Auditory Physiology PSY 310 Greg Francis. Lecture 30. Organ of Corti

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Transcription:

Auditory Physiology PSY 310 Greg Francis Lecture 30 Waves, waves, waves. Organ of Corti Tectorial membrane Sits on top Inner hair cells Outer hair cells The microphone for the brain 1

Hearing Perceptually, we hear sounds that differ in pitch and loudness And several other qualities, as we ll discuss later What is the physiological response to these perceptual qualities? How are different aspects of sounds represented in the cochlea? At least two possibilities Different neurons code different properties of sound Neural responses vary for different properties of sound Frequency We can explore the responses to different frequencies of sound waves Not the same thing as perceived pitch Georg von Bekesy (Nobel Prize in physiology and medicine in 1961) Something similar also proposed by Helmholtz (1857) Place theory of hearing The frequency of a sound is coded by the place on the organ of corti that responds to the sound best 2

Cochlea Pressure from the stapes pushes the fluid in the cochlea Causes membranes to vibrate Basilar membrane The vibration differs, depending on the frequency of the sound Different places on the basilar membrane have the best vibration in response to sounds of different frequencies Like a traveling wave on a rope 3

Basilar membrane The differences are partly due to the mechanical structure of the basilar membrane Thickness of material and with of the membrane Traveling wave Remember that there is constant push and pull by the stapes One can get a variety of interesting wave patterns 4

Traveling wave Another view of a traveling wave Traveling wave As the wave travels along, its amplitude changes Displacement of basilar membrane Base apex Maximum Displacement vs. position: envelope basilar membrane 5

Wave envelope The amplitude of the peak of the wave maps out the envelope of the wave Displacement of basilar membrane Base apex Maximum Displacement vs. position: envelope basilar membrane Frequency encoding The wave envelopes peak at different places for different frequencies of sounds 6

Frequency encoding So different frequencies give rise to peak responses at different places on the cochlea Neurons that respond to the hair cells at different places, represent different frequencies Wave envelope shape The way waves travel and the properties of the basilar membrane makes the waves asymmetrical base apex 7

Tuning curve Pick a place on the cochlea Measure the faintest sound that generates a small movement (db) Vary the frequency of the sound The three curves are for three different cats (the numbers are dates) Sound detection Pure tone sounds produce responses at different places in the cochlea base apex 8

Sound detection A sound that consists of more than one sine wave will produce separate responses at different places Fourier analysis? base apex Sound detection Suppose two sounds are presented together Target Noise The response on the basilar membrane is a mixture of the two sounds We can look at the discriminablity of the tones and relate it to the properties of the cochlea Masking demonstration Not all noise is created equal Expect significant effect of noise only when its frequency range will interfere with detection of the tone (e.g, spread out the peak of the traveling wave) 9

Sound detection There are several ways to do this kind of experiment One way: present a target tone of a given amplitude and frequency (the number on the graph) Vary the frequency and amplitude of the mask Adjust the amplitude to make the target tone not heard 0.5 1.0 2.0 4.0 8.0 A problem The cochlea is about 2.3 cm in length There are about 16,000-20,000 hair cells People resolve around 1,500 different pitches E.g., the difference between 1000 Hz and 1003 Hz This would imply that different pitches are coded every 0.002 cm The wave envelope is not that precise base apex 10

Tuning curves Here the animals (guinea pigs) are alive or dead The alive curve shows sharp tuning The dead curve shows broader tuning (less sensitivity) Something is different when the animal is alive that changes the properties of the basilar membrane Organ of corti The outer hair cells apparently move (motile response) to change the way the basilar membrane vibrates This changes the peak of the wave envelope 11

Sharpening With the motile response, the location of the wave envelope is more precise Frequency tuning Not everything is determined by the place on the cochlea Some neurons respond with bursts of activity at the same frequency as the stimulus Only for lower frequency stimuli Neurons cannot change fast enough for high frequency sounds 12

Conclusions Waves on the basilar membrane are different for different sound frequencies Provides the basis for pitch perception Different neurons respond to different frequencies Very complicated Lots of other neural processing that we have discussed Next time Using sound to understand the environment Auditory localization 13

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