Provided is a wearable assisted-walking device including one lower attachment body to the foot defining a lower anchoring point at the heel of the foot of a leg of the user; an upper attachment body to an upper part of the leg proximal from the knee defining an upper ventral anchoring point and an upper dorsal anchoring point arranged on the opposite side of the coronal plane of the user; and an intermediate attachment body defining a first intermediate anchoring point, a second intermediate anchoring point and a third intermediate anchoring point, each anchoring point movable respect and connected by cables to the leg; the intermediate attachment body being adapted to store the energy by a relative motion between the anchoring points and then use it for assist walking.

The present disclosure is relates to an orthosis device. The orthosis device, in one embodiment, includes an actuator housing, and an electric motor coupled to the actuator housing, the electric motor including a motor stator and a motor rotor, and the electric motor further having high output torque. The orthosis device, in this embodiment, further includes a low-ratio transmission coupled to the actuator housing, the transmission including a gear system coupled to the actuator housing, and a drive system coupling the electric motor and the gear system, wherein a combination of the electric motor and transmission provide a user backdrivable orthosis device.

An exoskeleton (1) having a plurality of autonomously operable modules (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) each having a dedicated controller (23.sub.RK, 23.sub.LK, 23.sub.RH, 23.sub.LH) connected to an actuated joint. The exoskeleton (1) further having a multimaster electrical communicator (3) between the controllers (23.sub.RK, 23.sub.LK, 23.sub.RH, 23.sub.LH) of the modules (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH). The controller (23.sub.RK, 23.sub.LK, 23.sub.RH, 23.sub.LH) of each module (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) is configured for: collecting information from sensors; sharing information with the remaining modules through the multimaster electrical communicator (3); determining which other modules (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) are present; and autonomously calculating and commanding a desired trajectory of the actuated joint of the module (2.sub.RK, 2.sub.LK, 2.sub.RH, 2.sub.LH) for assisting the movement of the corresponding biological joint in coordination with the kinematic condition of other biological joints.

A robotic system comprising an upper robotic assembly and a base platform rotatable relative to one another in at least one degree of freedom via one or more joints. The robotic system further comprises a joint position restoration assembly coupled to at least one of the upper robotic assembly or the base platform, and having a first spring coupled between the upper robotic assembly and the base platform, the joint position restoration assembly being operable to apply a restoring torque to the first joint, wherein the joint position restoration assembly is configured to provide a restoring torque versus joint position profile relative to the first joint that corresponds to mass properties of at least a portion of the robotic assembly associated with the first joint, such that the joint position restoration assembly operates to apply the restoring torque to position and to support the first joint in a stable support position.

Examples of a device for guiding and detecting a motion of a target joints and a motion assistance system such motion guiding devices are described. The motion guiding and detecting device comprises a motion generator and a motion transfer and target interfacing unit to transfer the motion generated by the motion generator to the target joint. The system further includes a motion detection and feedback unit that interfaces with the target, and a controller that interfaces with both the feedback unit and the motion generator to control and coordinate the motion of the motion generator and the target joint.

Provided are a method and apparatus for adjusting a control parameter value in association with a torque output to provide a force to a user, which, when the user performs a test walk while wearing a wearable device, assesses suitability of the control parameter value used for outputting the torque based on the torque output through the test walk and state information of a joint of the user and adjusts the control parameter value such that the user feels convenience in walking, in order to adjust the control parameter value.

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 distance adjustment part configured to adjust a distance between the first support and the third support by adjusting length of the second support.

A method, system, apparatus, and/or device for supporting a plantar flexion ridge. The method, system, apparatus, and/or device may include: a sheath; a stretch cord extending along an interior of the sheath from a first end of the sheath to a second end of the sheath; a first buckle attached to a first end of the stretch cord; a first sleeve configured to cover at least a portion of the first end of stretch cord; a second buckle attached to a second end of the stretch cord; and a second sleeve configured to cover at least a portion of the second end of stretch cord.

An ankle exoskeleton device is provided having a lower leg anchor, a foot/ankle anchor, a first actuator and a second actuator. The first actuator includes an upper end disposed at a first anchor point on the right side of the foot/ankle anchor and a lower end disposed at a second anchor point on the right side of the lower leg anchor. The first actuator includes a first biasing mean having a neutral position when the ankle is in a neutral position. The first biasing means provides for compression loading due to ground reaction forces on the foot/ankle anchor to provide a cushioning effect on the ankle as the being takes a step. The second actuator provides for substantially the same elements on the left side of the foot/ankle anchor and the lower leg anchor.

A flexible wearable robot for assisting with a walking motion of a user may include a thigh strap to be worn to enclose a thigh portion of a user, a shank strap to be worn to enclose a shank portion of the user, a driver to be worn on a back or waist portion of the user to provide a driving force for assisting with a walking motion of the user, a first driving wire with one end connected to the thigh strap and the other end connected to the driver to receive tension, a second driving wire with one end connected to the shank strap and the other end connected to the driver to receive tension, and a controller to control a drive of the driver to selectively apply tension to at least one of the first driving wire and the second driving wire.