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24.910 Topics in Linguistic Theory: Laboratory Phonology (MIT) 24.910 Topics in Linguistic Theory: Laboratory Phonology (MIT)

Description

The goal of this course is to prepare you to engage in experimental investigations of questions related to linguistic theory, focusing on phonetics and phonology. The goal of this course is to prepare you to engage in experimental investigations of questions related to linguistic theory, focusing on phonetics and phonology.

Subjects

audition | audition | digital signal processing | digital signal processing | acoustics of vowels | acoustics of vowels | adaptive dispersion | adaptive dispersion | spectral analysis | spectral analysis | licensing by cue | licensing by cue | intonation | intonation | meaning of intonation | meaning of intonation | lexicon | lexicon | cntext | cntext | speech perception | speech perception | phonetics | phonetics | phonology | phonology | accent variation | accent variation | laboratory phonology | laboratory phonology | source-filter theory | source-filter theory | A/D conversion | A/D conversion | acoustics | acoustics

License

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2.682 Acoustical Oceanography (MIT) 2.682 Acoustical Oceanography (MIT)

Description

This course will begin with brief overview of what important current research topics are in oceanography (physical, geological, and biological) and how acoustics can be used as a tool to address them. Three typical examples are climate, bottom geology, and marine mammal behavior. Will then address the acoustic inverse problem, reviewing inverse methods (linear and nonlinear) and the combination of acoustical methods with other measurements as an integrated system. Last part of course will concentrate on specific case studies, taken from current research journals. This course is taught on campus at MIT and with simultaneous video at Woods Hole Oceanographic Institution. This course will begin with brief overview of what important current research topics are in oceanography (physical, geological, and biological) and how acoustics can be used as a tool to address them. Three typical examples are climate, bottom geology, and marine mammal behavior. Will then address the acoustic inverse problem, reviewing inverse methods (linear and nonlinear) and the combination of acoustical methods with other measurements as an integrated system. Last part of course will concentrate on specific case studies, taken from current research journals. This course is taught on campus at MIT and with simultaneous video at Woods Hole Oceanographic Institution.

Subjects

oceanography | oceanography | acoustics | acoustics | shallow water acoustics | shallow water acoustics | acoustical oceanography | acoustical oceanography | WHOI | WHOI

License

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2.019 Design of Ocean Systems (MIT) 2.019 Design of Ocean Systems (MIT)

Description

This course is the completion of the cycle of designing, implementing and testing an ocean system, including hardware and software implementation, that begins with 2.017J. Design lectures are given in hydrodynamics, power and thermal aspects of ocean vehicles, environment, materials and construction for ocean use, electronics, sensors, and actuators. Student teams work within schedule and budget, setting goals, reviewing progress, and making regular and final presentations. Instruction and practice occur in oral and written communication. This course is the completion of the cycle of designing, implementing and testing an ocean system, including hardware and software implementation, that begins with 2.017J. Design lectures are given in hydrodynamics, power and thermal aspects of ocean vehicles, environment, materials and construction for ocean use, electronics, sensors, and actuators. Student teams work within schedule and budget, setting goals, reviewing progress, and making regular and final presentations. Instruction and practice occur in oral and written communication.

Subjects

hydrodynamics | hydrodynamics | power and thermal aspects of ocean vehicles | power and thermal aspects of ocean vehicles | environment | environment | electronics | electronics | sensors | sensors | actuators | actuators | sea-keeping | sea-keeping | hull strength | hull strength | physics of acoustics | physics of acoustics | resistance | resistance | propulsion | propulsion | control surfaces | control surfaces | dynamics | dynamics | feedback control | feedback control | graphical information systems | graphical information systems | GIS | GIS

License

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HST.725 Music Perception and Cognition (MIT) HST.725 Music Perception and Cognition (MIT)

