An ultrasound imaging device or an ultrasound imaging probe includes an imaging device including at least one heat generating component and at least one thermal energy storage insert spaced from and disposed in thermal contact with the imaging device, the at least one thermal energy storage insert containing a phase change material (PCM) therein. The thermal energy storage insert is manufactured to closely confirm to a shape of a space defined within the interior of the probe. A method of forming the ultrasound imaging probe includes the steps of manufacturing a thermal energy storage insert from a thermally conductive material, filling the thermal energy storage insert with a phase change material (PCM) and positioning the thermal energy storage insert within an interior of the probe.

An ultrasound diagnostic apparatus in accordance with one aspect of the disclosure includes: a plurality of channels configured to transmit and receive signal with a plurality of transducer elements comprised in a probe; a beamformer configured to perform beamforming a signal received from a preset number of active channel among the plurality of channels; a switch configured to connect the probe and the plurality of channels; and a controller configured to determine a faulty channel among the plurality of channels, compare whether the number of the plurality of channels is greater than or equal to the number of the plurality of transducer elements and control the switch based on the comparison result when the faulty channel is comprised in the active channel.

The present application provides an ultrasound probe comprising a housing that includes a coupling interface having a sinusoidal geometry. The housing is formed by a first body (300) and a second body having opposite and corresponding sinusoidal geometries. The first body includes a first proximal portion (105) and a first distal portion (107). The first proximal portion comprises a first sinusoidal shape (326). The second body includes a second proximal portion and a second distal portion. The second proximal portion comprises an opposite second sinusoidal shape. The first body and the second body are coupled to form a handle having a sinusoidal interface. Further, the first distal portion and the second distal portion form a head portion at which the ultrasound transducer assembly is disposed.

The ultrasonic probe according to a present embodiment includes a piezoelectric vibrator and an acoustic lens. The piezoelectric vibrator is configured to transmit and receive an ultrasonic wave. The acoustic lens is provided on an ultrasonic-wave transmission/reception side. The acoustic lens is formed in such a manner that a surface shape of each of end regions located on both sides of a central region of a surface of the acoustic lens is formed to have a curvature different from a curvature of a surface shape of the central region of the surface of the acoustic lens.

An ultrasound diagnostic apparatus includes: an image generator that generates ultrasound image data based on a reception signal received from an ultrasound probe that sends and receives ultrasound waves; a fastener that attaches the ultrasound probe to a subject and fastens the ultrasound probe on the subject such that a pressure applied to the subject to which the ultrasound probe is attached is adjustable; and a hardware processor. The hardware processor controls driving of the fastener, based on difference information between before fastening the ultrasound probe and during/after fastening the ultrasound probe, the difference information being on at least one of positional information on a position of an observation target of the subject, angle information on an angle of the observation target, and pressure information on a pressure applied to the subject.

The present invention related to an ultrasound imaging system win which the scan head includes a beamformer circuit that performs far field subarray beamforming or includes a sparse array selecting circuit that actuates selected elements. When using a hierarchical two-stage or three-stage beamforming system, three dimensional ultrasound images can be generated in real-time. The invention further relates to flexible printed circuit boards in the probe head. The invention furthermore related to the use of coded or spread spectrum signaling in ultrasound imagining systems. Matched filters based on pulse compression using Golay code pairs improve the signal-to-noise ratio thus enabling third harmonic imaging with suppressed sidelobes. The system is suitable for 3D full volume cardiac imaging.

Within the field of elastography, a new approach analyzes the limiting case of shear waves established as a reverberant field. In this framework, it is assumed that a distribution of shear waves exists, oriented across all directions in 3D (e.g. 2D space+time). The simultaneous multi-frequency application of reverberant shear wave fields can be accomplished by applying an array of external sources that can be excited by multiple frequencies within a bandwidth, for example 50, 100, 150, . . . 500 Hz, all contributing to the shear wave field produced in the liver or other target organ. This enables the analysis of the dispersion of shear wave speed as it increases with frequency, indicating the viscoelastic and lossy nature of the tissue under study. Furthermore, dispersion images can be created and displayed alongside the shear wave speed images. Studies on breast and liver tissues using the multi-frequency reverberant shear wave technique, employing frequencies up to 700 Hz in breast tissue, and robust reverberant patterns of shear waves across the entire liver and kidney in obese patients are reported. Dispersion images are shown to have contrast between tissue types and with quantitative values that align with previous studies.

The present invention relates to an automatic invasive device for body and, more particularly, to an automatic invasive device for body comprising a body press unit capable of pressing a human body part to detect a puncturing position. The present invention also relates to an automatic invasive device for body comprising at least one of a rotatable probe unit, a vacuum tube driving unit, and a body contact material supply unit. The automatic invasive device for body according to the present invention comprises: a syringe needle unit support part that supports a syringe needle that enters the body; and a press unit (500) that presses the body that has a site to be subjected to an invasive procedure.

Aspects of the technology described herein relate to control circuitry configured to turn on and off the ADC driver. In some embodiments, the control circuitry is configured to turn on and off the ADC driver in synchronization with sampling activity of an ADC, in particular based on when an ADC is sampling. The control circuitry may be configured to turn on the ADC driver during the hold phase of the ADC a time period before the track phase and to turn off the ADC driver during the hold phase a time period after the track phase. In some embodiments, the control circuitry is configured to control a duty cycle of the ADC driver turning on and off. In some embodiments, the control circuitry is configured to control a ratio between an off current and an on current in the ADC driver.

Described are systems, devices, and methods useful in the prevention and/or detection of liquid intrusion into ultrasound equipment. Ultrasound transducers and associated ultrasound circuitry, which can be located in an interior of an ultrasound system or device can be adversely affected by exposure to liquids. As described herein, ultrasound systems and devices can comprise a multilayer seal, for example, wherein the multilayer seal comprises one or more layers for preventing liquid intrusion and one or more layers for detection of liquid intrusion (e.g., wherein the one or more layers for detection of liquid intrusion comprise an indicator material capable of changing color when exposed to a liquid).