Sound waves enter through the outer ear, then sound waves move through the ear canal. Next sound waves strike the eardrum, causing it to vibrate, then vibrations enter the middle ear. Then the hammer picks up the vibrations, then vibrations are passed to the anvil. Next the vibrations are transmitted to the stirrup, then a vibrating membrane transmits vibrations to the inner ear, and then vibrations are channeled into the cochlea. Then nerve cells detect vibrations and convert them to electrical impulses, then electrical impulses are transmitted to the brain. Then the brain interprets electrical impulses as sound.
The cochlea is the structure of the ear that converts sound vibrations into nerve signals. It contains hair cells that are responsible for detecting the vibrations and transmitting them to the brain through the auditory nerve.
Sound waves cause vibrations in the air, which in turn cause vibrations in the eardrum. These vibrations are then transmitted through the middle ear bones to the cochlea in the inner ear. Within the cochlea, specialized hair cells convert these vibrations into electrical signals that travel along the auditory nerve to the brain for processing.
Impulses in the ear are transmitted by hair cells located in the cochlea. These hair cells convert sound vibrations into electrical signals that are then sent to the brain via the auditory nerve.
The movement of the perilymph activates the hair cells in the cochlea, which are responsible for detecting sound vibrations and transmitting auditory signals to the brain via the auditory nerve.
In the cochlea, sound vibrations are converted into electrical signals by hair cells located on the basilar membrane. These signals are then sent to the brain through the auditory nerve for interpretation. The cochlea is key to the process of hearing and is responsible for encoding sound frequency and intensity.
The cochlea is the structure of the ear that converts sound vibrations into nerve signals. It contains hair cells that are responsible for detecting the vibrations and transmitting them to the brain through the auditory nerve.
Sound vibrations are converted into nerve impulses in the inner ear. The vibrations are detected by hair cells in the cochlea, which then stimulate the auditory nerve to send signals to the brain for processing and interpretation of sound.
In the ear, sound vibrations are converted into nerve impulses in the cochlea, a spiral-shaped organ that contains hair cells. These hair cells respond to the vibrations by sending electrical signals through the auditory nerve to the brain, where they are perceived as sound.
When sound vibrations cause the hairs on the cochlea to bend, this activates sensory cells which then stimulate nerve cells to send signals to the brain. The brain processes these signals as sound, allowing us to hear.
Yes, the cochlear duct contains sensory cells that convert vibrations into nerve signals. These nerve signals are then transmitted via the auditory nerve fibers to the brain for processing and perception of sound.
Hair cells in the ear stimulate the auditory nerve by converting sound vibrations into electrical signals. When sound waves reach the ear, they cause the hair cells to move, which in turn triggers the release of neurotransmitters. These neurotransmitters then activate the auditory nerve fibers, sending signals to the brain for processing and interpretation of sound.
Explain vibrations, which they can feel. Then explain that sound is vibrations carried through the air.
sound energy
The cochlea, which is a spiral-shaped structure in the inner ear, is responsible for changing vibrations into nerve signals. Inside the cochlea, specialized hair cells convert the mechanical vibrations of sound waves into electrical signals that can be interpreted by the brain.
The cochlea in the inner ear contains receptors called hair cells that convert sound vibrations into electrical impulses. These impulses are then sent to the brain via the auditory nerve, where they are interpreted as sound.
The cochlea, which is located in the inner ear, is responsible for converting sound vibrations into electrical signals that are then transmitted to the brain via the auditory nerve. Hair cells within the cochlea help detect these vibrations and send signals to the brain for processing and interpretation of sound.
In general, the cochlea. More specifically, an impulse is carried into the brain along the auditory nerve when the tectorial membrane and the basilar membrane inside the cochlea are pressed together by the force of sound waves.