Description

Survey of perceptual and cognitive aspects of the psychology of music, with special emphasis on underlying neuronal and neurocomputational representations and mechanisms. Basic perceptual dimensions of hearing (pitch, timbre, consonance/roughness, loudness, auditory grouping) form salient qualities, contrasts, patterns and streams that are used in music to convey melody, harmony, rhythm and separate voices. Perceptual, cognitive, and neurophysiological aspects of the temporal dimension of music (rhythm, timing, duration, temporal expectation) are explored. Special topics include comparative, evolutionary, and developmental psychology of music perception, biological vs. cultural influences, Gestaltist vs. associationist vs. schema-based theories, comparison of music and speech perception, p Survey of perceptual and cognitive aspects of the psychology of music, with special emphasis on underlying neuronal and neurocomputational representations and mechanisms. Basic perceptual dimensions of hearing (pitch, timbre, consonance/roughness, loudness, auditory grouping) form salient qualities, contrasts, patterns and streams that are used in music to convey melody, harmony, rhythm and separate voices. Perceptual, cognitive, and neurophysiological aspects of the temporal dimension of music (rhythm, timing, duration, temporal expectation) are explored. Special topics include comparative, evolutionary, and developmental psychology of music perception, biological vs. cultural influences, Gestaltist vs. associationist vs. schema-based theories, comparison of music and speech perception, p

Subjects

music perception | music perception | music cognition | music cognition | music memory | music memory | pitch | pitch | timbre | timbre | consonance | consonance | harmony | harmony | tonality | tonality | melody | melody | expressive timing | expressive timing | rhythmic hierarchies | rhythmic hierarchies | auditory perception | auditory perception | auditory pathway | auditory pathway | musical acoustics | musical acoustics | power spectra | power spectra | psychophysics | psychophysics | neurocomputational models | neurocomputational models | neural correlates | neural correlates | music therapy | music therapy | synesthesia | synesthesia | absolute pitch | absolute pitch

License

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1.138J Wave Propagation (MIT) 1.138J Wave Propagation (MIT)

Description

This course discusses the Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. The topics include: basic concepts, one dimensional examples, characteristics, dispersion and group velocity, scattering, transmission and reflection, two dimensional reflection and refraction across an interface, mode conversion in elastic waves, diffraction and parabolic approximation, radiation from a line source, surface Rayleigh waves and Love waves in elastic media, waves on the sea surface and internal waves in a stratified fluid, waves in moving media, ship wave pattern, atmospheric lee waves behind an obstacle, and waves through a laminated media, etc. This course discusses the Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. The topics include: basic concepts, one dimensional examples, characteristics, dispersion and group velocity, scattering, transmission and reflection, two dimensional reflection and refraction across an interface, mode conversion in elastic waves, diffraction and parabolic approximation, radiation from a line source, surface Rayleigh waves and Love waves in elastic media, waves on the sea surface and internal waves in a stratified fluid, waves in moving media, ship wave pattern, atmospheric lee waves behind an obstacle, and waves through a laminated media, etc.

Subjects

1.138 | 1.138 | 2.062 | 2.062 | acoustics | acoustics | geophysics | geophysics | hydrodynamics | hydrodynamics | wave phenomena | wave phenomena | wave propagation | wave propagation

License

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13.00 Introduction to Ocean Science and Technology (MIT) 13.00 Introduction to Ocean Science and Technology (MIT)

Description

Introductory subject for students majoring or minoring in ocean engineering and others desiring introductory knowledge in the field. Physical oceanography including distributions of salinity, temperature, and density, heat balance, major ocean circulations and geostrophic flows, and influence of wind stress. Surface waves including wave velocities, propagation phenomena, and descriptions of real sea waves. Acoustics in the ocean including influence of water properties on sound speed and refraction, sounds generated by ships and marine animals, fundamentals of sonar, types of sonar systems and their principles of operation.Technical RequirementsAny number of software tools can be used to import the .dat files found on this course site. Please refer to the course materials for any specific i Introductory subject for students majoring or minoring in ocean engineering and others desiring introductory knowledge in the field. Physical oceanography including distributions of salinity, temperature, and density, heat balance, major ocean circulations and geostrophic flows, and influence of wind stress. Surface waves including wave velocities, propagation phenomena, and descriptions of real sea waves. Acoustics in the ocean including influence of water properties on sound speed and refraction, sounds generated by ships and marine animals, fundamentals of sonar, types of sonar systems and their principles of operation.Technical RequirementsAny number of software tools can be used to import the .dat files found on this course site. Please refer to the course materials for any specific i

