Abstract: A hoisting assembly for use with a wire rope. A rope guide is configured to mount around a rotating drum having a spiral rope groove defined therein. The spiral rope groove on the rotating drum is configured to receive the hoisting rope as it winds and unwinds from the rotating drum. The rope guide is configured to move laterally relative to the rotating drum to keep the hoisting rope in the spiral rope groove when winding the hoisting rope onto the rope groove or unwinding it from the rope groove. A sheave set may be configured to move along the longitudinal axis of the rotating drum while the hoist rope is unwinding from the rotating drum. The sheave set tensions and guides the hoisting rope and works in connection with a swivel sheave to accommodate the rope angle with respect to the axis of the rotating drum. Accordingly, the assembly is configured for spooling and unspooling the hoist rope to move the load in a completely vertical direction.

Abstract: An intraluminal imaging device is provided. In one embodiment, the imaging device includes a flexible elongate member having a distal portion and a proximal portion. The flexible elongate member can be positioned within a vessel. The imaging device has an imaging assembly that can be mounted within the distal portion. The imaging assembly includes a side-looking array of imaging elements and a micro-beamformer IC that is coupled to the side-looking array of imaging elements. The micro-beamformer IC can control the array of imaging elements, can determine a first angle and a second angle, and can perform beam forming for the array of imaging elements. The micro-beamformer IC can receive the first imaging signals associated with a first plane at the first angle, and the second imaging signals associated with a second plane at the second angle. In some embodiments, the first and second angles are selected to satisfy predetermined criteria.

Abstract: An intraluminal imaging device is provided. In one embodiment, the imaging device includes a flexible elongate member having a distal portion and a proximal portion. The flexible elongate member can be positioned within a vessel. The imaging device has an imaging assembly that can be mounted within the distal portion. The imaging assembly includes a side-looking array of imaging elements and a micro-beamformer IC that is coupled to the side-looking array of imaging elements. The micro-beamformer IC can control the array of imaging elements, can determine a first angle and a second angle, and can perform beam forming for the array of imaging elements. The micro-beamformer IC can receive the first imaging signals associated with a first plane (410) at the first angle (+45°), and the second imaging signals associated with a second plane (420) at the second angle (?45°). In some embodiments, the first and second angles are selected to satisfy predetermined criteria.

Abstract: Systems, methods, and apparatuses for confidence mapping of shear wave measurements are disclosed. Confidence maps of shear wave image measurements may be generated from one or more confidence factors. Masking of graphical overlays of tissue stiffness values, based at least in part on the confidence map is disclosed. The confidence map and/or masked graphical overlays of tissue stiffness values may be superimposed on ultrasound images and provided on a display.

Abstract: An ultrasound imaging system has an improved dynamic range control which enables a user to reduce image haze with substantially no effect on bright tissue in the image and without increasing speckle variance. A dynamic range processor processes an input image to produce an approximation image which is a spatially low pass filtered version of the input image. The dynamic range of the approximation image is compressed, and image detail, unaffected by the compression, is added back to produce a dynamically compressed image for display.

Abstract: Systems, methods, and apparatuses for confidence mapping of shear wave measurements are disclosed. Confidence maps of shear wave image measurements may be generated from one or more confidence factors. Masking of graphical overlays of tissue stiffness values, based at least in part on the confidence map is disclosed. The confidence map and/or masked graphical overlays of tissue stiffness values may be superimposed on ultrasound images and provided on a display.

Abstract: A system, as an engine with a crankcase containing oil or a fluid mixed with oil, has a reservoir containing liquid that extends up to a level of the fluid. A dipstick support structure supports a dipstick on it so that the dipstick extends into the fluid past the level of the fluid, and so that the dipstick is manually removable from the dipstick support structure by a user. An electrical system is connected with the dipstick, and the electrical system electrically senses the level of the fluid based on an electrical characteristic of the dipstick that varies with the varying level of the fluid when the dipstick extends into it. The electrical characteristic may be capacitance of the dipstick detected by sequential charging and discharging of the dipstick to produce a square wave electrical signal the frequency of which corresponds to the level of fluid.

Abstract: An ultrasound imaging system according to the present disclosure may include an ultrasound probe, a display unit, and a processor configured to receive source image data having a first dynamic range, wherein the source image data comprises log compressed echo intensity values based on the ultrasound echoes detected by the ultrasound probe, generate a histogram of at least a portion of source image data, generate a cumulative density function for the histogram, receive an indication of at least two points on the cumulative density function (CDF), and cause the display unit to display an ultrasound image representative of the source image data displayed in accordance with the second dynamic range.

Abstract: Systems, methods, and apparatuses for confidence mapping of shear wave measurements are disclosed. Confidence maps of shear wave image measurements may be generated from one or more confidence factors. Masking of graphical overlays of tissue stiffness values, based at least in part on the confidence map is disclosed. The confidence map and/or masked graphical overlays of tissue stiffness values may be superimposed on ultrasound images and provided on a display.

