There is disclosed a mobility aid for use by a user having a lower body amputation site. The mobility aid includes a lower body exoskeleton (LBE). The LBE has a pelvic support structure and a first leg and a second leg. Each of the first and second legs are movably coupled to the pelvic support structure, wherein at least the first and second legs are selectively actuable to move the lower body exoskeleton relative to a surface on which the mobility aid is positioned. The LBE also includes a carrier selectively positionable with respect to the lower body exoskeleton and, which in use, supports the user at or about an amputation site; and a harness system configured to, when in use, secure the user to the lower body exoskeleton.

A gait motion assisting apparatus of the present invention includes an actuator unit controlling driver so that assisting force calculated by applying gait motion timing based on detected thigh phase angle to output pattern saved data is imparted to lower leg, and a terminal device capable of wireless-communicating with control device of the actuator unit. The terminal device can receive assisting force setting value including assisting force imparting period during gait cycle and create, based on the assisting force setting value, output pattern setting data indicating a relationship between the gait motion timing and a size of assisting force to be imparted to the lower leg. The control device is configured to overwrite-save the output pattern setting data received from the terminal device as the output pattern saved data.

An apparatus for an active exoskeleton boot is provided. The apparatus can include a foot plate disposed within a boot of a user. The apparatus can include a first adapter extending from a side surface of the foot plate having a slot and an actuator module comprising a chassis and a post, and the post coupled to the chassis. The apparatus can include a second adapter extending from an end surface of the post. The slot of the first adapter can be configured to engage the second adapter when the actuator module is positioned at a first angle relative to the first adapter. The first adapter can be configured to lock with the second adapter when the actuator module rotates from the first angle to a second angle relative to the first adapter.

The present invention discloses a system for assisting a mobility-impaired individual or a patient. The system includes a track that mounts to a ceiling or wall of a structure such as a home. The track receives a sliding mechanism. The sliding mechanism connects to a strap hanging arrangement. The strap hanging arrangement connects to a vest. The vest connects to a leg support mechanism. The mobility-impaired individual wears the vest and the leg support mechanism. The sliding mechanism includes a lift strap for adjusting the height of the strap hanging arrangement thereby allowing the mobility-impaired individual to be placed in a sitting position or standing position. The mechanically driven mechanism moves along the track allowing the mobility-impaired individual to move around the structure.

An acquisition unit acquires a classification result obtained by classifying training assistants by performing a cluster analysis based on first rehabilitation data about rehabilitation performed by the trainee by using the rehabilitation support system, the first rehabilitation data including at least assistant data indicating a training assistant and index data indicating a degree of recovery of the trainee. A learning unit generates a learning model, the learning model being configured to input second rehabilitation data including at least the action data indicating an assisting action performed by the training assistant to assist the trainee and output the action data for suggesting a next action to be performed by the training assistant. The learning unit generates the learning model by using, as teacher data, the second rehabilitation data for which pre-processing has been performed based on the classification result.

A walking training device according to the present embodiment includes: a robot leg attached to one leg of a trainee; a treadmill; a load distribution sensor that detects a distribution of a load received from a sole of the trainee riding on the belt of the treadmill; and a walking state determination unit that determines whether the one leg has switched from a standing state to a swinging state based on a state of increase in a load detected by the load distribution sensor and received from another leg of the trainee performing walking training; and a control unit that starts bending control for the swinging state of the robot leg when the walking state determination unit determines that the one leg has switched from the standing state to the swinging state.

A motion assistance apparatus includes a shank frame configured to support a shank of a user, a thigh frame configured to rotate relative to the shank frame and support a thigh of the user, and a driving frame configured to assist a motion of a hip joint of the user by transmitting power directly or indirectly to the shank frame.

The invention relates a device for supporting two arms 4 of a user 2 wherein the device has two arm support elements 6, each of which has an arm shell 10 for placing on an arm 4, at least one passive actuator 26, which is configured to apply a force to at least one of the arm support elements 6, and at least one counter bearing 14 for the force to be applied, which comprises at least one counter bearing element 16 and at least two force transmission elements 18, which are configured to transfer a counter force from each of the arm support elements to the counter bearing element 16,

wherein the force transmission elements 18 are arranged on the counter bearing element 16 such that they can be moved relative to the counter bearing element 16, in particular they can be rotated about at least one rotational axis.

A method and device for controlling a walking assist device is disclosed. The method includes determining a first state variable for a gait state of a user wearing the walking assist device based on a gait of the user, obtaining a second state variable which is smoothed and time-delayed from the first state variable, obtaining a third state variable by applying a torque control variable to the second state variable, and determining an assist torque to be provided by the walking assist device based on the obtained third state variable.

An exoskeleton system comprising at least one actuator unit that includes a fluidic actuator; an exoskeleton device including a fluidic system, and electronics; and a first cable extending from the exoskeleton device to the at least one actuator unit.