Abstract: High-accuracy locating systems and methods are used for determining successful caregiver rounding, monitoring whether housekeepers have properly cleaned patient beds, or determining whether patients have ambulated sufficient distances during recovery. Patient beds having at least two locating tags are used for establishing patient care zones around the patient beds. Locating anchors and equipment tags are moved around a patient room to determine optimum locating anchor placement within the patient room based on signal quality values. A locating tag on a patient bed switches roles to operate as a locating anchor in response to the patient bed becoming stationary. A locating tag has a digital compass which is used to determine a field of good ranging relative to a front of a caregiver wearing the locating tag.

Abstract: A system and method for on-planter seed treatments is disclosed. The planter includes a seed meter, a seed drop tube, a seed, a seed-applied substance receptacle, and a seed-applied substance applicator having a discharge path. A seed-applied substance is loaded in the seed-applied substance receptacle. The seed-applied substance is supplied to the seed-applied substance applicator. The seed-applied substance is discharged from the seed-applied substance applicator into the discharge path during planting. The seed from the seed drop tube is combined with the seed-applied substance from the seed-applied substance applicator within the discharge path for prescriptively treating the seed with the seed applied substance. The seed having on it the seed applied substance is then planted.

Abstract: A shiftable backing feed is utilized with a tufting machine having reciprocating needles and gauge parts for seizing yarns at a plurality of fixed heights, wherein fabric support apparatus reciprocates in synchronization with the cycles of the needle bar to support the backing during penetration of the backing fabric yet allow backing shifts between stitches.

Abstract: A method for manufacturing a deflection member is disclosed. The method may include the step of incorporating a monomer, a photoinitiator system, a photoinhibitor, and/or a reinforcing member. A further step includes blending the monomer, photoinitiator, and/or photoinhibitor to form a blended photopolymer resin. Further steps may be exposing the photopolymer resin to radiation form a first radiation source and/or a second radiation source.

Abstract: An atomizer includes an atomizer body with a plurality of air passages defined therethrough from an upstream end of the atomizer body to a downstream end thereof. The air passages together define an air circuit through the atomizer body. A fuel circuit is defined in the atomizer body extending from a fuel inlet to a respective fuel outlet opening into each air passage. The air passages can be arranged circumferentially about a central axis defined by the atomizer body. The fuel circuit can include a manifold extending circumferentially about the atomizer body in fluid communication with a fuel opening in each respective air passage.

Abstract: Methods and systems are provided for recovering flight plan data for a bypassed segment of a flight plan aircraft. The method comprises loading an initial flight plan onto a Flight Management System (FMS) that is located on board the aircraft. The active flight plan includes multiple waypoints located along the active flight plan. A modified flight plan is created and executed that bypasses at least one of the waypoints located along the initial flight plan. The bypassed flight data is stored in the memory of the FMS. A restored flight plan is created later by retrieving the bypassed flight data from the FMS memory and loaded onto the FMS. The restored flight plan is then executed by the FMS.

Abstract: An exemplary depth capture system emits a first structured light pattern onto a surface of an object included in a real-world scene using a first structured light emitter included within the depth capture system. The depth capture system also emits, concurrently with the emitting of the first structured light pattern, a second structured light pattern onto the surface of the object using a second structured light emitter included within the depth capture system. The emitting of the second structured light pattern is different than the emitting of the first structured light pattern. The depth capture system detects the first and second structured light patterns using one or more optical sensors included within the depth capture system. Based on the detection of the structured light patterns, the depth capture system generates depth data representative of the surface of the object included in the real-world scene.

