A ultrasonic transducer device includes a transducer bottom electrode layer disposed over a substrate, and a plurality of vias that electrically connect the bottom electrode layer with the substrate, wherein substantially an entirety of the plurality of vias are disposed directly below a footprint of a transducer cavity. Alternatively, the transducer bottom electrode layer includes a first metal layer in contact with the plurality of vias and a second metal layer formed on the first metal layer, the first metal layer including a same material as the plurality of vias.

A piezoelectric element includes a piezoelectric body including a piezoelectric material, and a first electrode and a second electrode provided on the piezoelectric body. The piezoelectric body includes a base and a plurality of drivers. The base includes a first main surface and a second main surface opposing each other. The plurality of drivers is arranged on the first main surface in such a way as to be separate from each other. Each of the plurality of drivers includes a third main surface contacting the first main surface and a fourth main surface opposing the third main surface. The base includes a plurality of first regions in which the plurality of drivers is provided and a second region provided between the first regions adjacent to each other. The base is curved.

An acoustic transducer array and method of making same. A first metal layer is deposited on a first side of a piezoelectric composite to form a common electrode and a second metal layer is provided over the obverse side. Portions of the second metal layer are removed to create a plurality of individual electrodes. A third metal layer may be deposited onto the plurality of individual electrodes, the third metal layer being thicker than the second metal layer. The individual electrodes extend beyond the piezoelectric composite in the elevation direction to create electrode leads. Metal layers may be provided by lithography, a wireframe or a foil sheet.

Device for cleaning a support member covered with a liquid Electroacoustic device (10) comprising:—a support member (50),—at least two wave transducers (15a-h) which are acoustically coupled to the support member and each configured to generate an ultrasonic surface wave (Wa-h) which propagates in the support member, the propagation directions (P) of the ultrasonic surface waves generated by the transducers being different;—a control unit (40), the device comprising an analysis unit (35) which is configured to estimate the orientation of the external force (OFe) which is applied to a liquid when the liquid is in contact with the support member and/or the device being configured to receive the estimate of the orientation of the external force, the control unit being configured to control at least one of the transducers, from the estimate of the orientation of the external force, so that the acoustic force which is applied to the liquid and produced by the interaction between the ultrasonic surface wave(s) and the liquid is orientated in a predetermined direction.

An ultrasonic transducer device for use in an acoustic biometric imaging system, the ultrasonic transducer device comprising: a first piezoelectric element having a first face, a second face opposite the first face, and side edges extending between the first face and the second face; a first transducer electrode on the first face of the first piezoelectric element; a second transducer electrode on the second face of the first piezoelectric element; and a spacer structure leaving at least a portion of the first transducer electrode of the first piezoelectric element uncovered.

An imaging assembly for an intraluminal device is provided. In one embodiment, the imaging assembly includes: an array of ultrasound transducer elements spaced apart by air kerfs; a plurality of buffer elements surrounding the array of ultrasound transducer elements, wherein the plurality of buffer elements are spaced apart by gaps; and a sealing material filling portions of the gaps between the plurality of buffer elements

An ultrasound diaphragmography device includes a plurality of piezoelectric ultrasound transducers arranged in at least two linear arrays for placement on a patient's chest along a cranio-caudal axis of the patient. The ultrasound transducers generate and transmit ultrasound waves that penetrate the patient's anatomy and receive returned ultrasound waves. Circuitry in communication with the ultrasound transducers receive the returned ultrasound waves and analyzes the returned ultrasound waves to determine the quality of the patient's lung function in real-time and compare the movement of the left and right hemidiaphragms.

A sonicator assembly, including: a microplate defining a plurality of wells; a manifold for containing a transducer fluid that is thermally coupled to the plurality of wells of the microplate; an ultrasonic generator operable for applying an ultrasonic excitation to the wells of the microplate; one or more of a heating module thermally coupled to and operable for selectively heating the transducer fluid and a cooling module thermally coupled to and operable for selectively cooling the transducer fluid; and a controller operable for controlling operation of the ultrasonic generator and the one or more of the heating module and the cooling module. The controller is further operable for monitoring a temperature and a pressure within the manifold. A temperature of the plurality of wells is controllable over a temperature range from 4° C. to 95° C. Optionally, the plurality of wells include a plurality of heat-resistant round-bottom hydrophilic wells.

A phased array ultrasonic transducer includes a bonding wire structure, a damping material, a plurality of ultrasonic transducers, and a printed circuit board. The bonding wire structure includes a plurality of bonding wire elements. The damping material surrounds the bonding wire structure and is interposed with the plurality of bonding wire elements. The plurality of ultrasonic transducers is arranged in a matrix beneath a membrane, each of the plurality of ultrasonic transducers being coupled to a corresponding bonding wire element of the plurality of bonding wire elements. The printed circuit board includes a plurality of circuits. Each of the plurality of circuits is coupled to a corresponding bonding wire element of the plurality of bonding wire elements.

Some embodiments of the invention relate to an applicator for applying ultrasound energy to a tissue volume, comprising: an array comprising a plurality of ultrasound transducers, the transducers arranged side by side, the transducers configured to emit unfocused ultrasound energy suitable to thermally damage at least a portion of the tissue volume, each of the transducers comprising a coating thin enough so as not to substantially affect heat transfer via the coating to the tissue; and a cooling module configured to apply cooling via the transducers to prevent overheating of a surface of the tissue volume being contacted by the transducers.