Subjects

Physical oceanography | | Physical oceanography | | major ocean circulations | | major ocean circulations | | geostrophic flows | | geostrophic flows | | Surface waves | | Surface waves | | wave velocities | | wave velocities | | propagation phenomena | | propagation phenomena | | ocean acoustics | | ocean acoustics | | sonar | sonar

License

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HST.723 Neural Coding and Perception of Sound (MIT) HST.723 Neural Coding and Perception of Sound (MIT)

Description

Neural structures and mechanisms mediating the detection, localization and recognition of sounds. We will discuss how acoustic signals are coded by auditory neurons, the impact of these codes on behavioral performance, and the circuitry and cellular mechanisms underlying signal transformations. Topics include temporal coding, neural maps and feature detectors, learning and plasticity, and feedback control. General principles are conveyed by theme discussions of auditory masking, sound localization, musical pitch, speech coding, and cochlear implants. Neural structures and mechanisms mediating the detection, localization and recognition of sounds. We will discuss how acoustic signals are coded by auditory neurons, the impact of these codes on behavioral performance, and the circuitry and cellular mechanisms underlying signal transformations. Topics include temporal coding, neural maps and feature detectors, learning and plasticity, and feedback control. General principles are conveyed by theme discussions of auditory masking, sound localization, musical pitch, speech coding, and cochlear implants.

Subjects

hearing | hearing | neural structures | neural structures | auditory masking | auditory masking | acoustics | acoustics | signal transformations | signal transformations | temporal coding | temporal coding | neural maps | neural maps | feature detectors | feature detectors | learning | learning | plasticity | plasticity | feedback control | feedback control | sound localization | sound localization | musical pitch | musical pitch | speech coding | speech coding | cochlear implants | cochlear implants

License

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1.138J Wave Propagation (MIT) 1.138J Wave Propagation (MIT)

Description

Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. Basic concepts. One dimensional examples. Characteristics, dispersion and group velocity. Scattering, transmission and reflection. Two dimensional reflection and refraction across an interface. Mode conversion in elastic waves. Diffraction and parabolic approximation Radiation from a line source. Surface Rayleigh waves and Love waves in elastic media. Waves on the sea surface and internal waves in a stratified fluid. Waves in moving media. Ship wave pattern. Atmospheric lee waves behind an obstacle. Waves through a laminated media, etc. Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. Basic concepts. One dimensional examples. Characteristics, dispersion and group velocity. Scattering, transmission and reflection. Two dimensional reflection and refraction across an interface. Mode conversion in elastic waves. Diffraction and parabolic approximation Radiation from a line source. Surface Rayleigh waves and Love waves in elastic media. Waves on the sea surface and internal waves in a stratified fluid. Waves in moving media. Ship wave pattern. Atmospheric lee waves behind an obstacle. Waves through a laminated media, etc.

