An ultrasound diagnosis apparatus according to an embodiment includes processing circuitry. The processing circuitry is configured to speculate saturation of reflected-wave signals observed before a phased addition process performed by using the reflected-wave signals, in accordance with an intensity of reflected-wave data generated through the phased addition process, the reflected-wave signals being generated by transmitting an ultrasound wave with respect to mutually the same scanning line, and the processing circuitry is configured to output a result of the speculation. The processing circuitry is configured to cause a display to display data based on the result of the speculation.

A transducer fixation apparatus is configured to position and secure to a skin surface of a patient a transducer to allow repeated or continuous monitoring of blood flow in a subsurface vessel. The transducer fixation apparatus includes a housing having a plurality of flexible attachment wings that attach and conform in shape to the skin surface using an adhesive material present on each of the wing undersides. In some embodiments the wings may be biased upward away from the skin surface to facilitate positioning of the fixation apparatus prior to skin attachment. Alternative embodiments include a detachable retainer clip to hold the wings away from the mounting surface during placement as well as an optional positioning wand to aid with placement. Other embodiments may include a separate flexible attachment wing configured to hold a gel pad for acoustic coupling to the skin surface, the separate flexible attachment wing intended to be joined to the housing of the transducer fixation apparatus prior to skin surface attachment.

A multifunctional probe includes a hand-held housing, a signal detector and an array probe. The signal detector is flexibly disposed on the hand-held housing or at its first end. The array probe is disposed at one end (e.g., second end) of the hand-held housing and electrically coupled to the signal detector. The first contact time of the signal detector in contact with the living body may at least partially overlap with the second contact time of the array probe in contact with the living body. The signal detector and the array probe generate the first electronic signal. The multifunctional probe includes a flexibly-connected signal detector and an array probe, which can contact and/or detect the living body at the same time. Thus, the detection efficiency and accuracy are effectively increased. A detection method applied to the multifunctional probe is also provided.

Example implementations can include a method of calibrating orientation of a cerebral sensor and generating feedback from an injector for a cerebral sensor, by scanning an anatomical structure, by a cerebral sensor, proximate to the scan position and satisfying a first threshold, obtaining at least one cranial signal from the cerebral sensor in accordance with a first pathway over the anatomical structure, obtaining from the cranial signal a point corresponding to the anatomical structure, storing the obtained point to a point cache operable to store one or more points, in response to a determination that the point satisfies a second threshold, modifying the first pathway for actuating the cerebral sensor, in response to the determination that the obtained point satisfies the second threshold, selecting an optimized point from the point stack, and actuating the cerebral sensor continuously based on the optimized point.

According to one embodiment, an ultrasonic diagnostic apparatus includes processing circuitry. The processing circuitry extracts an odd harmonic component from a reflected wave signal received by each element of an ultrasonic probe. The processing circuitry determines whether the reflected wave signal is saturated or not using the extracted odd harmonic component. The processing circuitry multiplies the reflected wave signal of an element for which the reflected wave signal is determined to be saturated by a weight coefficient. The processing circuitry generates reflected wave data by performing phasing addition on the reflected wave signal.

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.

A medical image processing apparatus according to an embodiment includes processing circuitry configured to generate an output data set apparently expressing a second data set obtained by transmitting and receiving an ultrasound wave, for each scanning line, as many times as a second number that is larger than a first number, by inputting a first data set to a trained model that generates the output data set on a basis of the first data set obtained by transmitting and receiving an ultrasound wave as many times as the first number for each scanning line.

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.

An ultrasound imaging system for acquiring ultrasound images of an anatomical feature of interest in a subject, comprising a controller operable by a user and configured to: process input ultrasound images to extract anatomical data; determine a set of constraints to be applied to the ultrasound images, the constraints being spatial, temporal and/or of image quality, derived from the extracted anatomical data and/or on user input; monitor the ultrasound images, as they are received, for determining their compliance with the determined constraints; and output an indication based on the determined compliance. The user can adapt the imaging process using the feedback of these indications, and can decide to stop the process based on satisfactory indications.

An imaging device includes a two dimensional array of piezoelectric elements. Each piezoelectric element includes: a piezoelectric layer; a bottom electrode disposed on a bottom side of the piezoelectric layer and configured to receive a transmit signal during a transmit mode and develop an electrical charge during a receive mode; and a first top electrode disposed on a top side of the piezoelectric layer; and a first conductor, wherein the first top electrodes of a portion of the piezoelectric elements in a first column of the two dimensional array are electrically coupled to the first conductor.