Piezoelectric Transducers  Materials, Devices and Applications 

<br/><br/><br/>English[eng] 
<br/><br/><label>Subjects--Topical Terms: </label><br/>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||AlN thin film||piezoelectric effect||resonant accelerometer||z-axis||debonding||non-destructive testing||electromechanical impedance||damage detection||impedance-based technique||damage depth||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||pipelines||underwater networks||wireless sensor networks||control algorithm||waterproof||coating||reliability||flexible micro-devices||aqueous environments||seawater||capacitive pressure sensors||in-situ pressure sensing||sensor characterization||physiological applications||cardiac output||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||hysteresis compensation||single-neuron adaptive control||Hebb learning rules||supervised learning||vibration-based energy harvesting||multimodal structures||frequency tuning||nonlinear resonator||bistability||magnetostatic force||robot||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