞ±eiΞ±ΞΈ+DΞ±eβˆ’iΞ±ΞΈ

where CΞ±,DΞ± are undetermined constants. Then the solution of the acoustic wave equation is

p(r,ΞΈ)=[AΞ±JΞ±(kr)+BΞ±Jβˆ’Ξ±(kr)](CΞ±eiΞ±ΞΈ+DΞ±eβˆ’iΞ±ΞΈ)

Boundary conditions are needed at this stage to determine Ξ± and the other undetermined constants.

References

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See also

  1. ↑ Douglas D. Reynolds. (1981). Engineering Principles in Acoustics, Allyn and Bacon Inc., Boston.