Provided are an ultrasonic signal processing device that can evaluate reliability of a velocity vector calculated by sub-pixel tracking, an ultrasonic diagnosis apparatus, and an ultrasonic signal arithmetic processing method. The ultrasonic signal processing device includes an echo signal acquisition unit that acquires an echo signal reflected by an object to be inspected, a velocity vector calculation unit that calculates a velocity vector using the echo signal, a post-parallel-movement signal generation unit that generates a post-parallel-movement signal obtained by approximately parallelly moving the echo signal, an image deformation component extraction unit that extracts an image deformation component which is a change component of a signal value due to deformation of an image from a deviation between the post-parallel-movement signal and the echo signal, and an error energy calculation unit that calculates an error energy of the velocity vector from the image deformation component.

An ultrasound apparatus includes a plurality of channels, each including a transmission channel for generating and outputting a transmission signal based on a synchronization signal, a temperature detector for outputting a temperature information signal of the transmission channel, a transducer element for converting the transmission signal output from the transmission channel into an ultrasound signal and outputting the ultrasound signal, a reception channel for receiving a reception signal that returns after the ultrasound signal is transmitted to and reflected from an object, and acquiring ultrasound image data based on the received reception signal, and a switching circuit for connecting the temperature detector to the reception channel such that the reception channel receives the temperature information signal of the transmission channel. The reception channel generates a control signal for closing or opening the switching circuit, and the switching circuit is closed or opened on the generated control signal.

A method and a system for acquiring a 3D ultrasound image. The method includes receiving a request to capture a plurality of ultrasound image for a medical test corresponding to a medical condition. The method further includes determining a body part corresponding to the medical test. Further, the method includes identifying an imaging site particular to the medical test. Furthermore, the method includes providing a navigational guidance to the user in real time for positioning a handheld ultrasound device. Subsequently, the user is assisted to capture the plurality of ultrasound image of the imaging site in real time using deep learning. Further, the plurality of ultrasound images of the imaging site is captured. Finally, the method includes converting the plurality of ultrasound image to a 3-Dimensional (3D) ultrasound image in real time.

A method for positioning one or both of a gate and a color box on an ultrasound image generated during scanning of an anatomical feature using an ultrasound scanner comprises deploying an artificial intelligence (AI) model to execute on a computing device communicably connected to the ultrasound scanner, wherein the AI model is trained so that when the AI model is deployed, the computing device generates a prediction of at least one of an optimal position, size, or angle for the gate and/or an optimal location/size of the color box on the ultrasound image generated during ultrasound scanning of the anatomical feature, thereafter enabling the acquisition of corresponding Doppler mode signals.

Apparatus and methods of use are provided for complex flow imaging and analysis that is non-invasive, accurate, and time-resolved. It is particularly useful in imaging of vascular flow with spatiotemporal fluctuations. This apparatus is an ultrasound-based framework called vector projectile imaging (VPI) that can dynamically render complex flow patterns over an imaging view at millisecond time resolution. The VPI apparatus and methods comprise: (i) high-frame-rate broad-view data acquisition (based on steered plane wave firings); (ii) flow vector estimation derived from multi-angle Doppler analysis (coupled with data regularization and least-squares fitting); and (iii) dynamic visualization of color-encoded vector projectiles (with flow speckles displayed as adjunct).

A processing device includes a controller including hardware. The controller is configured to execute: generating an ultrasound image based on an ultrasound signal acquired by an ultrasound probe, the ultrasound probe being configured to transmit an ultrasonic wave to a subject that is an observation target and receive an ultrasonic wave reflected by the subject; generating shift information including a shift direction of a display area of the ultrasound image displayed on a display unit in accordance with a command position with respect to the ultrasound image; shifting the ultrasound image in accordance with the shift information; and generating a character image indicating an area targeted for a process performed on the ultrasound image in relation to the command position in the ultrasound image after being shifted.

Systems, devices, and methods for automated, fast lung pulse detection are provided. In an embodiment, a system for detecting pneumothorax (PTX) includes an ultrasound probe in communication with a processor. The processor is configured to generate, using the ultrasound imaging data received from the ultrasound probe, an M-mode image including a pleural line of the lung. Using the M-mode image, the processor generates a difference image comprising a plurality of difference lines generated by subtracting adjacent samples of the M-mode image. The processor analyzes the difference image to determine whether the difference image includes a periodic signal corresponding to the heartbeat of the patient and outputs a graphical representation of detecting the lung pulse based on determining that the difference image includes the periodic signal corresponding to the heartbeat.

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.