Abstract: An ultrasonography generation device includes an ultrasonic wave transceiver (1002), a user inputter (1006) which inputs input by an operator, a monitor (1011) capable of displaying an image, an image processor (1005) which generates tomographic image data of a fetus and the placenta based on signals acquired from the ultrasonic wave transceiver and sets a region of interest including a region between the fetus and the placenta according to the input from the inputter when the tomographic image data is displayed on the display, a 3D-ROI corrector (1008) which corrects the region of interest using the region of interest set by the operator and the tomographic image data and determines validity of the corrected region of interest, and a presentation part (1012) which presents the determination result from 3D-ROI corrector. The ultrasonography generation device generates a 3D image of the fetus using the corrected region of interest.

Abstract: On the basis of voxel data for a plurality of voxels constituting a set of ultrasound volume data, a voxel group identifying unit 50 identifies, in said ultrasound volume data, one or more voxel groups formed by a plurality of voxels in which voxel data satisfy a condition of being linked. On the basis of the voxel data for a plurality of voxels corresponding to each voxel group to be displayed, from among the one or more identified voxel groups, an image forming unit 80 forms an ultrasound image in which the voxel groups to be displayed are indicated clearly in a selective manner. It is thus possible for a three-dimensional image to be formed in such a way that one part of the image, such as floating matter in the amniotic fluid, does not interfere with another part of the image, such as a fetus.

Abstract: An ultrasound diagnostic apparatus generates Doppler waveform images whose visibility is improved appropriately in accordance with changes in measurement conditions. The ultrasound diagnostic apparatus includes a frequency-analyzing unit that generates frequency spectrum data on Doppler shift frequency components of ultrasonic waves that are received after being transmitted towards a subject and reflected in the subject, and a line data generating unit for generating line data, wherein arrays of multiple pixels are stipulated according to the corresponding frequencies and each pixel value represents the magnitude of the Doppler shift frequency component, based on the frequency spectrum data. The ultrasound diagnostic apparatus determines whether or not each pixel of line data at a previously appointed time point is a noise pixel, and the values of pixels that are determined to be noise pixels are adjusted by multiplying the pixel value with a weighting factor (w) of 0 to less than 1.

Abstract: According to the present invention, when measurement of a distance (fetal head biparietal diameter) on an ultrasonic image is started, a first mobile marker for designating a start point and a standard range display graphic are displayed. The standard range display graphic is a graphic that is centered on the first mobile marker and comprises two circular graphics having radii that are configured to be a lower limit and upper limit of a fetal head biparietal diameter standard range. A user can designate the start point while recognizing, via the standard range display graphic, an end point candidate range. Subsequently, an end point can be designated while recognizing the end point candidate range via a stationary standard range display graphic.

Abstract: When measurement of a circumference (abdominal circumference of a fetus) on an ultrasonic image is started, a first mobile marker for designating a major axis start point of an ellipse to be measured is displayed. After the major axis start point is designated, a second mobile marker for designating a major axis end point of the ellipse to be measured and a standard range display graphic are displayed. The standard range display graphic comprises two ellipses in which the major axis start point and second mobile marker constitute a major axis or minor axis and the circumferences are configured to be a lower limit and upper limit of the abdominal circumference. A user can designate the major axis end point while recognizing the positional relationship between the standard range display graphic and the outline of an abdominal cross section. Furthermore, a minor axis end of the ellipse to be measured can be designated using the standard range graphic as a guide.

Abstract: A region of interest setting unit sets a region of interest within image data for a tomographic image. The region of interest setting unit sets the region of interest to the heart of an embryo and partitions the region of interest into a plurality of blocks. A waveform generating unit generates an embryonic heartbeat waveform for each block of the plurality of blocks within the region of interest on the basis of the image data within the block. A waveform evaluating unit uses a standard waveform to evaluate the reliability of the embryonic heartbeat waveform for each block of the plurality of blocks within the region of interest.

