Sound Waves and the Eardrum
A
sound wave traveling through a fluid medium (such as a liquid or a
gaseous material) has a longitudinal nature. This means that the
particles of the medium vibrate in direction which is parallel (and
anti-parallel) to the direction which the sound wave travels. If the
sound wave travels from west to east, then the particles of the medium
vibrate back and forth along the east-west axis. As a sound wave
impinges upon a particle of air, that particle is temporarily disturbed
from its rest position. This particle in turn pushes upon its nearest
neighbor, causing it to be displaced from its rest position. The
displacement of several nearby particles produces a region of space in
which several particles are compressed together. Such a region is known
as a compression or high pressure region. A restoring force typically
pulls each particle back towards its original rest position. As the
particles are pulled away from each other, a region is created in which
the particles are spread apart. Such a region is known as a rarefaction
or low pressure region. Because a sound wave consists of an alternating
pattern of high pressure (compressions) and low pressure (rarefactions)
regions traveling through the medium, it is known as a pressure wave.
When
a pressure wave reaches the ear, a series of high and low pressure
regions impinge upon the eardrum. The arrival of a compression or high
pressure region pushes the eardrum inward; the arrival of a low pressure
regions serves to pull the eardrum outward. The continuous arrival of
high and low pressure regions sets the eardrum into vibrational motion.
This is depicted in the animation below.
The
eardrum is attached to the bones of the middle ear - the hammer, anvil,
and stirrup. As these bones begin vibrating, the sound signal is
transformed from a pressure wave traveling through air to the mechanical
vibrations of the bone structure of the middle ear. These vibrations
are then transmitted to the fluid of the inner ear where they are
converted to electrical nerve impulses which are sent to the brain.
Since
the eardrum is set into vibration by the incoming pressure wave, the
vibrations occur at the same frequency as the pressure wave. If the
incoming compressions and rarefactions arrive more frequently, then the
eardrum vibrates more frequently. This frequency is transmitted through
the middle and inner ear and provides the perception of pitch. Higher
frequency vibrations are perceived as higher pitch sounds and lower
frequency vibrations are perceived as lower pitch sounds.
The
intensity of the incoming sound wave can also be transmitted through
the middle ear to the inner ear and interpreted by the brain. A high
intensity sound wave is characterized by vibrations of air particles
with a high amplitude. When these high amplitude vibrations impinge upon
the eardrum, they produce a very forceful displacement of the eardrum
from its rest position. This high intensity sound wave causes a large
vibration of the eardrum and subsequently a large and forceful vibration
of the bones of the middle ear. This high amplitude vibration is
transmitted to the fluid of the inner ear and encoded in the nerve
signal which is sent to the brain. A high intensity sound is perceived
as a relatively loud sound by the brain.
For more information on physical descriptions of waves, visit The Physics Classroom Tutorial. Detailed information is available there on the following topics:
Mechanical Wave
Longitudinal Wave
Pressure Wave
The Human Ear
Pitch and Frequency
Intensity/Decibel Scale
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