An auditory cue is a sound signal that represents an incoming sign received through the ears, causing the brain to hear. The results of receiving and processing these cues are collectively known as the sense of
hearing and are the subject of research within the fields of
psychology,
cognitive science, and
neurobiology.
Auditory system The auditory system of humans and animals allows individuals to assimilate information from the surroundings, represented as sound waves. Sound waves first pass through the
pinnae and the auditory canal, the parts of the ear that comprise the outer ear. Sound then reaches the tympanic membrane in the
middle ear (also known as the eardrum). The tympanic membrane sets the
malleus,
incus, and
stapes into vibration. The stapes transmits these vibrations to the
inner ear by pushing on the membrane covering the
oval window, which separates the middle and inner ear. The inner ear contains the
cochlea, the liquid-filled structure containing the hair cells. These cells serve to transform the incoming vibration to electrical signals, which can then be transmitted to the brain. The auditory nerve carries the signal generated by the hair cells away from the inner ear and towards the auditory receiving area in the cortex. The signal then travels through fibers to several subcortical structures and on to the primary
auditory receiving area in the temporal lobe.
Cues for locating sound Humans use several cues to determine the location of a given stimuli, mainly by using the timing difference between ears. These cues allow individuals to identify both the elevation, the height of the stimuli relative to the individual, and the
azimuth, or the angle of the sound relative to the direction the individual is facing.
Interaural time and level difference Unless a sound is directly in front of or behind the individual, the sound stimuli will have a slightly different distance to travel to reach each ear. This difference in distance causes a slight delay in the time the signal is perceived by each ear. The magnitude of the
interaural time difference is greater the more the signal comes from the side of the head. Thus, this time delay allows humans to accurately predict the location of incoming sound cues. Interaural level difference is caused by the difference in sound pressure level reaching the two ears. This is because the head blocks the sound waves for the further ear, causing less intense sound to reach it. This level difference between the two ears allows humans to accurately predict the azimuth of an auditory signal. This effect only occurs for sounds that are high frequency.
Spectral cue A spectral cue is a monaural (single ear) cue for locating incoming sounds based on the distribution of the incoming signal. The differences in distribution (or spectrum) of the sound waves are caused by interactions of the sounds with the head and the outer ear before entering the ear canal.
Principles of auditory cue grouping The auditory system uses several
heuristics to make sense of incoming cues, based on the properties of auditory stimuli that usually occur in the environment. Cue grouping refers to how humans naturally perceive incoming stimuli as organized patterns, based on certain rules.
Onset time If two sounds start at different times, they are likely to have originated from different sources. Sounds that occur simultaneously likely originate from the same source.
Location Cues originating at the same or slowly changing positions usually have the same source. When two sounds are separated in space, the cue of location (see:
sound localization) helps an individual to separate them perceptually. If a sound is moving, it will move continuously. Erratically jumping sound is unlikely to come from the same source.
Similarity of timbre Timbre is the tone quality or tone character of a sound, independent of pitch. This helps us distinguish between musical instruments playing the same notes. When hearing multiple sounds, the timbre of each sound will be unchanging (regardless of pitch), and thus we can differentiate between sounds from different sources over time.
Similarity of pitch Pitch refers to the frequency of the sound wave reaching us. Although a single object could produce a variety of pitches over time, it is more likely that it would produce sounds in a similar range. Erratic changes in pitch are more likely to be perceived as originating from different sources.
Auditory continuity Similar to the Gestalt principle of good continuation (see:
principles of grouping), sounds that change smoothly or remain constant are often produced by the same source. Sound with the same frequency, even when interrupted by other noise, is perceived as continuous. Highly variable sound that is interrupted is perceived as separate.
Factors affecting auditory cue perception The precedence effect When one sound is presented for a long interval before the introduction of a second one originating from a different location, individuals will hear them as two distinct sounds, each originating from the correct location. However, when the delay between the onset of the first and second sound is shortened, listeners are unable to distinguish between the two sounds. Instead, they perceive them as both coming from the location of the lead sound. This effect counteracts the small disparity between the perception of sound caused by the difference in distance between each ear and the source of the auditory stimuli.
The interaction between auditory and visual cues There are strong interactions between visual and auditory stimuli. Since both auditory and
visual cues provide an accurate source of information about the location of an object, most times there will be minimal discrepancy between the two. However, it is possible to have a disparity in the information provided by the two sets of cues. An example of
visual capture is the
ventriloquism effect, that occurs when an individual's visual system locates the source of an auditory stimulus at a different position than where the auditory system locates it. When this occurs, the visual cues will override the auditory ones. The individual will perceive the sound as coming from the location where the object is seen. Audition can also affect visual perception. Research has demonstrated this effect by showing two objects on a screen, one moving diagonally from top-right to bottom-left and the other from top-left to bottom-right, intersecting in the middle. The paths of these identical objects could have been interpreted as crossing over each other, or as bouncing off each other. Without any auditory cue, a vast majority of subjects saw the objects crossing paths and continuing in their original trajectory. But with the addition of a small "click" sound, a majority of subjects perceived the objects as bouncing off each other. In this case, auditory cues help interpret visual cues. == Haptic cues ==