Disclosed herein is a transparent ultrasonic sensor including a matching unit configured to perform optical impedance matching and formed of a transparent material, a piezoelectric layer positioned behind the matching unit and formed of a transparent material, a first electrode layer and a second electrode layer positioned on a rear surface and a front surface of the piezoelectric layer, respectively, the first electrode layer and the second electrode layer being formed of a transparent conductive material, a first housing connected to the first electrode layer, and a second housing connected to the second electrode layer.

A resin composition for an acoustic matching layer; an acoustic matching sheet formed from the composition; an acoustic wave probe; an acoustic wave measuring apparatus; a method for manufacturing an acoustic wave probe; and a material set, for an acoustic matching layer, that is suitable for preparation of the composition, in which the resin composition for an acoustic matching layer includes a binder including a resin; and metal particles having a monodispersity of 40% to 80%, wherein the monodispersity is calculated by equation (1):
monodispersity (%)=(standard deviation of particle sizes of metal particles/average particle size of metal particles)×100.

The present disclosure provides an ultrasonic transceiver capable of stably measuring a fluid of high temperature and high humidity for a long period, and provides an ultrasonic flowmeter, an ultrasonic flow velocimeter, and an ultrasonic densitometer each including the ultrasonic transceiver. An ultrasonic transceiver (1) comprises a piezoelectric body (3) and an acoustic matching body (2) disposed in one face of the piezoelectric body (3), wherein the acoustic matching body (2) includes: a top plate, a bottom plate, and a side wall that define a closed space; and a perpendicular partition wall formed substantially perpendicular to the bottom plate and adhering to the top plate and the bottom plate, thereby dividing a closed space.

A method of fabricating a transducer includes embedding signal flexes and ground-return flexes inside a backing block. The method includes forming stack configurations with a height in elevation and a width perpendicular to the height. The forming includes: dicing a piezoelectric layer in the elevation into rows (separating the piezoelectric layer into portions); defining a beam pattern for the transducer by aligning the portions on the backing block; and forming gaps in-between each piezoelectric layer portion and each adjacently aligned piezoelectric layer portion. The method includes forming stacks by bonding one or more matching layers to the piezoelectric layer portions by utilizing a conductive surface of a first matching layer of the one or more matching layers. The method also includes forming cavities in the one or more matching layers in elevation, dicing the stacks along an elevation direction into multiple elements, and filling the cavities with a material.

Disclosed herein are acoustic transmission systems comprising an acoustic wave generator configured to generate an acoustic wave and propagate the acoustic wave through a tissue of a specimen, and a non-Hermitian complementary metamaterial (NHCMM) configured to add a first amount of energy amplification coherently to the acoustic wave to account for energy loss in the acoustic wave as a result of the wave propagating through the tissue of the specimen. The acoustic wave generator can be an ultrasound generator, and the tissue can be a cranium.

A method and apparatus are disclosed herein for a thermally conductive layer for transducer face temperature reduction in an ultrasound transducer assembly. In one embodiment, the ultrasound transducer assembly comprises: a transducer layer configured to emit ultrasound energy; one or more matching layers overlaying the transducer layer; a thermally conductive layer overlaying the one or more matching layers; and a lens overlaying the thermally conductive layer.

A method for producing a composite piezoelectric body includes: forming a composite piezoelectric body by filling a non-conductive polymer between a plurality of piezoelectric materials arranged in an array state at predetermined intervals, and polishing one surface of the composite piezoelectric body, from which surface at least the piezoelectric materials and the polymer are exposed, by using an abrasive film in which an abrasive particle is applied to a base film.

A sensor includes a substrate having a curved surface, a piezoelectric element, and an adhesive disposed between the piezoelectric element and the curved surface along a vertical direction. The adhesive attaches the piezoelectric element to the substrate. The adhesive has an exterior bond surface that has a tapered shape along the vertical direction from the piezoelectric element to the curved surface.

An ultrasonic transducer, including a piezoelectric element with physical characteristics of radial resonant frequencies and thickness resonant frequencies, and with an upper surface and a lower surface opposite to each other through the piezoelectric element and a lateral surface connecting the upper surface and the lower surface, and an acoustic matching layer set on the upper surface of the piezoelectric element and having a first resonant matching part and a second resonant matching part, wherein a thickness of the first resonant matching part in a direction perpendicular to the upper surface is greater than a thickness of the second resonant matching part in the direction, and the thickness of the first resonant matching part matches one radial resonant frequency of the piezoelectric element and the thickness of the second resonant matching part matches another radial resonant frequency or one of the thickness resonant frequency of the piezoelectric element.

The present disclosure relates to an ultrasound transducer and a control method thereof. More particularly, the present disclosure is related to an ultrasound transducer for facilitating waste clearance of the brain lymphatic system and a control method thereof. A transducer according to the present disclosure includes: an oscillator including a plurality of Piezoelectric materials, and a polymer encompassing the plurality of Piezoelectric materials, and irradiating an ultrasound using at least one of the plurality of Piezoelectric materials and the polymer; a lens having a first space where at least a part of the oscillator is inserted, and focuses the applied ultrasound; and a housing supporting connection between the oscillator and the lens, wherein a height of the oscillator is longer than a height of the first space, a first height difference between the height of the oscillator and the height of the first space is inverse proportion to overall height of the lens, and a width of the oscillator is smaller than a width of the first space.