Ear
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Transcript of Ear
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PsychoacousticsPsychoacoustics
ROY D. TIPONES, ECEROY D. TIPONES, ECE
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Hearing
� Psychoacoustics – the study of hearing -relationship between the physical properties of sound and the sensations they produce.
� Hearing – the process that transforms sound waves into neural signals that can be interpreted by our brain
� Sound waves – fluctuations in air pressure across time, created by the motion or vibration of an object (e.g. the vibration of vocal chords, oscillating violin string) - physical properties: frequency and amplitude.
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The peripheral auditory system
� The peripheral auditory system consists of
the outer, middle and inner ear.
� In brief: The ear drum moves in and out in
response to the pressure changes in sound
waves – transmitted through the middle to the
inner ear – transduced into neural sinals that
are interpreted by the brain
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The path of sound waves through the outer, middle and inner ear
� Sound waves travel down the auditory canal and cause the ear drum to vibrate.
� The main function of the ossicles is the efficient transfer of sound waves from air to the fluids of the cochlea.
� The ossicles of the middle ear vibrate in response to tympanic membrane (ear drum) vibration. They amplify and transmit these vibrations to the oval window.
� Amplification is necessary as more energy is required to move the fluids (of the inner ear) than air (in middle ear).
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The middle ear
� Achieved: difference in the effective areas of the ear drum and oval window; lever action of the ossicular chain
� Difference in the area of the eardrum and oval window [pressure = force/area]
� Middle ear reflex – muscles attached to the ossicles contract upon exposure to intense sounds (>~80dB SPL)
� Contraction of these muscles reduces the transmission of pressure through the ossicular chain – may prevent inner ear damage
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� Frequency dependent – most effective < 2 kHz
� Minimum time for reflex 10-150ms (depends on
intensity) – so reflex not effective for sounds with a
sudden onset e.g. gunshots
� This reflex may also function is the reduction of the
audibility of self-generated sounds, such as speech.
It has been shown to be activated just before
vocalisation.
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The structure of the inner ear
� The part of inner ear concerned with hearing is the fluid filled cochlea.
� Reissner’s membrane and the basilar membrane (BM) divide the cochlea along its length.
� The start of the cochlea (near oval window) is the base (basal end), the other end of the cochlea is the apex (apical end of the cochlea)
� Motion of the basilar membrane in response to sound
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The basilar membrane response to sound
� Movement of the stapes sets the oval window in motion – causes the BM to move.
� Response of BM to sinusoidal stimulation –travelling wave, which moves from base to apex.
� The position of the peak in the vibration pattern on the BM depends on the frequency of the sound –this is due to the mechanical properties of the BM
� High (low) frequencies produce max. BM displacement near the base (apex) – frequency analysis – each point on the BM is sharply tuned
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Aside
� Our central nervous system consists of the
brain and spinal cord
� Neurons are the building blocks of our central
nervous system
� Many different types of neuron (e.g. sensory
neuron, interneuron, motor neuron)
� Components of a typical biological neuron
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Structure of the neuron
� Three main sections: dendrites, cell body, and the axon.
� The function of the dendrites is to receive signals from other neurons at connection points called synapses.
� The function of the axon is to transmit signals out of the cell body
� The dendrite is separated from the transmitting axon by a narrow gap called a synapse
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� The signals received are combined by the cell body
� If the signal is above a certain threshold, the cell ‘fires’ producing a pulse that propagates down the axon and is passed on to other neurons
� Towards the end of the axon are multiple branches (axon terminals) each terminating in a synapse
� In this way a single neuron can excite or inhibit many other neurons