Subjects

wave propagation | wave propagation | wave phenomena | wave phenomena | hydrodynamics | hydrodynamics | geophysics | geophysics | acoustics | acoustics | 1.138 | 1.138 | 2.062 | 2.062

License

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2.011 Introduction to Ocean Science and Technology (13.00) (MIT) 2.011 Introduction to Ocean Science and Technology (13.00) (MIT)

Description

Introductory subject for students majoring or minoring in ocean engineering and others desiring introductory knowledge in the field. Physical oceanography including distributions of salinity, temperature, and density, heat balance, major ocean circulations and geostrophic flows, and influence of wind stress. Surface waves including wave velocities, propagation phenomena, and descriptions of real sea waves. Acoustics in the ocean including influence of water properties on sound speed and refraction, sounds generated by ships and marine animals, fundamentals of sonar, types of sonar systems and their principles of operation.This course was originally offered in Course 13 (Department of Ocean Engineering) as 13.00. In 2005, ocean engineering subjects became part of Course 2 (Department of Mec Introductory subject for students majoring or minoring in ocean engineering and others desiring introductory knowledge in the field. Physical oceanography including distributions of salinity, temperature, and density, heat balance, major ocean circulations and geostrophic flows, and influence of wind stress. Surface waves including wave velocities, propagation phenomena, and descriptions of real sea waves. Acoustics in the ocean including influence of water properties on sound speed and refraction, sounds generated by ships and marine animals, fundamentals of sonar, types of sonar systems and their principles of operation.This course was originally offered in Course 13 (Department of Ocean Engineering) as 13.00. In 2005, ocean engineering subjects became part of Course 2 (Department of Mec

Subjects

Physical oceanography | | Physical oceanography | | major ocean circulations | | major ocean circulations | | geostrophic flows | | geostrophic flows | | Surface waves | | Surface waves | | wave velocities | | wave velocities | | propagation phenomena | | propagation phenomena | | ocean acoustics | | ocean acoustics | | sonar | sonar

License

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HST.725 Music Perception and Cognition (MIT) HST.725 Music Perception and Cognition (MIT)

Description

Includes audio/video content: AV faculty introductions. This course is a survey of perceptual and cognitive aspects of the psychology of music, with special emphasis on underlying neuronal and neurocomputational representations and mechanisms. Basic perceptual dimensions of hearing (pitch, timbre, consonance/roughness, loudness, auditory grouping) form salient qualities, contrasts, patterns and streams that are used in music to convey melody, harmony, rhythm and separate voices. Perceptual, cognitive, and neurophysiological aspects of the temporal dimension of music (rhythm, timing, duration, temporal expectation) are explored. Special topics include comparative, evolutionary, and developmental psychology of music perception, biological vs. cultural influences, Gestaltist vs. associationis Includes audio/video content: AV faculty introductions. This course is a survey of perceptual and cognitive aspects of the psychology of music, with special emphasis on underlying neuronal and neurocomputational representations and mechanisms. Basic perceptual dimensions of hearing (pitch, timbre, consonance/roughness, loudness, auditory grouping) form salient qualities, contrasts, patterns and streams that are used in music to convey melody, harmony, rhythm and separate voices. Perceptual, cognitive, and neurophysiological aspects of the temporal dimension of music (rhythm, timing, duration, temporal expectation) are explored. Special topics include comparative, evolutionary, and developmental psychology of music perception, biological vs. cultural influences, Gestaltist vs. associationis

Subjects

music perception | music perception | music cognition | music cognition | music memory | music memory | pitch | pitch | timbre | timbre | consonance | consonance | harmony | harmony | tonality | tonality | melody | melody | expressive timing | expressive timing | rhythmic hierarchies | rhythmic hierarchies | auditory perception | auditory perception | auditory pathway | auditory pathway | musical acoustics | musical acoustics | power spectra | power spectra | psychophysics | psychophysics | neurocomputational models | neurocomputational models | neural correlates | neural correlates | music therapy | music therapy | synesthesia | synesthesia | absolute pitch | absolute pitch

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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6.013 Electromagnetics and Applications (MIT) 6.013 Electromagnetics and Applications (MIT)

