Fundamentals and applications of ultrasonic waves / / J. David N. Cheeke |
Autore | Cheeke J. David N. |
Edizione | [2nd ed.] |
Pubbl/distr/stampa | Boca Raton : , : CRC Press, , 2012 |
Descrizione fisica | 1 online resource (497 p.) |
Disciplina | 534.5/5 |
Soggetto topico |
Ultrasonic waves
Ultrasonic waves - Industrial applications |
Soggetto genere / forma | Electronic books. |
ISBN |
1-315-21730-9
1-4398-5498-X |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; Contents; Preface to the Second Edition; Acknowledgments; About the Author; Chapter 1 - Ultrasonics: An Overview; Chapter 2 - Introduction to Vibrations and Waves; Chapter 3 - Bulk Waves in Fluids; Chapter 4 - Introduction to the Theory of Elasticity; Chapter 5 - Bulk Acoustic Waves in Solids; Chapter 6 - Finite Beams: Radiation, Diffraction, and Scattering; Chapter 7 - Reflection and Transmission of Ultrasonic Waves at Interfaces; Chapter 8 - Rayleigh Waves; Chapter 9 - Lamb Waves; Chapter 10 - Acoustic Waveguides; Chapter 11 - Crystal Acoustics
Chapter 12 - Cavitation and SonoluminescenceChapter 13 - Bulk Acoustic Wave Transducers, Delay Lines, and Oscillators; Chapter 14 - Surface Acoustic Wave Transducers, Analog Signal Processing, and Mobile Applications; Chapter 15 - Microacoustics: RF MEMS, FBAR, and CMUT; Chapter 16 - Acoustic Sensors; Chapter 17 - Focused Beam Acoustic Microscopy; Chapter 18 - Near-Field Acoustic Microscopy; Chapter 19 - Nondestructive Evaluation of Materials; Chapter 20 - Non/Loosely Contacting NDE Techniques; Appendix A: Bessel Functions; Appendix B: Acoustic Properties of Materials Appendix C: Complementary Laboratory Experiments |
Record Nr. | UNINA-9910452382403321 |
Cheeke J. David N. | ||
Boca Raton : , : CRC Press, , 2012 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Fundamentals and applications of ultrasonic waves / / J. David N. Cheeke |
Autore | Cheeke J. David N. |
Edizione | [2nd ed.] |
Pubbl/distr/stampa | Boca Raton : , : CRC Press, , 2012 |
Descrizione fisica | 1 online resource (497 p.) |
Disciplina | 534.5/5 |
Soggetto topico |
Ultrasonic waves
Ultrasonic waves - Industrial applications |
ISBN |
1-351-83319-7
1-315-21730-9 1-4398-5498-X |
Classificazione | SCI055000 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; Contents; Preface to the Second Edition; Acknowledgments; About the Author; Chapter 1 - Ultrasonics: An Overview; Chapter 2 - Introduction to Vibrations and Waves; Chapter 3 - Bulk Waves in Fluids; Chapter 4 - Introduction to the Theory of Elasticity; Chapter 5 - Bulk Acoustic Waves in Solids; Chapter 6 - Finite Beams: Radiation, Diffraction, and Scattering; Chapter 7 - Reflection and Transmission of Ultrasonic Waves at Interfaces; Chapter 8 - Rayleigh Waves; Chapter 9 - Lamb Waves; Chapter 10 - Acoustic Waveguides; Chapter 11 - Crystal Acoustics
Chapter 12 - Cavitation and SonoluminescenceChapter 13 - Bulk Acoustic Wave Transducers, Delay Lines, and Oscillators; Chapter 14 - Surface Acoustic Wave Transducers, Analog Signal Processing, and Mobile Applications; Chapter 15 - Microacoustics: RF MEMS, FBAR, and CMUT; Chapter 16 - Acoustic Sensors; Chapter 17 - Focused Beam Acoustic Microscopy; Chapter 18 - Near-Field Acoustic Microscopy; Chapter 19 - Nondestructive Evaluation of Materials; Chapter 20 - Non/Loosely Contacting NDE Techniques; Appendix A: Bessel Functions; Appendix B: Acoustic Properties of Materials Appendix C: Complementary Laboratory Experiments |
Record Nr. | UNINA-9910779203003321 |
Cheeke J. David N. | ||
Boca Raton : , : CRC Press, , 2012 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Fundamentals and applications of ultrasonic waves / / J. David N. Cheeke |
Autore | Cheeke J. David N |
Edizione | [2nd ed.] |
Pubbl/distr/stampa | Boca Raton, : CRC Press/Taylor & Francis Group, 2012 |
Descrizione fisica | 1 online resource (497 p.) |
Disciplina | 534.5/5 |
Soggetto topico |
Ultrasonic waves
Ultrasonic waves - Industrial applications |
ISBN |
1-351-83319-7
1-315-21730-9 1-4398-5498-X |
