Piezoelectric Transducers

Materials, Devices and Applications

Edited by
August 2020
524 pages
  • ISBN978-3-03936-856-3 (Hardback)
  • ISBN978-3-03936-857-0 (PDF)

This book is a reprint of the Special Issue Piezoelectric Transducers: Materials, Devices and Applications that was published in

Chemistry & Materials Science
Physical Sciences
Advances in miniaturization of sensors, actuators, and smart systems are receiving substantial industrial attention, and a wide variety of transducers are commercially available or with high potential to impact emerging markets. Substituting existing products based on bulk materials, in fields such as automotive, environment, food, robotics, medicine, biotechnology, communications, and other technologies, with reduced size, lower cost, and higher performance, is now possible, with potential for manufacturing using advanced silicon integrated circuits technology or alternative additive techniques from the mili- to the nano-scale. In this Special Issue, which is focused on piezoelectric transducers, a wide range of topics are covered, including the design, fabrication, characterization, packaging, and system integration or final applications of mili/micro/nano-electro-mechanical systems based transducers.
  • Hardback
© 2020 by the authors; CC BY-NC-ND license
cylindrical composite; piezoceramic/epoxy composite; electromechanical characteristics; transducer; piezoelectric actuators; positioning; trajectory control; numerical analysis; trajectory planning; square piezoelectric vibrator; resonance; piezoelectric diaphragm pump; flexible support; piezoelectric resonance pump; piezoelectric ceramics actuators; hysteresis modeling; Bouc–Wen model; P-type IL; MFA control; SM control; evidence theory; active vibration control; piezoelectric smart structure; piezoelectric material; multiphysics simulation; finite element method (FEM); fluid–structure interaction (FSI); micro electromechanical systems (MEMS); traveling waves; piezoelectric; microactuator; MEMS; piezoelectric current sensing device; two-wire power cord; cymbal structure; force amplification effect; sensitivity; ciliary bodies touch beam; piezoelectric tactile feedback devices; anisotropic vibration tactile model; human factor experiment; nondestructive testing; maturity method; concrete early-age strength; SmartRock; ultrasonic waves; PZT (piezoelectric) sensors; structural health monitoring; MEMS; AlN thin film; piezoelectric effect; resonant accelerometer; z-axis; debonding; non-destructive testing; piezoelectric; electromechanical impedance; damage detection; impedance-based technique; damage depth; MEMS; piezoelectric vibration energy harvester; frequency up-conversion mechanism; impact; PZT thick film; piezoelectric ceramic materials; Duhem model; hysteresis model; class-C power amplifier; diode expander; piezoelectric transducers; point-of-care ultrasound systems; transverse impact; frequency up-conversion; piezoelectric bimorph; human-limb motion; hybrid energy harvester; cascade-connected transducer; low frequency; small size; finite element; acoustic telemetry; measurement while drilling; energy harvesting; piezoelectric; pipelines; underwater networks; wireless sensor networks; control algorithm; waterproof; coating; reliability; flexible micro-devices; piezoelectric transducers; aqueous environments; seawater; capacitive pressure sensors; in-situ pressure sensing; sensor characterization; physiological applications; cardiac output; MEMS; aluminum nitride; resonator; damping; quality factor; electromechanical coupling; implantable middle ear hearing device; piezoelectric transducer; stimulating site; finite element analysis; hearing compensation; adaptive lens; piezoelectric devices; fluid-structure interaction; moving mesh; thermal expansion; COMSOL; petroleum acoustical-logging; piezoelectric cylindrical-shell transducer; center-frequency; experimental-measurement; piezoelectricity; visual servo control; stepping motor; nano-positioner; stick-slip; piezoelectric energy harvester; cut-in wind speed; cut-out wind speed; energy conservation method; critical stress method; piezoelectric actuator; lever mechanism; analytical model; stick-slip frication; nanopositioning stage; piezoelectric hysteresis; mark point recognition; piecewise fitting; compensation control; piezo-electromagnetic coupling; up-conversion; vibration energy harvester; multi-directional vibration; low frequency vibration; piezoelectric actuator; hysteresis compensation; single-neuron adaptive control; Hebb learning rules; supervised learning; piezoelectricity; vibration-based energy harvesting; multimodal structures; frequency tuning; nonlinear resonator; bistability; magnetostatic force; robot; piezoelectric; miniature; traveling wave; leg; piezoelectric actuators (PEAs); asymmetric hysteresis; Prandtl–Ishlinskii (PI) model; polynomial-modified PI (PMPI) model; feedforward hysteresis compensation; PIN-PMN-PT; 1-3 composite; high frequency; phased array; n/a