Description

Includes audio/video content: AV special element video. This course explores electromagnetic phenomena in modern applications, including wireless and optical communications, circuits, computer interconnects and peripherals, microwave communications and radar, antennas, sensors, micro-electromechanical systems, and power generation and transmission. Fundamentals include quasistatic and dynamic solutions to Maxwell's equations; waves, radiation, and diffraction; coupling to media and structures; guided waves; resonance; acoustic analogs; and forces, power, and energy. Includes audio/video content: AV special element video. This course explores electromagnetic phenomena in modern applications, including wireless and optical communications, circuits, computer interconnects and peripherals, microwave communications and radar, antennas, sensors, micro-electromechanical systems, and power generation and transmission. Fundamentals include quasistatic and dynamic solutions to Maxwell's equations; waves, radiation, and diffraction; coupling to media and structures; guided waves; resonance; acoustic analogs; and forces, power, and energy.

Subjects

electromagnetics | electromagnetics | electromagnetic fields | electromagnetic fields | electrodynamics | electrodynamics | devices and circuits | devices and circuits | static and quasistatic fields | static and quasistatic fields | electromagnetic forces | electromagnetic forces | actuators | actuators | sensors | sensors | TEM lines | TEM lines | electromagnetic waves | electromagnetic waves | antennas | antennas | radiation | radiation | optical communications | optical communications | acoustics | acoustics

License

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24.963 Linguistic Phonetics (MIT) 24.963 Linguistic Phonetics (MIT)

Description

Includes audio/video content: AV special element audio. This course is a study of speech sounds: how we produce and perceive them and their acoustic properties. It explores the influence of the production and perception systems on phonological patterns and sound change. Acoustic analysis and experimental techniques are also discussed. Includes audio/video content: AV special element audio. This course is a study of speech sounds: how we produce and perceive them and their acoustic properties. It explores the influence of the production and perception systems on phonological patterns and sound change. Acoustic analysis and experimental techniques are also discussed.

Subjects

phonetics | phonetics | acoustics | acoustics | audition | audition | A/D conversion | A/D conversion | grammars | grammars | source-filter theory | source-filter theory | spectral analysis | spectral analysis | adaptive dispersion | adaptive dispersion | quantal theory | quantal theory | fricatives | fricatives | stops | stops | statistics | statistics | speech perception | speech perception | sounds | sounds | nasals | nasals | laterals | laterals | coarticulation | coarticulation | speech production | speech production | timing | timing | coordination | coordination | variability | variability

License

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2.062J Wave Propagation (MIT) 2.062J Wave Propagation (MIT)

Description

This course discusses the Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. The topics include: basic concepts, one dimensional examples, characteristics, dispersion and group velocity, scattering, transmission and reflection, two dimensional reflection and refraction across an interface, mode conversion in elastic waves, diffraction and parabolic approximation, radiation from a line source, surface Rayleigh waves and Love waves in elastic media, waves on the sea surface and internal waves in a stratified fluid, waves in moving media, ship wave pattern, atmospheric lee waves behind an obstacle, and waves through a laminated media. This course discusses the Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. The topics include: basic concepts, one dimensional examples, characteristics, dispersion and group velocity, scattering, transmission and reflection, two dimensional reflection and refraction across an interface, mode conversion in elastic waves, diffraction and parabolic approximation, radiation from a line source, surface Rayleigh waves and Love waves in elastic media, waves on the sea surface and internal waves in a stratified fluid, waves in moving media, ship wave pattern, atmospheric lee waves behind an obstacle, and waves through a laminated media.

Subjects

1.138 | 1.138 | 2.062 | 2.062 | acoustics | acoustics | geophysics | geophysics | hydrodynamics | hydrodynamics | wave phenomena | wave phenomena | wave propagation | wave propagation

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2.011 Introduction to Ocean Science and Engineering (MIT) 2.011 Introduction to Ocean Science and Engineering (MIT)