Abstract: An exemplary virtual reality media provider system differentiates static objects depicted in two-dimensional video data from dynamic objects depicted in the two-dimensional video data. Based on the differentiating of the static objects from the dynamic objects, the virtual reality media provider system generates dynamic volumetric models of the surfaces of the static objects and the dynamic objects. The virtual reality media provider system updates the dynamic volumetric models of the surfaces of the static objects with a lower regularity or on an as-needed basis, and the virtual reality media provider system separately updates the dynamic volumetric models of the surfaces of the dynamic objects with a higher regularity. The higher regularity is higher than the lower regularity and keeps the dynamic volumetric models of the surfaces of the dynamic objects up-to-date with what is occurring in the two-dimensional video data. Corresponding methods and systems are also disclosed.

Abstract: An exemplary virtual reality media provider system receives two-dimensional (“2D”) video data for surfaces of first and second objects located in a natural setting. The 2D video data is captured by first and second capture devices disposed at different positions with respect to the objects. The system distinguishes the first object from the second object by performing a plurality of techniques in combination with one another. The plurality of techniques include determining that the first object is moving in relation to the second object; and determining that, from a vantage point of at least one of the different positions, a representation of the first object captured within the 2D video data does not overlap with a representation of the second object. Based on the received 2D video data and the distinguishing of the first and second objects, the system generates an individually-manipulable volumetric model of the first object.

Abstract: An exemplary depth data generation system accesses first and second depth maps of a real-world scene, the depth maps independently captured using first and second depth map capture techniques, respectively. The first and second depth maps include, respectively, first and second depth data points both representative of a same physical point on a surface of an object in the real-world scene. Based on the first and second depth map capture techniques and based on an attribute of the surface of the object, the system assigns a first confidence value to the first depth data point and a second confidence value to the second depth data point. Based on the first and second confidence values, the system converges the first and second depth maps to form a converged depth map of the real-world scene that includes a third depth data point representing the physical point on the surface of the object.

Abstract: An exemplary depth scanning system includes first and second depth scanning devices disposed, respectively, at first and second locations on a boundary of a scan zone where segments of the boundary meet to form respective first and second angles that include the scan zone. The first device performs a first sequence of depth scanning operations where the first device detects depth data for surfaces included in the scan zone by sweeping a scan field across the first angle and in which the first device abstains from detecting depth data for surfaces outside the first angle. Concurrently, the second device performs a second sequence of depth scanning operations where the second device detects depth data for the surfaces in the scan zone by sweeping a scan field across the second angle and in which the second device abstains from detecting depth data for surfaces outside the second angle.

Abstract: A head up display arrangement is for a motor vehicle having a human driver. The arrangement includes a picture generation unit producing a light field. A light-reflective mirror reflects the light field such that the light field is visible to the driver as a virtual image. The mirror is transmissive of infrared energy. An infrared energy emitter emits infrared energy through the mirror such that the infrared energy is reflected off of a face of the driver. An infrared camera detects the reflected infrared energy after the reflected infrared energy passes through the mirror a second time.

Abstract: A method of operating a user interface for a vehicle system includes receiving, by a processor, a user input from an input device. The method further includes comparing, by the processor, the user input to a plurality of stored user commands stored within a command database. The plurality of stored user commands is configured for controlling the system of the vehicle. The method additionally includes identifying, by the processor, a predicted user command based on the comparison of the user input to the plurality of stored user commands. Moreover, the method includes outputting, by an output device, the predicted user command. Also, the method includes receiving, by the input device, a user selection of the predicted user command output by the output device. Furthermore, the method includes controlling, by a controller, the system of the vehicle according to the user selection of the predicted user command.

Abstract: An exemplary method includes a media player device (“device”) providing a user with an immersive virtual reality experience in accordance with a specification file corresponding to the immersive virtual reality experience. The specification file includes data that defines a plurality of elements included in the immersive virtual reality experience by providing a plurality of links for use by the device in acquiring the plurality of elements while providing the user with the immersive virtual reality experience. The method further includes the device detecting, while the immersive virtual reality experience is being provided to the user, real-world input associated with the user, and integrating the real-world input into the immersive virtual reality experience by updating the specification file to further include data that defines the real-world input as a user-specific element that is specific to the user and that is included in the immersive virtual reality experience.

