Diagnostic ultrasound imaging : inside out / / Thomas L. Szabo, Boston University, Boston, MA, USA |
Autore | Szabo Thomas L |
Edizione | [Second edition.] |
Pubbl/distr/stampa | Oxford : , : Academic Press, , 2014 |
Descrizione fisica | 1 online resource (829 p.) |
Disciplina | 829 |
Collana |
MATLAB examples
Biomedical engineering |
Soggetto topico |
Diagnostic ultrasonic imaging
Ultrasonic imaging |
Soggetto genere / forma | Electronic books. |
ISBN | 0-12-396542-X |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; Diagnostic Ultrasound Imaging: Inside Out; Copyright Page; Contents; Preface; Acknowledgments; 1 Introduction; 1.1 Introduction; 1.1.1 Early Beginnings; 1.1.2 Sonar; 1.2 Echo Ranging of the Body; 1.3 Ultrasound Portrait Photographers; 1.4 Ultrasound Cinematographers; 1.5 Modern Ultrasound Imaging Developments; 1.6 Enabling Technologies for Ultrasound Imaging; 1.7 Ultrasound Imaging Safety; 1.8 Ultrasound and Other Diagnostic Imaging Modalities; 1.8.1 Imaging Modalities Compared; 1.8.2 Ultrasound; 1.8.3 Plane X-rays; 1.8.4 Computed Tomography Imaging
1.8.5 Magnetic Resonance ImagingMagnetic Resonance Imaging Applications; 1.8.6 Magnetoencephalography; 1.8.7 Positron Emission Tomography; 1.9 Contrast Agents; 1.9.1 Computed Tomography Agents; 1.9.2 Magnetic Resonance Imaging Agents; 1.9.3 Ultrasound Agents; 1.10 Comparison of Imaging Modalities; 1.10.1 Image Fusion; 1.10.2 Multi-wave and Interactive Imaging; 1.11 Conclusion; References; Bibliography; 2 Overview; 2.1 Introduction; 2.2 Fourier Transform; 2.2.1 Introduction to the Fourier Transform; 2.2.2 Fourier Transform Relationships; 2.3 Building Blocks 2.3.1 Time and Frequency Building Blocks2.3.2 Space Wave Number Building Block; Spatial Transforms; Spatial Transform of a Line Source; Spatial Frequency Building Blocks; 2.4 Central Diagram; References; 3 Acoustic Wave Propagation; 3.1 Introduction to Waves; 3.2 Plane Waves in Liquids and Solids; 3.2.1 Introduction; 3.2.2 Wave Equations for Fluids; 3.2.3 One-dimensional Wave Hitting a Boundary; 3.2.4 ABCD Matrices; 3.2.5 Oblique Waves at a Liquid-Liquid Boundary; 3.3 Elastic Waves in Solids; 3.3.1 Types of Waves; 3.3.2 Equivalent Networks for Waves; 3.3.3 Waves at a Fluid-Solid Boundary 3.4 Elastic Wave Equations3.5 Conclusion; References; Bibliography; 4 Attenuation; 4.1 Losses in Tissues; 4.1.1 Losses in Exponential Terms and in Decibels; 4.1.2 Tissue Data; 4.2 Losses in Both Frequency and Time Domains; 4.2.1 The Material Transfer Function; 4.2.2 The Material Impulse Response Function; 4.3 Tissue Models; 4.3.1 Introduction; 4.3.2 The Time Causal Model; 4.4 Pulses in Lossy Media; 4.4.1 Scaling of the Material Impulse Response Function; 4.4.2 Pulse Propagation: Interactive Effects in Time and Frequency; 4.4.3 Pulse Echo Propagation 4.5 Modified Hooke's Laws and Tissue Models for Viscoelastic Media4.5.1 Voigt Model; 4.5.2 Time Causal Model; 4.5.3 Maxwell Model; 4.5.4 Thermoviscous Relaxation Model; 4.5.5 Multiple Relaxation Model; 4.5.6 Zener Model; 4.5.7 Fractional Zener and Kelvin-Voigt Fractional Derivative Models; 4.6 Wave Equations for Tissues; 4.6.1 Voigt Model Wave Equation; 4.6.2 Time Causal Model Wave Equations; 4.6.3 Time Causal Model Wave Equations in Fractional Calculus Form; 4.7 Discussion; 4.7.1 First Principles; 4.7.2 Power Law Wave Equation Implementations; 4.7.3 Transient Solutions for Power Law Media 4.7.4 Green Functions for Power Law Media |
