Abstract: An ultrasonic diagnostic apparatus has a unit which sets a display region for displaying a 3D image, a unit which transmits and receives ultrasound waves, a unit which generates volume data, a unit, on the basis of the volume data, which sets an analysis region, a unit, on the basis of the data on the analysis region contained in the volume data, which analyzes a fluctuations in signal intensity over time, a unit, on the basis of the analysis result, which calculates a cardiac cycle, a unit, on the basis of the cardiac cycle and the volume data, which generates data set constructed by data with substantially equal cardiac cycle, and generates data sets corresponding to a plurality of cardiac cycles, and a unit which displays the 3D images based on the data sets as a moving image.

Abstract: As an ROI for display and an ROI for valve observation as well as a projecting direction are input, a volume-rendering processing unit creates a first image in the ROI for display through volume rendering processing, and the ray-tracing processing unit creates a second image in the ROI for valve observation through ray tracing processing. An image compositing unit then creates a composite image by compositing the first image and the second image, and the composite image created by the image compositing unit (13) is displayed on a monitor.

Abstract: An ultrasonic diagnostic system for reducing black holes and highlighting of turbulent mosaic patterns without degradation in spatial resolution in an ultrasonic color Doppler method. The system includes a unit configured to extract image data in a specified range with reference to a specified pixel of the image data to generate kernel data, a pixel-value arranging unit configured to modulate the values of the pixels in the kernel data, a pixel-value selecting unit configured to select a pixel value of a modulated pixel value in a specified array rank, a characteristic determination unit configured to determine the characteristic of the image from the pixel value of the first image data, and a second image-data generating unit configured to generate second image data based on the value of a specified pixel in the first image data, and the selected pixel value in the specified array rank, or the demodulated pixel value.

Abstract: Ultrasonic image acquisition method comprising; calculating value for remaining parameter, from inputs of any values for three of four parameters, based on correlation information on four types of parameters; creating image that represents correlation graphically based on values for two of entered three parameters and obtained parameter, to create a setting screen on which display part variably displays parameters; displaying setting screen on display part; repeating calculation and setting-screen-creation by defining entered values for three parameters, as values for altered parameter and two non-graphically-represented parameters, when instruction to alter value for one of two graphically represented parameters is received through input part; and irradiating ultrasound beam to object based on entered values for three parameters and obtained value for remaining parameter when determination of values for each parameter are entered, so as to generate 3D dynamic image based on data obtained by receiving ultraso

Abstract: An ultrasonic diagnostic apparatus of the present invention capable of operation with a three-dimensional ultrasonic image performs a scan with a 3D probe for a predetermined time to acquire 3D volume data, and displays a plurality of sections of a heart on a monitor display, in conducting a functional diagnosis of the motion of the heart walls of a specimen before and after the application of a load. Then, the ultrasonic diagnostic apparatus displays a positional relation between the probe and the heart so that display angles of the sections of the heart displayed on the monitor display may be constant.

Abstract: Three times of ultrasonic transmissions are executed in positive, negative and negative polarities with reference to a predetermined rate period, for each of a plurality of ultrasonic scan lines, and echo signals caused and generated by the ultrasonic waves of the respective transmissions are received at the same rates. At each scan line, the echo signal based on the positive-polarity ultrasonic wave of the first transmission and the echo signal based on the negative-polarity ultrasonic wave of the second transmission are added up, thereby to generate an ordinary mode image. Besides, at each scan line, the echo signal based on the positive-polarity ultrasonic wave of the first transmission and the echo signal based on the negative-polarity ultrasonic wave of the third transmission are added up, thereby to generate puncture mode image data. The generated ordinary mode image and puncture mode image are displayed in a predetermined aspect.

Abstract: A measurement data processing device measures a size of a diagnostic region from a tomographic image as two-dimensional information. An ROI width determining device determines a size of a region of interest based on the size (lateral width and longitudinal width) of the diagnostic region. An oscillation angle determining device determines a range of an angle for oscillating ultrasonic transducers based on the size. An oscillation rate determining device determines a rate for oscillating the ultrasonic transducers based on information indicating the oscillation angle and image quality. In order to acquire a three-dimensional image of the diagnostic region, the probe oscillation control device controls the oscillation of the ultrasonic transducers based on the information. A three-dimensional image processing device extracts a three-dimensional image of in the determined region of interest from the acquired three-dimensional image. A display device displays the extracted three-dimensional image.

Abstract: The ultrasonic diagnostic system according to the present invention includes a kernel-data generating section for extracting first image data in a specified range set with reference to a specified pixel of a generated image data to generate kernel data, a pixel-value arranging section for modulating the values and arranging the values or the modulated values in descending order, a pixel-value selecting section for either selecting a pixel value in a specified rank or selecting a modulated pixel value in a specified rank and demodulating the modulated value, a characteristic determination section for determining the characteristic of the image from the pixel value of the first image data, and a second image-data generating section for selecting one of the value of a specified pixel in the first image data and the value in the specified rank or the demodulated value selected by the pixel selecting section to generate second image data.