Description

This course is an introduction to the fundamental aspects of science and engineering necessary for exploring, observing, and utilizing the oceans. Hands-on projects focus on instrumentation in the marine environment and the design of ocean observatories for ocean monitoring and exploration. Topics include acoustics, sound speed and refraction, sounds generated by ships and marine animals, sonar systems and their principles of operation, hydrostatic behavior of floating and submerged bodies geared towards ocean vehicle design, stability of ocean vessels, and the application of instrumentation and electronics in the marine environment. Students work with sensor systems and deploy them in the field to gather and analyze real world data. This course is an introduction to the fundamental aspects of science and engineering necessary for exploring, observing, and utilizing the oceans. Hands-on projects focus on instrumentation in the marine environment and the design of ocean observatories for ocean monitoring and exploration. Topics include acoustics, sound speed and refraction, sounds generated by ships and marine animals, sonar systems and their principles of operation, hydrostatic behavior of floating and submerged bodies geared towards ocean vehicle design, stability of ocean vessels, and the application of instrumentation and electronics in the marine environment. Students work with sensor systems and deploy them in the field to gather and analyze real world data.

Subjects

oceanography | oceanography | physical oceanography | physical oceanography | ocean circulation | ocean circulation | geostrophic flow | geostrophic flow | surface wave | surface wave | wave velocity | wave velocity | propagation phenomena | propagation phenomena | ocean acoustics | ocean acoustics | sonar | sonar | submarine | submarine | submersible | submersible | marine | marine | marine science | marine science | ship | ship | boat | boat | marine animal | marine animal | undersea | undersea | ROV | ROV | current | current | vortex | vortex | turbulence | turbulence

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6.911 Transcribing Prosodic Structure of Spoken Utterances with ToBI (MIT) 6.911 Transcribing Prosodic Structure of Spoken Utterances with ToBI (MIT)

Description

This course presents a tutorial on the ToBI (Tones and Break Indices) system, for labelling certain aspects of prosody in Mainstream American English (MAE-ToBI). The course is appropriate for undergrad or grad students with background in linguistics (phonology or phonetics), cognitive psychology (psycholinguistics), speech acoustics or music, who wish to learn about the prosody of speech, i.e. the intonation, rhythm, grouping and prominence patterns of spoken utterances, prosodic differences that signal meaning and phonetic implementation. This course presents a tutorial on the ToBI (Tones and Break Indices) system, for labelling certain aspects of prosody in Mainstream American English (MAE-ToBI). The course is appropriate for undergrad or grad students with background in linguistics (phonology or phonetics), cognitive psychology (psycholinguistics), speech acoustics or music, who wish to learn about the prosody of speech, i.e. the intonation, rhythm, grouping and prominence patterns of spoken utterances, prosodic differences that signal meaning and phonetic implementation.

Subjects

ToBI system | ToBI system | Tones and Break Indices | Tones and Break Indices | prosodic structure | prosodic structure | spoken utterances | spoken utterances | American English | American English | ToBI tutorial | ToBI tutorial | labelling | labelling | sample utterances | sample utterances | linguistics | linguistics | phonology | phonology | phonetics | phonetics | cognitive psychology | cognitive psychology | psycholinguistics | psycholinguistics | speech acoustics or music | speech acoustics or music | prosody of speech | prosody of speech | intonation | intonation | rhythm | rhythm | grouping | grouping | prosodic differences | prosodic differences | phonetic implementation | phonetic implementation

License

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6.551J Acoustics of Speech and Hearing (MIT) 6.551J Acoustics of Speech and Hearing (MIT)

Description

The Acoustics of Speech and Hearing is an H-Level graduate course that reviews the physical processes involved in the production, propagation and reception of human speech. Particular attention is paid to how the acoustics and mechanics of the speech and auditory system define what sounds we are capable of producing and what sounds we can sense. Areas of discussion include: the acoustic cues used in determining the direction of a sound source, the acoustic and mechanical mechanisms involved in speech production and the acoustic and mechanical mechanism used to transduce and analyze sounds in the ear. The Acoustics of Speech and Hearing is an H-Level graduate course that reviews the physical processes involved in the production, propagation and reception of human speech. Particular attention is paid to how the acoustics and mechanics of the speech and auditory system define what sounds we are capable of producing and what sounds we can sense. Areas of discussion include: the acoustic cues used in determining the direction of a sound source, the acoustic and mechanical mechanisms involved in speech production and the acoustic and mechanical mechanism used to transduce and analyze sounds in the ear.

