Last modified on 21 July 2009, at 19:23

Sensory Neuroscience: Hearing and speech/Outer & middle ear/middle ear

Middle ear.png
malleus
tensor tympani
incus
stapedius
stapes
Eustachian tube
tympanic cavity
Components of the middle ear

FunctionEdit

Looking at the inner surface of the tympanic membrane, you can see that the malleus is attached to pars tensa (1) along its long arm (3), beginning at the umbo (2)

The function of the middle ear is to get the sound energy which arrives at the tympanic membrane to the oval window of the cochlea.

OssiclesEdit


Spring-like actionEdit

Trommelfell.png

The ossicles do not move like the other joints in your body. That is, there is no flexion or extension. Instead, the ossicles vibrate as a unit, with the tensor tympani and stapedius muscles modulating the movement.

Purpose of the middle ear muscles: acoustic reflexEdit

Oval & round windowsEdit

The oval and round windows into the cochlea (A and B respectively).

Impedance mismatch problemEdit

Fun fact


The quietest sound a normally-hearing human can detect vibrates their eardrum with an amplitude of less than the diameter of a hydrogen atom.

When the impedence of two mediums is mismatched, only some of the energy is transmitted.

Recall that the more different the impedances for two mediums, the less acoustic energy will be transferred into the second medium (and the rest will be reflected). The middle ear faces an impedance mismatch problem since the sound energy is travelling from air into fluid (in the cochlea). According to the equation %\text{amplitude transmission} = 4\frac{Z_1 \cdot Z_2}{[Z_1 + Z_2]^2}, the reduction in amplitude due to this impedance mismatch is about 97% of the energy (that's 30dB less). Luckily the middle ear compensates for this mismatch in two ways:

  1. The A_{\text{tympanic membrane}}:A_{\text{footplate}} ratio is large: \frac{\text{pars tensa}}{\text{stapes footplate}} = \frac{59.4mm^2}{3.2mm^2} = 18.6
  2. The length of the long arm of the malleus is 1.3\times longer than that of the incus. This produces a lever effect.

18.6 \times 1.3 = 24.2, which is almost the 30dB amplitude loss the impedance mismatch problem would have created.