Classificazione | SCI055000 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; Contents; Preface to the Second Edition; Acknowledgments; About the Author; Chapter 1 - Ultrasonics: An Overview; Chapter 2 - Introduction to Vibrations and Waves; Chapter 3 - Bulk Waves in Fluids; Chapter 4 - Introduction to the Theory of Elasticity; Chapter 5 - Bulk Acoustic Waves in Solids; Chapter 6 - Finite Beams: Radiation, Diffraction, and Scattering; Chapter 7 - Reflection and Transmission of Ultrasonic Waves at Interfaces; Chapter 8 - Rayleigh Waves; Chapter 9 - Lamb Waves; Chapter 10 - Acoustic Waveguides; Chapter 11 - Crystal Acoustics
Chapter 12 - Cavitation and SonoluminescenceChapter 13 - Bulk Acoustic Wave Transducers, Delay Lines, and Oscillators; Chapter 14 - Surface Acoustic Wave Transducers, Analog Signal Processing, and Mobile Applications; Chapter 15 - Microacoustics: RF MEMS, FBAR, and CMUT; Chapter 16 - Acoustic Sensors; Chapter 17 - Focused Beam Acoustic Microscopy; Chapter 18 - Near-Field Acoustic Microscopy; Chapter 19 - Nondestructive Evaluation of Materials; Chapter 20 - Non/Loosely Contacting NDE Techniques; Appendix A: Bessel Functions; Appendix B: Acoustic Properties of Materials Appendix C: Complementary Laboratory Experiments |
Record Nr. | UNINA-9910813600203321 |
Cheeke J. David N | ||
Boca Raton, : CRC Press/Taylor & Francis Group, 2012 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Ultrasonics [[electronic resource] ] : Fundamentals and Applications / / edited by H. Kuttruff |
Autore | Kuttruff Heinrich |
Edizione | [1st ed. 1991.] |
Pubbl/distr/stampa | Dordrecht : , : Springer Netherlands : , : Imprint : Springer, , 1991 |
Descrizione fisica | 1 online resource (458 p. 20 illus.) |
Disciplina | 534.5/5 |
Soggetto topico |
Materials science
Physics Characterization and Evaluation of Materials Physics, general |
ISBN | 94-011-3846-X |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | I Introduction -- I.1 What is ultrasound? -- I.2 A few historical remarks -- I.3 Ultrasound in the living world -- I.4 Upper frequency limit of sound -- II Basic Concepts of Acoustics -- II.1 Sound fields and the physical quantities describing them -- II.2 Sound propagation in gases and liquids -- II.3 Sound waves in solids -- II.4 Reflection and refraction -- II.5 Doppler effect -- III Sound Radiation and Sound Diffraction -- III.1 Signals in time and frequency representation, linear systems -- III.2 The principle of point source synthesis, the moving piston -- III.3 Radiation from a circular piston -- III.4 Piston with non-uniform surface velocity -- III.5 Diffraction and scattering -- IV Generation of Ultrasound—Part I -- IV.1 The piezoelectric effect -- IV.2 Piezoelectric materials -- IV.3 Basic piezoelectric equations, electro-mechanical coupling factor -- IV.4 Dynamic characteristics of piezoelectric transducers operated in their thickness mode -- IV.5 Mechanical and electrical equivalent circuit of a piezoelectric transducer near its resonance -- IV.6 Practical design of piezoelectric ultrasound generators -- V Generation of Ultrasound—Part II -- V.1 Composite piezoelectric transducers -- V.2 Piezoelectric bending transducers -- V.3 Generation of high frequency ultrasound -- V.4 Concentration of ultrasound by focusing -- V.5 Generation of high vibrational amplitudes -- V.6 Generation of shear waves and Rayleigh waves -- V.7 Magnetostrictive generation of ultrasound -- V.8 Electrostatic ultrasound generators -- V.9 Mechanical methods -- VI Detection and Measurement of Ultrasound -- VI.1 Detection of ultrasound with extended piezo transducers, reciprocity -- VI.2 Electrostatic receivers -- VI.3 Ultrasound microphones, calibration -- VI.4 Mechanical detection -- VI.5 Thermal ultrasound detectors -- VI.6 Diffraction of light by ultrasound waves -- VI.7 Visualization of ultrasound -- VII Generation and Detection of Sound with Frequencies above 1 GHz (Hypersound) -- VII.1 Coherent methods for the generation and detection of hypersound -- VII.2 Phonons (sound quanta) in solids -- VII.3 Quantum acoustical interpretation