A method includes continuously transmitting, with a transducer array, an ultrasound signal in one direction. The method further includes beamforming, with a beamformer, an echo signal received by the transducer array using on a predetermined apodization function. The echo signal is generated in response to an interaction of the ultrasound signal with flowing structure. The method further includes estimating, with a velocity processor, a vector velocity of the flow, including velocity components, as a function of depth and time from the beamformed echo signals using transverse oscillation vector velocity estimation. The method further includes generating, with a measurement processor, a quantitative measurement from the velocity components. The method further includes visually displaying, with a display monitor, the quantitative measurement.

Disclosed are a method and a device for elasticity detection. The method comprises: controlling an excitation device (2) to periodically excite N shear waves in a tissue at a preset time interval and controlling an ultrasonic transducer (3) to transmit ultrasonic waves (101) to the tissue, where the excitation device and the ultrasonic transducer are maintained in contact with a surface of the tissue; receiving, by the ultrasonic transducer (3), an ultrasonic echo signal (102) corresponding to each of the shear waves; acquiring a propagation characteristic parameter (103) of each of the shear waves according to the ultrasonic echo signal corresponding to each of the shear waves; calculating an elasticity parameter of the tissue (104) according to propagation characteristic parameters of the N shear waves and a tissue density of the tissue.

Systems and methods are disclosed that facilitate obtaining two dimensional (2D) ultrasound images, using two or more ultrasound imaging modes or modalities, to generate 2D multi-parametric ultrasound (mpUS) images and/or to generate a three-dimensional (3D) mpUS image. The different ultrasound imaging modes acquire images in a common frame of reference during a single procedure to facilitate their registration. The mpUS images (i.e., 2D or 3D) may be used for enhanced detection of suspicious regions.

According to the present invention, a displacement measurement unit measures, on the basis of a reception signal corresponding to a tracking wave reception beam obtained from a reception unit, the displacement of a tissue inside a subject after the generation of a shear wave. A fluctuation detection unit detects periodic displacement on the basis of the displacement measurement result obtained from the displacement measurement unit. A shear wave speed calculation unit calculates the propagation speed of a shear wave in the subject on the basis of the measurement result obtained from the displacement measurement unit and the detection result obtained from the fluctuation detection unit.

Shear wave propagation is used to estimate the speed of sound in a patient. An ultrasound scanner detects a time of occurrence of a shear wave at each of multiple locations. The difference in time of occurrence, given tissue stiffness or shear velocity, is used to estimate the speed of sound for the specific tissue of the patient.

A method for detecting biological signs based on an ultrasonic detection system includes: sending, by a second processing module, a detection instruction to a master processing module in a first processing module; generating, by the master processing module, a first synchronization signal based on the detection instruction, and sending the first synchronization signal to a synchronous distribution module, so as to make the synchronous distribution module send the first synchronization signal to the master processing module and a slave processing module in the first processing module, and enable the slave processing module and the master processing module to control array elements to which they are respectively connected to transmit an ultrasonic wave simultaneously based on the first synchronization signal and collect an echo signal; and processing, by the second processing module, the echo signal collected by each array element to obtain information about the biological signs of an organism.

A probe for transient elastography includes a probe casing, at least one ultrasound transducer having a symmetry axis, a vibrator located inside the probe casing, a position sensor coupled to the probe casing, the position sensor being arranged to measure the displacement of the probe, wherein the vibrator is arranged to induce a movement of the probe casing along a predefined axis, the predefined axis being the symmetry axis of the ultrasound transducer. The ultrasound transducer is bound to the probe casing with no motion of the ultrasound transducer with respect to the probe casing, and the probe includes a feedback circuit including the position sensor and a control loop and configured to use the displacement of the probe as a feedback signal and to control the movement of the vibrator inside the probe casing and the shape of a low frequency pulse applied by the probe.

A method for performing shear wave elastography imaging of an observation field in a medium, the method including shear wave imaging steps to acquire sets of shear wave propagation parameters, the method further including a reliability indicator determining step during which a reliability indicator of the shear wave elastography imaging of the observation field is determined.

An ultrasonic diagnostic apparatus is provided for allowing a displacement between a direction of an acoustic line of ultrasound and a direction of movement of biological tissue to be recognized. The apparatus includes a strain calculating section for calculating a strain in biological tissue based on two temporally different echo signals in an identical acoustic line acquired by an ultrasonic probe; an elasticity image data generating section for generating data for an elasticity image according to the strain calculated by the strain calculating section; a movement detecting section for detecting movement of the biological tissue in a B-mode image; an angle calculating section for calculating an angle between a direction of an acoustic line of ultrasound transmitted/received by the ultrasonic probe and a direction of movement of the biological tissue detected by the movement detecting section; and an image display processing section for displaying an indicator indicating the angle.

A method for quantitatively measuring a physical characteristic of a material includes performing one or more interrogations of a material sample, each interrogation using a push focal configuration. The method further includes taking measurements of displacement over time of a material sample caused by the one or more interrogations. Each measurement uses an interrogation focal configuration. The method further includes determining a physical characteristic of the material sample based on the measurements of displacement over time of the material sample. According to the method, at least one of the following is true: a tracking focal configuration used for one of the measurements is different from a tracking focal configuration used for another of the measurements; and a push focal configuration used for one of the interrogations is different from a push focal configuration used for another of the interrogations.