Abstract: An ultrasound system and method for aberration correction processing in conjunction with finely pitched transducer elements and/or aberration correction processing in conjunction with a hierarchical control scheme. Results obtained from known aberration correction algorithms may be improved with the use of finely pitched transducer elements wherein the pitch of the elements (or subgroup of elements) is less than or equal to the wavelength of an ultrasound signal at the fundamental frequency. Elements of a transducer may be grouped into subgroups with aberration correction algorithms being applied to the output of each subgroup.

Abstract: The preferred embodiments described herein relate to a medical diagnostic ultrasound imaging system with at least one reprogrammable logic device, such as, for example, a field programmable gate array (“FPGA”). In one presently preferred embodiment, at least one reprogrammable logic device in the ultrasound system is reconfigured for probe changes (e.g., phased-array, curved array), for operator control changes (such as system mode changes, e.g., B-Mode, color Doppler), and/or dynamically as part of system operation (such as between ultrasonic pulse firings and/or between frames). By utilizing at least one reprogrammable logic device, the preferred embodiments reduce the size and cost of the ultrasound system without compromising the performance characteristics of the system.

Abstract: Speckle is reduced by compounding data associated with different aperture positions. The data is responsive to transmission and reception along the same scan lines. The data is detected and then combined.

Abstract: Received echo data are transferred from an ultrasound probe to the signal processing circuitry of an ultrasound imaging system by use of a reduced number of multiple coaxial cables. The system operates by frequency division multiplexing of the analog output signals produced by multiple individual array elements in the probe onto a single coaxial cable, which connects the probe to the central host computer or console for conventional signal processing and imaging.

Abstract: An ultrasonic diagnosis apparatus includes an ultrasonic probe. A transmitter supplies a transmission pulse to the ultrasonic probe to repeatedly transmit an ultrasonic wave to each of a plurality of scanning lines. A receiver receives echoes of the ultrasonic waves through the ultrasonic probe and obtaining a plurality of received signals for each of the plurality of scanning lines. A displacement estimating means estimates a relative change accompanying a tissue motion between received signals associated with each of scanning lines. A displacement correcting means corrects the received signals in accordance with the change detected by the displacement estimating means. A harmonic component extracting means extracts a harmonic component from the received signals corrected by the displacement correcting means. A display means generates an ultrasonic image on the basis of the harmonic component extracted by the harmonic component extracting means. A monitor displays the image generated by the display means.

Abstract: Systems and methods for controlling the phase and amplitude of individual drive sinus waves of a phased-array focused ultrasound transducer employ digitally controlled components to scale the amplitude of three or more bases sinuses into component sinus vectors. The component sinus vectors are linearly combined to generate the respective sinus of a selected phase and amplitude. The use of digitally controlled controlled components allows for digitally controlled switching between various distances, shapes and orientations (“characteristics”) of the focal zone of the transducer. The respective input parameters for any number of possible focal zone characteristics may be stored in a comprehensive table or memory for readily switching between focal zone characteristics in &mgr; seconds. Changes in the output frequency are accomplished without impacting on the specific focal zone characteristics of the transducer output.

Abstract: Medical diagnostic ultrasound methods and systems for automated flow analysis are provided. Multiple cross-sectional areas along a vessel are determined automatically. A processor locates an abnormality as a function of the multiple cross-sectional areas, such as identifying a cross-sectional area that is a threshold amount less than an average cross-sectional area. The abnormal area is highlighted on the display to assist with medical diagnosis. For the carotid artery, the interior and exterior branches are labeled to assist medical diagnosis. The two branches are automatically identified. The branch associated with additional small branches is identified as the exterior carotid.

Abstract: An ultrasound system that has transmit and receive circuitry that, pursuant to a plurality of image settings, transmits ultrasound signals into a patient, receives echoes from a patient and outputs a signal representative of the echo. Control circuitry is provided that sequentially adjusts the image settings so as to cause the transmit and receive circuitry to have a sequence of imaging configurations during an ultrasound imaging study. A memory may be provided that stores a plurality of state diagrams, each defining a sequence of imaging configurations for a particular imaging study, which are accessible by the control circuitry, wherein the control circuitry accesses a selected state diagram to conduct an imaging study. Such a system is particularly useful for imaging studies that utilize contrast agents.

Abstract: A PC board of a PC has a controller for controlling a motor drive circuit based on a timing signal, a memory for GAIN/STC for storing amplification data in an data in an amplifier for GAIN/STC as digital data and outputting the stored data synchronously with the timing signal of the controller, and a PC internal bus controller for connecting a PC internal bus to a local bus. Set values of GAIN and STC are converted into parameters and are set to the memory for GAIN/STC and a set value of contrast is converted into a parameter and is set to the controller both in a live state and in a freeze state.

Abstract: A first ultrasound dataset that represents an object in a first coordinate system can be acquired at a first time. Three landmarks of the object can be located in the first ultrasound dataset to define a second coordinate system. A first transform from the first to the second coordinate system can be determined for the first ultrasound dataset. A second ultrasound dataset that represents the object in the first coordinate system can be acquired at a second time. The same three landmarks in the second ultrasound dataset can be located to define a third coordinate system. A second transform from the first to the third coordinate systems can be determined for the second ultrasound dataset.

Abstract: An ultrasonic diagnostic apparatus including a three-dimensional scanner for carrying out a three-dimensional scanning by ultrasonic waves. The apparatus also includes a three-dimensional image data former for forming three-dimensional image data based on scanning data obtained from the three-dimensional scanner. An image data memory is included as part of the apparatus for storing in time series a plurality of pieces of three-dimensional image data formed by the three-dimensional image data former. The apparatus includes a memory controller for controlling write and read of the three-dimensional image data into or from the image data memory. And the apparatus further includes a display image former for forming a display image based on three-dimensional image data read out from the image data memory by the memory controller, and for displaying the formed display image on a display unit.

