Sound Characteristics Flashcards
Audition
The biological process by which our ears process sound waves
- Humans with normal hearing can easily detect the source, direction, and complex combinations of sound like voices and music
sound waves
- vibrations of molecules that travel through the air
- created by vibrating objects, and move much more slowly than light
- waves are characterized by their amplitude, wavelength, and purity
Wavelength
- the frequency, measured in cycles per second, and affects the pitch (high or low)
Amplitude
affects the loudness or intensity based on how much pressure is being forced through the air
decibels
- the intensity of sound is measured using a scale of decibels
- the absolute threshold for sound is 0 dB, while noise above 120 db can cause damage to one’s hearing
- 150 db can cause the eardrum to rupture
The Outer Ear
- called the pinna, catches sound waves
pinna
directs sound waves through the ear canal, or auditory canal to the eardrum, or tympanic membrane
The Middle Ear
- Sound waves then vibrate tiny malleus (hammer), incus (anvil), and stapes (stirrup)
- These bones transmit their vibrations to the cochlea, whose inner surface (basilar membrane) resonates to different sounds in different locations
cochlea
a snail-shaped tube with fluid inside that is jostled with vibrations from the middle ear, bending the hairs that line its surface
organ of corti
in the cochlea contains the hairs that convert the mechanical energy into electrical
the inner ear
the movement of the hairs is transmitted as messages along the auditory nerve to the auditory cortex in the temporal lobe
sensorineural hearing loss
there is damage to the inner ear, often to the cochlea
Conductive hearing loss
sounds cannot get through the outer and middle ear
Cochlear implants
help provide a sense of sound to a person who is deaf or hard of hearing
how the cochlear implants work
cochlear implants electronic signals to stimulate the cochlea’s nerves to get the message to the brain
Hermann von Helmholtz’s place theory
- higher and lower tones excite specific areas of the cochlea’s basilar membrane
- as sound waves enter the cochlea, higher pitched sounds displace the fluid in the inner ear
- high frequencies produce large vibrations along the beginning of the cochlea’s membrane, while low pitches vibrate the whole structure
frequency theory
- suggests that as a pitch rises, the entire basilar membrane vibrates at that frequency
- the brain reads the pitch by monitoring the frequency of neural impulses as they travel the auditory nerve
volley principle
suggests neural cells can fire alternately, allowing those that just fired to reset
Locating sound
- your ears rely on volume and timing to determine where a sound is coming from
- the louder the sound, the closer it is
- the timing of when each ear receives the sound is also important
Locating Sound
- the ear closer to the origin receives the sound first, with a slightly stronger signal
- the brain accurately locate sounds, unless they are directly in front, behind, or above us
Signal detection theory
detection of a stimulus depends on the intensity of the stimulus and the physical and psychological state of the individual