of some effects of ultrasound -- VII.4 Generation of hypersound with heat pulses -- VII.5 Detection of hypersound with superconducting bolometers -- VII.6 Generation and detection of incoherent hypersound with superconducting tunnel contacts -- VII.7 Detection of ‘natural’ hypersound -- VIII Absorption of Ultrasound -- VIII. 1 Classical sound absorption in gases and liquids -- VIII.2 Molecular sound absorption in gases -- VIII.3 Sound absorption in liquids -- VIII.4 Sound absorption in solids -- VIII.5 Experimental methods for the determination of sound velocity and attenuation in the ultrasonic range -- IX Applications in Signal Processing and Measuring Techniques -- IX. 1 Ultrasonic delay lines -- IX.2 Rayleigh wave filters -- IX.3 Light modulation and light deflection -- IX.4 Other small-signal applications -- X Non-destructive Testing of Materials -- X.1 Survey of various testing methods -- X.2 Impulse echo method -- X.3 Frequencies and wave types -- X.4 Transducers for flaw detection -- X.5 Types of display -- X.6 Suitability of materials for testing -- X.7 Practical examples of ultrasonic flaw detection -- XI Application of Ultrasound in Medical Diagnostics -- XI.1 Acoustic properties of biological tissue -- XI.2 Impulse echo method -- XI.3 Typical applications of the impulse echo method in sonography -- XI.4 Doppler sonography -- XII Special Methods of Ultrasonic Imaging -- XII.1 Ultrasonic microscopy -- XII.2 Acoustic holography -- XII.3 Ultrasonic tomography -- XIII Cavitation -- XIII.1 Basic types of sonically induced cavitation -- XIII.2 Dynamics of a single cavity -- XIII.3 Cavitation nuclei and cavitation thresholds -- XIII.4 Real cavitation and some effects caused by it -- XIV Applications of High Intensity Ultrasound -- XIV.1 Ultrasonic cleaning -- XIV.2 Joining with ultrasound -- XIV.3 Machining -- XIV.4 Production of dispersions -- XIV.5 Further applications -- XIV.6 Medical therapy -- XV On the Possibility of Health Risks Caused by Ultrasound -- XV.1 Damage to tissue caused by diagnostic ultrasound -- XV.2 Damage caused by airborne ultrasound -- Notation. |
Record Nr. | UNINA-9910789201603321 |
Kuttruff Heinrich | ||
Dordrecht : , : Springer Netherlands : , : Imprint : Springer, , 1991 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Ultrasonics : Fundamentals and Applications / / edited by H. Kuttruff |
Autore | Kuttruff Heinrich |
Edizione | [1st ed. 1991.] |
Pubbl/distr/stampa | Dordrecht : , : Springer Netherlands : , : Imprint : Springer, , 1991 |
Descrizione fisica | 1 online resource (458 p. 20 illus.) |
Disciplina | 534.5/5 |
Soggetto topico |
Materials science
Physics Characterization and Evaluation of Materials Physics, general |
ISBN | 94-011-3846-X |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | I Introduction -- I.1 What is ultrasound? -- I.2 A few historical remarks -- I.3 Ultrasound in the living world -- I.4 Upper frequency limit of sound -- II Basic Concepts of Acoustics -- II.1 Sound fields and the physical quantities describing them -- II.2 Sound propagation in gases and liquids -- II.3 Sound waves in solids -- II.4 Reflection and refraction -- II.5 Doppler effect -- III Sound Radiation and Sound Diffraction -- III.1 Signals in time and frequency representation, linear systems -- III.2 The principle of point source synthesis, the moving piston -- III.3 Radiation from a circular piston -- III.4 Piston with non-uniform surface velocity -- III.5 Diffraction and scattering -- IV Generation of Ultrasound—Part I -- IV.1 The piezoelectric effect -- IV.2 Piezoelectric materials -- IV.3 Basic piezoelectric equations, electro-mechanical coupling factor -- IV.4 Dynamic characteristics of piezoelectric transducers operated in their thickness mode -- IV.5 Mechanical and electrical equivalent circuit of a piezoelectric transducer near its resonance -- IV.6 Practical design of piezoelectric ultrasound generators -- V Generation of Ultrasound—Part II -- V.1 Composite piezoelectric transducers -- V.2 Piezoelectric bending transducers -- V.3 