An intraluminal imaging device is provided. In one embodiment, the imaging device includes a flexible elongate member having a distal portion and a proximal portion. The flexible elongate member can be positioned within a vessel. The imaging device an imaging assembly that can be mounted within the distal portion. The imaging assembly includes a side-looking array of imaging elements and a micro-beamformer IC that is coupled to the side-looking array of imaging elements. The micro-beamformer IC can control the array of imaging elements, can determine a first angle and a second angle, and can perform beam forming for the array of imaging elements. The micro-beamformer IC can receive the first imaging signals associated with a first plane (410) at the first angle (+45°), and the second imaging signals associated with a second plane (420) at the second angle(−45°). In some embodiments, the first and second angles are selected to satisfy predetermined criteria.

The present invention relates to a device for displaying image information, the device comprising: a detection unit (10), which is configured to identify a plurality of admissible display orientations of multiple data sets; a restriction unit (20), which is configured to restrict the plurality of admissible display orientations of at least one of the multiple data sets to a set of admissible display orientations in common for all the multiple data sets; and/or to restrict a plurality of admissible scrolling directions of at least one of the multiple data sets to a set of admissible scrolling directions that are normal to the restricted admissible display orientations; and a display unit (30), which is configured to display the multiple data sets using the set of the restricted display orientations and/or the set of restricted scrolling directions.

Disclosed herein are an ultrasonic imaging apparatus of successively displaying a plurality of slice images of an object at predetermined frame rate, and a control method of the ultrasonic imaging apparatus. According to an embodiment of the ultrasonic imaging apparatus, the ultrasonic imaging apparatus may include: an image processor configured to extract a target in an object based on volume data of the object; a controller configured to determine a region of interest in the object, based on the extracted target; and a display unit configured to successively display a plurality of slice images of the object, including the region of interest.

An ultrasound apparatus includes a touch screen configured to display, on an ultrasound image, a touch recognition region of an object used as a measurement mark; and a controller configured to move the object and the touch recognition region, in response to an input for touching and dragging the touch recognition region, to detect, from a portion of the ultrasound image which corresponds to the touch recognition region, a line formed by connecting points at which a brightness variation of a pixel is greater than a threshold value, and to move the object to a position of the detected line by using coordinates of the detected line.

An ultrasound imaging system includes a processor programmed to generate an anatomy image and a number of needle frames at different transmit beam angles. The system analyzes the data in the needle frames and selects segments therein that are identified as likely representing an interventional instrument. Data from one or more needle frames are blended with the data for the anatomy image of the tissue to create a composite image of the tissue and the interventional instrument.

An analyzing apparatus according to an embodiment includes processing circuitry. The processing circuitry is configured to detect a shear wave propagating in an object. The processing circuitry is configured to calculate an index value that indicates viscosity within the object and that is not dependent on any physical model related to viscoelasticity, by analyzing the detected shear wave.

The ultrasound imaging apparatus provided to quantify the degree of flash artifacts based on an ultrasound echo signal, and to notify a user of an image section with a severe flash artifact includes: a probe configured to irradiate an ultrasound signal to an object and receive an ultrasound echo signal reflected from the object; an image processor configured to obtain a color Doppler signal from which the clutter signal is removed by filtering the ultrasound echo signal, obtain a plurality of consecutive Doppler image frames based on the color Doppler signal and generate a Doppler image based on the plurality of Doppler image frames; a display configured to output the Doppler image; and a controller configured to calculate a flash artifact score of each of the plurality of Doppler image frames based on the ultrasound echo signal, generate a time line corresponding to the plurality of Doppler image frames and control the display so that flash artifact scores of each of the plurality of Doppler image frames appear on the timeline.

Provided are an ultrasound imaging apparatus and a control method thereof, the ultrasound imaging apparatus including: an input/output interface; a storage; and at least one processor configured to: display, via the input/output interface, at least one resulting value calculated based on a plurality of medical images; when one of the at least one resulting value is selected by an input via the input/output interface, retrieve, from the storage, a plurality of measurement values and a plurality of medical images used to calculate the selected resulting value; and output, via the input/output interface, the retrieved plurality of measurement values and the retrieved plurality of medical images on a single display.

A system and method for simultaneously presenting Doppler signals of a Multi-Gated Doppler (MGD) signal corresponding to different anatomical structures is provided. The method includes receiving an MGD signal having a plurality of Doppler signals. The method includes analyzing the MGD signal to select multiple gates, each of the gates corresponding with a Doppler signal, and each of the selected gates associated with a different anatomical structure. The method includes selecting a set of parameters for each of the selected gates and applying each selected set of parameters for each of the selected gates. The selected set of parameters for each of the selected gates may be one or both of image acquisition parameters or display processing parameters. The method includes simultaneously presenting the Doppler signal for each of the selected gates at a display system after the each selected set of parameters is applied.

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.