Record Nr. | UNINA-9910459114503321 |
Szabo Thomas L | ||
Oxford : , : Academic Press, , 2014 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Diagnostic ultrasound imaging : inside out / / Thomas L. Szabo, Boston University, Boston, MA, USA |
Autore | Szabo Thomas L |
Edizione | [Second edition.] |
Pubbl/distr/stampa | Oxford : , : Academic Press, , 2014 |
Descrizione fisica | 1 online resource (xxii, 806 pages) : illustrations (some color) |
Disciplina | 829 |
Collana |
MATLAB examples
Biomedical engineering |
Soggetto topico |
Diagnostic ultrasonic imaging
Ultrasonic imaging |
ISBN | 0-12-396542-X |
Classificazione |
UF 6300
YR 2530 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; Diagnostic Ultrasound Imaging: Inside Out; Copyright Page; Contents; Preface; Acknowledgments; 1 Introduction; 1.1 Introduction; 1.1.1 Early Beginnings; 1.1.2 Sonar; 1.2 Echo Ranging of the Body; 1.3 Ultrasound Portrait Photographers; 1.4 Ultrasound Cinematographers; 1.5 Modern Ultrasound Imaging Developments; 1.6 Enabling Technologies for Ultrasound Imaging; 1.7 Ultrasound Imaging Safety; 1.8 Ultrasound and Other Diagnostic Imaging Modalities; 1.8.1 Imaging Modalities Compared; 1.8.2 Ultrasound; 1.8.3 Plane X-rays; 1.8.4 Computed Tomography Imaging
1.8.5 Magnetic Resonance ImagingMagnetic Resonance Imaging Applications; 1.8.6 Magnetoencephalography; 1.8.7 Positron Emission Tomography; 1.9 Contrast Agents; 1.9.1 Computed Tomography Agents; 1.9.2 Magnetic Resonance Imaging Agents; 1.9.3 Ultrasound Agents; 1.10 Comparison of Imaging Modalities; 1.10.1 Image Fusion; 1.10.2 Multi-wave and Interactive Imaging; 1.11 Conclusion; References; Bibliography; 2 Overview; 2.1 Introduction; 2.2 Fourier Transform; 2.2.1 Introduction to the Fourier Transform; 2.2.2 Fourier Transform Relationships; 2.3 Building Blocks 2.3.1 Time and Frequency Building Blocks2.3.2 Space Wave Number Building Block; Spatial Transforms; Spatial Transform of a Line Source; Spatial Frequency Building Blocks; 2.4 Central Diagram; References; 3 Acoustic Wave Propagation; 3.1 Introduction to Waves; 3.2 Plane Waves in Liquids and Solids; 3.2.1 Introduction; 3.2.2 Wave Equations for Fluids; 3.2.3 One-dimensional Wave Hitting a Boundary; 3.2.4 ABCD Matrices; 3.2.5 Oblique Waves at a Liquid-Liquid Boundary; 3.3 Elastic Waves in Solids; 3.3.1 Types of Waves; 3.3.2 Equivalent Networks for Waves; 3.3.3 Waves at a Fluid-Solid Boundary 3.4 Elastic Wave Equations3.5 Conclusion; References; Bibliography; 4 Attenuation; 4.1 Losses in Tissues; 4.1.1 Losses in Exponential Terms and in Decibels; 4.1.2 Tissue Data; 4.2 Losses in Both Frequency and Time Domains; 4.2.1 The Material Transfer Function; 4.2.2 The Material Impulse Response Function; 4.3 