Structural Health Monitoring with Piezoelectric Wafer Active Sensors

Structural Health Monitoring with Piezoelectric Wafer Active Sensors, Third Edition provides an authoritative theoretical and experimental guide to this fast-paced, interdisciplinary area with exciting applications across a range of industries. It judiciously combines theory, numerical examples, and experiments providing the background needed to fully understand the physical principles involved in performing structural health monitoring (SHM) with piezoelectric wafer active...
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Structural Health Monitoring with Piezoelectric Wafer Active Sensors, Third Edition provides an authoritative theoretical and experimental guide to this fast-paced, interdisciplinary area with exciting applications across a range of industries. It judiciously combines theory, numerical examples, and experiments providing the background needed to fully understand the physical principles involved in performing structural health monitoring (SHM) with piezoelectric wafer active sensor (PWAS) transducers.
The book starts with a detailed yet digestible consolidation of the fundamental theory relating to SHM, covering fracture and failure basics, relevant piezoelectric material properties, vibration modes in different structures, and different wave types, providing the background necessary to understand SHM and apply it to real-world structural challenges. From there the book segues to experimental practice covering several complementary methods of using PWAS transducers for SHM applications, such as propagating guided waves (pitch-catch; pulse-echo; phased-array) and standing guided waves. Numerical examples have been added throughout in support of understanding the underlying theory, and the companion website contains MATLAB code, simulation videos, and other supporting materials. An instructor's manual is available upon request for teachers using the book in the classroom. 
Updates to this 3rd edition include sections covering flexural vibration energy of a beam; bulk wave interaction at interfaces; power and energy of Rayleigh waves; group velocity, power, and energy of shear waves; power and energy of Lamb waves; simplified Helmholtz equations solution through gauge condition manipulation; normal mode expansion solution for Lamb waves tuning; guided wave interaction with damage, hybrid global local method; and determination of wave damage interaction coefficients through local FEM analysis with nonreflective boundaries in the frequency domain.

• In-depth coverage of the underlying theory of piezoelectricity, vibration, and wave propagation alongside experimental techniques fostering a well-rounded understanding of this interdisciplinary topic
• Features step-by-step guidance on the use of piezoelectric wafer active sensors to detect and quantify damage in structures, including clear information on how to interpret sensor signal patterns
• Updates to this edition include real-world numerical and modeling examples in each chapter, and the introduction of new topics and techniques such as flexural vibration energy of a beam, Rayleigh waves, Lamb waves, Helmholtz equations, and the hybrid local field method