Deck 10: How Do We Hear, Speak, and Make Music 

A)Tinnitus can be intermittent or continuous.
B)Tinnitus is a ringing in the ears.
C)There are two categories of tinnitus.
D)Objective tinnitus is the more common form of tinnitus.

A)birds
B)whales
C)humans
D)bats

A)50 dB
B)90 dB
C)100 dB
D)70 dB

A)frequency.
B)pitch.
C)loudness.
D)timbre.

A)4000 Hz range.
B)5000 Hz range.
C)6000 Hz range.
D)7000 Hz range.

A)all singing primates are monogamous.
B)music may be related to sexual behavior.
C)music is processed by the right temporal lobe.
D)All of the answers are correct.

A)rarefication
B)frequency
C)amplitude
D)complexity

A)timbre.
B)pitch.
C)amplitude.
D)frequency.

A)50 dB
B)70 dB
C)120 dB
D)100 dB

A)the compression of air molecules.
B)the rarefaction of air molecules.
C)undulating displacement of air molecules caused by pressure changes.
D)None of the answers are correct.

A)pitch.
B)timbre.
C)loudness.
D)prosody.

A)30 dB.
B)40 dB.
C)50 dB.
D)60 dB.

A)5 Hz.
B)25 Hz.
C)50 Hz.
D)100 Hz.

A)audition; vocalization
B)vocalization; audition
C)audition; hearing
D)vocalization; echolocation

A)Language always involves auditory input and motor output.
B)Language is the use of complex systems of communication and includes syntax.
C)Language is the use of complex systems of communication and always involves auditory, visual, and motor inputs and outputs.
D)Vocalization and audition are necessary to understand language.

A)sound amplitude.
B)pitch.
C)frequency.
D)timbre.

A)10 to 15,000 Hz.
B)20 to 20,000 Hz.
C)30 to 25,000 Hz.
D)20 to 30,000 Hz.

A)did not bury their dead with artifacts.
B)were assumed to have complex language.
C)left evidence that they may have had musical instruments.
D)did not use tools.

A)700 feet/second.
B)1100 feet/second.
C)1000 feet/second.
D)800 feet/second.

A)low-frequency tones.
B)high-frequency tones.
C)a combination of frequencies.
D)half tones.

A)10 picometers.
B)1 picometer.
C)20 picometers.
D)100 picometers.

A)Notes played by musical instruments
B)Bird songs
C)Human speech sounds
D)All of the answers are correct.

A)that are not amplified.
B)with a single frequency.
C)that have a unique timbre.
D)with a pitch between 5000 and 10,000 Hz.

A)tone of voice.
B)speech amplitude.
C)speed of language.
D)frequency.

A)Subjective; objective
B)Objective; subjective
C)Positive; negative
D)Auditory; deaf

A)frontal lobes.
B)parietal lobes.
C)temporal lobes.
D)frontal and temporal lobes.

A)3 segments per second.
B)5 segments per second.
C)7 segments per second.
D)10 segments per second.

A)low-frequency tones.
B)half increments of the fundamental frequency.
C)multiples of the fundamental frequency.
D)restricted only to speech sounds.

A)Fourier analysis.
B)regression analysis.
C)pattern analysis.
D)spectral analysis.

A)stirrup, anvil, hammer.
B)anvil, hammer, stirrup.
C)hammer, stirrup, anvil.
D)hammer, anvil, stirrup.

A)The right and left ears pick up sounds with different frequencies.
B)Different sound waves stimulate different neurons.
C)The brain can identify sounds at varying volumes at the same time, though not at varying pitches.
D)Different sound waves activate different auditory hormones.

A)amplitude.
B)pitch.
C)frequency.
D)timbre.

A)timbre, quality, pitch
B)loudness, timbre, quality
C)loudness, timbre, pitch
D)frequency, amplitude, pitch

A)transduce sound waves into neural firing.
B)protect the inner ear.
C)funnel sound waves into the ear canal.
D)vibrate in response to sound waves.

A)30
B)40
C)50
D)60

A)decibels.
B)hertz.
C)pitch.
D)segments per second.

A)noise.
B)pure tones.
C)complex tones.
D)overtones.

A)our perception of loudness.
B)our perception of pitch.
C)a sound's perceived uniqueness.
D)None of the answers are correct.

A)resonant frequency.
B)Fourier frequency.
C)fundamental frequency.
D)repetition frequency.

A)frequency
B)timbre
C)amplitude
D)duration

A)the medial geniculate nucleus
B)the cochlea
C)the primary auditory core
D)Wernicke's area

A)hyperpolarization.
B)polarization.
C)depolarization.
D)hypopolarization.