Abstract: A tracking processing unit performs tracking processing for a plurality of states during a tracking period and, on the basis of a plurality of tracking results obtained from the tracking processing for the plurality of states, tracks the movement of a measurement point during the tracking period. In addition, with regard to a plurality of tracking points that comprise the measurement point and an auxiliary point, the tracking processing unit performs tracking processing for each tracking point during the tracking period and, on the basis of a plurality of tracking results obtained from the plurality of tracking points, tracks the movement of the measurement point during the tracking period.

Abstract: An ultrasonography generation device includes an ultrasonic wave transceiver (1002), a user inputter (1006) which inputs input by an operator, a monitor (1011) capable of displaying an image, an image processor (1005) which generates tomographic image data of a fetus and the placenta based on signals acquired from the ultrasonic wave transceiver and sets a region of interest including a region between the fetus and the placenta according to the input from the inputter when the tomographic image data is displayed on the display, a 3D-ROI corrector (1008) which corrects the region of interest using the region of interest set by the operator and the tomographic image data and determines validity of the corrected region of interest, and a presentation part (1012) which presents the determination result from 3D-ROI corrector. The ultrasonography generation device generates a 3D image of the fetus using the corrected region of interest.

Abstract: In tomographic image data, a reference region-setting unit (30) sets a body reference region for the body of a fetus and sets a cardiac reference region for the heart of the fetus. A body shift analysis unit (50) analyzes the movement of the fetus' body in the tomographic image data using the body reference region and obtains body shift information. A cardiac motion analysis unit (60) analyzes the movement of the fetus' heart in the tomographic image data using the cardiac reference region and obtains cardiac motion information. Once body shift information and cardiac motion information are obtained in this manner, a pulse information-processing unit (70) obtains fetal pulse information on the basis of the cardiac motion information from which the body shift information has been subtracted. The pulse information obtained by the pulse information-processing unit (70) is displayed on the display unit (80).

Abstract: There is provided an ultrasound image processing apparatus which displays an ultrasonic image with a higher resolution. For each pixel of interest on a previous frame, a pattern matching process is applied between the previous frame and a current frame, to calculate, for each pixel of interest, a mapping address to the current frame as a movement destination or a two-dimensional movement vector. The mapping address includes an integer value and a fractional value. The current frame is re-constructed into a high-density frame including a plurality of interpolation lines based on an original group of pixels of the current frame and an additional group of pixels defined by a pixel value and the mapping address of each pixel of interest on the previous frame. In generation of the mapping address, a sub-pixel process is applied.

Abstract: In the present invention, a reference frame selection unit selects a reference frame from among a sequence of frames showing the heart of a fetus. A candidate region group setting unit sets a candidate region group for each of the frames that constitute the sequence of frames. A correlation value calculation unit calculates, for each candidate region, a correlation value between the reference frame and all the other frames. Due to this, a plurality of correlation value waveforms corresponding to the plurality of candidate regions is generated. A stabilized waveform portion specification unit specifies a stabilized waveform portion for each correlation value waveform. A stabilized region specification unit specifies, from among the plurality of stabilized waveform portions, the stabilized waveform portion having the highest degree of stabilization (in other words, the candidate region having the highest degree of stabilization).

Abstract: There is provided an ultrasound image processing apparatus which displays an ultrasonic image with a higher resolution. In a received frame, a first pixel array, a second pixel array, and a third pixel array are defined in depths different from each other. For each pixel of interest on the first pixel array, a pattern matching process is applied between the first pixel array and the second pixel array, to calculate a mapping address on the second pixel array for the pixel of interest. In addition, for each pixel of interest on the third pixel array, a pattern matching process is applied between the third pixel array and the second pixel array, to calculate a mapping address on the second pixel array for each pixel of interest. The second pixel array is re-constructed into a high-density pixel array using pixel values and mapping addresses of a plurality of pixels of interest.

Abstract: The purpose of the present invention is to use multiresolution decomposition to reduce image sections, such as fogging and stationary artifacts, which appear in an ultrasound image. An image processing unit (20) performs resolution conversion processing on an ultrasound image obtained on the basis of a reception signal, to form a plurality of resolution images having mutually different resolutions, determines, on the basis of the plurality of resolution images, a reduction degree for each section in the image, and forms an ultrasound image in which reduction processing has been performed on each section in the image in accordance with the reduction degrees.

