Abstract: An exoskeleton includes a first support, a second support, and a joint connecting the first and second supports. An actuator causes relative rotation between the first and second supports at the joint. The actuator includes a motor, a ball screw, a ball nut, and a yoke. The motor causes translation of the yoke via the ball screw and the ball nut. In some embodiments, the actuator further includes a roller and a joint cam having a track. Translation of the yoke causes movement of the roller within the track, and movement of the roller within the track causes rotation of the joint cam. In other embodiments, the actuator further includes a linkage and a joint crank. Translation of the yoke causes movement of the linkage, and movement of the linkage causes rotation of the joint crank. Rotation of the joint cam or the joint crank causes relative rotation between the first and second supports.

Abstract: A tool-holding arm includes a plurality of links and a tool coupling that removably secures a tool to the tool-holding arm. A first fluid spring provides a gravity-counteracting force to the tool-holding arm. A locking mechanism selectively locks the first fluid spring. An adjustment mechanism selectively adjusts an amount of the gravity-counteracting force provided by the first fluid spring.

Abstract: A system and method by which movements desired by a user of a lower extremity orthotic is determined and a control system automatically regulates the sequential operation of powered lower extremity orthotic components to enable the user, having mobility disorders, to walk, as well as perform other common mobility tasks which involve leg movements, perhaps with the use of a gait aid.

Abstract: A positionable tool support device is mounted near a work surface for supporting a tool for a user. The tool support device includes a surface mount to secure the tool support device to a support surface. A gravity-balancing articulated arm assembly is coupled to and extends from the surface mount. The gravity-balancing articulated arm assembly is selectively adjustable about both vertical and horizontal axes. A rigid support extension is coupled to the gravity-balancing articulated arm assembly for selective rotation relative to the gravity-balancing articulated arm assembly. A flexible tensile member is coupled to and extends, in a relaxed state, vertically downward from the rigid support extension. The tensile member is coupled to the tool.

Abstract: An operator supervising a wearer of an exoskeleton is verified by performing a verification routine on the operator using the exoskeleton. If the verification routine is unsuccessful, the exoskeleton is caused to follow a pre-established response routine. If the verification routine is successful, movement of the exoskeleton is allowed.

Abstract: An exoskeleton includes first and second supports coupled to an exoskeleton wearer, a joint connecting the first support to the second support and an actuator. The actuator includes a ball screw, a ball nut assembly coupled to the ball screw and first and second tensile members. The ball nut assembly has first and second cord reactors. The first tensile member is routed through the first cord reactor, and the second tensile member is routed through the second cord reactor. Movement of the ball nut assembly along the ball screw in a first direction causes the second support to move relative to the first support in a first rotational direction about the joint. Movement of the ball nut assembly along the ball screw in a second direction causes the second support to move relative to the first support in a second rotational direction about the joint.

Abstract: An exoskeleton includes an arm brace coupled to an arm of a wearer and a tensile member connected to the arm brace. An actuator exerts a pulling force on the tensile member. The pulling force reduces a length of the tensile member between the arm brace and the actuator and causes the arm of the wearer to bend at an elbow.

Abstract: An exoskeleton configured to be coupled to a user includes a plurality of interconnected support elements constituted by rigid compression members interconnected through a tensegrity joint. The joint includes a tensile member having a first end and a second end coupled to first and second ones of the support elements respectively.

Abstract: Use of an exoskeleton by a wearer of the exoskeleton is improved through several features. In a first feature, the exoskeleton enters a gait therapy preparation mode to prepare the wearer for subsequent gait therapy. In a second feature, the exoskeleton enters a balance training mode to help the wearer learn to balance while wearing the exoskeleton. In a third feature, the exoskeleton prompts the wearer to shift weight and/or automatically shifts the wearer's weight in a center of pressure control mode. In a fourth feature, an element of variability is introduced into trajectory cycles performed by the exoskeleton in a trajectory cycle mode. Overall, the various disclosed operating modes can be used individually or in various combinations to enhance the rehabilitation or training of the wearer.

Abstract: An exoskeleton includes a first link that pivots in a transverse plane about a first vertical axis and a second link that pivots in a transverse plane about a second vertical axis. The second link is coupled to the first link. An arm support assembly is coupled to the second link and pivots about a horizontal axis. The arm support assembly includes a spring that generates an assistive torque that counteracts gravity. The arm support assembly provides the assistive torque to an arm of a wearer to support the arm of the wearer. The arm support assembly further includes a cam profile and a cam follower. Contact between the spring, cam follower and cam profile determines an amount of the assistive force provided by the arm support assembly. A cuff is coupled to the arm support assembly and the arm of the wearer.