Subjects

HST.714 | HST.714 | sound | sound | speech communication | speech communication | human anatomy | human anatomy | speech production | speech production | sound production | sound production | airflow | airflow | filtering | filtering | vocal tract | vocal tract | auditory physiology | auditory physiology | acoustical waves | acoustical waves | mechanical vibrations | mechanical vibrations | cochlear structures | cochlear structures | sound perception | sound perception | spatial hearing | spatial hearing | masking | masking | auditory frequency selectivity | auditory frequency selectivity | physical processes | physical processes | sound propagation | sound propagation | human speech | human speech | acoustics | acoustics | speech mechanics | speech mechanics | auditory system | auditory system | sound direction | sound direction | ear | ear | 6.551 | 6.551

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18.307 Integral Equations (MIT) 18.307 Integral Equations (MIT)

Description

This course emphasizes concepts and techniques for solving integral equations from an applied mathematics perspective. Material is selected from the following topics: Volterra and Fredholm equations, Fredholm theory, the Hilbert-Schmidt theorem; Wiener-Hopf Method; Wiener-Hopf Method and partial differential equations; the Hilbert Problem and singular integral equations of Cauchy type; inverse scattering transform; and group theory. Examples are taken from fluid and solid mechanics, acoustics, quantum mechanics, and other applications. This course emphasizes concepts and techniques for solving integral equations from an applied mathematics perspective. Material is selected from the following topics: Volterra and Fredholm equations, Fredholm theory, the Hilbert-Schmidt theorem; Wiener-Hopf Method; Wiener-Hopf Method and partial differential equations; the Hilbert Problem and singular integral equations of Cauchy type; inverse scattering transform; and group theory. Examples are taken from fluid and solid mechanics, acoustics, quantum mechanics, and other applications.

Subjects

integral equations | integral equations | applied mathematics | applied mathematics | Volterra equation | Volterra equation | Fredholm equation | Fredholm equation | Fredholm theory | Fredholm theory | Hilbert-Schmidt theorem | Hilbert-Schmidt theorem | Wiener-Hopf Method | Wiener-Hopf Method | partial differential equations | partial differential equations | Hilbert Problem | Hilbert Problem | ingular integral equations | ingular integral equations | Cauchy type | Cauchy type | inverse scattering transform | inverse scattering transform | group theory | group theory | fluid mechanics | fluid mechanics | solid mechanics | solid mechanics | acoustics | acoustics | quantum mechanics | quantum mechanics

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see http://ocw.mit.edu/terms/index.htm

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Northrop T-38A Talon Northrop T-38A Talon

Description

Subjects

sound | sound | langley | langley | northropt38 | northropt38 | acousticsnoisepollution | acousticsnoisepollution | talont38a | talont38a

License

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What's this gadget? (LOC) What's this gadget? (LOC)

Description

Subjects

libraryofcongress | libraryofcongress | acoustics | acoustics | physicists | physicists | nationalbureauofstandards | nationalbureauofstandards | usbureauofstandards | usbureauofstandards | acousticalresearch | acousticalresearch | vlchrisler | vlchrisler | vivianleroychrisler | vivianleroychrisler

License

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2.682 Acoustical Oceanography (MIT)

Description

This course will begin with brief overview of what important current research topics are in oceanography (physical, geological, and biological) and how acoustics can be used as a tool to address them. Three typical examples are climate, bottom geology, and marine mammal behavior. Will then address the acoustic inverse problem, reviewing inverse methods (linear and nonlinear) and the combination of acoustical methods with other measurements as an integrated system. Last part of course will concentrate on specific case studies, taken from current research journals. This course is taught on campus at MIT and with simultaneous video at Woods Hole Oceanographic Institution.

