Abstract: An ultrasound imaging system performs spectral Doppler processing in a manner that considers a physiological cycle of a subject. In one embodiment, gaps in a spectral Doppler signal are filled taking by a processor that analyzes changes in the spectral Doppler signal caused by a physiological cycle. Spectral Doppler data are scaled to fit with the data occurring before and after a gap. The firing order of an interleaved imaging mode can also be adjusted so that spectral Doppler imaging is not interrupted during pre-defined or user defined portions of a physiological cycle.

Abstract: An ultrasound imaging system performs spectral Doppler processing in a manner that considers a physiological cycle of a subject. In one embodiment, gaps in a spectral Doppler signal are filled taking by a processor that analyzes changes in the spectral Doppler signal caused by a physiological cycle. Spectral Doppler data are scaled to fit with the data occurring before and after a gap. The firing order of an interleaved imaging mode can also be adjusted so that spectral Doppler imaging is not interrupted during pre-defined or user defined portions of a physiological cycle.

Abstract: An ultrasound imaging system performs spectral Doppler processing in a manner that considers a physiological cycle of a subject. In one embodiment, gaps in a spectral Doppler signal are filled taking by a processor that analyzes changes in the spectral Doppler signal caused by a physiological cycle. Spectral Doppler data are scaled to fit with the data occurring before and after a gap. The firing order of an interleaved imaging mode can also be adjusted so that spectral Doppler imaging is not interrupted during pre-defined or user defined portions of a physiological cycle.

Abstract: The embodiments of the tracking device for the ultrasound imaging diagnostic apparatus include a predetermined combination of an ultrasound probe, an operator and a patient to be tracked, a space measuring device for measuring at least distance and angle of the probe based upon emitted electromagnetic radiation that is emitted towards the probe and reflected electromagnetic radiation that is reflected from the probe; and a processing device connected to the space measuring device for determining a change in distance and angle of the probe in space based upon on the emitted electromagnetic radiation and the reflected electromagnetic radiation. The space measuring device is used to track movement in a combination of a probe, a patient and an operator.

Abstract: An ultrasound probe and corresponding method of obtaining motion related data for the ultrasound probe. The probe including a housing, a transducer located inside said housing having transducer elements in a predetermined configuration that generates ultrasound, transmits the generated ultrasound towards an object, and receives echoes that have been reflected from the object, a motion sensing device having a fixed position with respect to said housing and including a sensor configured to generate a movement signal indicative of at least one type of movement of the ultrasound probe, and processing circuitry configured to generate images from the echoes received by the transducer and to correct the generated images by image correlation based on the generated movement signal.

Abstract: A method and system of obtaining information by interrogating an information mark attached to a device implanted in a body of a patient by transmitting a non-ionizing pulse through the body of the patient, receiving, from the information mark, a response to the transmitted non-ionizing pulse, the response including encoded information, and extracting the encoded information from the response.

Abstract: The subarrays are formed dynamically switching the individual output signals from the transducer elements on an element-to-element basis after the time delay circuits have individually perform on the signal signals for time delay. For example, at least one crosspoint switch flexibly connects the time-delayed outputs on the element-to-element basis in order to dynamically form predetermined sets of subarrays. The subarrays are optionally unequal in shape and or a number of transducer elements.

Abstract: The embodiments of the tracking device for the ultrasound imaging diagnostic apparatus include a predetermined combination of an ultrasound probe, an operator and a patient to be tracked, a space measuring device for measuring at least distance and angle of the probe based upon emitted electromagnetic radiation that is emitted towards the probe and reflected electromagnetic radiation that is reflected from the probe; and a processing device connected to the space measuring device for determining a change in distance and angle of the probe in space based upon on the emitted electromagnetic radiation and the reflected electromagnetic radiation. The space measuring device is used to track movement in a combination of a probe, a patient and an operator.

Abstract: The embodiments of the ultrasound imaging diagnostic apparatus include at least one non-touch input device for receiving a predetermined gesture as an input command. An optional sequence of predetermined gestures is inputted as an operational command and or data to the embodiments of the ultrasound imaging diagnostic apparatus. A gesture is optionally combined with other conventional input modes through devices such as a microphone, a mouse, a keyboard, a button, a panel switch, a touch command screen, a foot switch, a trackball, and the like.

Abstract: Sidelobe levels of bipolar and unipolar waveforms are suppressed. Bipolar and unipolar transmit waveforms are generated with a coded excitation, such as a chirp coding, and pulse width modulation. For harmonic, such as second harmonic, imaging, the fundamental transmit frequency of the transmit waveform is centered at a lower end of the bandwidth of the transducer. The transducer filters higher frequency components of the transmit waveform differently than lower frequency components. To generate the desired acoustic waveform, the transmit waveform generated for application to the transducer is adjusted to account for the frequency response of the transducer. For example, higher frequency parts of a chirp waveform has more pulse width modulation or narrower pulse widths to account for lesser magnitude reductions. Multiple transmit waveforms may be combined to reduce sidelobes for fundamental or second harmonic imaging. Two coded excitation waveforms are generated.

Abstract: Transmit based axial whitening is provided. Ultrasonic waveforms to be transmitted are designed to provide for wideband imaging characteristics prior to detection. Rather than transmitting a waveform having a spectral magnitude as white or flat as possible, waveforms with adjusted spectral content, such as spectrally bi-modal waveforms are generated in order to compensate for subsequent effects. Prior to detection, a more wideband or whiter signal response is provided in response to the transmitted waveform. Any of various alterations of the transmit waveform, such as asymmetric, spectrally bi-modal or other characteristics in anticipation of a system transfer function or physical phenomena through which the signal passes electronically or acoustically to result in a wideband or white spectral magnitude and generally linear spectral phase is used. The transmit waveform is altered to improve the imaging characteristics of the downstream processing.

