Acoustic impedance and specific acoustic impedance are measures of the opposition that a system presents to the acoustic flow resulting from an acoustic pressure applied to the system. The SI unit of acoustic impedance is the pascal-second per cubic metre (symbol Pa·s/m3), or in the MKS system the rayl per square metre (Rayl/m2), while that of specific acoustic impedance is the pascal-second per metre (Pa·s/m), or in the MKS system the rayl (Rayl).[1] There is a close analogy with electrical impedance, which measures the opposition that a system presents to the electric current resulting from a voltage applied to the system.
For a linear time-invariant system, the relationship between the acoustic pressure applied to the system and the resulting acoustic volume flow rate through a surface perpendicular to the direction of that pressure at its point of application is given by:
p(t)=[R*Q](t),
Q(t)=[G*p](t),
*
Acoustic impedance, denoted Z, is the Laplace transform, or the Fourier transform, or the analytic representation of time domain acoustic resistance:
Z(s)\stackrel{def
Z(\omega)\stackrel{def
Z(t)\stackrel{def
lL
lF
Acoustic resistance, denoted R, and acoustic reactance, denoted X, are the real part and imaginary part of acoustic impedance respectively:
Z(s)=R(s)+iX(s),
Z(\omega)=R(\omega)+iX(\omega),
Z(t)=R(t)+iX(t),
Inductive acoustic reactance, denoted XL, and capacitive acoustic reactance, denoted XC, are the positive part and negative part of acoustic reactance respectively:
X(s)=XL(s)-XC(s),
X(\omega)=XL(\omega)-XC(\omega),
X(t)=XL(t)-XC(t).
Acoustic admittance, denoted Y, is the Laplace transform, or the Fourier transform, or the analytic representation of time domain acoustic conductance:
Y(s)\stackrel{def
Y(\omega)\stackrel{def
Y(t)\stackrel{def
Acoustic conductance, denoted G, and acoustic susceptance, denoted B, are the real part and imaginary part of acoustic admittance respectively:
Y(s)=G(s)+iB(s),
Y(\omega)=G(\omega)+iB(\omega),
Y(t)=G(t)+iB(t),
Acoustic resistance represents the energy transfer of an acoustic wave. The pressure and motion are in phase, so work is done on the medium ahead of the wave. Acoustic reactance represents the pressure that is out of phase with the motion and causes no average energy transfer. For example, a closed bulb connected to an organ pipe will have air moving into it and pressure, but they are out of phase so no net energy is transmitted into it. While the pressure rises, air moves in, and while it falls, it moves out, but the average pressure when the air moves in is the same as that when it moves out, so the power flows back and forth but with no time averaged energy transfer. A further electrical analogy is a capacitor connected across a power line: current flows through the capacitor but it is out of phase with the voltage, so no net power is transmitted into it.
For a linear time-invariant system, the relationship between the acoustic pressure applied to the system and the resulting particle velocity in the direction of that pressure at its point of application is given by
p(t)=[r*v](t),
v(t)=[g*p](t),
Specific acoustic impedance, denoted z is the Laplace transform, or the Fourier transform, or the analytic representation of time domain specific acoustic resistance:
z(s)\stackrel{def
z(\omega)\stackrel{def
z(t)\stackrel{def
Specific acoustic resistance, denoted r, and specific acoustic reactance, denoted x, are the real part and imaginary part of specific acoustic impedance respectively:
z(s)=r(s)+ix(s),
z(\omega)=r(\omega)+ix(\omega),
z(t)=r(t)+ix(t),
Specific inductive acoustic reactance, denoted xL, and specific capacitive acoustic reactance, denoted xC, are the positive part and negative part of specific acoustic reactance respectively:
x(s)=xL(s)-xC(s),
x(\omega)=xL(\omega)-xC(\omega),
x(t)=xL(t)-xC(t).
Specific acoustic admittance, denoted y, is the Laplace transform, or the Fourier transform, or the analytic representation of time domain specific acoustic conductance:
y(s)\stackrel{def
y(\omega)\stackrel{def
y(t)\stackrel{def
Specific acoustic conductance, denoted g, and specific acoustic susceptance, denoted b, are the real part and imaginary part of specific acoustic admittance respectively:
y(s)=g(s)+ib(s),
y(\omega)=g(\omega)+ib(\omega),
y(t)=g(t)+ib(t),
Specific acoustic impedance z is an intensive property of a particular medium (e.g., the z of air or water can be specified); on the other hand, acoustic impedance Z is an extensive property of a particular medium and geometry (e.g., the Z of a particular duct filled with air can be specified).