Generation of high frequency ultrasound -- V.4 Concentration of ultrasound by focusing -- V.5 Generation of high vibrational amplitudes -- V.6 Generation of shear waves and Rayleigh waves -- V.7 Magnetostrictive generation of ultrasound -- V.8 Electrostatic ultrasound generators -- V.9 Mechanical methods -- VI Detection and Measurement of Ultrasound -- VI.1 Detection of ultrasound with extended piezo transducers, reciprocity -- VI.2 Electrostatic receivers -- VI.3 Ultrasound microphones, calibration -- VI.4 Mechanical detection -- VI.5 Thermal ultrasound detectors -- VI.6 Diffraction of light by ultrasound waves -- VI.7 Visualization of ultrasound -- VII Generation and Detection of Sound with Frequencies above 1 GHz (Hypersound) -- VII.1 Coherent methods for the generation and detection of hypersound -- VII.2 Phonons (sound quanta) in solids -- VII.3 Quantum acoustical interpretation of some effects of ultrasound -- VII.4 Generation of hypersound with heat pulses -- VII.5 Detection of hypersound with superconducting bolometers -- VII.6 Generation and detection of incoherent hypersound with superconducting tunnel contacts -- VII.7 Detection of ‘natural’ hypersound -- VIII Absorption of Ultrasound -- VIII. 1 Classical sound absorption in gases and liquids -- VIII.2 Molecular sound absorption in gases -- VIII.3 Sound absorption in liquids -- VIII.4 Sound absorption in solids -- VIII.5 Experimental methods for the determination of sound velocity and attenuation in the ultrasonic range -- IX Applications in Signal Processing and Measuring Techniques -- IX. 1 Ultrasonic delay lines -- IX.2 Rayleigh wave filters -- IX.3 Light modulation and light deflection -- IX.4 Other small-signal applications -- X Non-destructive Testing of Materials -- X.1 Survey of various testing methods -- X.2 Impulse echo method -- X.3 Frequencies and wave types -- X.4 Transducers for flaw detection -- X.5 Types of display -- X.6 Suitability of materials for testing -- X.7 Practical examples of ultrasonic flaw detection -- XI Application of Ultrasound in Medical Diagnostics -- XI.1 Acoustic properties of biological tissue -- XI.2 Impulse echo method -- XI.3 Typical applications of the impulse echo method in sonography -- XI.4 Doppler sonography -- XII Special Methods of Ultrasonic Imaging -- XII.1 Ultrasonic microscopy -- XII.2 Acoustic holography -- XII.3 Ultrasonic tomography -- XIII Cavitation -- XIII.1 Basic types of sonically induced cavitation -- XIII.2 Dynamics of a single cavity -- XIII.3 Cavitation nuclei and cavitation thresholds -- XIII.4 Real cavitation and some effects caused by it -- XIV Applications of High Intensity Ultrasound -- XIV.1 Ultrasonic cleaning -- XIV.2 Joining with ultrasound -- XIV.3 Machining -- XIV.4 Production of dispersions -- XIV.5 Further applications -- XIV.6 Medical therapy -- XV On the Possibility of Health Risks Caused by Ultrasound -- XV.1 Damage to tissue caused by diagnostic ultrasound -- XV.2 Damage caused by airborne ultrasound -- Notation. |
Record Nr. | UNINA-9910807839003321 |
Kuttruff Heinrich | ||
Dordrecht : , : Springer Netherlands : , : Imprint : Springer, , 1991 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Ultrasonics [[electronic resource] ] : Fundamentals and Applications / / edited by H. Kuttruff |
Edizione | [1st ed. 1991.] |
Pubbl/distr/stampa | Dordrecht : , : Springer Netherlands : , : Imprint : Springer, , 1991 |
Descrizione fisica | 1 online resource (458 p. 20 illus.) |
Disciplina | 534.5/5 |
Soggetto topico |
Materials science
Physics Characterization and Evaluation of Materials Physics, general |
