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18.2 Hearing and vestibular sensation  (Page 2/28)

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The illustration shows the parts of the human ear. The visible part of the exterior ear is called the pinna. The ear canal extends inward from the pinna to a circular membrane called the tympanum. On the other side of the tympanum is the Eustachian tube. Inside the Eustachian tube the malleus, which touches the inside of the tympanum, is attached to the incus, which is in turn attached to the horseshoe-shaped stapes. The stapes is attached to the round window, a membrane in the snail shell-shaped cochlea. Another window, called the round window, is located in the wide part of the cochlea. Ring-like semicircular canals extend from the cochlea. The cochlear nerve and vestibular nerve both connect to the cochlea.
Sound travels through the outer ear to the middle ear, which is bounded on its exterior by the tympanic membrane. The middle ear contains three bones called ossicles that transfer the sound wave to the oval window, the exterior boundary of the inner ear. The organ of Corti, which is the organ of sound transduction, lies inside the cochlea. (credit: modification of work by Lars Chittka, Axel Brockmann)

Transduction of sound

Vibrating objects, such as vocal cords, create sound waves or pressure waves in the air. When these pressure waves reach the ear, the ear transduces this mechanical stimulus (pressure wave) into a nerve impulse (electrical signal) that the brain perceives as sound. The pressure waves strike the tympanum, causing it to vibrate. The mechanical energy from the moving tympanum transmits the vibrations to the three bones of the middle ear. The stapes transmits the vibrations to a thin diaphragm called the oval window    , which is the outermost structure of the inner ear    . The structures of the inner ear are found in the labyrinth    , a bony, hollow structure that is the most interior portion of the ear. Here, the energy from the sound wave is transferred from the stapes through the flexible oval window and to the fluid of the cochlea. The vibrations of the oval window create pressure waves in the fluid (perilymph) inside the cochlea. The cochlea    is a whorled structure, like the shell of a snail, and it contains receptors for transduction of the mechanical wave into an electrical signal (as illustrated in [link] ). Inside the cochlea, the basilar membrane    is a mechanical analyzer that runs the length of the cochlea, curling toward the cochlea’s center.

The mechanical properties of the basilar membrane change along its length, such that it is thicker, tauter, and narrower at the outside of the whorl (where the cochlea is largest), and thinner, floppier, and broader toward the apex, or center, of the whorl (where the cochlea is smallest). Different regions of the basilar membrane vibrate according to the frequency of the sound wave conducted through the fluid in the cochlea. For these reasons, the fluid-filled cochlea detects different wave frequencies (pitches) at different regions of the membrane. When the sound waves in the cochlear fluid contact the basilar membrane, it flexes back and forth in a wave-like fashion. Above the basilar membrane is the tectorial membrane    .

Art connection

A series of three illustrations are shown. The top illustration shows a cochlea, which is shaped like a snail shell with two parallel chambers, the upper chamber and the lower chamber, coiling from the outside in. These chambers are separated by a flexible membrane basilar membrane. The oval window covers the inner of these parallel chambers. Sound waves enter here, and travel to the middle, or apex, of the coil. The membrane separating the two chambers gets thinner from the outside in, such that is vibrates at different sound frequencies, about 20,000 hertz on the outside and about 200 hertz on the inside. Sound then travels back out through the lower chamber, and exits through the round window. The middle illustration shows a closer view of a cross-sectional image of the cochlea. A roughly circular shape has a roughly circular bone exterior, with the middle portion of the circle divided into four major areas. Two of these are spaces labeled “upper canal” and “lower canal.” In the middle is the organ of Corti, and extending from the middle out through the outer bone area is the cochlear nerve, which extends from the middle as a thin tube and then bulges into a larger oval shape as it extends through the bone. The bottom illustration is an enlarged image of the organ of Corti. In the view shown, the top section is a flattish pink area called the tectorial membrane. Extending beneath that membrane are three areas with hair-like connectors (stereocilia) that run from the membrane to the outer hair cells. The outer hair cells are shaped like rectangles with rounded corners. From the end of each protrudes a narrow tube: the cochlear nerve. These narrow tubes join to an inner hair cell, which looks similar to the outer hair cells but with its rectangular shape remaining a consistent width instead of narrowing into a nerve. At the bottom of the image, opposite the top tectorial membrane, is a basilar membrane.
In the human ear, sound waves cause the stapes to press against the oval window. Vibrations travel up the fluid-filled interior of the cochlea. The basilar membrane that lines the cochlea gets continuously thinner toward the apex of the cochlea. Different thicknesses of membrane vibrate in response to different frequencies of sound. Sound waves then exit through the round window. In the cross section of the cochlea (top right figure), note that in addition to the upper canal and lower canal, the cochlea also has a middle canal. The organ of Corti (bottom image) is the site of sound transduction. Movement of stereocilia on hair cells results in an action potential that travels along the auditory nerve.

Questions & Answers

A golfer on a fairway is 70 m away from the green, which sits below the level of the fairway by 20 m. If the golfer hits the ball at an angle of 40° with an initial speed of 20 m/s, how close to the green does she come?
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Samuel Reply
can someone explain to me, an ignorant high school student, why the trend of the graph doesn't follow the fact that the higher frequency a sound wave is, the more power it is, hence, making me think the phons output would follow this general trend?
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Nevermind i just realied that the graph is the phons output for a person with normal hearing and not just the phons output of the sound waves power, I should read the entire thing next time
Joseph
Follow up question, does anyone know where I can find a graph that accuretly depicts the actual relative "power" output of sound over its frequency instead of just humans hearing
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"Generation of electrical energy from sound energy | IEEE Conference Publication | IEEE Xplore" ***ieeexplore.ieee.org/document/7150687?reload=true
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Source:  OpenStax, Human biology. OpenStax CNX. Dec 01, 2015 Download for free at http://legacy.cnx.org/content/col11903/1.3
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