Tissue Models; 4.3.1 Introduction; 4.3.2 The Time Causal Model; 4.4 Pulses in Lossy Media; 4.4.1 Scaling of the Material Impulse Response Function; 4.4.2 Pulse Propagation: Interactive Effects in Time and Frequency; 4.4.3 Pulse Echo Propagation 4.5 Modified Hooke's Laws and Tissue Models for Viscoelastic Media4.5.1 Voigt Model; 4.5.2 Time Causal Model; 4.5.3 Maxwell Model; 4.5.4 Thermoviscous Relaxation Model; 4.5.5 Multiple Relaxation Model; 4.5.6 Zener Model; 4.5.7 Fractional Zener and Kelvin-Voigt Fractional Derivative Models; 4.6 Wave Equations for Tissues; 4.6.1 Voigt Model Wave Equation; 4.6.2 Time Causal Model Wave Equations; 4.6.3 Time Causal Model Wave Equations in Fractional Calculus Form; 4.7 Discussion; 4.7.1 First Principles; 4.7.2 Power Law Wave Equation Implementations; 4.7.3 Transient Solutions for Power Law Media 4.7.4 Green Functions for Power Law Media |
Record Nr. | UNINA-9910792479703321 |
Szabo Thomas L | ||
Oxford : , : Academic Press, , 2014 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Diagnostic ultrasound imaging : inside out / / Thomas L. Szabo, Boston University, Boston, MA, USA |
Autore | Szabo Thomas L |
Edizione | [Second edition.] |
Pubbl/distr/stampa | Oxford : , : Academic Press, , 2014 |
Descrizione fisica | 1 online resource (xxii, 806 pages) : illustrations (some color) |
Disciplina | 829 |
Collana |
MATLAB examples
Biomedical engineering |
Soggetto topico |
Diagnostic ultrasonic imaging
Ultrasonic imaging |
ISBN | 0-12-396542-X |
Classificazione |
UF 6300
YR 2530 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; Diagnostic Ultrasound Imaging: Inside Out; Copyright Page; Contents; Preface; Acknowledgments; 1 Introduction; 1.1 Introduction; 1.1.1 Early Beginnings; 1.1.2 Sonar; 1.2 Echo Ranging of the Body; 1.3 Ultrasound Portrait Photographers; 1.4 Ultrasound Cinematographers; 1.5 Modern Ultrasound Imaging Developments; 1.6 Enabling Technologies for Ultrasound Imaging; 1.7 Ultrasound Imaging Safety; 1.8 Ultrasound and Other Diagnostic Imaging Modalities; 1.8.1 Imaging Modalities Compared; 1.8.2 Ultrasound; 1.8.3 Plane X-rays; 1.8.4 Computed Tomography Imaging
1.8.5 Magnetic Resonance ImagingMagnetic Resonance Imaging Applications; 1.8.6 Magnetoencephalography; 1.8.7 Positron Emission Tomography; 1.9 Contrast Agents; 1.9.1 Computed Tomography Agents; 1.9.2 Magnetic Resonance Imaging Agents; 1.9.3 Ultrasound Agents; 1.10 Comparison of Imaging Modalities; 1.10.1 Image Fusion; 1.10.2 Multi-wave and Interactive Imaging; 1.11 Conclusion; References; Bibliography; 2 Overview; 2.1 Introduction; 2.2 Fourier Transform; 2.2.1 Introduction to the Fourier Transform; 2.2.2 Fourier Transform Relationships; 2.3 Building Blocks 2.3.1 Time and Frequency Building Blocks2.3.2 Space Wave Number Building Block; Spatial Transforms; Spatial Transform of a Line Source; Spatial Frequency Building Blocks; 2.4 Central Diagram; References; 3 Acoustic Wave Propagation; 3.1 Introduction to Waves; 3.2 Plane Waves in Liquids and Solids; 3.2.1 Introduction; 3.2.2 Wave Equations for Fluids; 3.2.3 One-dimensional Wave