A)Frequency analysis
B)Otoacoustic emissions
C)Fourier analysis
D)Auditory evoked potentials

A)are a sign of hearing loss.
B)play no direct role in hearing.
C)can only be measured with conventional hearing tests.
D)can be one of three types.

A)ossicles
B)cilia
C)bipolar cells
D)cochlear nuclei

A)apex; base
B)base; apex
C)middle; base
D)base; middle

A)pulvinar nucleus.
B)lateral geniculate nucleus.
C)medial geniculate nucleus.
D)ventrolateral nucleus.

A)inner hair cells
B)outer hair cells
C)eardrum
D)basilar membrane

A)deafness in the left ear.
B)deafness in the right ear.
C)deafness in both ears.
D)None of the answers are correct.

A)inner hair cells
B)outer hair cells
C)bipolar cells
D)auditory interneurons

A)cochlear nucleus, olivary complex, inferior colliculus, medial geniculate, auditory cortex
B)cochlear nucleus, inferior colliculus, olivary complex, medial geniculate, auditory cortex
C)cochlear nucleus, olivary complex, medial geniculate, inferior colliculus, auditory cortex
D)cochlear nucleus, medial geniculate, olivary complex, inferior colliculus, auditory cortex

A)dorsal lateral geniculate nucleus
B)ventral lateral geniculate nucleus
C)ventral medial geniculate nucleus
D)dorsal medial geniculate nucleus

A)2000
B)3500
C)12,000
D)15,500

A)hyperpolarization.
B)polarization.
C)depolarization.
D)hypopolarization.

A)many hair cells.
B)many ganglion cells.
C)one hair cell.
D)one ganglion cell.

A)eardrum.
B)oval window.
C)round window.
D)cochlea.

A)15,000 Hz
B)18,000 Hz
C)300 Hz
D)1000 Hz

A)Inner hair cells can be destroyed by disease, infection, drugs, or exposure to intense sound waves.
B)Animals without inner hair cells are effectively deaf.
C)Inner hair cells regenerate in mammals.
D)Inner hair cells are tipped with cilia.

A)otoacoustics.
B)echolocation.
C)tinnitus.
D)aphasia.

A)differences in the arrival times of the sound between the two ears.
B)differences in the elevation of the sound between the two ears.
C)differences in the intensity of the sound arriving at both ears.
D)All of the answers are correct.

A)auditory cortex.
B)superior olivary complex.
C)medial geniculate.
D)inferior colliculus.

A)the brain
B)the outer ear
C)the inner ear
D)the primary auditory cortex

A)the planum temporale.
B)Wernicke's area.
C)Broca's area.
D)Heschl's gyrus.

A)Language is universal in human populations.
B)Children learn language early in life and without effort.
C)Technology complexity influences the complexity of language.
D)Many languages share basic structural elements.

A)The left planum temporale
B)The right planum temporale
C)Heschl's gyrus in the left hemisphere
D)Heschl's gyrus in the right hemisphere

A)left planum temporale
B)insula
C)left Wernicke's area
D)right parietal cortex

A)specification.
B)autolocation.
C)lateralization.
D)echolocation.

A)language is not affected by genetics.
B)all languages share common structural characteristics.
C)each language has a unique structure.
D)language affects culture.

A)each hair cell responds only to a single frequency.
B)each hair cell responds to all possible frequencies in the human hearing range.
C)each hair cell responds maximally to a single frequency but also responds somewhat to nearby frequencies.
D)only outer hair cells respond to different frequencies.

A)5
B)10
C)15
D)20

A)the activation of more hair cells.
B)the activation of more bipolar cells.
C)an increased rate of firing in bipolar cells.
D)activation of loudness detectors in the medial geniculate nucleus.

A)1000-3000
B)3000-5000
C)5000-7000
D)10,000-15,000

A)left-handed individuals.
B)right-handed individuals.
C)bilingual speakers.
D)females.

A)to the left or right.
B)above or below.
C)in front or behind.
D)All of the answers are correct.

A)The technology does not yet exist to do so.
B)It is too expensive to carry out large-scale studies.
C)There is no noninvasive way to do so.
D)It is impossible to study individual neurons.

A)a cure for deafness.
B)a hearing substitute.
C)able to replicate the experience of natural hearing.
D)more effective the longer a person has been deaf.

A)Broca's area.
B)the ventral auditory pathway.
C)the primary auditory cortex.
D)the visual cortex.

A)the same as Heschl's gyrus.
B)smaller on the left than on the right in right-handed people.
C)also known as Wernicke's area on the left side.
D)All of the answers are correct.

A)differences in arrival time between the two ears; medial superior olive
B)differences in loudness between the two ears; medial superior olive
C)differences in arrival time between the two ears; lateral superior olive
D)differences in loudness between the two ears; lateral superior olive