Abstract: An ultrasonic diagnostic imaging method and system are described for detecting abnormalities in the synchronicity of heart wall stimulation. Points on opposite sides of a chamber of the heart are identified in a starting ultrasound image, then tracked through at least a portion of the heart cycle. The changing positions of lines extending between pairs of the points are accumulated and displayed in a color kinesis display in which each color depicts the location of a line at a particular point in the cardiac cycle. In an illustrated example the points are tracked through the cardiac cycle by speckle tracking of the speckle pattern of the adjacent myocardial tissue, tracking specific anatomy, or tracking tissue texture.

Abstract: In certain example embodiments of this invention, improved seal systems that include flexible seals that are integrally formed (e.g., co-extruded) with other vehicle components, and/or methods of making the same, are provided. In certain example embodiments, some or all sealing system components may be integrated into trim and/or other components of the vehicle such as, for example, more structural elements of the vehicle that generally are required to be present. For instance, in certain example embodiments, the current U-shaped seal that typically is used to receive the glass of a window may be replaced with seal members attached to elements of the overall vehicle construct. Certain example embodiments accomplish this integration, for example, by forming seal members together with the trim components, e.g., as a part of the roll form and/or extruding processes.

Abstract: Described herein are embodiments of an electromagnetic system that can be used to replace the traditional hydraulic oil systems that actuate mass movement. The embodiments described herein provide wide frequency range operation, ground force application with high fidelity, and low environmental impact. Embodiments described herein can be used for seismic exploration and vibroseis applications, among other uses.

Abstract: A three dimensional ultrasonic imaging system acquires 3D image data from a volumetric region and processes the image data to produce a live 3D image of the volumetric region in a given orientation. A user control can be switched by a user to present the image in a different orientation if desired. Both the anatomy in the 3D image and the image format can be inverted, and the left-right appearance of the 3D image can be reversed with a corresponding front-back reversal of the anatomy.

Abstract: A three dimensional ultrasonic imaging system includes a matrix array transducer which is capable of scanning beams over a maximal volumetric region. The array transducer is operable to selectively scan one of a plurality of subvolumes of the maximal volumetric region at a real time scanning rate such that a live 3D image of the subvolume is processed and displayed. A user control is actuated to step the system through the scanning of a sequence different subvolumes. In an illustrated embodiment the maximal volumetric region encompasses the heart, and the system can be stepped through the scanning and display of live 3D images of front, center, and back subvolumes of the heart.

Abstract: A three dimensional ultrasonic imaging system produces a live steerable 3D image of a volumetric region of a subject. The system includes a user control which is continuously adjustable by a user to sweep the displayed 3D volume between the limits of left and right beam steering angles of an electronically steered matrix array transducer.

Abstract: A three dimensional ultrasonic imaging system acquires 3D image data from a volumetric region and processes the image data to produce a live 3D image of the volumetric region, a 2D image of a face or a central cut plane of the volumetric region, and a 2D image of a cut plane which is orthogonal to the plane of the first 2D image. The two 2D images enable the user to quickly orient the position of the anatomy shown in 3D in the live 3D image.

Abstract: An ultrasonic diagnostic imaging method and system are described for detecting abnormalities in the synchronicity of heart wall stimulation. Points on opposite sides of a chamber of the heart are identified in a starting ultrasound image, then tracked through at least a portion of the heart cycle. The changing positions of lines extending between pairs of the points are accumulated and displayed in a color kinesis display in which each color depicts the location of a line at a particular point in the cardiac cycle. In an illustrated example the points are tracked through the cardiac cycle by speckle tracking of the speckle pattern of the adjacent myocardial tissue, tracking specific anatomy, or tracking tissue texture.