Hitting a Boundary; 3.2.4 ABCD Matrices; 3.2.5 Oblique Waves at a Liquid-Liquid Boundary; 3.3 Elastic Waves in Solids; 3.3.1 Types of Waves; 3.3.2 Equivalent Networks for Waves; 3.3.3 Waves at a Fluid-Solid Boundary 3.4 Elastic Wave Equations3.5 Conclusion; References; Bibliography; 4 Attenuation; 4.1 Losses in Tissues; 4.1.1 Losses in Exponential Terms and in Decibels; 4.1.2 Tissue Data; 4.2 Losses in Both Frequency and Time Domains; 4.2.1 The Material Transfer Function; 4.2.2 The Material Impulse Response Function; 4.3 Tissue Models; 4.3.1 Introduction; 4.3.2 The Time Causal Model; 4.4 Pulses in Lossy Media; 4.4.1 Scaling of the Material Impulse Response Function; 4.4.2 Pulse Propagation: Interactive Effects in Time and Frequency; 4.4.3 Pulse Echo Propagation 4.5 Modified Hooke's Laws and Tissue Models for Viscoelastic Media4.5.1 Voigt Model; 4.5.2 Time Causal Model; 4.5.3 Maxwell Model; 4.5.4 Thermoviscous Relaxation Model; 4.5.5 Multiple Relaxation Model; 4.5.6 Zener Model; 4.5.7 Fractional Zener and Kelvin-Voigt Fractional Derivative Models; 4.6 Wave Equations for Tissues; 4.6.1 Voigt Model Wave Equation; 4.6.2 Time Causal Model Wave Equations; 4.6.3 Time Causal Model Wave Equations in Fractional Calculus Form; 4.7 Discussion; 4.7.1 First Principles; 4.7.2 Power Law Wave Equation Implementations; 4.7.3 Transient Solutions for Power Law Media 4.7.4 Green Functions for Power Law Media |
Record Nr. | UNINA-9910822846103321 |
Szabo Thomas L | ||
Oxford : , : Academic Press, , 2014 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Diagnostic ultrasound imaging [[electronic resource] ] : inside out / / Thomas L. Szabo |
Autore | Szabo Thomas L |
Pubbl/distr/stampa | Amsterdam ; ; Boston, : Elsevier/Academic Press, c2004 |
Descrizione fisica | 1 online resource (584 p.) |
Disciplina | 616.07543 |
Collana | Biomedical Engineering |
Soggetto topico |
Diagnostic ultrasonic imaging
Ultrasonic imaging |
Soggetto genere / forma | Electronic books. |
ISBN |
1-281-02006-0
9786611020064 1-4175-4443-0 0-08-049113-8 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; DIAGNOSTIC ULTRASOUND IMAGING: INSIDE OUT; Copyright Page; ACKNOWLEDGMENTS; PREFACE; CONTENTS; Chapter 1. INTRODUCTION; 1.1 Introduction; 1.2 Echo Ranging of the Body; 1.3 Ultrasound Portrait Photographers; 1.4 Ultrasound Cinematographers; 1.5 Modern Ultrasound Imaging Developments; 1.6 Enabling Technologies for Ultrasound Imaging; 1.7 Ultrasound Imaging Safety; 1.8 Ultrasound and Other Diagnostic Imaging Modalities; 1.9 Conclusion; Bibliography; References; Chapter 2. OVERVIEW; 2.1 Introduction; 2.2 Fourier Transform; 2.3 Building Blocks; 2.4 Central Diagram; References
