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1. µµ¼¸í : Hearing
2. Àú ÀÚ : Aage R. Moller, Aage R. Mller
3. ÃâÆÇ»ç : Academic Press
4. ÆÇ Çü : 160 ¡¿ 230 ¡¿ 30 §®
5. ÆäÀÌÁö : 515 ÆäÀÌÁö
6. ¹ßÇàÀÏ : 2000³â 5¿ù 1ÀÏ
7. ISBN : 0125042558
8. Ã¥¼Ò°³ :
¡á ¸ñ ·Ï
Introduction xv
SECTION I The Ear
Anatomy of the Ear
Abstract 5 (1)
Introduction 6 (1)
Outer Ear 6 (3)
Ear Canal 6 (3)
Middle Ear 9 (6)
Tympanic Membrane 9 (3)
Ossicles 12 (1)
Middle Ear Muscles 12 (1)
Eustachian Tube 13 (1)
Middle Ear Cavities 13 (2)
Inner Ear 15 (14)
Cochlea 15 (9)
Fluid Systems of the Cochlea 24 (5)
Sound Conduction to the Cochlea
Abstract 29 (1)
Introduction 30 (1)
Head, Outer Ear, and Ear Canal 30 (7)
Sound Delivered by Earphones 37 (1)
Middle Ear 37 (13)
Middle Ear As an Impedance Transformer 39 (1)
Measurement of Sound Transmission through 40 (1)
the Middle Ear
Transfer Function of the Middle Ear 41 (5)
Impulse Response of the Human Middle Ear 46 (3)
Linearity of the Middle Ear 49 (1)
Acoustic Impedance of the Ear 50 (17)
Measurement of the Ear's Acoustic 53 (1)
Impedance
Acoustic Impedance of the Human Ear 53 (4)
Contributions of Individual Parts of the 57 (10)
Middle Ear to Its Impedance
Effect of Contraction of the Middle Ear 67 (4)
Muscles on the Function of the Middle Ear
Physiology of the Cochlea
Abstract 71 (1)
Introduction 72 (1)
Frequency Selectivity of the Basilar 73 (10)
Membrane
Traveling Wave Motion 75 (1)
Basilar Membrane Frequency Tuning Is 76 (3)
Nonlinear
Role of the Outer Hair Cells in Basilar 79 (3)
Membrane Motion
Amplitude Compression 82 (1)
Role of the Tectorial Membrane for 82 (1)
Basilar Membrane Tuning
Cochlea as a Generator of Sound 83 (3)
Cochlear Echoes 83 (1)
Otoacoustic Emissions That Depend on 84 (1)
Active Processes
Distortion Product Otoacoustic Emissions 85 (1)
(DPOAE)
Spontaneous Otoacoustic Emission 86 (1)
Epochs of Research in Cochlear Mechanics 86 (1)
Sensory Transduction in the Cochlea 87 (5)
Which Phases of a Sound Excite Hair Cells 88 (2)
(Rarefaction or Condensation)?
Are Hair Cells Sensitive to Velocity or 90 (1)
Displacement of the Basilar Membrane?
Efferent Control of Inner Hair Cells 91 (1)
Autonomic Control of the Cochlea 92 (1)
Nonauditory Aspects of the Cochlea 92 (3)
Electrical Potentials in the Cochlea 92 (1)
Autoregulation of Blood Flow to the 93 (2)
Cochlea
Electrical Potentials in the Cochlea
Abstract 95 (1)
Introduction 96 (1)
Recordings from the Round Window 96 (14)
Cochlear Microphonics (CM) 98 (1)
Summating Potentials (SP) 99 (1)
Action Potential (AP) 100(10)
Electrocochleographic (ECoG) Potentials 110(5)
Use of the ECoG to Determine Frequency 114(1)
Tuning of the Auditory Nerve in Humans
Section I References 115(14)
SECTION II Auditory Nervous System
Anatomy of the Auditory Nervous System
Abstract 129(1)
Classical Ascending Auditory Pathway 130(13)
Auditory Nerve 130(5)
Cochlear Nucleus 135(4)
Superior Olivary Complex and Nuclei of 139(4)
the Lateral Lemniscus
Auditory Cerebral Cortex 143(1)
Connections between the Two Sides 143(1)
Differences between the Classical Auditory 143(3)
Pathway in Humans and in Animals
Nonclassical Ascending Auditory 146(3)
Descending Pathways 149(2)
Representation of Frequency in the Auditory
System
Abstract 151(1)
Introduction 152(3)
Frequency Tuning in the Auditory Nervous 155(14)
System
Frequency Tuning in the Auditory Nerve 155(2)
Auditory System Is a Nonlinear Spectrum 157(6)
Analyzer
Frequency Tuning in Nuclei of the 163(1)
Ascending Auditory Pathway
Primary Auditory Cortex 164(1)
Frequency Tuning Depends on Measures of 165(3)
Neural Discharges
Frequency Tuning Can Be Modified by Sound 168(1)
Tonotopic Organization in the Nuclei of 168(1)
the Ascending Auditory Pathway
Time Interval Coding 169(12)
Neural Coding of Periodic Sounds 170(1)
Phase Locking in the Auditory Nerve 171(2)
Phase Locking in Nuclei of the Ascending 173(1)
Auditory Pathway
Phase Locking of Complex Sounds 173(1)
Preservation of the Temporal Code of 174(1)
Frequency
How Does the Nervous System Extract 175(3)
Information from the Temporal Code of
Neural Discharges?