ISBN | 94-011-3846-X |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | I Introduction -- I.1 What is ultrasound? -- I.2 A few historical remarks -- I.3 Ultrasound in the living world -- I.4 Upper frequency limit of sound -- II Basic Concepts of Acoustics -- II.1 Sound fields and the physical quantities describing them -- II.2 Sound propagation in gases and liquids -- II.3 Sound waves in solids -- II.4 Reflection and refraction -- II.5 Doppler effect -- III Sound Radiation and Sound Diffraction -- III.1 Signals in time and frequency representation, linear systems -- III.2 The principle of point source synthesis, the moving piston -- III.3 Radiation from a circular piston -- III.4 Piston with non-uniform surface velocity -- III.5 Diffraction and scattering -- IV Generation of Ultrasound—Part I -- IV.1 The piezoelectric effect -- IV.2 Piezoelectric materials -- IV.3 Basic piezoelectric equations, electro-mechanical coupling factor -- IV.4 Dynamic characteristics of piezoelectric transducers operated in their thickness mode -- IV.5 Mechanical and electrical equivalent circuit of a piezoelectric transducer near its resonance -- IV.6 Practical design of piezoelectric ultrasound generators -- V Generation of Ultrasound—Part II -- V.1 Composite piezoelectric transducers -- V.2 Piezoelectric bending transducers -- V.3 Generation of high frequency ultrasound -- V.4 Concentration of ultrasound by focusing -- V.5 Generation of high vibrational amplitudes -- V.6 Generation of shear waves and Rayleigh waves -- V.7 Magnetostrictive generation of ultrasound -- V.8 Electrostatic ultrasound generators -- V.9 Mechanical methods -- VI Detection and Measurement of Ultrasound -- VI.1 Detection of ultrasound with extended piezo transducers, reciprocity -- VI.2 Electrostatic receivers -- VI.3 Ultrasound microphones, calibration -- VI.4 Mechanical detection -- VI.5 Thermal ultrasound detectors -- VI.6 Diffraction of light by ultrasound waves -- VI.7 Visualization of ultrasound -- VII Generation and Detection of Sound with Frequencies above 1 GHz (Hypersound) -- VII.1 Coherent methods for the generation and detection of hypersound -- VII.2 Phonons (sound quanta) in solids -- VII.3 Quantum acoustical interpretation of some effects of ultrasound -- VII.4 Generation of hypersound with heat pulses -- VII.5 Detection of hypersound with superconducting bolometers -- VII.6 Generation and detection of incoherent hypersound with superconducting tunnel contacts -- VII.7 Detection of ‘natural’ hypersound -- VIII Absorption of Ultrasound -- VIII. 1 Classical sound absorption in gases and liquids -- VIII.2 Molecular sound absorption in gases -- VIII.3 Sound absorption in liquids -- VIII.4 Sound absorption in solids -- VIII.5 Experimental methods for the determination of sound velocity and attenuation in the ultrasonic range -- IX Applications in Signal Processing and Measuring Techniques -- IX. 1 Ultrasonic delay lines -- IX.2 Rayleigh wave filters -- IX.3 Light modulation and light deflection -- IX.4 Other small-signal applications -- X Non-destructive Testing of Materials -- X.1 Survey of various testing methods -- X.2 Impulse echo method -- X.3 Frequencies and wave types -- X.4 Transducers for flaw detection -- X.5 Types of display -- X.6 Suitability of materials for testing -- X.7 Practical examples of ultrasonic flaw detection -- XI Application of Ultrasound in Medical Diagnostics -- XI.1 Acoustic properties of biological tissue -- XI.2 Impulse echo method -- XI.3 Typical applications of the impulse echo method in sonography -- XI.4 Doppler sonography -- XII Special Methods of Ultrasonic Imaging -- XII.1 Ultrasonic microscopy -- XII.2 Acoustic holography -- XII.3 Ultrasonic tomography -- XIII Cavitation -- XIII.1 Basic types of sonically induced cavitation -- XIII.2 Dynamics of a single cavity -- XIII.3 Cavitation nuclei and cavitation thresholds -- XIII.4 Real cavitation and some effects caused by it -- XIV Applications of High Intensity Ultrasound -- XIV.1 Ultrasonic cleaning -- XIV.2 Joining with ultrasound -- XIV.3 Machining -- XIV.4 Production of dispersions -- XIV.5 Further applications -- XIV.6 Medical therapy -- XV On the Possibility of Health Risks Caused by Ultrasound -- XV.1 Damage to tissue caused by diagnostic ultrasound -- XV.2 Damage caused by airborne ultrasound -- Notation. |
Record Nr. | UNINA-9910478860003321 |
Dordrecht : , : Springer Netherlands : , : Imprint : Springer, , 1991 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|