Chapter 3. ACOUSTIC WAVE PROPAGATION3.1 Introduction to Waves; 3.2 Plane Waves in Liquids and Solids; 3.3 Elastic Waves in Solids; 3.4 Conclusion; Bibliography; References; Chapter 4. ATTENUATION; 4.1 Losses in Tissues; 4.2 Losses in Both Frequency and Time Domains; 4.3 Tissue Models; 4.4 Pulses in Lossy Media; 4.5 Penetration and Time Gain Compensation; 4.6 Hooke's Law for Viscoelastic Media; 4.7 Wave Equations for Tissues; References; Chapter 5. TRANSDUCERS; 5.1 Introduction to Transducers; 5.2 Resonant Modes of Transducers; 5.3 Equivalent Circuit Transducer Model 5.4 Transducer Design Considerations5.5 Transducer Pulses; 5.6 Equations for Piezoelectric Media; 5.7 Piezoelectric Materials; 5.8 Comparison of Piezoelectric Materials; 5.9 Transducer Advanced Topics; Bibliography; References; Chapter 6. BEAMFORMING; 6.1 What is Diffraction?; 6.2 Fresnel Approximation of Spatial Diffraction Integral; 6.3 Rectangular Aperture; 6.4 Apodization; 6.5 Circular Apertures; 6.6 Focusing; 6.7 Angular Spectrum of Waves; 6.8 Diffraction Loss; 6.9 Limited Diffraction Beams; Bibliography; References; Chapter 7. ARRAY BEAMFORMING; 7.1 Why Arrays? 7.2 Diffraction in the Time Domain7.3 Circular Radiators in the Time Domain; 7.4 Arrays; 7.5 Pulse-Echo Beamforming; 7.6 Two-Dimensional Arrays; 7.7 Baffled; 7.8 General Approaches; 7.9 Nonideal Array Performance; Bibliography; References; Chapter 8. WAVE SCATTERING AND IMAGING; 8.1 Introduction; 8.2 Scattering of Objects; 8.3 Role of Transducer Diffraction and Focusing; 8.4 Role of Imaging; Bibliography; References; Chapter 9. SCATTERING FROM TISSUE AND TISSUE CHARACTERIZATION; 9.1 Introduction; 9.2 Scattering from Tissues; 9.3 Properties of and Propagation in Heterogeneous Tissue 9.4 Array Processing of Scattered Pulse-Echo Signals9.5 Tissue Characterization Methods; 9.6 Applications of Tissue Characterization; 9.7 Elastography; 9.8 Aberration Correction; 9.9 Wave Equations for Tissue; Bibliography; References; Chapter 10. IMAGING SYSTEMS AND APPLICATIONS; 10.1 Introduction; 10.2 Trends in Imaging Systems; 10.3 Major Controls; 10.4 Block Diagram; 10.5 Major Modes; 10.6 Clinical Applications; 10.7 Transducers and Image Formats; 10.8 Front End; 10.9 Scanner; 10.10 Back End; 10.11 Advanced Signal Processing; 10.12 Alternate Imaging System Architectures; Bibliography References |
Record Nr. | UNINA-9910458144503321 |
Szabo Thomas L | ||
Amsterdam ; ; Boston, : Elsevier/Academic Press, c2004 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Diagnostic ultrasound imaging [[electronic resource]] : inside out / / Thomas L. Szabo |
Autore | Szabo Thomas L |
Pubbl/distr/stampa | Amsterdam ; ; Boston, : Elsevier/Academic Press, c2004 |
Descrizione fisica | 1 online resource (584 p.) |
Disciplina | 616.07543 |
Collana | Biomedical Engineering |
Soggetto topico |
Diagnostic ultrasonic imaging
Ultrasonic imaging |
ISBN |
1-281-02006-0
9786611020064 1-4175-4443-0 0-08-049113-8 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; DIAGNOSTIC ULTRASOUND IMAGING: INSIDE OUT; Copyright Page; ACKNOWLEDGMENTS; PREFACE; CONTENTS; Chapter 1. INTRODUCTION; 1.1 Introduction; 1.2 Echo Ranging of the Body; 1.3 Ultrasound Portrait Photographers; 1.4 Ultrasound Cinematographers; 1.5 Modern Ultrasound Imaging Developments; 1.6 Enabling Technologies for Ultrasound Imaging; 1.7 Ultrasound Imaging Safety; 1.8 Ultrasound and Other Diagnostic Imaging Modalities; 1.9 Conclusion; Bibliography; References; Chapter 2. OVERVIEW; 2.1 Introduction; 2.2 Fourier Transform; 2.3 Building Blocks; 2.4 Central Diagram; References
