A human-computer interface system having an exoskeleton including a plurality of structural members coupled to one another by at least one articulation configured to apply a force to a body segment of a user, the exoskeleton comprising a body-borne portion and a point-of-use portion; the body-borne portion configured to be operatively coupled to the point-of-use portion; and at least one locomotor module including at least one actuator configured to actuate the at least one articulation, the at least one actuator being in operative communication with the exoskeleton.

Proposed is a rehabilitation exercise device for upper and lower limbs. The rehabilitation exercise device is characterized by including: a first support supporting a user's hand or foot; a second support supporting a user's forearm or calf; a pair of first hinges rotatably connecting the first support and the second support to each other; a third support supporting a user's upper arm or thigh; a pair of second hinges rotatably connecting the second support and the third support to each other; and a drive module selectively mounted on any one of the pair of first hinges and the pair of second hinges, and configured to pivot the first support or the second support.

A passive energy-storage exoskeleton for assisting elbow joint is provided, which includes an upper arm unit, a lower arm unit, and an elbow joint unit located therebetween, the upper arm unit is rotatably connected with the lower arm unit. The elbow joint unit includes an anti-gravity mechanism, a coil spring mechanism, and a lower-arm-unit self-locking mechanism. The anti-gravity mechanism generates an equilibrant moment to eliminate the influence of the weight of the arm of the user and the weight of the device on the elbow joint. The lower-arm-unit self-locking mechanism is configured for locking/releasing the lower arm unit at any specified angle of rotation. The coil spring mechanism is configured for capturing and storing kinetic energy generated by rotation and swing of the arm of the user and releasing the energy as required.

An assist garment is configured to be worn on a part of a human body and includes a plurality of garment-fitting actuators placed linearly along at least one end portion of a garment body and configured to be driven to extend and contract, a plurality of assisting actuators placed linearly on the garment body to cross the plurality of garment-fitting actuators and configured to be driven to extend and contract, and a controller configured to individually control driving of the plurality of assisting actuators and driving of the plurality of garment-fitting actuators.

A walking assist device has a frame, a pair of right and left arm portions, a pair of right and left grasp portions, wheels including a pair of right and left drive wheels, drive units, a battery, a drive control unit, acting force measurement units that measure acting forces on the grasp portions, and holding units that hold the grasp portions at a predetermined position in the front-rear direction of the arm portions set in advance. The walking assist device travels forward together with a user. The holding units generate a restoring force for returning the grasp portions to the predetermined position. The drive control unit controls the drive units on the basis of acting forces calculated on the basis of detection signals from the acting force measurement units.

A support device comprises a first band secured to a second band in a cross pattern. A proximal end of the first band and a proximal end of the second band can also be configured to fasten around a waist of a user. Further, a distal end of the first band can be configured to fasten around a first leg of the user, and a distal end of the second band can be configured to fasten around a second leg of the user. The support device may prevent improper and dangerous misalignment of the back, hips and knees while squatting.

A wire-driven wrist three-degree-freedom training mechanism comprises a wrist executing mechanism, a wrist linking mechanism, a forearm mechanism and an elbow linking mechanism, and adopts a wire-driven design, through comprehensive utilization of two rotation pairs in the training mechanism, wherein wrist three-degree-freedom passive training is realized through two driving motors. By way of the implementation of the wire-driven wrist three-degree-freedom training mechanism, a patient can adopt a passive training manner to perform rehabilitating training of the upper limbs. The wire-driven wrist three-degree-freedom training mechanism includes a position compensation mechanism and can be adapted to individual differences of patients.

A system and apparatus that performs a capture of human motion and location in order to relay the mechanics of joint and body movement to virtual- and augmented-reality based environments. Collected data and measurements using sensors that can be analyzed and sorted. The sensors can be used to passively collect data or can be used to provide data into a feedback loop to drive other systems.

A walking assist device has a frame, fixed handles, rails provided with movable handles, front wheels, rear wheels and that serve as drive wheels, drive units, a battery, and a drive control unit, and travels forward or rearward together with a user that walks while grasping the fixed handles or the movable handles. The walking assist device has an operation mode switching unit that switches between a training mode, in which a load is applied to operation of the body of the user performed as the user walks, and an assist mode in which a load on operation of the body of the user performed as the user walks is alleviated.

Wearable assistance devices and methods of operating and using the same are provided. A wearable assistance device includes a first body interface and a second body interface. The assistance device also includes one or more elastic members operatively coupling the first body interface to the second body interface and extending along a body segment (e.g., back, elbow, knee, etc.) of the user so as to provide an assistive force to or assistive torque about the body segment or another body segment. The assistance device further includes a clutch mechanism operatively connected to at least one of the one or more elastic members, the clutch mechanism configured to selectively adjust the assistive force or assistive torque provided by the one or more elastic members to/about the body segment or the another body segment.