The present application pertains to two-dimensional ultrasound transducers and systems, methods of making such transducers and systems, and methods for using such transducers and systems including processing of data acquired with such devices and systems.

In an embodiment, an acoustic transducer includes an element with an acoustic radiative surface having two warped edges at opposing sides. In another embodiment, an acoustic transducer includes first and second elements, each divided into at least two spatially separated portions electrically coupled to each other, the portions configured to interleave. In a further embodiment, an acoustic transducer includes first and second transducer elements. The second element is situated adjacent to the first element and includes a radiative surface with an edge having periodic elongations. In yet another embodiment, an acoustic transducer includes a transducer element with an acoustic radiative surface that has a skewed diamond shape.

The present invention provides a resin composition for an acoustic matching layer which maintains uniform dispersibility of a hollow filler, can suppress bubble trapping, and is excellent in moldability and handleability. The resin composition for an acoustic matching layer, comprises a resin, a hollow filler, and a thixotropy imparting agent, wherein the resin composition has a viscosity measured using a B-type viscometer with rotor No. 4 at a rotation speed of 0.3 rpm at 25? C. of 1130 to 4000 Pa.Math.s, and has a thixotropy index expressed by the ratio (V1/V2) between a viscosity (V1) measured using a B-type viscometer with rotor No. 4 at a rotation speed of 0.3 rpm and a viscosity (V2) measured using a B-type viscometer with rotor No. 4 at a rotation speed of 1.5 rpm, at 50? C., of 3.0 to 5.0.

The present invention provides a resin composition for an acoustic matching layer which maintains uniform dispersibility of a hollow filler, can suppress bubble trapping, and is excellent in moldability and handleability. The resin composition for an acoustic matching layer, comprises a resin, a hollow filler, and a thixotropy imparting agent, wherein the resin composition has a viscosity measured using a B-type viscometer with rotor No. 4 at a rotation speed of 0.3 rpm at 25? C. of 1130 to 4000 Pa.Math.s, and has a thixotropy index expressed by the ratio (V1/V2) between a viscosity (V1) measured using a B-type viscometer with rotor No. 4 at a rotation speed of 0.3 rpm and a viscosity (V2) measured using a B-type viscometer with rotor No. 4 at a rotation speed of 1.5 rpm, at 50? C., of 3.0 to 5.0.

An assembly including: a printed circuit board (PCB) having a first surface and a second surface; at least one energy transmitter mounted on the first surface; at least one cooling element associated with the PCB second surface, wherein the cooling element is configured to cool the at least one energy transmitter via the PCB.

An assembly including: a printed circuit board (PCB) having a first surface and a second surface; at least one energy transmitter mounted on the first surface; at least one cooling element associated with the PCB second surface, wherein the cooling element is configured to cool the at least one energy transmitter via the PCB.

The present invention relates to an ultrasonic cartridge and a head for ultrasound therapy using the same. A cartridge housing, which has an ultrasonic transducer unit therein, stores a liquid, and has an ultrasonic wave transmission window on the lower surface thereof, is divided into an upper housing member provided with the ultrasonic transducer unit and a lower housing member provided with the ultrasonic wave transmission window, and a distance between the ultrasonic transducer unit and the ultrasonic wave transmission window is adjusted, such that the depth of focus of ultrasonic waves in the skin can be controlled. As such, the structure of a product can be significantly simplified, and the manufacturing cost can be considerably reduced.

A sensing structure is presented for use in testing integrated circuits on a substrate. The sensing structure includes a probe region corresponding to a conductive region for connecting to the integrated circuit. A first sensing region at least partially surrounds the probe region. A plurality of sensing elements connects in series such that a first of the plurality of sensing elements has two terminals respectively connected to the first sensing region and the probe region. And a second of the plurality of sensing elements has two terminals respectively connected to the probe region and a first reference potential.

This invention relates to an ore beneficiation process by flotation. In this context, an ore beneficiation system is provided with application of ultrasound to the flotation froth comprising an air-emission ultrasonic transducer positioned above the flotation froth, with the ultrasonic transducer being adapted to emit ultrasonic waves towards the flotation froth. This invention also provides an ore beneficiation process associated with the system described above. Thus, this invention provides a process and system for ore beneficiation with the application of ultrasound to the flotation froth without immersing the ultrasonic transducer into the ore slurry. The current invention can partially remove the liquid film that resides between the air bubbles, thereby enhancing metallurgical recovery rates. Furthermore, it can be employed to effectively counteract the persistence of three-phase froth resulting from flotation, thereby improving the efficiency of processes associated with water and waste management.

This invention relates to an ore beneficiation process by flotation. In this context, an ore beneficiation system is provided with application of ultrasound to the flotation froth comprising an air-emission ultrasonic transducer positioned above the flotation froth, with the ultrasonic transducer being adapted to emit ultrasonic waves towards the flotation froth. This invention also provides an ore beneficiation process associated with the system described above. Thus, this invention provides a process and system for ore beneficiation with the application of ultrasound to the flotation froth without immersing the ultrasonic transducer into the ore slurry. The current invention can partially remove the liquid film that resides between the air bubbles, thereby enhancing metallurgical recovery rates. Furthermore, it can be employed to effectively counteract the persistence of three-phase froth resulting from flotation, thereby improving the efficiency of processes associated with water and waste management.