Chapter 3. ACOUSTIC WAVE PROPAGATION3.1 Introduction to Waves; 3.2 Plane Waves in Liquids and Solids; 3.3 Elastic Waves in Solids; 3.4 Conclusion; Bibliography; References; Chapter 4. ATTENUATION; 4.1 Losses in Tissues; 4.2 Losses in Both Frequency and Time Domains; 4.3 Tissue Models; 4.4 Pulses in Lossy Media; 4.5 Penetration and Time Gain Compensation; 4.6 Hooke's Law for Viscoelastic Media; 4.7 Wave Equations for Tissues; References; Chapter 5. TRANSDUCERS; 5.1 Introduction to Transducers; 5.2 Resonant Modes of Transducers; 5.3 Equivalent Circuit Transducer Model 5.4 Transducer Design Considerations5.5 Transducer Pulses; 5.6 Equations for Piezoelectric Media; 5.7 Piezoelectric Materials; 5.8 Comparison of Piezoelectric Materials; 5.9 Transducer Advanced Topics; Bibliography; References; Chapter 6. BEAMFORMING; 6.1 What is Diffraction?; 6.2 Fresnel Approximation of Spatial Diffraction Integral; 6.3 Rectangular Aperture; 6.4 Apodization; 6.5 Circular Apertures; 6.6 Focusing; 6.7 Angular Spectrum of Waves; 6.8 Diffraction Loss; 6.9 Limited Diffraction Beams; Bibliography; References; Chapter 7. ARRAY BEAMFORMING; 7.1 Why Arrays? 7.2 Diffraction in the Time Domain7.3 Circular Radiators in the Time Domain; 7.4 Arrays; 7.5 Pulse-Echo Beamforming; 7.6 Two-Dimensional Arrays; 7.7 Baffled; 7.8 General Approaches; 7.9 Nonideal Array Performance; Bibliography; References; Chapter 8. WAVE SCATTERING AND IMAGING; 8.1 Introduction; 8.2 Scattering of Objects; 8.3 Role of Transducer Diffraction and Focusing; 8.4 Role of Imaging; Bibliography; References; Chapter 9. SCATTERING FROM TISSUE AND TISSUE CHARACTERIZATION; 9.1 Introduction; 9.2 Scattering from Tissues; 9.3 Properties of and Propagation in Heterogeneous Tissue 9.4 Array Processing of Scattered Pulse-Echo Signals9.5 Tissue Characterization Methods; 9.6 Applications of Tissue Characterization; 9.7 Elastography; 9.8 Aberration Correction; 9.9 Wave Equations for Tissue; Bibliography; References; Chapter 10. IMAGING SYSTEMS AND APPLICATIONS; 10.1 Introduction; 10.2 Trends in Imaging Systems; 10.3 Major Controls; 10.4 Block Diagram; 10.5 Major Modes; 10.6 Clinical Applications; 10.7 Transducers and Image Formats; 10.8 Front End; 10.9 Scanner; 10.10 Back End; 10.11 Advanced Signal Processing; 10.12 Alternate Imaging System Architectures; Bibliography References |
Record Nr. | UNINA-9910784563603321 |
Szabo Thomas L | ||
Amsterdam ; ; Boston, : Elsevier/Academic Press, c2004 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Diagnostic ultrasound imaging : inside out / / Thomas L. Szabo |
Autore | Szabo Thomas L |
Edizione | [1st ed.] |
Pubbl/distr/stampa | Amsterdam ; ; Boston, : Elsevier/Academic Press, c2004 |
Descrizione fisica | 1 online resource (584 p.) |
Disciplina | 616.07543 |
Collana | Biomedical Engineering |
Soggetto topico |
Diagnostic ultrasonic imaging
Ultrasonic imaging |
ISBN |
1-281-02006-0
