![]() Includes the eardrum and the organs of transmission of the sound which are the ossicles (hammer, anvil, stirrup). ![]() This is why an intraductal device naturally benefits from this anatomical amplifier. The pinna plays an essential role in the focusing of sounds (horn of Professor Sunflower). The ear is divided into three parts : The external ear : Anatomy of the ear and sound transmission This article discusses the auditory function of the ear. It allows to hear and also intervenes in an essential way in the balance. This pressure amplification is enough to pass the sound information on to the inner ear, where it is translated into nerve impulses the brain can understand.The ear has a double function. The pressure applied to the cochlear fluid is about 22 times the pressure felt at the eardrum. This amplification system is extremely effective. The malleus moves a greater distance, and the incus moves with greater force (energy = force x distance). The malleus is longer than the incus, forming a basic lever between the eardrum and the stapes. The configuration of ossicles provides additional amplification. To learn more about this hydraulic multiplication, check out How Hydraulic Machines Work. When you concentrate this energy over a smaller surface area, the pressure (force per unit of volume) is much greater. Sound waves apply force to every square inch of the eardrum, and the eardrum transfers all this energy to the stapes. The eardrum has a surface area of approximately 55 square millimeters, while the faceplate of the stapes has a surface area of about 3.2 square millimeters. ![]() The main amplification comes from the size difference between the eardrum and the stirrup. The ossicles amplify the force from the eardrum in two ways. Essentially, the stapes acts as a piston, creating waves in the inner-ear fluid to represent the air-pressure fluctuations of the sound wave. When air-pressure rarefaction pulls out on the eardrum, the ossicles move so that the faceplate of the stapes pulls in on the fluid. When air-pressure compression pushes in on the eardrum, the ossicles move so that the faceplate of the stapes pushes in on the cochlear fluid. The other end of the stapes - its faceplate - rests against the cochlea, through the oval window. The other end of the malleus is connected to the incus, which is attached to the stapes. When the eardrum vibrates, it moves the malleus from side to side like a lever. The malleus is connected to the center of the eardrum, on the inner side. Sound waves vibrate the eardrum, which moves the malleus, incus and stapes. The stapes, commonly called the stirrup.The malleus, commonly called the hammer.The ossicles are actually the smallest bones in your body. This is the job of the ossicles, a group of tiny bones in the middle ear. ![]() Before the sound passes on to the inner ear, the total pressure (force per unit of area) must be amplified. The small force felt at the eardrum is not strong enough to move this fluid. This fluid has a much higher inertia than air - that is, it is harder to move (think of pushing air versus pushing water). They don't apply much force on the eardrum, but the eardrum is so sensitive that this minimal force moves it a good distance.Īs we'll see in the next section, the cochlea in the inner ear conducts sound through a fluid, instead of through air. For the most part, these changes in air pressure are extremely small. We saw in the last section that the compressions and rarefactions in sound waves move your eardrum back and forth.
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