Ultrasonic Guided Waves in Solid Media

Ultrasonic guided waves in solid media have become a critically important subject in nondestructive testing and structural health monitoring, as new faster, more sensitive, and more economical ways of looking at materials and structures have become possible. This book will lead to fresh creative ideas for use in new inspection procedures. Although the mathematics is sometimes sophisticated, the book can also be read by managers without detailed understanding of the concepts as it can be read from a 'black box' point of view. Overall, the material presented on wave mechanics - in particular, guided wave mechanics - establishes a framework for the creative data collection and signal processing needed to solve many problems using ultrasonic nondestructive evaluation and structural health monitoring. The book can be used as a reference in ultrasonic nondestructive evaluation by professionals and as a textbook for seniors and graduate students. This work extends the coverage of Rose's earlier book Ultrasonic Waves in Solid Media.

Preface; Acknowledgments; 1. Introduction; 2. Dispersion principles; 3. Unbounded isotropic and anisotropic media; 4. Reflection and refraction; 5. Oblique incidence; 6. Waves in plates; 7. Surface and subsurface waves; 8. Finite element method for guided wave mechanics; 9. The semi-analytical finite element method (SAFE); 10. Guided waves in hollow cylinders; 11. Circumferential guided waves; 12. Guided waves in layered structures; 13. Source influence on guided wave excitation; 14. Horizontal shear; 15. Guided waves in anisotropic media; 16. Guided wave phased arrays in piping; 17. Guided waves in viscoelastic media; 18. Ultrasonic vibrations; 19. Guided wave array transducers; 20. Introduction to guided wave nonlinear methods; 21. Guided wave imaging methods; Appendix A: ultrasonic nondestructive testing principles, analysis and display technology; Appendix B: basic formulas and concepts in the theory of elasticity; Appendix C: physically based signal processing concepts for guided waves; Appendix D: guided wave mode and frequency selection tips.

Dr Joseph L. Rose is the Paul Morrow Professor in the Engineering Science and Mechanics Department at Pennsylvania State University. He is also Chief Scientist and President of FBS, Inc., a company dedicated to technology transfer, product development, and consulting on ultrasonic guided waves in nondestructive evaluation and structural health monitoring. He received his PhD from Drexel University in 1970. He is the author of twenty patents, four textbooks, and more than 600 scholarly articles, most focused on ultrasonics. He has served as principal adviser to more than 60 PhD and 150 MS students, and is a fellow of ASNT, ASME, IEEE, and the British Society for Nondestructive Testing. Dr Rose has also received many awards, including the SPIE Lifetime Achievement Award in recognition of sustained contributions to the advancement of nondestructive evaluation and structural health monitoring in 2011, the Penn State University Graduate Teaching Award in 2012, and the distinction of being a finalist in the Discover magazine award for innovation in aviation and aerospace in 1995.