A sport chair includes a seating surface operative to support a user and a processor. The processor is configured to detect the presence of a user on the seating surface, establish communication with an article of apparel on the body of the user, receive an indication of a physiological parameter of the user from a biometric sensor provided with the article of apparel, and output the physiological parameter to a display.

A sport chair includes a seating surface operative to support a user and a processor. The processor is configured to detect the presence of a user on the seating surface, establish communication with an article of apparel on the body of the user, receive an indication of a physiological parameter of the user from a biometric sensor provided with the article of apparel, and output the physiological parameter to a display.

A mobility assistance apparatus includes first and second frames positioned on left and right sides of a user; a hinge arm mechanism coupled to the first and second frames; and a pivotable securing unit or a walking seat coupled to the frames to transfer at least a portion of the user's body weight from the legs and to transfer weight through the user's hip or pelvis to the first and second frame enabling the user to stand or work for an extended period without requiring the user's arms to hold the frame.

A mobility assistance apparatus includes first and second frames positioned on left and right sides of a user; a hinge arm mechanism coupled to the first and second frames; and a pivotable securing unit or a walking seat coupled to the frames to transfer at least a portion of the user's body weight from the legs and to transfer weight through the user's hip or pelvis to the first and second frame enabling the user to stand or work for an extended period without requiring the user's arms to hold the frame.

An apparatus and method are provided for imparting a repetitive motion to a user. The apparatus may include one or more seat platforms and one or more backrests. Repeated motion of the pelvis and shoulders of the user may be contra lateral. The motions of the user may mimic walking. The apparatus may include a chair. The apparatus may include a sensor. The sensor may be used to control the apparatus and/or the sensor may be used to adjust the movement regime according to the user. The apparatus may help for example, to mobilize limited mobility users and/or to train healthier habits.

Systems and methods for predicting emotional state, behavioral state, or mood of a subject including a non-contacting physiologic sensing apparatus, as well as, possibly, an image capture sensor or a microphone, which may be incorporated into an article of furniture, for detecting parameters indicative of emotional state of a non-recumbent subject.

Systems and methods for predicting emotional state, behavioral state, or mood of a subject including a non-contacting physiologic sensing apparatus, as well as, possibly, an image capture sensor or a microphone, which may be incorporated into an article of furniture, for detecting parameters indicative of emotional state of a non-recumbent subject.

A computer cockpit including a cockpit body, a driving module, a sensing module and a controlling module. The cockpit body includes a seat, a backrest and a display interface all movably disposed on the cockpit body. The display interface and the backrest are respectively located at two opposite sides of the seat. The driving module and the sensing module are disposed to the cockpit body, and the sensing module is configured to provide sensing data. The sensing data includes a seat pressure sensing value and a backrest pressure sensing value. The controlling module is electrically connected to the driving module and the sensing module, and configured to send an adjusting command according to the sensing data. The driving module is configured to receive the adjusting command to synchronously rotate the seat, the backrest and the display interface to a working angle and reduce a difference between the backrest pressure sensing value and the seat pressure sensing value.

A computer cockpit including a cockpit body, a driving module, a sensing module and a controlling module. The cockpit body includes a seat, a backrest and a display interface all movably disposed on the cockpit body. The display interface and the backrest are respectively located at two opposite sides of the seat. The driving module and the sensing module are disposed to the cockpit body, and the sensing module is configured to provide sensing data. The sensing data includes a seat pressure sensing value and a backrest pressure sensing value. The controlling module is electrically connected to the driving module and the sensing module, and configured to send an adjusting command according to the sensing data. The driving module is configured to receive the adjusting command to synchronously rotate the seat, the backrest and the display interface to a working angle and reduce a difference between the backrest pressure sensing value and the seat pressure sensing value.

A seating assembly for athletes includes seats having a back and seat portion, a base, an adjustable element, a user interface device, and a controller. The back portion includes a back heating member that provides heat to a user's torso. The seat portion includes a lower limb heating member that provides heat to the user's lower limbs. The base supports each seat. The adjustable element is coupled to the base and one of the seats and adjusts height of the seat. The user interface device receives an input regarding a desired temperature of the back heating member and the lower limb heating member. The controller receives the input and adjusts an operation of the back heating member and the lower limb heating member to achieve the desired temperature. The user interface device receives a second input to adjust the a height of the seat relative to the floor surface.