Auditory illusion explained

Auditory illusions are illusions of real sound or outside stimulus.[1] These false perceptions are the equivalent of an optical illusion: the listener hears either sounds which are not present in the stimulus, or sounds that should not be possible given the circumstance on how they were created.[2]

Humans are fairly susceptible to illusions, despite an innate ability to process complex stimuli. Confirmation bias is believed to be largely responsible for the inaccurate judgments that people make when evaluating information, given that humans typically interpret and recall information that appeals to their own biases.[3] Amongst these misinterpretations, known as illusions, falls the category of auditory illusions. The brain uses multiple senses simultaneously to process information, spatial information is processed with greater detail and accuracy in vision than in hearing.[4] [5] [6] Auditory illusions highlight areas where the human ear and brain, as organic survival tools, differentiate from perfect audio receptors; this shows that it is possible for a human being to hear something that is not there and be able to react to the sound they supposedly heard. When someone is experiencing an auditory illusion, their brain is falsely interpreting its surroundings and distorting their perception of the world around them.[7]

Causes

Many auditory illusions, particularly of music and of speech, result from hearing sound patterns that are highly probable, even though they are heard incorrectly. This is due to the influence of our knowledge and experience of many sounds we have heard.[8] In order to prevent hearing echo created by perceiving multiple sounds coming from different spaces, the human auditory system relates the sounds as being from one source. However, that does not prevent people from being fooled by auditory illusions. Sounds that are found in words are called embedded sounds, and these sounds are the cause of some auditory illusions. A person's perception of a word can be influenced by the way they see the speaker's mouth move, even if the sound they hear is unchanged.[9] For example, if someone is looking at two people saying "far" and "bar", the word they will hear will be determined by who they look at.[10] If these sounds are played in a loop, the listener will be able to hear different words inside the same sound.[11] People with brain damage can be more susceptible to auditory illusions and they can become more common for that person.[12]

In music

Composers have long been using the spatial components of music to alter the overall sound experienced by the listener.[13] One of the more common methods of sound synthesis is the use of combination tones. Combination tones are illusions that are not physically present as sound waves, but rather, they are created by one's own neuromechanics.[14] According to Purwins,[15] auditory illusions have been used effectively by the following: Beethoven (Leonore Overture), Berg (Wozzeck), Krenek (Spiritus Intelligentiae, Sanctus), Ligeti (Études), Violin Concerto, Double Concerto, for flute, oboe and orchestra), Honegger (Pacific 231), and Stahnke (Partota 12).

Examples

There are a multitude of examples out in the world of auditory illusions. These are examples of some auditory illusions:

a special case of auditory pareidolia

See also

External links

Notes and References

  1. 10.1121/1.1981302. Auditory Illusions as Caused by Embedded Sounds. 1972. Scott. Brian L.. Cole. Ronald A.. The Journal of the Acoustical Society of America. 51. 1A. 112. 1972ASAJ...51R.112S. free.
  2. Web site: Auditory illusion: How our brains can fill in the gaps to create continuous sound . Science Daily . February 20, 2019.
  3. Brundage. Steven. 2016. Fooled By FLUENCY: UNDERSTANDING ILLUSIONS AND MISJUDGMENTS IN MUSIC LEARNING. American Music Teacher. 66. 2. 10–13. 26385737. 0003-0112.
  4. Guttman. Sharon E.. Gilroy. Lee A.. Blake. Randolph. 2005. Hearing What the Eyes See: Auditory Encoding of Visual Temporal Sequences. Psychological Science. 16. 3. 228–235. 10.1111/j.0956-7976.2005.00808.x. 40064206. 15733204. 1431611. 0956-7976.
  5. O'Callaghan. Casey. 2011. Lessons from beyond vision (sounds and audition). Philosophical Studies. 153. 1. 143–160. 10.1007/s11098-010-9652-7. 41487621. 7486290. 0031-8116.
  6. What Are Musical Paradox and Illusion?. American Journal of Psychology. 2007. 120. 1. 124, 132. https://ghostarchive.org/archive/20221009/http://deutsch.ucsd.edu/pdf/ben_carson_review_AJP.pdf . 2022-10-09 . live. 15 November 2013. Dominic W.. Massaro. University of California, Santa Cruz.
  7. KAYSER. CHRISTOPH. 2007. Listening with your Eyes. Scientific American Mind. 18. 2. 24–29. 10.1038/scientificamericanmind0407-24. 24939602. 1555-2284.
  8. Book: Deutsch, D.. Musical Illusions and Phantom Words: How Music and Speech Unlock Mysteries of the Brain . 2019 . Oxford University Press. 2018051786. Diana Deutsch. 9780190206833 .
  9. Web site: Auditory Illusions: How your ears can be fooled. hear.com. en-US. 2019-04-19.
  10. Web site: Do You Hear What I Hear? Amazing Auditory Illusions Explained. IFLScience. en. 2019-04-21.
  11. Scott. Brian L.. Cole. Ronald A.. 1972-01-01. Auditory Illusions as Caused by Embedded Sounds. The Journal of the Acoustical Society of America. 51. 1A. 112. 10.1121/1.1981302. 1972ASAJ...51R.112S. 0001-4966. free.
  12. Fukutake. Toshio. Hattori. Takamichi. 1998-11-01. Auditory illusions caused by a small lesion in the right medial geniculate body. Neurology. en. 51. 5. 1469–1471. 10.1212/WNL.51.5.1469. 0028-3878. 9818885. 8928159.
  13. Begault. Durand R.. 1990. The Composition of Auditory Space: Recent Developments in Headphone Music. Leonardo. 23. 1. 45–52. 10.2307/1578465. 1578465. 191375886. 0024-094X.
  14. Kendall. Gary S.. Haworth. Christopher. Cádiz. Rodrigo F.. 2014. Sound Synthesis with Auditory Distortion Products. Computer Music Journal. 38. 4. 5–23. 10.1162/COMJ_a_00265. 24265446. 15744586. 0148-9267. free. 2027/spo.bbp2372.2012.016. free.
  15. Book: Purwins. Hendrik. Profiles of pitch classes circularity of relative pitch and key-experiments, models, computational music analysis, and perspectives. https://ghostarchive.org/archive/20221009/http://ccrma.stanford.edu/~purwins/purwinsPhD.pdf . 2022-10-09 . live. 2005. 110–120.