Abstract: A method for displaying a region of interest graphic on an imaging system includes: (a) establishing a communication connection over a network between the imaging system and a remote facility; (b) displaying an image frame, the image frame having a reference point; (c) displaying a region of interest graphic on the image frame at a depth determined relative to the reference point, the region of interest graphic having a bottom width, a top width, a height, and an angle between a projection of a first edge line and a projection of a second edge line; (d) changing the depth of the region of interest; and (e) changing the top width and the angle of the region of interest graphic as a function of the change in depth, while maintaining the height and the bottom width of the region of interest graphic substantially unchanged. At least one of steps (b) through (e) is done remotely over the communication connection.

Abstract: A medical ultrasonic imaging system transmits a set of two or more substantially identical transmit pulses into a tissue containing a contrast agent. The associated received pulses are filtered with a broadband filter that passes both the fundamental and at least one harmonic component of the echoes. The filtered received pulses are then applied to a clutter filter that suppresses harmonic and fundamental responses from slowly moving and stationary tissue, while clearly showing contrast agent response due to the loss of correlation effect. The disclosed system includes other signal paths for generating conventional B-mode images as well as combined images that include both components from the contrast-specific image as well as components from the B-mode image. An improved user interface allows the user to switch among these three images.

Abstract: An ultrasonic imaging method and apparatus are described for imaging the coronary arteries of the heart. The vascular system is infused with an ultrasonic contrast agent. A volumetric region of the heart wall including a coronary artery is three dimensionally scanned. A projection image of the volumetric region is produced from the scanning, providing a two dimensional contrast image of the coronary artery with the appearance of an angiogram. Preferably the coronary artery signals are segmented from contrast signals emanating from the myocardium and the heart blood pool so that the coronary arteries are clearly highlighted and distinct in the ultrasonic angiogram.

Abstract: A medical diagnostic ultrasound receive beamformer includes an upsampler upstream of a time delay device and a summer, and a smoothing filter downstream of the time delay device and the summer. The receive beamformer is automatically programmed into a gate array as a single-beam, dynamic-focus receive beamformer when the user selects B-mode and as a dual-beam, fixed-focus receive beamformer when the user selects color flow mode.

Abstract: Elastography can produce quality strain images in vitro and in vivo. Standard elastography uses a coherent cross-correlation technique to estimate tissue displacement and tissue strain using a subsequent gradient operator. While coherent estimation methods generally have the advantage of being highly accurate and precise, even relatively small undesired motions are likely to cause enough signal decorrelation to produce significant degradation of the elastogram. For elastography to become more universally practical in such applications as hand-held, intravascular and abdominal imaging, the limitations associated with coherent strain estimation methods that require tissue and system stability, must be overcome. In this paper, we propose the use of a spectral shift method that uses a centroid shift estimate to measure local strain directly. Furthermore, we also show theoretically that a spectral bandwidth method can also provide a direct strain estimation.

Abstract: A method of generating three-dimensional image data by transmitting beams to an object from a transmitting part and detecting beams reflected from the object by using a two-dimensional sensor array having a plurality of sensors. The method includes the steps of: (a) storing detection signals obtained by the plurality of sensors during a predetermined period after transmission; (b) obtaining image data about at least one measured point included in the object on the basis of a detection signal output from at least one of the plurality of sensors at a time point obtained from relationship between a distance from the transmission part to at least one of the plurality of sensors through the at least one measured point and a transmission velocity of the beams passing through the object; and (c) obtaining image data by repeating step (b) while changing the time point.

Abstract: A system and a method generate a 3-D image by fast computing the distance between adjacent 2-D images. The method comprises the steps of: producing a first main frame, a second main frame parallel to the first main frame, and a supplementary frame inclined at an angle with respect to the first main frame; creating a virtual frame by using the first main frame and the supplementary frame; calculating a first correlation coefficient between the first main frame and the virtual frame; computing a second correlation coefficient between the first and second main frames; and estimating a distance between the first and second main frames. The system comprises a probe for generating pairs of image frames; a distance calculating unit for calculating distances between main frames of the pairs; and a screen for displaying a 3-D image of the target produced by using the distances.

Abstract: By using a novel structure of a beamformer which produce data for multiple receive scanlines in a time multiplexed manner, the size of the delay memory is reduced. An ultrasound receive beamforming apparatus for processing signals received from an array of transducers, comprises: a plurality of beamforming devices for applying delays to data samples of M channels. Each of said beamforming devices includes: a predetermined number of per-channel delay elements which provide first delays to the data samples of M channels, to provide delayed data per each channel and per each receive beam, first adders for adding the delayed data of not less than 2 channels provided from the per-channel delay elements, and multi-channel delay elements which provide second delays to the outputs of the first adders.

Abstract: A method and apparatus for forming a three-dimensional image of a subsurface object utilizes an ultrasonic transducer wand to acquire ultrasonic images of an object, and a target plate attached to the wand which is optically imaged during each of a sequence of ultrasound scans, each of which is made with a different positioning of the ultrasonic scanning beam, thereby forming a sequence of quasi two-dimensional sonogram image slices of the object. Intersecting lines on the target are used to calculate a first coordinate transformation which transforms each optical image of the target plate and sensor to a normal view thereof, and each normally oriented target plate image is used to orient each sonogram image in a fixed coordinate system. A transformation matrix is then used to construct in a fixed coordinate system normalized two-dimensional sensor image slices of correct relative size, location, and orientation.