Abstract: An ultrasonic imaging system includes an ultrasonic transducer having an image data array and a tracking array at each end of the image data array. The tracking arrays are oriented transversely to the image data array. Images from the image data array are used to reconstruct a three-dimensional representation of the target. The relative movement between respective frames of the image data is automatically estimated by a motion estimator, based on frames of data from the tracking arrays. As the transducer is rotated about the azimuthal axis of the image data array, features of the target remain within the image planes of the tracking arrays. Movements of these features in the image planes of the tracking arrays are used to estimate motion as required for the three-dimensional reconstruction. Similar techniques estimate motion within the plane of an image to create an extended field of view.

Abstract: A method for imaging a target includes the steps of transmitting ultrasonic energy at a fundamental frequency and receiving reflected ultrasonic energy at a harmonic of the fundamental frequency. The ultrasonic energy is transmitted in power bursts, each having a respective envelope shape, wherein the envelope shapes rise gradually to a respective maximum value and fall gradually from the respective maximum value. Ultrasonic energy in the transmit beam is focused in an elongated high power region, as for example by means of a line focus.

Abstract: A medical diagnostic ultrasonic imaging method and system subdivide the transmit aperture into two or more subapertures, each subaperture having at least four adjacent transducer elements. The subapertures are phased differently with respect to one another to selectively reduce either fundamental components or harmonic components of echoes from tissue. These techniques can be used to improve contrast agent harmonic imaging as well as tissue harmonic imaging, depending upon the phase shift selected.

Abstract: The preferred embodiments include a diagnostic medical ultrasound system and method for object of interest extraction. Unlike some extraction techniques, the preferred embodiments do not require the user to perform the time consuming task of manually tracing the border of the object of interest. Further, unlike some automatic border detection techniques, the preferred embodiments produce an accurate border of an object of interest even if the object of interest is connected to neighboring anatomy with similar properties.

Abstract: A medical diagnostic ultrasound imaging method and system insonify a tissue containing a contrast agent with ultrasonic transmit signals at a fundamental frequency f. Backscattered ultrasonic receive signals are acquired and filtered to emphasize frequency components between the fundamental frequency f and the second harmonic frequency 2f, and the filtered receive signals are processed for display. This filtering enhances the ability of the method and system to discriminate between contrast agent and adjacent tissue.

Abstract: The preferred embodiments described herein provide a method and system for generating a graphical vascular report. Unlike prior vascular calculation packages that generate a report listing the results along with the assigned vessel location name, the use of a graphical vascular report provides a visual roadmap of the vascular system under study, incorporating calculations and results in an at-a-glance display. These preferred embodiments make vascular calculations more meaningful to a wider number of physicians and promote the use of vascular calculations to a wider number of disciplines. Additionally, these preferred embodiments improve the presentation of outgoing reports by directly associating results to target areas. Further, the graphical vascular report of these preferred embodiments are easy to create and are easily duplicated and stored.

Abstract: Coded transmit signals are used in medical diagnostic ultrasonic imaging systems. In one mode, first and second ultrasonic beams are launched into a body along first and second spatially distinct transmit beam directions and used with B-mode or motion detection processing. The two beams are coded with unique, preferably orthogonal, spatially invariant, nonlinear phase modulation codes and the second beam is launched before the first beam has left the tissue. The first and second transmit beams may be included in a single transmit event. Frame rates are improved. Multiple spectral Doppler images from independent gates are generated. In another mode, first and second uniquely coded ultrasonic beams are launched into a body to focus at substantially the same point such that the two beams sample motion at different times. Unconventionally high velocity parameters are estimated and other motion parameters, including velocity parameters, may be estimated with improved accuracy.

Abstract: A method and system for detecting energy using pulse inversion and Doppler processing are provided. Pulse inversion may be used to image the harmonic response of tissue alone or with contrast agents. Lowpass or bandpass clutter filters suppress the harmonic and/or fundamental response of tissue clutter to provide improvements in imaging, such as for imaging small vessels. Elimination of tissue clutter from both the fundamental components and second harmonic components in the Doppler domain increases the specificity of contrast agent and/or tissue.

Abstract: A region of interest in the body is imaged using at least two different trigger intervals between images. Imaging automatically switches from one trigger interval to another in response to a user command, such as depressing a button. This automation avoids cumbersome manual changes of the trigger intervals. Perfusion is measured in a shorter time in this way, reducing the effects of breathing and transducer movement. Variation of the trigger intervals allows for a convenient determination of perfusion. For example, the trigger intervals are varied from one heart cycle to two heart cycles and then to other integer numbers of heart cycles.

Abstract: An ultrasonic imaging system includes an ultrasonic transducer having an image data array and a tracking array at each end of the image data array. The tracking arrays are oriented transversely to the image data array. Images from the image data array are used to reconstruct a three-dimensional representation of the target. The relative movement between respective frames of the image data is automatically estimated by a motion estimator, based on frames of data from the tracking arrays. As the transducer is rotated about the azimuthal axis of the image data array, features of the target remain within the image planes of the tracking arrays. Movements of these features in the image planes of the tracking arrays are used to estimate motion as required for the three-dimensional reconstruction. Similar techniques estimate motion within the plane of an image to create an extended field of view.

