Disclosed is a method for remote presence detection and remote behavioral analysis of an individual in a living area, including furnishing detection data by a presence detection unit during the detection of the individual in at least one detection zone covered by the detection unit, the transmission of data by the detection unit to an electronic data acquisition module, remote sending of data, from the electronic data acquisition module via a communication unit, to a remote data processing unit for automatically generating at least one piece of information, with the remote data processing unit being associated with at least one software application that can automatically generate one or more pieces of information relative to the fall of an individual from a standing, seated or lying-down position, and/or relative to the behavior of an individual in the detection zone or zones in particular to deduce therefrom one or more behavioral anomalies.

A protective hood for individuals positioned in hazard areas is provided that comprises a constant hood structure having an opening, wherein the hood structure is configured to accommodate a portion of a bed that partially protrudes through the opening; a closing board outwardly connected to the hood structure and positioned opposite the opening; and a movable portion sleeved juxtaposed to the constant structure, wherein the movable portion is configured to move relative to the constant structure so as to elongate the constant structure from a first position in which the movable portion is fully adjacent to the constant structure and a second position in which the movable portion is extended outwardly beyond the opening so as to cling to the closing board and form a protected and secure inner space.

The disclosure generally relates to an adjustable bed, in particular incorporating improved power management systems. In various embodiments, an adjustable bed can include a wirelessly chargeable remote control unit, one or more pulse width modulator units to provide DC power at a variety of voltages appropriate for varied peripheral electrical components of the bed, and/or a battery backup unit providing power to the bed in addition to a mains power input. The various power management systems can reduce wire clutter for peripheral electrical components, permit a wider range of peripheral electrical components to be driven by a single power supply, provide for adjustable bed operation in the absence of mains power supply, and reduce power consumption in different operation modes.

There is disclosed a portably suspended retractable shelf for storing furniture-side items that includes a horizontal platform having an inner portion and an outer portion. In various embodiments, the inner portion is adapted to be slidably captured between an upper cushion and a lower supporting structure. At least one of a projector insert rotationally adjustable to a plurality of orientations and the following upward-facing compartments is disposed on the outer portion of the horizontal platform and is accessible to a user on the furniture: a collapsible basin, a hanging flexible pocket, and a foldable box. A cutout hole is configured to hold the projector insert or the compartments in a suspended configuration through the shelf. A downward-facing sliding drawer compartment is mounted and/or supported underneath the outer portion of the shelf. A storage container extends from a leading surface of the portable suspended retractable shelf. Other embodiments are also disclosed.

Disclosed herein is an apparatus to block off a space under a bed frame, the apparatus comprising a longitudinal member configured to fill a gap between a floor and a lower edge of the elongated portion of the bed frame, the first end of the longitudinal member being removably connected to the first leg of the bed frame by a first connector, and the second end of the longitudinal member being removably connected to the second leg of the bed frame by a second connector. Corresponding systems and methods also are disclosed.

The present invention provides systems and methods for management and orchestration of a fleet of remote Internet-of-Things (IoT) devices. The present invention includes a platform for onboarding, provisioning, and managing remote IoT devices throughout their lifetime. The platform includes portals for manufacturers, vendors, and consumers to access device data and sensor data collected by the devices. The data collected by the portal is used to control the fleet of remote IoT devices as well as make recommendations, e.g., for sleep promotion and stress reduction.

A headboard structure includes a backboard mounted on a headboard frame, a sponge cushion on the backboard, and a headboard covering on the sponge cushion. The sponge cushion is formed with at least one groove. The groove is provided with an LED light and a sponge strip in front of the LED light. The headboard covering has a light-pervious area corresponding in position to the LED light. The headboard provided with the LED light has a lighting effect, and the user can lean against the headboard comfortably, thereby improving the function of the headboard.

Described herein are multifunctional smart beds and methods of operating thereof. Specifically, a multifunctional smart bed comprises a controller, configured to receive input from various sensors (e.g., load cells positioned in bed legs, thermometers, and/or microphones) and/or user. These inputs are analyzed and used to control various bed components to improve the sleep quality, to monitor users' health, score couple's relationship, and the like. For example, these inputs may be used to control the firmness of different mattress portions, change orientations of the head, torso, and/or leg sections, adjust the light, and the like. In some examples, the smart bed generates a report indicating one or more sleep duration, sleep depth profile, sleep scope, heart rate, breath rate, environment conditions, couple's relationship, and the like. Furthermore, in some examples, a multifunctional smart bed is also configured to control external devices in the same environment, e.g., smart switches, smart thermostats.

A charging device for providing power from a power supply to an electronic device is provided. The charging device includes a detachable first electrical connector connected to a wired or wireless power output port, and a detachable second electrical connector attached to the power supply. The power output port is configured to provide power to the electronic device when the first electrical connector is connected to the power supply.

The present disclosure illustrates a motorized mount with a plurality of degrees of freedom coupled to a seating system. The motorized mount assembly can include an attachment assembly configured to attach to a seating assembly. A vertical control assembly can be connected to the attachment assembly with an arm having a first end attached to vertical control assembly by a first hinge. A mounting assembly can be attached to a second end of the arm. The mounting assembly can configured to receive a personal computing device. A linear actuator may be attached to the vertical control assembly to raise and lower the arm and mounting assembly. A first motor can be configured to attach to the arm. A second motor can be configured to attach between the arm and the mounting assembly.