Abstract: An exoskeleton includes first and second compression members configured to be coupled to a wearer of the exoskeleton. A tensegrity joint connects the first compression member to the second compression member, the joint including a tensile member having a first end and a second end. The first end is coupled to the first compression member on a first side of the joint, and the second end is coupled to the first compression member on a second side of the joint opposite the first side.

Abstract: An exoskeleton includes first and second support structures configured to be coupled to a wearer of the exoskeleton. A joint connects the first and second support structures, the joint enabling relative movement between the first and second structures. First and second cord loops connect the first and second support structures. At least one motor twists and thereby shortens the first and second cord loops, wherein shortening of the first cord loop causes relative movement of the first and second support structures about the joint in a first direction, and shortening of the second cord loop causes relative movement of the first and second support structures about the joint in a second, opposite direction. A brake mechanism prevents relative movement of the first and second support structures about the joint in at least one of the first and second directions if one of the first and second cord loops breaks.

Abstract: An exoskeleton can be reconfigured, adjusted and/or controlled on the fly utilizing devices which fall into three categories, particularly including a swappable unactuated leg, lockable transverse and coronal hip rotations, and software controlled free joints. More specifically, the first device allows for the creation of a modular joint system in which individual exoskeleton joints or limbs can be changed or swapped to optimize an exoskeleton for a particular user. The second device is concerned with mechanically controlling, such as locking and unlocking, joints thereby allowing, for example, an exoskeleton leg to pivot or not pivot in an axis that is not actuated. The third device allows an actuated exoskeleton joint to be adjusted on the fly using software to simulate a freely rotating joint. The various devices can be used either alone or in combination to enable any given exoskeleton to be appropriately reconfigured, such as when a patient advances during therapy.

Abstract: An exoskeleton includes strapping for coupling the exoskeleton to a wearer. The exoskeleton also includes a hip structure, a thigh link rotatably connected to the hip structure and a shank link rotatably connected to the thigh link. The weight of the exoskeleton is transferred to a surface on which the exoskeleton is standing through the hip structure, the thigh link and the shank link. An arm brace supports an arm of the wearer, and a telescopic link is rotatably connected to the arm brace. An energy storage device delivers power to a tool through a conduit, and a conduit-energy storage device coupling connects the conduit to the energy storage device.

Abstract: A mobility system includes an energy module, an exoskeleton and a mobile base. The exoskeleton has an exoskeleton energy module receptacle that can receive the energy module, and the mobile base has a mobile base energy module receptacle that can also receive the energy module. In addition, the mobile base has an exoskeleton support that can support the exoskeleton on the mobile base so that the mobile base can transport the exoskeleton across a support surface.

Abstract: An exoskeleton device includes a first brace coupled to a first portion of a wearer of the exoskeleton device and a second brace coupled to a second portion of the wearer. A first joint connects the first and second braces and allows relative movement between the first and second braces. A first brake is controllable between an unactuated state and a plurality of actuated states, and the first brake impedes relative movement between the first and second braces at the first joint while the first brake is in one of the plurality of actuated states. A manual actuator is selectively used by the wearer during relative movement between the first and second braces. Use of the actuator causes the first brake to enter one of the plurality of actuated states such that relative movement between the first and second braces is impeded at the first joint.

Abstract: An ambulatory exoskeleton can be selectively operated in at least two different modes, with one mode constituting an unworn propulsion mode, used when the exoskeleton is not worn by a user, and another mode constituting a default or worn propulsion mode, used when the exoskeleton is worn by a user. With this arrangement, a physical therapist, or other operator, wishing to move an unworn exoskeleton, can balance the unworn exoskeleton, while simultaneously utilizing a control system and actuators of the exoskeleton to propel the unworn exoskeleton. Therefore, the exoskeleton walks by taking steps forward, as commanded by the operator using any of a plurality of input arrangements, while the operator balances and steers the exoskeleton by physically guiding the exoskeleton using a handle or other interaction surface of the exoskeleton.

Abstract: A lower extremity orthosis, including at least one actuator configured to control a motion of at least one joint of a person wearing the orthosis, is provided with a handle including a force sensor configured to produce a signal representing a force applied to the handle. A controller, which is in communication with the force sensor and the at least one actuator, is configured to modify the motion based on the signal from the force sensor. The system can be particularly employed to enable a physical therapist to have input in controlling and modifying the positions and/or forces prescribed by the lower extremity orthosis during rehabilitation of the person.

