A method and ultrasound imaging system includes generating a cine including a plurality of cardiac views based on the cardiac ultrasound data, segmenting a plurality of cardiac chambers from each of the plurality of cardiac images, and automatically determining a cardiac chamber area for each of the plurality of cardiac chambers. The method and ultrasound imaging system includes displaying the cine on a display device and displaying a plurality of single trace curves on the display device at the same time as the cine to provide feedback regarding an acquisition quality of the cine, wherein each of the single trace curves represents the cardiac chamber area for a different one of the plurality of cardiac chambers over the plurality of cardiac cycles.

An interface unit (12) for connecting between an ultrasound sensing apparatus (14) and a patient monitor (18) for providing ultrasound monitoring functionality of one or more physiological or anatomical parameters based on processing of ultrasound data. The interface unit includes means for processing acquired ultrasound data to derive measurements of one or more physiological or anatomical parameters and is configured for outputting said derived measurements to a coupled patient monitor unit, e.g. for display and/or trending by the patient monitor.

The invention provides an ultrasound system comprising an ultrasound probe, adapted to transmit and receive ultrasound signals, and an interventional device for insertion into a vessel of a subject. The interventional device includes an ultrasound transducer adapted to acquire a first set of ultrasound data at a first ultrasound frequency, wherein the first set of ultrasound data relates to flow data. The ultrasound system is further adapted exchange a second set of ultrasound data between the ultrasound probe and the interventional device at a second ultrasound frequency different from the first ultrasound frequency, wherein the second ultrasound data relates to interventional device positioning data.

Provided is an ultrasound imaging device and an operation method thereof. An embodiment of the present disclosure provides an ultrasound imaging device comprising: an ultrasound probe; a display unit; a memory for storing at least one instruction; and a processor for executing the at least one instruction stored in the memory, wherein the processor: image-processes an echo signal to acquire multiple ultrasound images; calculates suitability indicating, as a numerical value, whether the multiple acquired ultrasound images are suitable as input images for a diagnosis algorithm for diagnosing a lesion; displays the calculated suitability on the display unit; and determines an input ultrasound image, which is to be input into the diagnosis algorithm, among the multiple ultrasound images based on the suitability.

A wearable ultrasonic therapeutic device controlled by a mobile electronic device is provided, which includes a mobile device, at least one ultrasonic probe module and a strap. The mobile device has a mobile device control interface for setting ultrasonic parameters and displaying an echo wave through a specific software interface of the mobile device. The ultrasonic probe module includes at least one ultrasonic transducer and a control circuit corresponding thereto. The ultrasonic transducer generates and receives an ultrasonic wave. The control circuit has the functions of generating/receiving signals, phase regulation, power amplification and matching. One end of the ultrasonic probe module is electrically connected to the mobile device and the other end of the ultrasonic probe module is connected to the strap.

There are provided an acoustic wave image generating apparatus for generating a B-mode image having a fixed brightness and a control method thereof. First brightness information (81) indicating the brightness of a first B-mode image in the depth direction of the subject is generated. Positional deviation correction is performed on an acoustic wave echo signal having a positional deviation between the focusing position of acoustic waves and the observation target position, and second brightness information (82) indicating the brightness in the depth direction of the subject is generated from a superposition signal obtained by superimposing an acoustic wave echo signal for which the positional deviation has been corrected and an acoustic wave echo signal without positional deviation. The brightness of the first B-mode image is corrected based on the first brightness information and the second brightness information.

The present invention is directed to a method for health monitoring using one or more sensors comprising first measuring (100) a body composition via one or more sensors. The measured body composition is then classified (102) into one of a plurality of categories. An at least one setting to be used for the health monitoring is adjusted (104) based on the classified body composition. Then, the health monitoring is performed (106) using the adjusted at least one health monitoring setting, wherein at least one of the sensors used to measure the body composition may also be used to perform the health monitoring.

The invention provides an ultrasound processing unit. A controller (18) of the unit is adapted to receive ultrasound data of an anatomical region, for example of the heart. The controller processes the ultrasound data over a period of time to monitor and detect whether alignment of a particular anatomical feature (34) represented in the data relative to a field of view (36) of the transducer unit is changing over time. In the event that the alignment is changing, the controller generates an output signal for communicating this to a user, allowing a user to be alerted at an early stage to likelihood of misalignment and loss of imaging or measurement capability.

A method for ultrasound imaging a target region including: (a) transmitting a tracking beam from at least a subset of the elements of the array to the region, each of the subset of the elements emitting a signal of the tracking beam with a respective transmission time shift; (b) receiving echo signals at at least some of the subset of the elements of the array, each echo signal being responsive to the tracking beam; (c) applying the time shift to at least some of the subset of the respective elements to the echo signals received at corresponding elements; (d) modifying the time shift and repeating (a)-(c) to provide an ultrasound dataset representing a recovered source element domain; (e) focusing and beamforming the dataset to map time signals of the dataset and combine channel signals to provide spatial pixel data; and (f) forming an ultrasound image from the spatial pixel data.

A device and a control program of a device. According to an embodiment, the device includes a display and a processor. The processor is configured to display first and second B-mode images created based on an echo signal of an ultrasonic pulse acquired from a subject on the display. The first and second B-mode images displayed on the display are moving images, and the first and second B-mode images of each frame forming the moving image are created based on the same echo signal. The second B-mode image is displayed smaller than the first B-mode image on the display.