Subjects

oceanography | acoustics | shallow water acoustics | acoustical oceanography | WHOI

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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24.910 Topics in Linguistic Theory: Laboratory Phonology (MIT)

Description

The goal of this course is to prepare you to engage in experimental investigations of questions related to linguistic theory, focusing on phonetics and phonology.

Subjects

audition | digital signal processing | acoustics of vowels | adaptive dispersion | spectral analysis | licensing by cue | intonation | meaning of intonation | lexicon | cntext | speech perception | phonetics | phonology | accent variation | laboratory phonology | source-filter theory | A/D conversion | acoustics

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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6.013 Electromagnetics and Applications (MIT)

Description

This course explores electromagnetic phenomena in modern applications, including wireless and optical communications, circuits, computer interconnects and peripherals, microwave communications and radar, antennas, sensors, micro-electromechanical systems, and power generation and transmission. Fundamentals include quasistatic and dynamic solutions to Maxwell's equations; waves, radiation, and diffraction; coupling to media and structures; guided waves; resonance; acoustic analogs; and forces, power, and energy.

Subjects

electromagnetics | electromagnetic fields | electrodynamics | devices and circuits | static and quasistatic fields | electromagnetic forces | actuators | sensors | TEM lines | electromagnetic waves | antennas | radiation | optical communications | acoustics

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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2.062J Wave Propagation (MIT)

Description

This course discusses the Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. The topics include: basic concepts, one dimensional examples, characteristics, dispersion and group velocity, scattering, transmission and reflection, two dimensional reflection and refraction across an interface, mode conversion in elastic waves, diffraction and parabolic approximation, radiation from a line source, surface Rayleigh waves and Love waves in elastic media, waves on the sea surface and internal waves in a stratified fluid, waves in moving media, ship wave pattern, atmospheric lee waves behind an obstacle, and waves through a laminated media.

Subjects

1.138 | 2.062 | acoustics | geophysics | hydrodynamics | wave phenomena | wave propagation

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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2.062J Wave Propagation (MIT)

Description

This course discusses the Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. The topics include: basic concepts, one dimensional examples, characteristics, dispersion and group velocity, scattering, transmission and reflection, two dimensional reflection and refraction across an interface, mode conversion in elastic waves, diffraction and parabolic approximation, radiation from a line source, surface Rayleigh waves and Love waves in elastic media, waves on the sea surface and internal waves in a stratified fluid, waves in moving media, ship wave pattern, atmospheric lee waves behind an obstacle, and waves through a laminated media.

Subjects

1.138 | 2.062 | acoustics | geophysics | hydrodynamics | wave phenomena | wave propagation

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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2.062J Wave Propagation (MIT)

Description

This course discusses the Linearized theory of wave phenomena in applied mechanics. Examples are chosen from elasticity, acoustics, geophysics, hydrodynamics and other subjects. The topics include: basic concepts, one dimensional examples, characteristics, dispersion and group velocity, scattering, transmission and reflection, two dimensional reflection and refraction across an interface, mode conversion in elastic waves, diffraction and parabolic approximation, radiation from a line source, surface Rayleigh waves and Love waves in elastic media, waves on the sea surface and internal waves in a stratified fluid, waves in moving media, ship wave pattern, atmospheric lee waves behind an obstacle, and waves through a laminated media.

Subjects

1.138 | 2.062 | acoustics | geophysics | hydrodynamics | wave phenomena | wave propagation

License

Content within individual OCW courses is (c) by the individual authors unless otherwise noted. MIT OpenCourseWare materials are licensed by the Massachusetts Institute of Technology under a Creative Commons License (Attribution-NonCommercial-ShareAlike). For further information see https://ocw.mit.edu/terms/index.htm

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