Abstract: A lower extremity orthotic control system determines a movement desired by a user, particularly with a user employing gestures or other signals to convey or express their intent to the system, and automatically regulates the sequential operation of powered lower extremity orthotic components. In a particular application, the orientation of a stance leg is used to determine when the user wants to initiate a step, as well as when the user is in a safe position from which to take a step. The invention has particular applicability for use in enabling a paraplegic user to walk through a controlled operation of a human exoskeleton coupled to the user's lower limbs. A controller receives inputs regarding a motion desired by the user, determines the desired motion and then controls the movement of the user's legs or limbs through actuation of the exoskeleton.

Abstract: A gait orthotic system includes a balance aid and a gait orthotic device. The gait orthotic device has a rigid attachment mechanism configured to securely and releasably couple the balance aid to the gait orthotic device. When the balance aid is coupled to the gait orthotic device, the gait orthotic device is supported in a standing position so that a user of the gait orthotic device is able to use his/her hands freely. When the balance aid is not coupled to the gait orthotic device, the user is able to use the balance aid for locomotion. In certain embodiments, the balance aid is a forearm crutch, a walker or a cane, while the rigid attachment mechanism is a clamp with an over-center latch.

Abstract: A gait orthotic device, such as a powered exoskeleton, includes at least one joint; at least one actuator configured to cause movement of the device at the joint; a cushioning mechanism coupled to the device for absorbing energy or spreading a force during an impact with a surface or object; and a controller. The controller is configured to determine when a fall is occurring and direct the actuator to: orient the device so the cushioning mechanism makes contact with the surface or object during the fall; or reduce a kinetic energy of the device during the fall by performing positive joint work. The cushioning mechanism can take various forms, including an airbag, a spring, a bumper, a roll bar or a kickstand. Preferably, the cushioning mechanism is an airbag in the form of an airbag module that is detachably coupled to the device for removal and replacement.

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: A three-dimensional surface scan of an exoskeleton wearer is performed to generate three-dimensional surface data, and a three-dimensional surface model of the exoskeleton wearer is generated from the three-dimensional surface scan data. A three-dimensional exoskeleton model is generated from the three-dimensional surface model. At least one three-dimensional exoskeleton component is printed from the three-dimensional exoskeleton model, and a custom-fit exoskeleton is assembled using the at least one three-dimensional exoskeleton component.

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: A first exoskeleton is in communication with a central server or a peripheral device. The first exoskeleton collects first data and transmits the first data to the central server or peripheral device. The central server or peripheral device generates second data using the first data and transmits the second data to the first exoskeleton or a second exoskeleton.

Abstract: An exoskeleton includes first and second support structures configured to be coupled to a wearer of the exoskeleton. A joint connects the first and second support structures, the joint enabling relative movement between the first and second structures. First and second cord loops connect the first and second support structures. At least one motor twists and thereby shortens the first and second cord loops, wherein shortening of the first cord loop causes relative movement of the first and second support structures about the joint in a first direction, and shortening of the second cord loop causes relative movement of the first and second support structures about the joint in a second, opposite direction. A brake mechanism prevents relative movement of the first and second support structures about the joint in at least one of the first and second directions if one of the first and second cord loops breaks.

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: 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: An exoskeleton comprises at least one load-bearing element including a flexible hose, sleeve or cable having a first end portion and a second end portion opposite the first end portion. The first end portion is engageable with a load and is configured to transfer a weight of the load to the hose, sleeve or cable. The hose, sleeve or cable is configured to transfer the weight of the load from the first end portion to the second end portion, and the second end portion is configured to transfer the weight of the load to a support surface upon which the exoskeleton is supported.

Abstract: An exoskeleton device provides for selectively adjusting an exoskeleton hip pivot/pivot position in the sagittal plane relative to the position of the hip pivot of a wearer of the exoskeleton. The exoskeleton hip pivots/pivot positions can be shifted forward or rearward relative to the hip pivots of the wearer and can either be automatically actuated by an exoskeleton control system or manually adjusted by the exoskeleton wearer. The invention particularly allows for differential hip placement in order to compensate for changing load or actuation conditions.