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.

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.

A bedding system uses a convolutional neural network (CNN)-based machine vision to makes adjustments for comfort and/or support. The machine vision process identities a body position by using a trained CNN that receives a pressure image and identifies a body position. The body position may be determined by classifying the pressure image into a predetermined body position classification. The machine vision process includes at least one trained CNN that determines joint locations. The machine vision tracks pressure accumulated at joints over time.

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.

An intelligent bed monitoring system and device are provided in this disclosure. The system is applied to a bed frame, and the bed frame includes a bed board. The intelligent bed monitoring system includes a first server, an intelligent bed monitoring device and an electronic device. The intelligent bed monitoring device is communicated with the first server and the electronic device. The intelligent bed monitoring device further includes a pressure sensor, a processor, and a controlling module. The processor is electrically connected with the pressure sensor and the controlling module. The pressure sensor is configured to detect a vibration signal. The processor is configured to generate a physiological information according to the vibration signal, and transmit the physiological information to the first server via a communication interface. The controlling module is configured to control the bed board to adjust the bed board into a plurality of modes.

A decorative bed leg cover for a bed frame and at least one perpendicularly and downwardly-extending bed leg that is disposed in a substantially vertical position, the bed leg cover having a visually pleasing aesthetic appearance together with a substantially vertically-disposed aperture disposed within the bed leg cover body for receiving the bed leg within the bed leg cover body. The bed leg cover also includes a bed leg cover sidewall, a recess defined within the bed leg cover sidewall, and a light/sensor housing that is removably disposed within the recess of the bed leg cover sidewall, the light/sensor housing comprising circuitry between a proximity sensor and a light-emitting device.

This disclosure concerns a handheld wireless remote control in communication with a cellular network infrastructure that is adapted to transmit adjustable bed control signals to an adjustable bed controller via one of a standard wireless connection, RF, Bluetooth or WiFi in response to the user input. The remote control can receive, on the touch screen, feedback from the adjustable bed controller indicating the success of the control signal.

A wraparound inflatable headboard apparatus (100) includes a headboard portion (104), first and second arms (106, 108), and a plurality of accessories (138, 140,142, 144, 148), wherein the headboard portion (104) and the first and second arms (106, 108) are configured to accommodate plurality of accessories (138, 140,142, 144, 148), at least one of which is fixedly attached to the at least one of the headboard portion (104), the first arm (106), and the second arm (108), and at least one of which is removable from the at least one of the headboard portion (104), the first arm (106), and the second arm (108). An inflatable bed system (122) includes an inflatable headboard apparatus (100) comprised of a headboard (104), arms (106, 108), an inflatable mattress (102), and at least one accessory (138, 140,142, 144, 148), wherein the headboard (104) and arms (106, 108) are configured in a bracket shape, the inflatable mattress (102) comprises a shape complementary to the bracket shape of the headboard (104) and arms (106, 108) such that the inflatable headboard apparatus (100) at least partially surrounds the inflatable mattress (102), and the at least one accessory (138, 140,142, 144, 148) is supplied proximal to a user when the inflatable headboard apparatus (100) is arranged about the inflatable mattress (102).

The present invention provides a sleeping apparatus which can improve the quality of sleep, by evaluating the quality of human sleep and presenting the control methods of the exercise forcing means based on the evaluation result. The sleeping apparatus comprises a body support part which supports the user's body, a sleep information detection means which detects said user's sleep information, and a memory part which stores said user's sleep information, wherein the sleeping apparatus comprises an exercise forcing means which forces said user's body to exercise, a sleep state evaluation means which evaluates said user's sleep state based on said user's sleep information, and a control means which can output control methods of said exercise forcing means based on the evaluation result from said sleep state evaluation means.

An enclosure for installation on a bed. The enclosure includes an enclosure-frame, an attachment-bracket, a foldable-board and a canopy. In some embodiments, the enclosure includes a power-supply, vents, fans, speakers and lights. The enclosure is useful for providing a user with a peaceful night sleep by preventing external noises and light from disrupting the user.