Various systems and methods relate to an adaptive chair system having (i) a stowed mode in which the members of the chair frame are contained within a compact flexible multi-function bag (MFB), and (ii) a deployed mode in which the MFB is adapted to releasably couple to an arm of the chair to provide a multipurpose accessory chamber. In an illustrative example, the MFB may, for example, fold in on itself in an accessory mode. The MFB may provide various utilities for hikers, for example, by providing a case to receive an inflatable bladder so as to form a pillow. The MFB may receive a thermal liner adapted to maintain, for example, food or beverage temperature. Various embodiments may advantageously provide a rugged, water resistant MFB system in an ultralight form factor that serves as a multipurpose accessory (e.g., to store items), yet provides a compact, adaptive chair frame containment.

A seat system includes a seat including a sensor configured to acquire information for detection of a motion of an occupant seated on a seat body, a terminal device configured to acquire the information from the sensor, and a server capable of communicating with the terminal device. The terminal device executes a game using the sensor based on the information, and acquires an execution result corresponding to the occupant for a game played by the occupant. The server generates integrated data by integrating execution results of the game acquired from another terminal device, and computes a reference value for execution results of the game based on the integrated data. The terminal device or the server assigns a difficulty level of the game for the terminal device based on the execution result corresponding to the occupant and the reference value. The terminal device reflects the difficulty level on the game.

A force or pressure sensing device comprises one or more magnets resiliently held spaced from one or more magnetic sensors such that pressure on the device displaces the magnets relative to the magnetic field sensors. The device may be incorporated into an insole of a shoe, or integrated into a shoe, or integrated into a seat, cushion, mattress or saddle. The device includes one or more magnetic focussing elements on the opposite side of the magnetic field sensor from the magnets to focus and condition the magnetic field passing through the sensor. The magnetic focussing elements may be permanent magnets or magnetic materials having a high magnetic permeability such as mu-metals. Additional magnetic focussing elements may be placed adjacent to the magnets. Plural magnetic field sensors can be arranged in a symmetrical arrangement in a plane below the one or more magnets so that shear forces applied to the device causes lateral relative displacement of the magnet and magnetic field sensors changing the magnetic field sensed by the magnetic field sensors. The device can also include a motion detector such as an accelerometer which may be integral with the magnetic field sensor.

A force or pressure sensing device comprises one or more magnets resiliently held spaced from one or more magnetic sensors such that pressure on the device displaces the magnets relative to the magnetic field sensors. The device may be incorporated into an insole of a shoe, or integrated into a shoe, or integrated into a seat, cushion, mattress or saddle. The device includes one or more magnetic focussing elements on the opposite side of the magnetic field sensor from the magnets to focus and condition the magnetic field passing through the sensor. The magnetic focussing elements may be permanent magnets or magnetic materials having a high magnetic permeability such as mu-metals. Additional magnetic focussing elements may be placed adjacent to the magnets. Plural magnetic field sensors can be arranged in a symmetrical arrangement in a plane below the one or more magnets so that shear forces applied to the device causes lateral relative displacement of the magnet and magnetic field sensors changing the magnetic field sensed by the magnetic field sensors. The device can also include a motion detector such as an accelerometer which may be integral with the magnetic field sensor.

A work chair includes a chair body, a plurality of wheel sets mounted at the bottom side of the chair body, a seat cushion mounted at the top side of the peripheral wall of the chair body, two guide rails mounted at the chair body at one lateral side each defining a longitudinal sliding slot and locating notch in communication with the sliding slot, a tray, a pivot bolt pivotally connecting the tray to the sliding slots of the rail for allowing the tray to be moved along the sliding slots of the guide rails and having an engagement portion for selectively engaging in one locating notch of each guide rail to hold the tray positively at the selected elevational position for carrying tools.

A work chair includes a chair body, a plurality of wheel sets mounted at the bottom side of the chair body, a seat cushion mounted at the top side of the peripheral wall of the chair body, two guide rails mounted at the chair body at one lateral side each defining a longitudinal sliding slot and locating notch in communication with the sliding slot, a tray, a pivot bolt pivotally connecting the tray to the sliding slots of the rail for allowing the tray to be moved along the sliding slots of the guide rails and having an engagement portion for selectively engaging in one locating notch of each guide rail to hold the tray positively at the selected elevational position for carrying tools.

A furniture system includes an office productivity structure (OPS). The furniture system also includes a sensor coupled to the OPS, the sensor operable to detect occupancy of the OPS and generate an output signal indicative of the occupancy; and a processor coupled to the sensor. The processor is operable to receive the output signal generated by the sensor, determine, based on the output signal, that the OPS is occupied, and, in response to determining that the OPS is occupied, generate a command to initiate at least one action associated with the OPS or an operator of the OPS.

A furniture system includes an office productivity structure (OPS). The furniture system also includes a sensor coupled to the OPS, the sensor operable to detect occupancy of the OPS and generate an output signal indicative of the occupancy; and a processor coupled to the sensor. The processor is operable to receive the output signal generated by the sensor, determine, based on the output signal, that the OPS is occupied, and, in response to determining that the OPS is occupied, generate a command to initiate at least one action associated with the OPS or an operator of the OPS.

A seat cover for covering the seat portion of a chair in a public venue includes a shell that is flexible. The shell is waterproof and substantially rectangularly box shaped. The shell has a back, which is open. The back is positioned in the shell such that the shell is configured to substantially envelop the seat of a chair to prevent transfer of moisture and contaminants from the seat to a user.

A method of detecting and correcting a user's posture through use of a mobile posture-detection cushion for a chair or any other seating apparatus. The cushion contains individual support modules that actively monitor a user's current seated position and adjust the user to attain an optimum sitting posture in response to individual pressure sensors within the cushion, and provides user-specific feedback to each individual user over a period of time of use of the cushion.