A robotic joint comprises a first link, a middle link, a torque generator, a second link, and a locking mechanism. Different ends of the middle link are rotatably coupled to the first link and the second link. The torque generator is coupled to the first link and the middle link and is configured to produce a torque between these links. The locking mechanism is switchable between a locking state and an unlocking state. In the unlocking state, the locking mechanism allows free rotation of the second link relative to the middle link in the first and second rotation directions. In the locking state, the locking mechanism is configured to impede rotation of the second link relative to the middle link in the first rotation direction and to allow rotation of the second link relative to the middle link in the second rotation direction opposite of the first rotation direction.

A prosthetic or orthotic device has an elongate frame that houses electronics and an actuator rotatably mounted to the frame. The actuator can rotate in an anterior-posterior direction about a medial-lateral axis and includes magnetorheological (MR) fluid and a coil operable to selectively apply a magnetic field to the MR fluid to vary its viscosity and thereby vary a torsional resistance of the actuator about the medial-lateral axis. The device contains a layered control system that makes use of data collected by the embedded sensors in a prosthetic device for intent recognition, management, and actuator control. The layered control system uses a Luenberger observer for estimating joint velocity and a heuristic torque-setpoint component to control the function of a MR actuated knee prosthesis.

An electronic device may provide a user with at least one of target motion information of a wearable device according to a target period or basic torque information mapped to the target motion information and output by the wearable device, receive an input for modifying at least a portion of the basic torque information from the user, generate modified torque information based on the basic torque information and the input, and generate a motion control model for controlling the wearable device based on the target motion information and the modified torque information.

A system and method for operating a prosthesis is provided. The system includes a socket configured to engage a residual limb of a subject and a shaft having a first end connected to the socket and an opposing second end. The system also includes a foot piece connected to the second end of the shaft. The foot piece includes an ankle plate and a sole piece configured to contact a surface. The system also includes at least one computer configured to detect a state of the foot piece and to transmit an indication of the state of the foot. The system further includes a motor assembly configured to receive the indication of the state of the foot and to control a position and impedance of the ankle plate based on the state of the foot.

Apparatus is provided to cushion between a prosthetic socket and an amputee's residual limb. A plurality of putty-filled packets are assembled into a liner that, when assembled, provides a generally smooth contact surface toward the residual limb. At least one of the packets has a fluid bladder positioned between the putty material and the socket, and the fluid volume in the bladder can be adjusted to affect the fit of the assembly on the residual limb. Methods of fabrication, fitting, and use of such prosthetic devices are disclosed.

A device and method for measuring prosthetic or orthotic slip is presented. An optical sensor device is attached to the prosthesis or orthosis and measures the amount of relative motion between the prosthetic socket and the residual limb surface or between the orthosis and the affected body part. The sensor device is comprised of an optical sensor, a light source, a processing unit and a power source contained within a housing. A system for measuring multidirectional prosthetic or orthotic slip using the sensor device and automatically adjusting the fit of the prosthetic based on a determined threshold is also presented.

A fall prevention device configured to be coupled to a person and comprising a mechanical torso configured to be coupled to the person's torso and a mechanical structure configurable to be coupled to the mechanical torso from its first end. The mechanical structure and mechanical torso resist forces at least along one direction to maintain their posture relative to each other. In operation the second end of the mechanical structure is positioned behind the person and substantially close to the ground. When the second end of the mechanical structure contacts the ground, contact points of legs of the person on the ground and contact points of the second end of the mechanical structure outline a multi-sided polygon on the ground. If the vertical projection of the center of gravity of the person to the ground intersects the ground within the multi-sided polygon, the person and fall prevention device remain stable.

A system for control of a device includes at least one sensor module detecting orientation of a user's body part. The at least one sensor module is in communication with a device module configured to command an associated device. The at least one sensor module detects orientation of the body part. The at least one sensor module sends output signals related to orientation of the user's body part to the device module and the device module controls the associated device based on the signals from the at least one sensor module.

A robotic assembly control system is disclosed. The robotic assembly control system includes an exoskeleton apparatus adapted to be worn by a user, at least one robotic assembly, the at least one robotic assembly controlled by the user by way of the exoskeleton, and at least one mobile platform, the at least one mobile platform controlled by the user and wherein the at least one robotic assembly is attached to the at least one mobile platform.

The invention relates to a method for controlling at least one actuator (4) of an orthopedic device (2) with an electronic control device (E), which is coupled to the actuator (4) and at least one sensor (8) and which has an electronic processor (μC) for processing sensor data (s), wherein at least one state machine (SM) in which states (z) of the orthopedic device (2) and state transitions of the actuator (4) are determined is stored in the control device (E), wherein a classifier (K) in which sensor data (s) and/or states (z) are automatically classified within the scope of a classification method is stored in the control device (E), wherein the state machine (SM) and the classification method are used in combination and, on the basis of the classification and the states (z), a decision is made about the manner of activating or deactivating the actuator (4) as a control signal.