Abstract: An improvement to the method for harmonic imaging including the steps of (a) transmitting ultrasonic energy at a fundamental frequency and (b) receiving reflected ultrasonic energy at a harmonic of the fundamental frequency is provided. The transmitting step includes the step of: applying the plurality of waveforms to a respective plurality of transducer elements, a first waveform of the plurality of waveforms characterized by a first value of a harmonic power ratio, waveforms transmitted from the transducer elements and corresponding to the plurality of waveforms summing as an acoustic waveform substantially at the point, the acoustic waveform characterized by a second value of the harmonic power ratio less than the first value. The imaging method can also include a step for subdividing the transmit aperture into two or more subapertures, each subaperture having at least four adjacent transducer elements.

Abstract: A method and apparatus for quantifying and displaying ultrasound signals in an ultrasonic system are provided. A first signal value for each of at least one spatial location in a region of interest is acquired at a first time, and the signal values are summed to obtain a first surface integral value. A second signal value for each of said at least one spatial location in said region of interest is acquired at a second time, and the second signal values are summed to obtain a second surface integral value. The first surface integral value is summed with the second surface integral value to obtain a time based integral. The time based integral is displayed. Other quantities based on any of various ultrasound parameters, such as Doppler energy, Doppler velocity and B-mode intensity, are calculated and displayed as quantities or as waveforms as a function of time. Furthermore, various comparisons of quantities and waveforms are provided. Image plane data or other ultrasound data are used in the calculations.

Abstract: An ultrasound transducer is provided that includes a plurality of transducer elements having a first surface facing a region of examination when the transducer is in use and a second surface opposite of the first surface. The first surface or the second surface or both may be non-planar in an elevation direction. A nosepiece having an integrated faceplate is disposed over the transducer and a filler material may fill an area between the first surface of the transducer elements and the interior surface of the integrated faceplate. The filler material may have focusing or non-focusing properties.

Abstract: A method and system for determining the location of a region of interest throughout a sequence of images is provided. The system, in response to user input or automatically, identifies a region of interest associated with anatomy represented in an image. The data associated with the region of interest is compared with data for other or subsequent images. A maximum degree of correlation between the data associated with the region of interest and data for the subsequent image is determined. A translation and/or rotation associated with the maximum correlation determines the position of a region of interest designator in the subsequent image. The process may be repeated for a plurality of images. The same process may be used to determine the position of the designator in previous images.

Abstract: A medical diagnostic ultrasonic imaging system acquires receive beams from spatially distinct transmit beams. The receive beams alternate in type between at least first and second types across the region being imaged. The first and second types of receive beams differ in at least one scan parameter other than transmit and receive line geometry, and can for example differ in transmit phase, transmit or receive aperture, system frequency, transmit focus, complex phase angle, transmit code or transmit gain. Receive beams associated with spatially distinct ones of the transmit beams (including at least one beam of the first type and at least one beam of the second type) are then combined. In this way, many two-pulse techniques, including, for example, phase inversion techniques, synthetic aperture techniques, synthetic frequency techniques, and synthetic focus techniques, can be used while substantially reducing the frame rate penalty normally associated with such techniques.

Abstract: An medical diagnostic ultrasonic image processing method estimates motion between first and second composite ultrasonic images that include both B-mode and Color Doppler information. First and second B-mode images are extracted from the first and second composite ultrasonic images, respectively, and then motion is estimated between the first and second B-mode images. The estimated motion is then used to compose a multi-frame image using at least portions of the composite ultrasonic images or derivatives of the composite ultrasonic images, such as the B-mode images.

Abstract: A method for improving the coupling of an acoustic window or lens to a RFI shield by modifying the surface of the shield to promote adhesion. The surface of the shield can be chemically modified with an epoxy and/or mechanically modified by creating an unsmooth top surface.

Abstract: A method and system for Doppler processing of information at two or more different frequency bands for improved accuracy is provided. Signals from two or more unique frequency bands are processed separately to detect motion. Using signals at different frequency bands allows for more effective use of unused bandwidth to increase information content and improve estimation accuracy. One of or more of the two or more receive frequency bands may be within the transmitted fundamental frequency band or within harmonic frequency bands of the transmitted fundamental frequency band. The increased information content generated by using two separate narrow receive frequency bands is used to improve many aspects of motion detection. The resulting Doppler values of each parameter, such as velocity, energy, and variance parameters, are averaged or otherwise combined. One of the average, the Doppler values at each frequency band and a null value are selected for further processing and display.

Abstract: A medical diagnostic ultrasound real-time 3-D transmitting and imaging system generates multiple transmit beam sets using a 2-D transducer array. Each transmit beam set includes multiple simultaneous ultrasound transmit beams. The system acquires multiple receive beam sets in response to the transmit beams, and each receive beam set includes multiple simultaneous receive beams. A real-time, three-dimensional medical diagnostic ultrasound image is formed in response to these receive beams. Several techniques for reducing cross talk in such a system are discussed.

Abstract: Both the energy and velocity contents of received Doppler and time shift signals are simultaneously displayed. A continuous range of imaging modes are provided ranging from velocity imaging to energy imaging. The user may select the particular imaging mode desired for a particular clinical application.