Abstract: A free-moving piece (jellyfish sign) having a high probability of separation in the near future in an unstable plaque is clearly displayed. Ultrasonic tomographic images (25) of a cross section including an axis of the carotid artery are successively obtained. Using a threshold value which sets a surface (48) of the unstable plaque as a boundary between brightness and darkness, the plurality of ultrasonic tomographic images (25) are binarized. A difference is calculated between corresponding pixels of two binarized ultrasonic tomographic images so that a free-moving piece (52) is extracted and displayed overlapped over the ultrasonic tomographic image (25).

Abstract: An image processing unit (20) performs resolution conversion processing on an ultrasound image obtained on the basis of a reception signal, to generate a plurality of resolution images having mutually different resolutions. Furthermore, the image processing unit (20) performs non-linear processing on a difference image obtained by comparing the plurality of resolution images with each other, to generate boundary components related to boundaries included in the image. Moreover, a boundary-enhanced image is generated by performing enhancement processing on the ultrasound image on the basis of the generated boundary components.

Abstract: A densification processing unit (20) densifies image data composed of a plurality of pieces of line data corresponding to a plurality of ultrasound beams obtained by scanning with an ultrasonic beam (a transmission beam and a reception beam). The densification processing unit (20) densifies the image data by compensating for density of scanning direction data arranged at a low density along the scanning direction of the ultrasonic beam on the basis of depth direction data arranged at a high density along the depth direction of the ultrasonic beam within the imaging data.

Abstract: Image-use data of a low-density image acquired by scanning an ultrasound beam at a low density is densified in a densification processing unit. The densification processing unit densifies image-use data of a low-density image by compensating for density of image-use data of the low-density image using a plurality of densified data units that have been acquired from a high-density image as a result of learning, by way of the learning related to the high-density image which has been acquired by scanning an ultrasound beam at a high density.

Abstract: An ultrasonic diagnostic apparatus which can measure a time difference of motion between a plurality of sites of a cardiac muscle for the heart of a fetus is provided. On a tomographic image of the heart, a user sets a plurality of observation points. Each observation point is tracked, and a plurality of displacement waveforms representing a temporal displacement of the plurality of observation points are generated. A time difference between a plurality of representative points is calculated between the plurality of displacement waveforms. Such a time difference is displayed as a numerical value or as a graph. The representative point is a peak point, a zero-cross point, an inflection point, or the like. The plurality of observation points are set along conduction pathways in the heart for the electric signal.

Abstract: In an ultrasonic image processing apparatus, an original image in the form of a three-dimensional ultrasonic image is generated from volume data based on the volume rendering method. Directional interpolation processing is then applied to the original image. More specifically, a corresponding point corresponding to a noted pixel in the display image is first determined on the original image. Then, on the original image, a plurality of candidate directions extending through the corresponding point are set, and a dispersion value is computed for each of the candidate directions. Further, a normal direction with the maximum dispersion value is specified among the candidate directions, and a reference direction along the contour of a tissue is determined in the direction orthogonal to the specified normal line. Alternatively, the reference direction is determined as a direction with the minimum dispersion value among the plurality of candidate directions.

Abstract: An ultrasound diagnostic apparatus which forms a three-dimensional bloodstream image by reference to volume data obtained from a three-dimensional space within a living organism. A modified maximum value detection method is applied along each ray. Search of a maximum value is sequentially executed from a search start point, and at a time point when a predetermined termination condition is satisfied, a maximum value which is being detected at this time point is regarded as a specific maximum value. The specific maximum value is then converted into a pixel value. The specific maximum value is a first peak and is specified even if a higher peak exists after the first peak. A three-dimensional bloodstream image is formed by a plurality of pixel values. In a portion of the three-dimensional bloodstream image in which two bloodstreams cross each other, a bloodstream located on the front side is preferentially displayed.