Deck 7: The Other Sensory Systems

A) frequency
B) loudness
C) amplitude
D) tone

A) The larger the organism, the more intense the stimulus must be to be detected.
B) All organisms detect all stimuli, but only focus on those involved in survival.
C) Organisms detect a range of stimuli that are biologically relevant for that species.
D) The larger the organism, the larger the range of stimuli detected.

A) pitch
B) frequency
C) amplitude
D) loudness

A) biologically useful stimuli.
B) low intensity stimuli.
C) detecting odors of other species.
D) detection of chemical stimuli.

A) pitch
B) frequency
C) amplitude
D) loudness

A) Humans can detect all sights and sounds, as long as they are above a minimal intensity.
B) Humans respond to a narrower range of stimuli than most other species.
C) Humans are sensitive to all the stimuli lower organisms can detect, as well as some they cannot.
D) Humans are sensitive to a wide range of range of stimuli.

A) amplitude
B) frequency
C) intensity
D) across-fiber pattern coding

A) Pitch gets higher.
B) Pitch gets lower.
C) Loudness increases.
D) Loudness decreases.

A) impossible.
B) learned.
C) restricted to activity of the cochlea.
D) enhanced by having small ears.

A) tympanic membrane.
B) middle ear.
C) cochlea.
D) ossicles.

A) a much higher frequency than the sound waves that hit it.
B) half the frequency of the sound waves that hit it.
C) the same frequency as the sound waves that hit it.
D) a constant frequency regardless of the frequency of the sound.

A) haircells.
B) scala media.
C) eardrum.
D) scala vestibuli.

A) eardrum
B) pinna
C) auditory nerve
D) cochlea

A) It vibrates in synchrony with high-frequency tones.
B) It protects the eardrum from overstimulation.
C) It filters out distracting sounds.
D) It helps us locate the source of sounds.

A) pinna.
B) ossicle.
C) tympanic membrane.
D) cochlea.

A) It drops naturally as you grow older.
B) It drops if you go several months without listening to any high pitches.
C) It drops only as a result of injury or disease.
D) It increases with musical training.

A) pinna, tympanic membrane, oval window, cochlea
B) tympanic membrane, pinna, cochlea
C) pinna, stapes, eardrum
D) malleus, tympanic membrane, oval window, pinna

A) tympanic membrane.
B) stapes.
C) pinna.
D) malleus.

A) The inner membrane gets less sensitive with age.
B) More force is needed to create waves in fluid.
C) Much of the vibration is lost in the eardrum.
D) Too much is lost through friction.

A) cochlea.
B) middle ear.
C) external auditory canal.
D) temporal lobe.

A) amplitude.
B) number of waves per second.
C) height of each wave.
D) loudness.

A) in the inner ear.
B) in the outer ear.
C) that transmit information from the outer ear to the middle ear.
D) that transmit information from the tympanic membrane to the oval window.

A) tympanic membrane.
B) cochlea.
C) middle ear.
D) ossicles.

A) cochlea.
B) pinna.
C) oval window.
D) hair cells.

A) frequency; intensity
B) amplitude; frequency
C) pitch; tone
D) amplitude; intensity

A) the tympanic membrane.
B) the pinna.
C) the MGN.
D) the cochlea.

A) They hold the tympanic membrane in place.
B) They convert airwaves into waves of greater pressure.
C) They spread out the air waves over an area of larger diameter.
D) They change the frequency of air waves into lower frequencies that can be heard.

A) movement of the pinna.
B) hair cells to displace.
C) vibrations of the eardrum.
D) vestibular input.

A) It cannot account for perception of low pitch sounds.
B) It cannot account for perception of low amplitude sounds.
C) It requires the cochlea to vibrate, and it does not.
D) Neurons cannot respond as quickly as the theory requires.

A) the frequency of action potentials.
B) the area along the basilar membrane that responds most strongly.
C) volleys of responses.
D) the asymmetrical positioning of an individual's ears.

A) volley principle; frequency theory
B) frequency theory; place theory
C) place theory; volley principle
D) gate theory; frequency theory

A) volley principle
B) frequency theory
C) place theory
D) opponent-process theory

A) frequency theory
B) place theory
C) volley theory
D) both the frequency theory and the place theory

A) tectorial membrane vibrates in synchrony with the auditory nerve.
B) auditory nerve is responsible for perception of sound but not loudness.
C) basilar membrane vibrates in synchrony with a sound, producing action potentials at the same frequency.
D) basilar membrane is tuned to a specific frequency and vibrates whenever that frequency is present.

A) the frequency theory.
B) the place theory.
C) the volley principle.
D) a combination of frequency, place, and volley principles, depending on the frequency of the tone.

A) rods and cones
B) sound bulbs
C) hair cells
D) basilar membranes

A) low; low
B) high; low
C) high; high
D) low; high

A) Various auditory neurons respond best to different wavelengths.
B) The response of an auditory neuron declines if a sound is repeated many times.
C) The louder a sound, the more auditory neurons respond to it.
D) Most times we hear a combination of many wavelengths, not a pure tone.

A) The tectorial membrane squeezes the auditory nerve.
B) The basilar membrane releases neurotransmitters.
C) Hair cells in the cochlea vibrate, causing ion channels to open in their membrane.
D) The scala vestibuli has receptors that create action potentials.

A) mechanical displacement.
B) electromagnetic energy.
C) chemicals.
D) vestibular input.

A) farther along the membrane.
B) near the base of the membrane.
C) in the middle of the membrane.
D) along the entire length of the membrane.

A) the frequency of responses by each auditory neuron.
B) volleys of responses by many auditory neurons.
C) where along the basilar membrane neurons fire most rapidly.
D) the ratio of firing among three types of receptors.

A) anvil; hammer
B) stirrup; anvil
C) inner ear; middle ear
D) middle ear; inner ear

A) frequency of action potentials.
B) number of neurons producing action potentials.
C) oval window.
D) the relative frequency of action potentials.

A) in the semicircular canal
B) on the tympanic membrane
C) on the basilar membrane
D) in the malleus

A) the frequency theory
B) the place theory
C) the volley theory
D) both the frequency theory and the place theory

A) the number of activated hair cells.
B) the frequency of action potentials.
C) which neurons are activated.
D) which part of the basilar membrane is vibrating.

A) tympanic membrane.
B) middle ear.
C) cochlea.
D) ossicles.