Anatomical Location of Neurons That 178(3)
Detect Time Intervals
Is Temporal Code or Place Code the Basis for
Frequency Discrimination?
Abstract 181(1)
Introduction 182(1)
Studies of Coding of Synthetic Vowels 183(5)
Preservation of the Place Code 183(1)
Preservation of the Temporal Code 184(4)
Bases for Preservation of the Temporal Code 188(2)
of Frequency
Robustness of the Place Code of Frequency 190(5)
Importance of Frequency Analysis in the 192(1)
Cochlea
Importance of Temporal Coherency of 193(1)
Auditory Nerve Firing for Speech
Discrimination
Decoding Temporal Information 194(1)
Cochlear Spectral Filtering May Be 194(1)
Important for Temporal Coding
A Duplex Hypothesis of Frequency 195(2)
Discrimination
Coding of Complex Sounds
Abstract 197(1)
Introduction 198(2)
Response to Tone Bursts 200(4)
Auditory Nerve 200(3)
Cochlear Nucleus 203(1)
Other Nuclei of the Classical Ascending 203(1)
Auditory Pathway
Coding of Small Changes in Amplitude 204(18)
Amplitude-Modulated Sounds 205(17)
Response to Tones with Changing Frequency 222(12)
Effect of Rate of Change in the Frequency 223(11)
of Tone Stimuli
Neural Selectivity to Other Temporal 234(2)
Patterns of Sounds
Tuning to Duration of Sounds 234(1)
Tuning to Time Intervals Unrelated to 234(2)
Spectrum
Spatial Organization to Features Other Than 236(3)
Frequency
Coding of Sound Intensity 239(1)
Conclusions 240(3)
Hearing with Two Ears
Abstract 243(1)
Introduction 244(1)
Physical Basis for Directional Hearing 245(1)
Bilateral Interaction in the Auditory System 246(19)
Neural Mechanisms for Detection of Small 246(10)
Interaural Time Differences
Detection of Interaural Intensity 256(3)
Differences
Discrimination of Elevation 259(1)
Representation of Auditory Space 259(6)
Electrical Potentials in the Auditory Nervous
System
Abstract 265(1)
Introduction 266(1)
Recordings from the Auditory Nerve 267(4)
Studies in Animals 267(4)
Recording Directly from the Human Auditory 271(18)
Nerve
Monopolar Recordings 273(6)
Bipolar Recordings 279(2)
Conduction Velocity of the Auditory Nerve 281(2)
Frequency Following Response 283(6)
Recordings from the Cochlear Nucleus 289(2)
Recordings from More Central Parts of the 291(6)
Ascending Auditory Pathway
Frequency Following Responses from the 293(2)
Superior Olivary Nuclei
Recordings from the Midbrain 295(2)
Far-Field Auditory Evoked Potentials
Abstract 297(1)
Introduction 298(1)
Brainstem Auditory Evoked Potentials 299(23)
Neural Generators of the Brainstem 305(16)
Auditory Evoked Potentials
Conclusion about the Neural Generators of 321(1)
the Brainstem Auditory Evoked Potentials
Middle Latency Responses 322(2)
Neural Generators of the Middle Latency 323(1)
Responses
The 40-HZ Response 324(1)
Other Sound-Evoked Potentials 324(7)
Far-Field Frequency Following Responses 324(2)
in Humans
Myogenic Auditory Evoked Potentials 326(5)
Section II References 331(14)
SECTION III Acoustic Reflexes
Acoustic Middle Ear Reflex
Abstract 345(1)
Introduction 346(1)
Neural Pathway of the Acoustic Middle Ear 346(3)
Reflex
Physiology 349(1)
Responses to Stimulation with Tones 349(9)
Threshold of the Reflex 353(2)
Latency of the Reflex Response 355(3)
Functional Importance of the Acoustic 358(6)
Middle Ear Reflex
Acoustic Reflex as a Control System 359(5)
Nonacoustic Ways to Elicit Contraction of 364(2)
the Middle Ear Muscles
Voluntary Control over Middle Ear Muscles 365(1)
Stapedius Contraction May Be Elicited 366(1)
before Vocalization
Clinical Use of the Acoustic Middle Ear 366(3)
Reflex
Section III References 369(10)
SECTION IV Disorders of the Auditory System and
Their Pathophysiology
Sound-Conducting Apparatus
Abstract 379(1)
Introduction 380(1)
Ear Canal 380(2)
Ear Canal Collapse 380(1)
Ear Canal Atresia 381(1)
Middle Ear 382(8)
Air Pressure 382(1)
Fluid in the Middle Ear (Otitis Media 383(2)
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