Physics:Acoustic wave equation

In physics, the acoustic wave equation is a second-order partial differential equation that governs the propagation of acoustic waves through a material medium resp. a standing wavefield. The equation describes the evolution of acoustic pressure p or particle velocity u as a function of position x and time t. A simplified (scalar) form of the equation describes acoustic waves in only one spatial dimension, while a more general form describes waves in three dimensions. Propagating waves in a pre-defined direction can also be calculated using a first order one-way wave equation.

For lossy media, more intricate models need to be applied in order to take into account frequency-dependent attenuation and phase speed. Such models include acoustic wave equations that incorporate fractional derivative terms, see also the acoustic attenuation article or the survey paper.^[1]

The wave equation describing a standing wave field in one dimension (position ${\displaystyle x}$) is

${\displaystyle \frac{{\partial }^{2}p}{\partial x^2}-\frac{1}{c^2}\frac{{\partial }^{2}p}{\partial t^2}=0,}$

where ${\displaystyle p}$ is the acoustic pressure (the local deviation from the ambient pressure), and where ${\displaystyle c}$ is the speed of sound.^[2]

Provided that the speed ${\displaystyle c}$ is a constant, not dependent on frequency (the dispersionless case), then the most general solution is

${\displaystyle p=f(ct-x)+g(ct+x)}$

where ${\displaystyle f}$ and ${\displaystyle g}$ are any two twice-differentiable functions. This may be pictured as the superposition of two waveforms of arbitrary profile, one (${\displaystyle f}$) traveling up the x-axis and the other (${\displaystyle g}$) down the x-axis at the speed ${\displaystyle c}$. The particular case of a sinusoidal wave traveling in one direction is obtained by choosing either ${\displaystyle f}$ or ${\displaystyle g}$ to be a sinusoid, and the other to be zero, giving

${\displaystyle p=p_0\sin (\omega t\mp kx)}$.

where ${\displaystyle \omega }$ is the angular frequency of the wave and ${\displaystyle k}$ is its wave number.

The derivation of the wave equation involves three steps: derivation of the equation of state, the linearized one-dimensional continuity equation, and the linearized one-dimensional force equation.

The equation of state (ideal gas law)

${\displaystyle PV=nRT}$

In an adiabatic process, pressure P as a function of density ${\displaystyle \rho }$ can be linearized to

${\displaystyle P=C\rho }$

where C is some constant. Breaking the pressure and density into their mean and total components and noting that ${\displaystyle C=\frac{\partial P}{\partial \rho }}$:

${\displaystyle P-P_0=\left(\frac{\partial P}{\partial \rho }\right)(\rho -{\rho }_0)}$.

The adiabatic bulk modulus for a fluid is defined as

${\displaystyle B={\rho }_0{\left(\frac{\partial P}{\partial \rho }\right)}_{adiabatic}}$

which gives the result

${\displaystyle P-P_0=B\frac{\rho -{\rho }_0}{{\rho }_0}}$.

Condensation, s, is defined as the change in density for a given ambient fluid density.

${\displaystyle s=\frac{\rho -{\rho }_0}{{\rho }_0}}$

The linearized equation of state becomes

${\displaystyle p=Bs}$ where p is the acoustic pressure (${\displaystyle P-P_0}$).

The continuity equation (conservation of mass) in one dimension is

${\displaystyle \frac{\partial \rho }{\partial t}+\frac{\partial }{\partial x}(\rho u)=0}$.

Where u is the flow velocity of the fluid. Again the equation must be linearized and the variables split into mean and variable components.

${\displaystyle \frac{\partial }{\partial t}({\rho }_0+{\rho }_{0}s)+\frac{\partial }{\partial x}({\rho }_{0}u+{\rho }_{0}su)=0}$

Rearranging and noting that ambient density changes with neither time nor position and that the condensation multiplied by the velocity is a very small number:

${\displaystyle \frac{\partial s}{\partial t}+\frac{\partial }{\partial x}u=0}$

Euler's Force equation (conservation of momentum) is the last needed component. In one dimension the equation is:

${\displaystyle \rho \frac{Du}{Dt}+\frac{\partial P}{\partial x}=0}$,

where ${\displaystyle D/Dt}$ represents the convective, substantial or material derivative, which is the derivative at a point moving along with the medium rather than at a fixed point.

Linearizing the variables:

${\displaystyle ({\rho }_0+{\rho }_{0}s)(\frac{\partial }{\partial t}+u\frac{\partial }{\partial x})u+\frac{\partial }{\partial x}(P_0+p)=0}$.