The acoustic ohm is a unit of measurement of acoustic impedance. The SI unit of pressure is the pascal and of flow is cubic metres per second, so the acoustic ohm is equal to 1 Pa·s/m3.
The acoustic ohm can be applied to fluid flow outside the domain of acoustics. For such applications a hydraulic ohm with an identical definition may be used. A hydraulic ohm measurement would be the ratio of hydraulic pressure to hydraulic volume flow.
For a one-dimensional wave passing through an aperture with area A, the acoustic volume flow rate Q is the volume of medium passing per second through the aperture; if the acoustic flow moves a distance, then the volume of medium passing through is, so:
Q=
| dV | |
| dt |
=A
| dx | |
| dt |
=Av.
Z(s)=
| l{L | |
| [p](s)}{l{L}[Q](s)}= |
| l{L | |
| [p](s)}{A |
l{L}[v](s)}=
| z(s) | |
| A |
,
Z(\omega)=
| l{F | |
| [p](\omega)}{l{F}[Q](\omega)}= |
| l{F | |
| [p](\omega)}{A |
l{F}[v](\omega)}=
| z(\omega) | |
| A |
,
Z(t)=
| 1 | |
| 2 |
\left[pa*\left(Q-1\right)a\right](t)=
| 1 | |
| 2 |
\left[pa*\left(
| v-1 | |
| A |
\right)a\right](t)=
| z(t) | |
| A |
.
The constitutive law of nondispersive linear acoustics in one dimension gives a relation between stress and strain:
p=-\rhoc2
| \partial\delta | |
| \partialx |
,
This equation is valid both for fluids and solids. In
Newton's second law applied locally in the medium gives:[2]
\rho
| \partial2\delta | |
| \partialt2 |
=-
| \partialp | |
| \partialx |
.
| \partial2\delta | |
| \partialt2 |
=c2
| \partial2\delta | |
| \partialx2 |
.
\delta(r,t)=\delta(x,t)
\delta(r,t)=f(x-ct)+g(x+ct)
v(r,t)=
| \partial\delta | |
| \partialt |
(r,t)=-c[f'(x-ct)-g'(x+ct)],
p(r,t)=-\rhoc2
| \partial\delta | |
| \partialx |
(r,t)=-\rhoc2[f'(x-ct)+g'(x+ct)].
\begin{cases} p(r,t)=-\rhoc2f'(x-ct)\\ v(r,t)=-cf'(x-ct) \end{cases}
\begin{cases} p(r,t)=-\rhoc2g'(x+ct)\\ v(r,t)=cg'(x+ct). \end{cases}
z(r,s)=
| l{L | |
| [p](r, |
s)}{l{L}[v](r,s)}=\pm\rhoc,
z(r,\omega)=
| l{F | |
| [p](r, |
\omega)}{l{F}[v](r,\omega)}=\pm\rhoc,
z(r,t)=
| 1 | |
| 2 |
\left[pa*\left(v-1\right)a\right](r,t)=\pm\rhoc.
z0=\rhoc.
| p(r,t) | |
| v(r,t) |
=\pm\rhoc=\pmz0.
Temperature acts on speed of sound and mass density and thus on specific acoustic impedance.
For a one dimensional wave passing through an aperture with area A,, so if the wave is a progressive plane wave, then:
Z(r,s)=\pm
| \rhoc | |
| A |
,
Z(r,\omega)=\pm
| \rhoc | |
| A |
,
Z(r,t)=\pm
| \rhoc | |
| A |
.
Z0=
| \rhoc | |
| A |
.
| p(r,t) | |
| Q(r,t) |
=\pm
| \rhoc | |
| A |
=\pmZ0.
If the aperture with area A is the start of a pipe and a plane wave is sent into the pipe, the wave passing through the aperture is a progressive plane wave in the absence of reflections, and the usually reflections from the other end of the pipe, whether open or closed, are the sum of waves travelling from one end to the other.[3] (It is possible to have no reflections when the pipe is very long, because of the long time taken for the reflected waves to return, and their attenuation through losses at the pipe wall.) Such reflections and resultant standing waves are very important in the design and operation of musical wind instruments.[4]