A robot includes: a communicator; a driver configured to drive the robot; at least one memory configured to store at least one instruction; and at least one processor configured to execute the at least one instruction to: receive first driving data from an external device in communication with the robot through the communicator and store the first driving data in the memory, control the driver to perform an operation based on the first driving data, identify, based on an error in communication connection between the robot and the external device occurring, second driving data received by the robot from the external device within a threshold period based on a point in time at which the error in communication connection occurs, wherein the second driving data matches with at least a portion of the first driving data, identify third driving data that is at least a portion of the first driving data and is consecutive to the portion of the first driving data that matches with the second driving data, and control the driver to perform an operation after the point in time at which the error in communication connection between the robot and the external device occurs based on the third driving data.

A wearable device may include a proximal support configured to support a proximal part (e.g., waist) of a user, a distal support configured to support a distal part (e.g., thigh) of the user, a driving assembly which is connected to the proximal support and configured to generate power, and a driving frame configured to transmit the force from the driving assembly to the distal support. The driving assembly may include a housing which is connected to the proximal support, an actuator including a stator which is fixed to the housing and has a ring shape and a rotor which is located inside the stator and rotatable relative to the stator, a speed reducer which is inserted inside the rotor and includes an input end which is connected to an output end of the actuator, and a supporting part configured to support the speed reducer and connected detachably to the housing.

A method of controlling an exoskeleton mobility device includes executing a control application with an electronic controller to perform: sensing at least one of an angular position or angular velocity of a stance/trailing leg during a single support dynamic state of a gait cycle; determining whether the angular position satisfies an advanced gait threshold; and when it is determined that the angular position satisfies the advanced gait threshold, the control system employs advanced gait control in which a duration of double support states between single support dynamic states is minimized. For advanced gait control the control system controls such that hip joint component velocities are non-zero during transitions from swing states to stance states, and knee joint component velocities are non-zero during transitions from stance states to swing states of the gait cycle. Each step of the gait cycle thus blends into a next step by way of hip joint component swing-to-stance extension, and/or knee joint component stance-to-swing flexion.

A stretching machine includes a table having a surface for supporting a patient and a first leg rest for supporting and moving a first leg of the patient. The first leg rest has a first vertical frame operable to rotate around a first horizontal pivot point at an end of the table and a first horizontal frame operable to rotate around a first vertical pivot point on the first vertical frame. A first vertical actuator is for rotating the first vertical frame around the first horizontal pivot point to move the first leg rest in a vertical direction relative to the surface of the table, and a first horizontal actuator is for rotating the first horizontal frame around the first vertical pivot point to move the first leg rest in a horizontal direction relative to the first vertical frame.

There are provided a wearable robot and a method of controlling the same. The method includes obtaining a joint angle and a joint angular velocity of a plurality of joints, calculating a target joint angle of one joint among the plurality of joints using a joint angle and a joint angular velocity of at least one joint among the other joints, calculating assistive torque to be applied to the one joint using the calculated target joint angle, and outputting the calculated assistive torque to the one joint.

Driving modules, motion assistance apparatuses including at least one of the driving modules, and methods of controlling at least one of the motion assistance apparatuses may be provided. For example, a driving module including a driving source on one side of a user and configured to transmit power, an input side rotary body coupled to the driving source and configured to rotate, first and second decelerators configured to operate using the power respectively received from the driving source through the input side rotary body, and a first stopper and a second stopper configured to selectively enable or disable a transmission of the power between the input side rotary body and respective output terminals of the first and second decelerators may be provided.

Embodiments of an apparatus and systems for assisting mobility of a person comprise an exoskeleton device; and one or more straps extending between a first leg of the exoskeleton device and a second leg of the exoskeleton device, the one or more straps configured to reduce slumping of a user seated in the exoskeleton when the exoskeleton is in a sitting position.

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.

A pneumatic exomuscle system and methods for manufacturing and using same. The pneumatic exomuscle system includes a pneumatic module; a plurality of pneumatic actuators each operably coupled to the pneumatic module via at least one pneumatic line, a portion of the pneumatic actuators configured to be worn about respective body joints of a user; and a control module operably coupled to the pneumatic module, the control module configured to control the pneumatic module to selectively inflate portions of the pneumatic actuators.

A wearable device and an exercise support method performed by the wearable device are disclosed. The exercise support method includes receiving exercise setting information associated with a lower body muscle that is selected by a user input, determining a torque profile to be applied to the wearable device based on the received exercise setting information, and operating an actuator of the wearable device based on the determined torque profile.