Abstract: One or more radar sensors can be used to monitor patients in a variety of different environments and embodiments. In one embodiment, radar sensors can be used to monitor a patient's breathing, including monitoring of tidal volume, chest expansion distance, breathing rate, etc. In another embodiment, a patient position can be monitored in a patient bed, which can be used as feedback for control of bladders of a patient bed. Additional embodiments are described herein.

Abstract: A movement detection device includes a signal transmission device configured to transmit a radar signal transmission toward a target area and to receive reflected radar signals, and a signal analysis device configured to analyze the reflected radar signals to detect a movement in the target area that is indicative of micro-shivering. In response to detecting the micro-shivering, the movement detection device generates an alarm.

Abstract: One or more radar sensors can be used to monitor patients in a variety of different environments and embodiments. In one embodiment, radar sensors can be used to monitor a patient's breathing, including monitoring of tidal volume, chest expansion distance, breathing rate, etc. In another embodiment, a patient position can be monitored in a patient bed, which can be used as feedback for control of bladders of a patient bed. Additional embodiments are described herein.

Abstract: Systems and methods include a medical device that matches an identifier received over its optical channel and associated with a control device within a line-of-sight of the medical device with an identifier received over its wireless channel and that automatically pairs with the control device associated with the matching identifier over its wireless channel, as well as, a control device that matches an identifier received over its optical channel and associated with a medical device within a line-of-sight of the control device with an identifier received over its wireless channel and that automatically pairs with the medical device associated with the matching identifier over its wireless channel, as well as, a first device and a second device that automatically pair over a wireless channel based on a location identifier received over an optical channel from a transmitter within a line-of-sight of the first device and the second device.

Abstract: A patient support apparatus includes a support surface including a topper. An opening is formed in a side of the support surface. A cavity extends from the opening into the support surface. An inlet port is positioned within the cavity and fluidly coupled to the topper. A pneumatic blower is configured to removably position within the cavity and has an outlet port that couples to the inlet port.

Abstract: A patient support apparatus may include a support surface configured to conduct air along a top face of the support surface so that heat and moisture from a patient lying on the support surface are drawn away from the top face of the support surface. An opening may be formed in a side of the support surface. A cavity may extend from the opening into the support surface. An inlet port may be positioned within the cavity and fluidly coupled to the top face. A blower assembly may be configured to position within the cavity. The blower assembly may have an outlet port that couples to the inlet port when the blower assembly is positioned within the cavity. The blower assembly may conduct air through the inlet port to the top face of the support surface.

Abstract: A time-based wireless pairing operation between a medical device, such as a patient bed, and a wall module in a patient room is initiated in response to a power plug of the medical device being plugged into a power receptacle carried by the wall module. Times determined by timers of the medical device and the wall module are compared by the wall module or by the medical device so that wireless pairing occurs only with the medical device that was plugged into the wall module. Different types of plug detectors used in the wall module to detect connection of the power plug include optical detectors, mechanical switches, and current sensors.

Abstract: Systems and methods include a medical device that matches an identifier received over its optical channel and associated with a control device within a line-of-sight of the medical device with an identifier received over its wireless channel and that automatically pairs with the control device associated with the matching identifier over its wireless channel, as well as, a control device that matches an identifier received over its optical channel and associated with a medical device within a line-of-sight of the control device with an identifier received over its wireless channel and that automatically pairs with the medical device associated with the matching identifier over its wireless channel, as well as, a first device and a second device that automatically pair over a wireless channel based on a location identifier received over an optical channel from a transmitter within a line-of-sight of the first device and the second device.

Abstract: Systems and methods include a medical device that matches an identifier received over its optical channel and associated with a control device within a line-of-sight of the medical device with an identifier received over its wireless channel and that automatically pairs with the control device associated with the matching identifier over its wireless channel, as well as, a control device that matches an identifier received over its optical channel and associated with a medical device within a line-of-sight of the control device with an identifier received over its wireless channel and that automatically pairs with the medical device associated with the matching identifier over its wireless channel, as well as, a first device and a second device that automatically pair over a wireless channel based on a location identifier received over an optical channel from a transmitter within a line-of-sight of the first device and the second device.

Abstract: One or more radar sensors can be used to monitor patients in a variety of different environments and embodiments. In one embodiment, radar sensors can be used to monitor a patient's movement, including movement in a patient bed and around a room. In another embodiment, a patient position can be monitored in a patient bed, which can be used as feedback for control of bladders of a patient bed. Additional embodiments are described herein.

Abstract: One or more radar sensors can be used to monitor patients in a variety of different environments and embodiments. In one embodiment, radar sensors can be used to monitor a patient's breathing, including monitoring of tidal volume, chest expansion distance, breathing rate, etc. In another embodiment, a patient position can be monitored in a patient bed, which can be used as feedback for control of bladders of a patient bed. Additional embodiments are described herein.