Rearranging and neglecting small terms, the resultant equation becomes the linearized one-dimensional Euler Equation:

${\displaystyle {\rho }_0\frac{\partial u}{\partial t}+\frac{\partial p}{\partial x}=0}$.

Taking the time derivative of the continuity equation and the spatial derivative of the force equation results in:

${\displaystyle \frac{{\partial }^{2}s}{\partial t^2}+\frac{{\partial }^{2}u}{\partial x\partial t}=0}$

${\displaystyle {\rho }_0\frac{{\partial }^{2}u}{\partial x\partial t}+\frac{{\partial }^{2}p}{\partial x^2}=0}$.

Multiplying the first by ${\displaystyle {\rho }_0}$, subtracting the two, and substituting the linearized equation of state,

${\displaystyle -\frac{{\rho }_0}{B}\frac{{\partial }^{2}p}{\partial t^2}+\frac{{\partial }^{2}p}{\partial x^2}=0}$.

The final result is

${\displaystyle \frac{{\partial }^{2}p}{\partial x^2}-\frac{1}{c^2}\frac{{\partial }^{2}p}{\partial t^2}=0}$

where ${\displaystyle c=\sqrt{\frac{B}{{\rho }_0}}}$ is the speed of propagation.

Feynman^[3] provides a derivation of the wave equation for sound in three dimensions as

${\displaystyle {\mathrm{\nabla }}^{2}p-\frac{1}{c^2}\frac{{\partial }^{2}p}{\partial t^2}=0,}$

where ${\displaystyle {\mathrm{\nabla }}^2}$ is the Laplace operator, ${\displaystyle p}$ is the acoustic pressure (the local deviation from the ambient pressure), and ${\displaystyle c}$ is the speed of sound.

A similar looking wave equation but for the vector field particle velocity is given by

${\displaystyle {\mathrm{\nabla }}^2\mathbf{𝐮}-\frac{1}{c^2}\frac{{\partial }^2\mathbf{𝐮}}{\partial t^2}=0}$.

In some situations, it is more convenient to solve the wave equation for an abstract scalar field velocity potential which has the form

${\displaystyle {\mathrm{\nabla }}^2\mathrm{\Phi }-\frac{1}{c^2}\frac{{\partial }^2\mathrm{\Phi }}{\partial t^2}=0}$

and then derive the physical quantities particle velocity and acoustic pressure by the equations (or definition, in the case of particle velocity):

${\displaystyle \mathbf{𝐮}=\mathrm{\nabla }\mathrm{\Phi }}$,

${\displaystyle p=-\rho \frac{\partial }{\partial t}\mathrm{\Phi }}$.

The following solutions are obtained by separation of variables in different coordinate systems. They are phasor solutions, that is they have an implicit time-dependence factor of ${\displaystyle e^{i\omega t}}$ where ${\displaystyle \omega =2\pi f}$ is the angular frequency. The explicit time dependence is given by

${\displaystyle p(r,t,k)=\mathrm{Real}[p(r,k)e^{i\omega t}]}$

Here ${\displaystyle k=\omega /c}$ is the wave number.

${\displaystyle p(r,k)=A{e}^{\pm ikr}}$.

${\displaystyle p(r,k)=A{H}_0^{(1)}(kr)+B{H}_0^{(2)}(kr)}$.

where the asymptotic approximations to the Hankel functions, when ${\displaystyle kr\to \mathrm{\infty }}$, are

${\displaystyle H_0^{(1)}(kr)\simeq \sqrt{\frac{2}{\pi kr}}{e}^{i(kr-\pi /4)}}$

${\displaystyle H_0^{(2)}(kr)\simeq \sqrt{\frac{2}{\pi kr}}{e}^{-i(kr-\pi /4)}}$.

${\displaystyle p(r,k)=\frac{A}{r}{e}^{\pm ikr}}$.

Depending on the chosen Fourier convention, one of these represents an outward travelling wave and the other a nonphysical inward travelling wave. The inward travelling solution wave is only nonphysical because of the singularity that occurs at r=0; inward travelling waves do exist.

• Acoustics
• Acoustic attenuation
• Acoustic theory
• Wave equation
• One-way wave equation
• Differential equations
• Thermodynamics
• Fluid dynamics
• Pressure
• Ideal gas law

0.00 (0 votes) Original source: https://en.wikipedia.org/wiki/Acoustic wave equation. Read more