The disclosure is related to the technical field of functional imaging, and discloses an ultrasound CT image reconstruction method and system based on ray theory, wherein the method includes an ultrasound CT sound speed reconstruction method and an ultrasound CT attenuation coefficient reconstruction method based on ray theory; the ultrasound CT sound speed reconstruction method based on ray theory includes: (1) extraction of the difference in travel time; (2) calculate the ray path that the acoustic wave passes from the transmitting array element to the receiving array element; (3) solution for inverse problem: by using the quasi-Newton method to solve the path-slowness-time equation system, the speed reconstruction value vector of the object to be measured can be obtained.

An ultrasound diagnostic device including: a transmitter which outputs a driving signal for a C-mode image to an ultrasound probe sending and receiving ultrasound; a receiver which obtains a reception signal from the ultrasound probe; and a controller which: calculates an inner product value of packet data of the reception signal and a first orthonormal basis for each degree; sets a conversion function to convert the inner product value into a removal rate to remove a clutter component; converts the calculated inner product value into the removal rate for each degree by using the set conversion function; and generates image data from which a signal component of the C-mode image is removed according to the removal rate for each degree.

An ultrasound diagnostic apparatus includes a transmitter, a receiver and a hardware processor. The transmitter outputs a drive signal for a C-mode image to an ultrasound probe. The receiver obtains a reception signal from the probe. The processor sets at least one mask in a frame of packet data of the reception signal; calculates a covariance matrix from a plurality of packet data included in the mask; calculates an eigenvector for the mask from the covariance matrix; calculates a first filter coefficient for the packet data by using the eigenvector and a gain matrix; performs interpolation on the first filter coefficient to calculate a second filter coefficient for packet data of each position in the frame; filters the packet data of the position by using the second filter coefficient; and generates C-mode image data from the filtered packet data.

An ultrasound apparatus, ultrasound-based liver examination device and ultrasound imaging method are provided. The ultrasound apparatus may include: an ultrasound probe, a transmission and receiving controller, an ultrasound echo signal processor, a data processor and a display device. The ultrasound echo signal processor may perform different processes on an ultrasound echo signal according to usage of the ultrasound echo signal. A gain compensation for enhancing image quality may be performed on a first ultrasound echo signal to be used for obtaining the ultrasound image, and a gain compensation for preserving original information may be performed on a second ultrasound echo signal to be used for calculating a quantitative parameter of a liver. The data processor may generate the ultrasound image according to the processed first ultrasound echo signal, calculate the quantitative parameter according to the processed second ultrasound echo signal, and output the ultrasound image and the quantitative parameter.

An ultrasound diagnostic apparatus 1 includes an image acquisition unit 17 that acquires an ultrasound image of a subject a bladder extraction unit 18 that extracts a bladder from the ultrasound image; a prostate extraction unit 19 that extracts a prostate or cervix from the ultrasound image from which the bladder is extracted; a region-of-interest setting unit 20 that sets a region of interest at a depth position in the ultrasound image based on a position of the extracted prostate or cervix in a case where the prostate or cervix is extracted and that sets a region of interest at a depth position in the ultrasound image based on a position of the extracted bladder in a case where the prostate or cervix is not extracted; and an image quality adjustment unit 21 that adjusts the transmission/reception condition according to the depth position of the region of interest.

An ultrasonic diagnostic apparatus includes an ultrasonic probe configured to transmit and receives ultrasonic waves to and from an observation region of an object. The ultrasonic diagnostic apparatus further includes an estimated image generating unit configured to generate estimated image data corresponding to image data based on an ultrasonic focused beam from image data obtained by transmission of an ultrasonic plane-wave beam by using a model having been machine-learned from learning data including image data obtained by the transmission of the ultrasonic plane-wave beam and image data obtained by the transmission of the ultrasonic focused beam.

An ultrasound method and apparatus can include: transducer elements arranged in a sub-array for generating analog signals based on a return signal detected by the transducer elements during a receive interval; analog delay lines including individual delays unique to each of the transducer elements and calculated based on a linear delay slope for delaying the analog signals; an analog to digital converter for converting the analog signals to a digital signal; a digital beamformer with a digital delay based on one portion of the linear delay slope for delaying the digital signal; and a profile control register containing depth bits corresponding to multiple points for updating the linear delay slope during the receive interval to adjust for the multiple points within an image line.

A diagnostic ultrasound apparatus includes a sound ray signal generator, an extractor and an arithmetic unit. The sound ray signal generator generates a sound ray signal based on a reception signal obtained from an ultrasound probe. The ultrasound probe transmits and receives ultrasound to and from a subject. The extractor extracts imaging signals from the sound ray signal by performing filtering of passing different bands. The arithmetic unit generates a difference signal by using the imaging signals, and performs an arithmetic operation on at least one of the imaging signals by using the difference signal.

A catheter-based ultrasound imaging system configured to provide a full circumferential 360-degree view around an intra-vascular/intra-cardiac imaging-catheter-head by generating a three-dimensional view of the tissue surrounding the imaging-head over time. The ultrasound imaging system can also provide tissue-state mapping capability. The evaluation of the vasculature and tissue characteristics include path and depth of lesions during cardiac-interventions such as ablation. The ultrasound imaging system comprises a catheter with a static or rotating sensor array tip supporting continuous circumferential rotation around its axis, connected to an ultrasound module and respective processing machinery allowing ultrafast imaging and a rotary motor that translates radial movements around a longitudinal catheter axis through a rotary torque transmitting part to rotate the sensor array-tip. This allows the capture and reconstruction of information of the vasculature including tissue structure around the catheter tip for generation of the three-dimensional view over time.

A displacement measurement apparatus includes an ultrasound sensor transmitting ultrasounds to an object in accordance with a drive signal, and detecting ultrasound echo signals generated in the object to output echo signals; a driving and processing unit supplying the drive signal to the sensor, and processing the echo signals from the sensor to obtain ultrasound echo data; and a controller controlling the driving and processing unit to yield an ultrasound echo data frame at each of plural different temporal phases based on the ultrasound echo data obtained by scanning the object. The ultrasound echo data has one of local single octant spectra, local single quadrant spectra, and local single half-band-sided spectra in a frequency domain. The ultrasound echo data is obtained from plural same bandwidth spectra. A data processing unit calculates a displacement at each local position or distribution thereof in at least one of axial, lateral, and elevational directions by solving simultaneous equations derived at each local position via implementing a predetermined displacement measurement method on the ultrasound echo data yielded at the plural different temporal phases with respect to at least one of the axial, lateral, and elevational carrier frequencies and the phase, or the one of the local single octant spectra, the local single quadrant spectra, and the local single half-band-sided spectra.