Download - Figure 13.1 The periodic condensation and rarefaction of air molecules produced by a tuning fork
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Figure 13.1 The periodic condensation and rarefaction of air molecules produced by a tuning fork
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Figure 13.2 A sine wave and its projection as circular motion
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Box 13B Music
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Figure 13.3 The human ear
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Box 13C Sensorineural Hearing Loss and Cochlear Implants
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Figure 13.4 The cochlea
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Figure 13.4 The cochlea (Part 1)
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Figure 13.4 The cochlea (Part 2)
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Figure 13.4 The cochlea (Part 3)
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Figure 13.5 Traveling waves along the cochlea
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Figure 13.5 Traveling waves along the cochlea (Part 1)
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Figure 13.5 Traveling waves along the cochlea (Part 2)
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Figure 13.6 Vertical movement of the basilar membrane bends the stereocilia of the hair cells
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Figure 13.6 Vertical movement of the basilar membrane bends the stereocilia of hair cells (Part 1)
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Figure 13.6 Vertical movement of the basilar membrane bends the stereocilia of hair cells (Part 2)
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Figure 13.7 The hair bundle in cochlear and vestibular hair cells
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Figure 13.8 Mechanoelectrical transduction mediated by hair cells
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Figure 13.9 Mechanoelectrical transduction mediated by vestibular hair cells
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Figure 13.9 Mechanoelectrical transduction mediated by vestibular hair cells (Part 1)
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Figure 13.9 Mechanoelectrical transduction mediated by vestibular hair cells (Part 2)
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Figure 13.9 Mechanoelectrical transduction mediated by vestibular hair cells (Part 3)
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Figure 13.10 Depolarization and repolarization of hair cells is mediated by K+
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Figure 13.11 Response properties of auditory nerve fibers
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Figure 13.11 Response properties of auditory nerve fibers (Part 1)
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Figure 13.11 Response properties of auditory nerve fibers (Part 2)
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Figure 13.11 Response properties of auditory nerve fibers (Part 3)
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Figure 13.12 The major auditory pathways
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Figure 13.12 The major auditory pathways (Part 1)
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Figure 13.12 The major auditory pathways (Part 2)
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Figure 13.13 How the MSO computes the location of a sound by interaural time differences
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Figure 13.13 How the MSO computes the location of a sound by interaural time differences
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Figure 13.14 LSO neurons encode sound location through interaural intensity differences
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Figure 13.14 LSO neurons encode sound location through interaural intensity differences (Part 1)
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Figure 13.14 LSO neurons encode sound location through interaural intensity differences (Part 2)
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Figure 13.15 The human auditory cortex
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Figure 13.15 The human auditory cortex (Part 1)
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Figure 13.15 The human auditory cortex (Part 2)
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Box 13E(1) Representing Complex Sounds in the Brains of Bats and Humans
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Box 13E(2) Representing Complex Sounds in the Brains of Bats and Humans
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Box 13E(2) Representing Complex Sounds in the Brains of Bats and Humans (Part 1)
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Box 13E(2) Representing Complex Sounds in the Brains of Bats and Humans (Part 2)