Physics of the Ear and Hearing 2025 PDF

Summary

This document is a lecture presentation on the physics of the ear and hearing, covering topics such as the hearing system, parts of the ear, and hearing loss. It includes diagrams and explanations.

Full Transcript

Physics of the Ear
and Hearing 2025
D r. E n t i d h a r a l t a e e

college of medicine

medical physics
 Topics of the Lecture

Hearing system
Parts of the ear.
Outer ear
 Middle ear
Inner ear
Hearing loss (Deafness).
Hearing test (Audiometer)
Hearing system
Any hearing system consists of:

The ear is the organ that detects sound. It not only receives sound, but also aids in balance and body position.
The ear is part of the auditory system.

The ear is a cleverly designed converter of very weak mechanical waves in air into electrical pulses in the
auditory nerve.
The auditory system of the body is structured into
Mechanical system to catch and to amplify acoustical information (ear).
 Sensory (electrical) system which converts mechanical pulses into electrical signals which are passed on by
the auditory nerves to the brain.
 Auditory system to decode and analyze the electrical nerve signal in the auditory cortex (brain).
The auditory system
The ear is divided into three parts : the outer, the
middle and the inner ears.
 The outer ear
It is the outer visible portion of the ear that
collects and directs sound waves toward the
tympanic membrane by way of a canal. It
consists of pinna, auditory canal and the
tympanic (eardrum) membrane as following
 Pinna: The Pinna collects sound, acting as a funnel to  Protects the eardrum from shocks.
amplify sound and directing sound toward the ear  Preventing harmful items from
canal and adding directional information to the sound. entering the ear canal by the help of
 Auditory canal; is a tube running from the outer ear hair and wax.
to the middle ear. It is about 2.5cm in length and  Amplification the sound by acting as
0.7cm in diameter. Functions of the auditory canal a resonator.
By producing standing wave.
are:
 Where( V) velocity
of sound in air =330
m/s

F1=1*330/4*2.5/100
=3300 HZ

This resonance will
enhance the sensitivity
of ear in the higher
frequency range 2000-
10000 Hz and the best
sensitivity of the ear will
be in the region 2000-
4000 Hz
it Tympanic (eardrum)
is a cone-shaped piece of skin about 10 membrane;
mm in width, separating the outer ear from the middle ear. It is

very sensitive, even the slightest pressure variation will cause it to vibrate. The main function of the

tympanic membrane is to transfer the sound that comes from the air into the ossicles of the middle ear
Reflection and Transmission at the Tympanic Membrane
The acoustical signal travels along the ear canal and hits the eardrum. This causes partial reflection and
transmission of the signal. To optimize the hearing sensitivity reflection should be minimized and
transmission maximized.
From measuring the intensity ratios for reflected and transmitted acoustical waves at the eardrum, we can
obtain the following (where, = 430 kg/m².s, = 1.48x kg/m².s):
,
From the above values, one can observe that most of the incoming wave intensity is reflected (bad impedance
matching) and therefore lost for hearing process.
 Middle Ear
It is the central part of the ear, behind the eardrum, through which sound
travels. It consists of: hammer, the anvil and the stirrup. They transmit the
vibrations of the tympanic membrane to the oval window of the inner ear.
The functions of the bones of the middle ear
are:
a) act a lever system, in which amplify the pressure on the oval window by a
factor of about 22, as shown in the following:
 The force on the oval window () is about 1.5 times the force on the
eardrum ().
 The area of the oval window () is about 15 times smaller than the area
of the eardrum().
=
 Filter out noise generated in the body.
 Protect the ear from excessive vibrations by switching to a less-
efficient mode of vibration at high sound levels
 The inner ear
Serves to transform the energy
of the compressional wave within
the inner ear fluid into nerve
impulses which can be transmitted
to the brain.
The hearing portion of the inner
ear is the cochlea, a snail shaped
structure that is connected to the
stirrup (or stapes). As the stapes
moves in and out, it produces fluid
waves within the cochlea.
The inner ear
It is divided into three small fluid-filled
chambers
vestibular chamber,
the middle chamber
tympanic chamber.
Reissner membrane separates the scala vestibule
from the scala media, Basilar membrane
separates the scala media from the scala tympani.
Along the basilar membrane there are two types
of sensory cells (or hair cells) called the outer and
the inner cells. These are arranged to response to
the frequency (or pitch) of that they detect and
they are covered by the tectorial membrane..
When sound energy is transmitted to the cochlea,
the basilar membrane vibrates up and down
causing the hair cells to shear on the tectorial
membrane above them. These shearings causes
the hair cells to undergo a chemical change the
results in electrical charge inside the cells. The
electrical charges make neural impulses which
travel along the auditory nerve to the brain.
These impulses are interpreted in the brain into
sounds.
 High frequency sounds produce the greatest motion of the
basilar membrane near the oval window.
 Low frequency sounds produce the greatest motion of the
basilar membrane farthest from the apex.
 This results in different nerve cells, distributed along the
organ of Corti, producing electrical pulses depending on the
frequency of the sound waves.

https://youtu.be/98-6WfdumZY
 H.W /Write a Hearing test from the figure below, with an explanation of the reason? Where
air conduction testing O
bone conduction testing X
H.W