Abstract: A movement detection device includes a signal transmission device configured to transmit a radar signal transmission toward a target area and to receive reflected radar signals, and a signal analysis device configured to analyze the reflected radar signals to detect a movement in the target area that is indicative of micro-shivering. In response to detecting the micro-shivering, the movement detection device generates an alarm.

Abstract: Systems and methods include a medical device that matches an identifier received over its optical channel and associated with a control device within a line-of-sight of the medical device with an identifier received over its wireless channel and that automatically pairs with the control device associated with the matching identifier over its wireless channel, as well as, a control device that matches an identifier received over its optical channel and associated with a medical device within a line-of-sight of the control device with an identifier received over its wireless channel and that automatically pairs with the medical device associated with the matching identifier over its wireless channel, as well as, a first device and a second device that automatically pair over a wireless channel based on a location identifier received over an optical channel from a transmitter within a line-of-sight of the first device and the second device.

Abstract: Lift communications systems, wall-mounted controls, and methods of using and configuring the same are disclosed. A lift communications system includes one or more lifts, each one of the one or more lifts is movable within a space. The lift communications system further includes a wall-mounted control coupled to a wall of the space. The wall-mounted control is configured to communicatively couple to the one or more lifts via a wireless connection. When the wall-mounted control is communicatively coupled to a lift of the one or more lifts, the wall-mounted control is configured to direct operation of the lift and receive data from the lift.

Abstract: A patient support apparatus may include a support surface configured to conduct air along a top face of the support surface so that heat and moisture from a patient lying on the support surface are drawn away from the top face of the support surface. An opening may be formed in a side of the support surface. A cavity may extend from the opening into the support surface. An inlet port may be positioned within the cavity and fluidly coupled to the top face. A blower assembly may be configured to position within the cavity. The blower assembly may have an outlet port that couples to the inlet port when the blower assembly is positioned within the cavity. The blower assembly may conduct air through the inlet port to the top face of the support surface.

Abstract: A method for triggering a pause event in a turn and hold operation applied to a mattress replacement system of a person support apparatus may include inflating at least one air bladder in only one of a right side portion and a left side portion of the mattress replacement system; detecting, automatically with at least one sensor, a force applied to at least one of a frame of the personal support apparatus and the at least one air bladder as the at least one air bladder is inflated; determining, automatically with a microcontroller communicatively coupled to the at least one sensor, if the force applied has a force duration that is greater than a threshold force duration to trigger the pause event; and discontinuing inflation of the at least one air bladder when the pause event is triggered.

Abstract: A patient support apparatus comprises a fluidization therapy bed. The fluidization therapy bed includes a fluidization space and a fluidizable medium positioned in the fluidization space. The patient support apparatus receives a flow of pressurized air from an air supply that fluidizes the fluidizable medium to provide an air fluidized therapy to a patient supported on the patient support apparatus.

Abstract: A method for triggering a pause event in a turn and hold operation applied to a mattress replacement system of a person support apparatus may include inflating at least one air bladder in only one of a right side portion and a left side portion of the mattress replacement system; detecting, automatically with at least one sensor, a force applied to at least one of a frame of the personal support apparatus and the at least one air bladder as the at least one air bladder is inflated; determining, automatically with a microcontroller communicatively coupled to the at least one sensor, if the force applied has a force duration that is greater than a threshold force duration to trigger the pause event; and discontinuing inflation of the at least one air bladder when the pause event is triggered.

Abstract: A patient support apparatus includes load cells and a controller operable to automatically update a weight offset for use in determining a true patient weight. The controller is configured to receive signals produced by the load cells, determine whether a patient is being supported by a patient support surface of the patient support apparatus, detect movement on the patient support surface, determine a weight of the patient being supported on the patient support surface, determine whether a patient is no longer being supported by the patient support surface, and update a weight offset.

Abstract: A pressure sensing pad or mat comprises a piezoresistive layer, a top electrically conductive layer comprising a plurality of electrically conductive top strips extending in a first direction along one side of the piezoresistive layer, a bottom electrically conductive layer comprising a plurality of electrically conductive bottom strips extending in a second direction, nonparallel to the first direction, along the other side of the piezoresistive layer, and top and bottom adhesive layers holding the top and bottom strips against the piezoresistive layer so as to inhibit relative displacement of the strips relative to the piezoresistive layer and relative to each other. Also disclosed are a method of manufacturing the pressure sensor pad, a pressure sensing system that employs the a sensor mat, and a pressure map display for displaying a pressure distribution of an object resting on the pressure sensing mat.