Abstract: A system and method for cooling an entirely or partially immersed mechanical or other type of transducer array is disclosed. Motion/flow of the immersion fluid is induced either by motion of the mechanical transducer itself, where the transducer is of the mechanically movable type, or by a separate motion-inducing mechanism located in or coupled with the fluid-filled, or partially filled, array housing. The resultant fluid flow/motion increases, i.e. more efficiently utilizes, the thermal carrying capacity of the immersion fluid by more uniformly distributing the thermal energy convected from the transducer array throughout the fluid volume. This results in an improved ability to cool the transducer array. The disclosed cooling system and method may be used in such a way so as to not substantially inhibit operation of the transducer array.

Abstract: Transmit based axial whitening is provided. Ultrasonic waveforms to be transmitted are designed to provide for wideband imaging characteristics prior to detection. Rather than transmitting a waveform having a spectral magnitude as white or flat as possible, waveforms with adjusted spectral content, such as spectrally bi-modal waveforms are generated in order to compensate for subsequent effects. Prior to detection, a more wideband or whiter signal response is provided in response to the transmitted waveform. Any of various alterations of the transmit waveform, such as asymmetric, spectrally bi-modal or other characteristics in anticipation of a system transfer function or physical phenomena through which the signal passes electronically or acoustically to result in a wideband or white spectral magnitude and generally linear spectral phase is used. The transmit waveform is altered to improve the imaging characteristics of the downstream processing.

Abstract: Methods and systems for obtaining ultrasound and sensing other patient charactristics are provided from summary. One or more sensors are provided in a same transducer probe as an array of elements. For example, sensors are formed on a same semiconductor substrate, such as a silicon substrate, as microelectromechanical devices or a capacitive membrane ultrasonic transducer (CMUT). As another example, a sensor is provided separate from or attached to transducer materials. Possible sensors include temperature, pressure, microphone, chemical and/or other sensors.

Abstract: A cooling device for an electric or electronic apparatus includes an inhaling member formed to draw in air and then discharge the air heated by heat generated from a component of the electric or electronic apparatus, an exhausting member communicating with the inhaling member and formed to receive the heated air discharged from the inhaling member, a fan provided adjacent to the exhausting member to forcibly draw in the air from the exhausting member, and a heat exchanger absorbing the heat from the air discharged from the fan and discharging the heat through a body casing of the electric or electronic apparatus. The cooling device for the electric or electronic apparatus has a high cooling efficiency, reduces noise, and prevents an inflow of dust.

Abstract: Sidelobe levels of bipolar and unipolar waveforms are suppressed. Bipolar and unipolar transmit waveforms are generated with a coded excitation, such as a chirp coding, and pulse width modulation. For harmonic, such as second harmonic, imaging, the fundamental transmit frequency of the transmit waveform is centered at a lower end of the bandwidth of the transducer. The transducer filters higher frequency components of the transmit waveform differently than lower frequency components. To generate the desired acoustic waveform, the transmit waveform generated for application to the transducer is adjusted to account for the frequency response of the transducer. For example, higher frequency parts of a chirp waveform has more pulse width modulation or narrower pulse widths to account for lesser magnitude reductions. Multiple transmit waveforms may be combined to reduce sidelobes for fundamental or second harmonic imaging. Two coded excitation waveforms are generated.

Abstract: A system and method for reducing parallel beamforming artifacts. An interpolation of amplitude data is performed to correct for the blocky appearance of images formed with parallel receive beams. In addition, the transmit beam is modified to approximate a rectangular beam.

Abstract: A method for automatically placing a range gate over a moving blood vessel during ultrasound imaging. Doppler data received from a number of depths in the tissue is analyzed in order to calculate the average velocity of the tissue at each depth. A search is performed in the average velocities to select a maximum velocity. The maximum velocity is associated with a blood vessel and a range gate is placed at a depth corresponding to the maximum velocity. In a presently preferred embodiment of the invention, the average velocity is calculated by performing a first lag autocorrelation of the echo data received from each depth in response to a series of Doppler pulses.

Abstract: An improved technique for providing persistence to velocity signals obtained by an ultrasound imaging system is disclosed. The velocity signals with appropriate persistence are then used to form an image on a display device so as to accurately depict fluid flow. The persistence technique intelligently decides whether or not to provide persistence to the velocity signals. In making these persistence determinations, the persistence technique not only avoids distorting the velocity values with corrupt signals, but also preserves directional flow information. The persistence technique can also make use of various thresholds to reduce errors (e.g., flash artifacts or random noise) as well as persistence of such errors.

Abstract: A method (280) and system (128) for selectively smoothing color flow images in a Doppler ultrasound system (100). A set of original digitized ultrasound signals is received for points (m, m-1, m-2) on a beamline (l-1), each point having associated with it a velocity signal (.phi..sub.j), a magnitude of autocorrelation signal (R.sub.i), and a power signal (P.sub.i). A point (X(1,1)) along a beamline is selected for processing. The set of digitized ultrasound signals is applied to a digital filter (152), and the digital filter computes a set of smoothed digitized ultrasound signals by computing an average velocity signal (.phi..sub.av), an average magnitude of autocorrelation signal (R.sub.av), and an average power signal (P.sub.av) of each point in the selected beamline and points in adjacent beamlines. For the selected point along the selected beamline, a selected velocity signal (.phi.(1,1)) is compared to a velocity threshold (V.sub.