Abstract: A system for detecting a characteristic of a fluid. In one example, the system includes a tube, a float, a sensor, and a controller. The tube is configured to receive the fluid. The float is located within the tube. The sensor is configured to sense a position of the float. The controller is configured to receive, from the sensor, the position of the float, and determine a characteristic of the fluid based on the position of the float. The characteristic may be a density or a concentration.

Abstract: A fluid sensor including a guide, a float, a permanent magnet, and a magnetic angle sensor. In one example, the float is constrained at least in part by the guide to move along a vertical axis. The permanent magnet is mechanically coupled to the float. The magnetic angle sensor is configured to measure an angle of a magnetic field generated by the permanent magnet and is positioned such that movement of the float along the vertical axis varies the angle of the magnetic field generated by the permanent magnet through the magnetic angle sensor.

Abstract: A magnetic proximity sensor includes first and second spaced wings. Each wing has a protrusion extending outwardly from an edge near or at a corner thereof. The protrusions face each other to provide a narrow gap area. A magnetic assembly secured to each of the wings extends across the gap and is spaced from the protrusions. A magnetic sensor element is disposed at the narrow gap area. The magnetic assembly projects magnetic flux toward the first wing. Magnetic flux passes via the first wing and the protrusion thereof and crosses the narrow gap area to the protrusion of the second wing. The second wing provides a return path for magnetic flux to the magnetic assembly. The magnetic proximity sensor senses decreased magnetic flux when a target approaches.

Abstract: A dual mode R.F./IR seeker suitable for use in an anti-radiation missile is disclosed. The infrared sensor is responsive to radiation within the 4.0 to 4.8 micron band and the radio frequency sensor is responsive to radio frequency signals within a 6.5 to 16.5 GHz band. The infrared sensor comprises a folded Cassegrainian telescope arrangement, including a primary mirror which is transparent to radio frequency energy. The radio frequency sensor comprises an annular array of orthogonally disposed stripline flared notch radiating elements. A broadband microwave receiver, fabricated in a multilayered stripline package, is provided for forming radio frequency monopulse sum (?) and difference (?) signals and for converting such radio frequency monopulse signals to suitable intermediate frequency signals for processing in an I.F. receiver. The infrared and radio frequency sensors share a common aperture and optical axis.

Abstract: A fluid sensor including a guide, a float, a permanent magnet, and a magnetic angle sensor. In one example, the float is constrained at least in part by the guide to move along a vertical axis. The permanent magnet is mechanically coupled to the float. The magnetic angle sensor is configured to measure an angle of a magnetic field generated by the permanent magnet and is positioned such that movement of the float along the vertical axis varies the angle of the magnetic field generated by the permanent magnet through the magnetic angle sensor.

Abstract: A system for detecting a characteristic of a fluid. In one example, the system includes a tube, a float, a sensor, and a controller. The tube is configured to receive the fluid. The float is located within the tube. The sensor is configured to sense a position of the float. The controller is configured to receive, from the sensor, the position of the float, and determine a characteristic of the fluid based on the position of the float. The characteristic may be a density or a concentration.

Abstract: A magnetic proximity sensor includes first and second spaced wings. Each wing has a protrusion extending outwardly from an edge near or at a corner thereof. The protrusions face each other to provide a narrow gap area. A magnetic assembly secured to each of the wings extends across the gap and is spaced from the protrusions. A magnetic sensor element is disposed at the narrow gap area. The magnetic assembly projects magnetic flux toward the first wing. Magnetic flux passes via the first wing and the protrusion thereof and crosses the narrow gap area to the protrusion of the second wing. The second wing provides a return path for magnetic flux to the magnetic assembly. The magnetic proximity sensor senses decreased magnetic flux when a target approaches.

Abstract: Aspects of the disclosure provide a method for crowd segmentation that can globally optimize crowd segmentation of an input image based on local information of the input image. The method can include receiving an input image of a site, initializing a plurality of hypothesis based on the input image, dividing the input image into a plurality of patches, calculating an affinity measure of one or more patches to a hypothesis based on a partial response of the patches to a whole body classifier of the hypothesis that includes a combination of weak classifiers, and optimizing assignments of the plurality of patches to the plurality of hypothesis based on the affinity measures of the plurality of patches to the plurality of hypothesis.

Abstract: Aspects of the disclosure provide a method for crowd segmentation that can globally optimize crowd segmentation of an input image based on local information of the input image. The method can include receiving an input image of a site, initializing a plurality of hypothesis based on the input image, dividing the input image into a plurality of patches, calculating an affinity measure of one or more patches to a hypothesis based on a partial response of the patches to a whole body classifier of the hypothesis that includes a combination of weak classifiers, and optimizing assignments of the plurality of patches to the plurality of hypothesis based on the affinity measures of the plurality of patches to the plurality of hypothesis.

Abstract: A disposable shield for stethoscope heads, preventing the transfer of disease or other contaminants by repeated use of the stethoscope. The shield or envelope is formed from a single piece of plastic material in which the sides are folded toward each other, thereby defining two top portions overlying a bottom portion. The edges are sealed as by heat sealing, thereby defining an envelope or shield. In a preferred embodiment, the shields are formed and maintained in a ribbon or array, maintained in the form of a roll within a container or the like. Adjoining shields are interconnected at the heat sealed areas which may be perforated for ease of separation.

Abstract: Suction device for use with a tracheostomy tube to remove matter from the upper respiratory tract of a patient. The suction device is essentially tubular and open at both ends, and comprises a bulb near one end and a tubular portion which extends from the bulb to the other end. To use, one connects the end remote from the bulb to a source of vacuum and inserts the bulbous end of the suction device into the end of a tracheostomy tube which is outside the patient's body. The suction device can be used with tracheostomy tubes of different sizes, and is used in place of a catheter.