Abstract: An exoskeleton includes a first support, a second support, and a joint connecting the first and second supports. An actuator causes relative rotation between the first and second supports at the joint. The actuator includes a motor, a ball screw, a ball nut, and a yoke. The motor causes translation of the yoke via the ball screw and the ball nut. In some embodiments, the actuator further includes a roller and a joint cam having a track. Translation of the yoke causes movement of the roller within the track, and movement of the roller within the track causes rotation of the joint cam. In other embodiments, the actuator further includes a linkage and a joint crank. Translation of the yoke causes movement of the linkage, and movement of the linkage causes rotation of the joint crank. Rotation of the joint cam or the joint crank causes relative rotation between the first and second supports.

Abstract: A lower extremity orthosis is configured to be coupled to across at least one joint of a person for gait assistance and can incorporate knee, thigh, hip and ankle/foot assistive orthotic devices which can be used in various combinations to aid in the rehabilitation and restoration of muscular function in patients with impaired muscular function or control.

Abstract: An exoskeleton includes an arm brace coupled to an arm of a wearer and a tensile member connected to the arm brace. An actuator exerts a pulling force on the tensile member. The pulling force reduces a length of the tensile member between the arm brace and the actuator and causes the arm of the wearer to bend at an elbow.

Abstract: A tool arm mount couples a tool arm to an aerial work platform. The tool arm mount includes a first mounting hook that hangs on a first rail of the aerial work platform and a second mounting hook that hangs on a second rail of the aerial work platform. The first mounting hook defines a first channel in which the first rail is received, and the second mounting hook defines a second channel in which the second rail is received. The first and second mounting hooks are coupled to a spine of the tool arm mount. The tool arm mount also includes a first lock that locks the first mounting hook to the first rail.

Abstract: An exoskeleton trajectory sequence is received with at least one server, and the sequence is transferred to a first device where the sequence is validated. The validation includes a safety check in which a determination is made as to whether the sequence is safe for use with an exoskeleton. The validated sequence, or a confirmation that the sequence is valid, is received from the first device, and the validated sequence is offered for sale, license or lease. In one embodiment, a request for the sequence to be transferred is received from a first exoskeleton user. The sequence is validated and transferred to a second exoskeleton user. In another embodiment, a request for the sequence to be edited is received from an exoskeleton user. The sequence is edited, validated and transferred to the exoskeleton user.

Abstract: A tool-holding arm includes a plurality of links and a tool coupling that removably secures a tool to the tool-holding arm. A first fluid spring provides a gravity-counteracting force to the tool-holding arm. A locking mechanism selectively locks the first fluid spring. An adjustment mechanism selectively adjusts an amount of the gravity-counteracting force provided by the first fluid spring.

Abstract: An exoskeleton includes a control system which incorporates a feedback system used to establish and communicate orthosis operational information to a physical therapist and/or to an exoskeleton user. The feedback system can take various forms, including employing sensors to establish a feedback ready value and communicating the value through one or more light sources which can be in close proximity to joints of the exoskeleton joints.

Abstract: A positionable tool support device is mounted near a work surface for supporting a tool for a user. The tool support device includes a surface mount to secure the tool support device to a support surface. A gravity-balancing articulated arm assembly is coupled to and extends from the surface mount. The gravity-balancing articulated arm assembly is selectively adjustable about both vertical and horizontal axes. A rigid support extension is coupled to the gravity-balancing articulated arm assembly for selective rotation relative to the gravity-balancing articulated arm assembly. A flexible tensile member is coupled to and extends, in a relaxed state, vertically downward from the rigid support extension. The tensile member is coupled to the tool.

Abstract: A powered orthotic system, such as an exoskeleton, is employed for overground rehabilitation purposes by adapting and adjusting to real-time needs in a rehabilitation situation whereby the system can be initially controlled to perform gait functions for a wearer based on a predetermined level of assistance but the predetermined level of assistance can be varied, based on one or more rehabilitation parameters or specific needs of the wearer undergoing therapy, through the application and adjustment of appropriate variables associated with operation of the system.

Abstract: The invention is directed to controlling a hydraulic actuation system having at least one degree of freedom, a prime mover, at least one actuation module and a controller, with each actuation module including: an over-center variable displacement pump having a power input connection configured to power the pump from the prime mover and a displacement varying input for varying the displacement of the pump; a displacement varying actuator configured to modulate the displacement varying input of the pump; an output actuator in direct communication with the pump, the output actuator configured to drive a corresponding degree of freedom; and at least one sensor establishing a feedback measurement that represents a force or motion of the output actuator. Based on a value of each feedback measurement, the force or motion of the output actuator is regulated by controlling the prime mover and the displacement actuator for the output actuator.