| Titre : | Biomedical Engineering Principles | | Type de document : | texte imprimé | | Auteurs : | Arthur B. Ritter, Auteur ; Vikki Hazelwood, Auteur ; Antonio Valdevit, Auteur | | Mention d'édition : | 1er + 2 ème ed. | | Editeur : | Boca Raton : CRC Press/Taylor | | Année de publication : | 2005 | | Importance : | 516 p. | | Présentation : | couv. ill. en coul., ill. | | Format : | 23,5 cm. | | ISBN/ISSN/EAN : | 978-1-439-81232-7 | | Langues : | Anglais (eng) | | Index. décimale : | 35-01 Génie biomédical général | | Résumé : | Current demand in biomedical sciences emphasizes the understanding of basic mechanisms and problem solving rather than rigid empiricism and factual recall. Knowledge of the basic laws of mass and momentum transport as well as model development and validation, biomedical signal processing, biomechanics, and capstone design have indispensable roles in the engineering analysis of physiological processes. To this end, an introductory, multidisciplinary text is a must to provide the necessary foundation for beginning biomedical students.
Assuming no more than a passing acquaintance with molecular biology, physiology, biochemistry, and signal processing, Biomedical Engineering Principles, Second Edition provides just such a solid, accessible grounding to this rapidly advancing field. Acknowledging the vast range of backgrounds and prior education from which the biomedical field draws, the organization of this book lends itself to a tailored course specific to the experience and interests of the student.
Divided into four sections, the book begins with systems physiology, transport processes, cell physiology, and the cardiovascular system. Part I covers systems analysis, biological data, and modeling and simulation in experimental design, applying concepts of diffusion, and facilitated and active transport. Part II presents biomedical signal processing, reviewing frequency, periodic functions, and Fourier series as well as signal acquisition and processing techniques.
Part III presents the practical applications of biomechanics, focusing on the mechanical and structural properties of bone, musculoskeletal, and connective tissue with respect to joint range, load bearing capacity, and electrical stimulation. The final part highlights capstone design, discussing design perspectives for living and nonliving systems, the role of the FDA, and the project timeline from inception to proof of concept.
Cutting across many disciplines, Biomedical Engineering Principles, Second Edition offers illustrative examples as well as problems and discussion questions designed specifically for this book to provide a readily accessible, widely applicable introductory text. | | Note de contenu : | Contents
Part 1 Systems Physiology, Transport Processes, Cell Physiology, and the cardiovascular system
1. a system approach to Physiology
2. Modeling of physiological processes
3. Cell Physiology and Transport
4. Principles and Biomedical Applications of Hemodynamics
5. The Cardiovascular System
Part 2 Signal Processing
6. Biomedical Signals Processing
7. Fourier Series
8. DSP System Level Concepts and Digital Filter Implementations
9. Techniques for Physiological Signal Processing
Part 3 Biomechanics
10. Biomechanics: Bone
11. Structure and Function of Musculoskeletal Tissues, Connective tissue, and Spine
Part IV Capstone Design
12 Biomedical Engineering and Design
13 A Capstone Design Curriculum for Biomedical Engineers
Appendix A: Selected Reference Values
Appendix B: The Continuity Equation and the Equations of Motion in several coordinate systems
Appendix C: Frequency Components of Pressure Wave
Index |
Biomedical Engineering Principles [texte imprimé] / Arthur B. Ritter, Auteur ; Vikki Hazelwood, Auteur ; Antonio Valdevit, Auteur . - 1er + 2 ème ed. . - Boca Raton : CRC Press/Taylor, 2005 . - 516 p. : couv. ill. en coul., ill. ; 23,5 cm. ISBN : 978-1-439-81232-7 Langues : Anglais ( eng) | Index. décimale : | 35-01 Génie biomédical général | | Résumé : | Current demand in biomedical sciences emphasizes the understanding of basic mechanisms and problem solving rather than rigid empiricism and factual recall. Knowledge of the basic laws of mass and momentum transport as well as model development and validation, biomedical signal processing, biomechanics, and capstone design have indispensable roles in the engineering analysis of physiological processes. To this end, an introductory, multidisciplinary text is a must to provide the necessary foundation for beginning biomedical students.
Assuming no more than a passing acquaintance with molecular biology, physiology, biochemistry, and signal processing, Biomedical Engineering Principles, Second Edition provides just such a solid, accessible grounding to this rapidly advancing field. Acknowledging the vast range of backgrounds and prior education from which the biomedical field draws, the organization of this book lends itself to a tailored course specific to the experience and interests of the student.
Divided into four sections, the book begins with systems physiology, transport processes, cell physiology, and the cardiovascular system. Part I covers systems analysis, biological data, and modeling and simulation in experimental design, applying concepts of diffusion, and facilitated and active transport. Part II presents biomedical signal processing, reviewing frequency, periodic functions, and Fourier series as well as signal acquisition and processing techniques.
Part III presents the practical applications of biomechanics, focusing on the mechanical and structural properties of bone, musculoskeletal, and connective tissue with respect to joint range, load bearing capacity, and electrical stimulation. The final part highlights capstone design, discussing design perspectives for living and nonliving systems, the role of the FDA, and the project timeline from inception to proof of concept.
Cutting across many disciplines, Biomedical Engineering Principles, Second Edition offers illustrative examples as well as problems and discussion questions designed specifically for this book to provide a readily accessible, widely applicable introductory text. | | Note de contenu : | Contents
Part 1 Systems Physiology, Transport Processes, Cell Physiology, and the cardiovascular system
1. a system approach to Physiology
2. Modeling of physiological processes
3. Cell Physiology and Transport
4. Principles and Biomedical Applications of Hemodynamics
5. The Cardiovascular System
Part 2 Signal Processing
6. Biomedical Signals Processing
7. Fourier Series
8. DSP System Level Concepts and Digital Filter Implementations
9. Techniques for Physiological Signal Processing
Part 3 Biomechanics
10. Biomechanics: Bone
11. Structure and Function of Musculoskeletal Tissues, Connective tissue, and Spine
Part IV Capstone Design
12 Biomedical Engineering and Design
13 A Capstone Design Curriculum for Biomedical Engineers
Appendix A: Selected Reference Values
Appendix B: The Continuity Equation and the Equations of Motion in several coordinate systems
Appendix C: Frequency Components of Pressure Wave
Index |
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