Abstract: An ultrasonic diagnostic imaging for analyzing shear wave characteristics utilizes a background motion compensation subsystem which acts as a spatial filter of pulse-to-pulse autocorrelation phases over the ROI of tracking pulse vectors to compensate for background motion. The subsystem is configured to compute the sum of all lag-1 autocorrelations of tracking line ensemble data over the tracking ROI, for each PRI. The inventive technique does not significantly reduce sensitivity to shear waves, because the shear wave is spatially smaller than the ROI.

Abstract: Systems, methods, and apparatuses for confidence mapping of shear wave measurements are disclosed. Confidence maps of shear wave image measurements may be generated from one or more confidence factors. Masking of graphical overlays of tissue stiffness values, based at least in part on the confidence map is disclosed. The confidence map and/or masked graphical overlays of tissue stiffness values may be superimposed on ultrasound images and provided on a display.

Abstract: This invention relates to crystalline (1S,2S,3S,5R)-3-((6-(difluoromethyl)-5-fluoro-1,2,3,4-tetrahydroisoquinolin-8-yl)oxy)-5-(4-methyl-7H-pyrrolo[2,3-d]pyrimidin-7-yl)cyclopentane-1,2-diol monophosphate hydrate, and to compositions and therapeutic uses thereof.

Abstract: An ultrasound imaging system according to the present disclosure may include an ultrasound probe, a display unit, and a processor configured to receive source image data having a first dynamic range, wherein the source image data comprises log compressed echo intensity values based on the ultrasound echoes detected by the ultrasound probe, generate a histogram of at least a portion of source image data, generate a cumulative density function for the histogram, receive an indication of at least two points on the cumulative density function (CDF), and cause the display unit to display an ultrasound image representative of the source image data displayed in accordance with the second dynamic range.

Abstract: An ultrasound imaging system includes an intraluminal ultrasound device configured to be positioned within a body lumen of a patient. The intraluminal ultrasound device includes a transducer array disposed along a distal portion of a flexible elongate member. The transducer array includes an aperture and is configured to obtain imaging data along one or more imaging planes. The system also includes a processor in communication with the transducer array. The processor is configured to: receive first imaging data from the transducer array along a first imaging plane at a first angular position with respect to an axial direction of the aperture; output, to a display device in communication with the processor, the first imaging data; and output, to the display device, a visual representation of the first angular position of the first imaging plane with respect to the axial direction of the aperture.

Abstract: A weatherproof television cover of pliable material having a rear side and upper and lower flaps and at least one air vent cover. Adhesive material associated with the upper and lower flaps securely encloses and fastens the weatherproof television cover around a television and accompanying arm of various television wall mounts.

Abstract: An intraluminal imaging device is provided. In one embodiment, the imaging device includes a flexible elongate member having a distal portion and a proximal portion. The flexible elongate member can be positioned within a vessel. The imaging device an imaging assembly that can be mounted within the distal portion. The imaging assembly includes a side-looking array of imaging elements and a micro-beamformer IC that is coupled to the side-looking array of imaging elements. The micro-beamformer IC can control the array of imaging elements, can determine a first angle and a second angle, and can perform beam forming for the array of imaging elements. The micro-beamformer IC can receive the first imaging signals associated with a first plane (410) at the first angle (+45°), and the second imaging signals associated with a second plane (420) at the second angle(?45°). In some embodiments, the first and second angles are selected to satisfy predetermined criteria.

Abstract: An ultrasound imaging system according to the present disclosure may include an ultrasound probe, a display unit, and a processor configured to receive source image data having a first dynamic range, wherein the source image data comprises log compressed echo intensity values based on the ultrasound echoes detected by the ultrasound probe, generate a histogram of at least a portion of source image data, generate a cumulative density function for the histogram, receive an indication of at least two points on the cumulative density function (CDF), and cause the display unit to display an ultrasound image representative of the source image data displayed in accordance with the second dynamic range.

Abstract: An ultrasound imaging system has an improved dynamic range control which enables a user to reduce image haze with substantially no effect on bright tissue in the image and without increasing speckle variance. A dynamic range processor processes an input image to produce an approximation image which is a spatially low pass filtered version of the input image. The dynamic range of the approximation image is compressed, and image detail, unaffected by the compression, is added back to produce a dynamically compressed image for display.

Abstract: A system, as an engine with a crankcase containing oil or a fluid mixed with oil, has a reservoir containing liquid that extends up to a level of the fluid. A dipstick support structure supports a dipstick on it so that the dipstick extends into the fluid past the level of the fluid, and so that the dipstick is manually removable from the dipstick support structure by a user. An electrical system is connected with the dipstick, and the electrical system electrically senses the level of the fluid based on an electrical characteristic of the dipstick that varies with the varying level of the fluid when the dipstick extends into it. The electrical characteristic may be capacitance of the dipstick detected by sequential charging and discharging of the dipstick to produce a square wave electrical signal the frequency of which corresponds to the level of fluid.

Abstract: A spectral Doppler processor for an ultrasound system produces blood flow velocity estimates by processing a sequence of complex blood flow echo samples with an FFT algorithm. The FFT algorithm is executed with a long window of samples to produce velocity estimates with good velocity precision and is executed with a short window of samples to produce velocity estimates with good time precision. The long window algorithm is used when blood flow velocity is not changing rapidly, and the short window algorithm is used when blood flow velocity is changing rapidly.