Abstract: An exemplary depth scanning system includes first and second depth scanning devices. The first device detects depth data for surfaces included within a real-world scene from a first vantage point by rotating a first scan head in one rotational direction to progressively aim a first scan field to sweep across the surfaces during a scan time period. The second device detects depth data for the surfaces from a second vantage point by rotating a second scan head in phase with the rotation of the first scan head and in the opposite rotational direction so as to progressively aim a second scan field to sweep across the surfaces during the scan time period. The in-phase rotations of the first and second scan heads cause the first scan field to aim at the second vantage point at a same moment when the second scan field aims at the first vantage point.

Abstract: An exemplary virtual reality media provider system differentiates static objects depicted in two-dimensional video data from dynamic objects depicted in the two-dimensional video data. Based on the differentiating of the static objects from the dynamic objects, the virtual reality media provider system generates dynamic volumetric models of the surfaces of the static objects and the dynamic objects. The virtual reality media provider system updates the dynamic volumetric models of the surfaces of the static objects with a lower regularity or on an as-needed basis, and the virtual reality media provider system separately updates the dynamic volumetric models of the surfaces of the dynamic objects with a higher regularity. The higher regularity is higher than the lower regularity and keeps the dynamic volumetric models of the surfaces of the dynamic objects up-to-date with what is occurring in the two-dimensional video data. Corresponding methods and systems are also disclosed.

Abstract: An exemplary depth data generation system accesses first and second depth maps of a real-world scene, the depth maps independently captured using first and second depth map capture techniques, respectively. The first and second depth maps include, respectively, first and second depth data points both representative of a same physical point on a surface of an object in the real-world scene. Based on the first and second depth map capture techniques and based on an attribute of the surface of the object, the system assigns a first confidence value to the first depth data point and a second confidence value to the second depth data point. Based on the first and second confidence values, the system converges the first and second depth maps to form a converged depth map of the real-world scene that includes a third depth data point representing the physical point on the surface of the object.

Abstract: An exemplary virtual reality media provider system receives two-dimensional (“2D”) video data for surfaces of first and second objects located in a natural setting. The 2D video data is captured by first and second capture devices disposed at different positions with respect to the objects. The system distinguishes the first object from the second object by performing a plurality of techniques in combination with one another. The plurality of techniques include determining that the first object is moving in relation to the second object; and determining that, from a vantage point of at least one of the different positions, a representation of the first object captured within the 2D video data does not overlap with a representation of the second object. Based on the received 2D video data and the distinguishing of the first and second objects, the system generates an individually-manipulable volumetric model of the first object.

Abstract: An exemplary depth data generation system (“system”) accesses a first depth map and a second depth map of surfaces of objects included in a real-world scene. The first and second depth maps are captured independently from one another. The system converges the first and second depth maps into a converged depth map of the surfaces of the objects included in the real-world scene. More specifically, the converging comprises assigning a first confidence value to a first depth data point in the first depth map, assigning a second confidence value to a second depth data point in the second depth map, and generating a third depth data point representing a same particular physical point as the first and second depth data points based on the first and second confidence values and on at least one of the first depth data point and the second depth data point.

Abstract: An exemplary virtual reality media provider system (“system”) includes a configuration of synchronous video and depth capture devices disposed at fixed positions at a real-world event. In real time, the video and depth capture devices capture two-dimensional video data and depth data for surfaces of objects at the real-world event. The system generates a real-time volumetric data stream representative of a dynamic volumetric model of the surfaces of the objects at the real-world event in real time based on the captured two-dimensional video data and captured depth data. The dynamic volumetric model of the surfaces of the objects at the real-world event is configured to be used to generate virtual reality media content representative of the real-world event as experienced from a dynamically selectable viewpoint corresponding to an arbitrary location at the real-world event and selected by a user experiencing the real-world event using a media player device.