9786611020064 1-4175-4443-0 0-08-049113-8 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; DIAGNOSTIC ULTRASOUND IMAGING: INSIDE OUT; Copyright Page; ACKNOWLEDGMENTS; PREFACE; CONTENTS; Chapter 1. INTRODUCTION; 1.1 Introduction; 1.2 Echo Ranging of the Body; 1.3 Ultrasound Portrait Photographers; 1.4 Ultrasound Cinematographers; 1.5 Modern Ultrasound Imaging Developments; 1.6 Enabling Technologies for Ultrasound Imaging; 1.7 Ultrasound Imaging Safety; 1.8 Ultrasound and Other Diagnostic Imaging Modalities; 1.9 Conclusion; Bibliography; References; Chapter 2. OVERVIEW; 2.1 Introduction; 2.2 Fourier Transform; 2.3 Building Blocks; 2.4 Central Diagram; References
Chapter 3. ACOUSTIC WAVE PROPAGATION3.1 Introduction to Waves; 3.2 Plane Waves in Liquids and Solids; 3.3 Elastic Waves in Solids; 3.4 Conclusion; Bibliography; References; Chapter 4. ATTENUATION; 4.1 Losses in Tissues; 4.2 Losses in Both Frequency and Time Domains; 4.3 Tissue Models; 4.4 Pulses in Lossy Media; 4.5 Penetration and Time Gain Compensation; 4.6 Hooke's Law for Viscoelastic Media; 4.7 Wave Equations for Tissues; References; Chapter 5. TRANSDUCERS; 5.1 Introduction to Transducers; 5.2 Resonant Modes of Transducers; 5.3 Equivalent Circuit Transducer Model 5.4 Transducer Design Considerations5.5 Transducer Pulses; 5.6 Equations for Piezoelectric Media; 5.7 Piezoelectric Materials; 5.8 Comparison of Piezoelectric Materials; 5.9 Transducer Advanced Topics; Bibliography; References; Chapter 6. BEAMFORMING; 6.1 What is Diffraction?; 6.2 Fresnel Approximation of Spatial Diffraction Integral; 6.3 Rectangular Aperture; 6.4 Apodization; 6.5 Circular Apertures; 6.6 Focusing; 6.7 Angular Spectrum of Waves; 6.8 Diffraction Loss; 6.9 Limited Diffraction Beams; Bibliography; References; Chapter 7. ARRAY BEAMFORMING; 7.1 Why Arrays? 7.2 Diffraction in the Time Domain7.3 Circular Radiators in the Time Domain; 7.4 Arrays; 7.5 Pulse-Echo Beamforming; 7.6 Two-Dimensional Arrays; 7.7 Baffled; 7.8 General Approaches; 7.9 Nonideal Array Performance; Bibliography; References; Chapter 8. WAVE SCATTERING AND IMAGING; 8.1 Introduction; 8.2 Scattering of Objects; 8.3 Role of Transducer Diffraction and Focusing; 8.4 Role of Imaging; Bibliography; References; Chapter 9. SCATTERING FROM TISSUE AND TISSUE CHARACTERIZATION; 9.1 Introduction; 9.2 Scattering from Tissues; 9.3 Properties of and Propagation in Heterogeneous Tissue 9.4 Array Processing of Scattered Pulse-Echo Signals9.5 Tissue Characterization Methods; 9.6 Applications of Tissue Characterization; 9.7 Elastography; 9.8 Aberration Correction; 9.9 Wave Equations for Tissue; Bibliography; References; Chapter 10. IMAGING SYSTEMS AND APPLICATIONS; 10.1 Introduction; 10.2 Trends in Imaging Systems; 10.3 Major Controls; 10.4 Block Diagram; 10.5 Major Modes; 10.6 Clinical Applications; 10.7 Transducers and Image Formats; 10.8 Front End; 10.9 Scanner; 10.10 Back End; 10.11 Advanced Signal Processing; 10.12 Alternate Imaging System Architectures; Bibliography References |
Record Nr. | UNINA-9910810985903321 |
Szabo Thomas L | ||
Amsterdam ; ; Boston, : Elsevier/Academic Press, c2004 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|