Abstract: A robotic end-effector comprises a pair of members being movable with respect to one another and a bladder on at least one of the members. The bladder can comprise a filler within the bladder. The filler can comprise a plurality of jamming particles and a plurality of elongate resilient spacers. The jamming particles are operable to flow within the bladder and to contact and engage with the elongate resilient spacers where flow characteristics vary within the bladder. The bladder with the filler can comprise at least two configurations: a compliant configuration in which a shape of the bladder and filler are changeable, and a stiff configuration in which change in shape of the bladder and filler are resisted.

Abstract: A walk-about platform in support of an exoskeleton is provided. The walk-about platform can include a conveyance system operable to facilitate movement of the walk-about platform about a ground surface. The conveyance system can comprise a plurality of rollers, and at least one actuator operable to actuate one or more of the plurality of rollers to facilitate the movement of the walk-about platform about the ground surface. A bi-pedal locomotion zone can be defined, at least in part, by the plurality of rollers. The bi-pedal locomotion zone can provide clearance for bi-pedal locomotion of an operator donning the exoskeleton. The at least one actuator actuates the one or more of the plurality of rollers based on the bi-pedal locomotion of the operator donning the exoskeleton.

Abstract: A convertible ride-on and walk-about platform for a robotic upper exoskeleton is provided. The convertible ride-on and walk-about platform can be maneuverable about a ground surface and can include rollers operable to facilitate movement about the ground surface. The rollers can define at least in part a bi-pedal locomotion zone that provides clearance for bi-pedal locomotion of an operator donning the exoskeleton. The convertible ride-on and walk-about platform can also comprise a riding platform operable to be selectively moveable into the bi-pedal locomotion zone to allow the operator to ride thereon.

Abstract: A walk-about exoskeleton system can comprise an exoskeleton and a walk-about platform in support of the exoskeleton. The walk-about platform can be maneuverable about a ground surface. The walk-about platform can comprise a conveyance system operable with the walk-about platform. The conveyance system can be operable to facilitate movement of the walk-about platform about the ground surface. The walk-about platform can also comprise a bi-pedal locomotion zone defined, at least in part, by the walk-about platform. The bi-pedal locomotion zone can provide clearance for bi-pedal locomotion of an operator donning the exoskeleton.

Abstract: A robotic end-effector comprises a pair of members being movable with respect to one another and a bladder on at least one of the members. The bladder can comprise a filler within the bladder. The filler can comprise a plurality of jamming particles and a plurality of elongate resilient spacers. The jamming particles are operable to flow within the bladder and to contact and engage with the elongate resilient spacers where flow characteristics vary within the bladder. The bladder with the filler can comprise at least two configurations: a compliant configuration in which a shape of the bladder and filler are changeable, and a stiff configuration in which change in shape of the bladder and filler are resisted.

Abstract: A robotic system for a robotic limb configured to recover energy for minimizing power consumption of the robotic system, comprising a first support member, a second support member, and a quasi-passive elastic actuator rotatably coupling the first and second support members to define a joint of the robotic system rotatable about an axis of rotation defining a degree of freedom. The quasi-passive elastic actuator can comprise a first vane device and a second vane device, the first vane device and second vane device being rotatable relative to each other within the housing and defining, at least in part, a compression chamber and an expansion chamber. The system can further comprise a valve assembly, the valve assembly comprising a valve device disposed through an opening of the first vane device along the axis of rotation, and a shunt circuit facilitating fluid flow between the compression and expansion chambers through the valve assembly.

Abstract: A foot-supporting appendage of a wearable robotic exoskeleton configured to support a foot of a user wearing the robotic exoskeleton. The foot-supporting appendage can include a rearward support configured to support a hind foot portion of a foot of the user. The foot-supporting appendage can further include a frontward support configured to connect to the rearward support and configured to support a forefoot portion of the foot of the user. A size of the foot-supporting appendage is adjustable to accommodate a respective foot of a user of a plurality of users having different sizes of feet.

Abstract: A length adjustable robotic limb comprises a first joint assembly, a second joint assembly, and a structural member extending between the first joint assembly and the second joint assembly, the structural member defining a longitudinal axis. An adjustable interface can be provided between the structural member and one of the first and second joint assemblies. The adjustable interface can facilitate adjustment of a length between the first and second joint assemblies. A rotational interface between the structural member and one of the first and second joint assemblies can facilitate relative rotation between the first joint assembly and the second joint assembly about the longitudinal axis in a degree of freedom corresponding to medial/lateral rotation of a portion of a human limb.

Abstract: A method for operating a robotic joint of a robotic system comprising selectively operating a clutch mechanism of a clutched joint module in an engaged state to cause a quasi-passive elastic actuator to enter an elastic state, the clutched joint module operating about and defining a joint of the robotic system. The method comprising effecting a first rotation of the joint to cause the quasi-passive elastic actuator to store energy during at least a portion of the rotation of the joint. The method comprising effecting a second rotation of the joint and causing the stored energy from the quasi-passive elastic actuator to be released in the form of an augmented torque applied to an output member of the clutched joint module. The method comprising selectively operating the clutch mechanism in a disengaged state to cause the quasi-passive elastic actuator to enter an inelastic state.

Abstract: A technology is described for redundant network communication in a robot. An example of the technology can include a main robotic controller and a robotic component including a local controller and a controlled component that is operable based on a data signal comprising control instructions executed by the local controller. A command can be sent between the main robotic controller and the local controller. The command can be encoded in a first data signal and a second data signal. The first data signal can be sent over a first network channel, and the second data signal can be sent over a second network channel. The first data signal and the second data signal can be configured to be redundant data signals for the local controller sent respectively over the first network channel and the second network channel.

Abstract: A robotic joint system is provided that facilitates efficient movement of a ground-contacting robotic system, such as during a gait cycle. The robotic joint system can comprise a first support member, a second support member, and a joint assembly rotatably coupling the first support member to the second support member about an axis of rotation. The joint assembly can comprise a passive actuation system coupled between the first and second support members. The passive actuation system can comprise a passive actuator operable to store energy and to release energy to apply a torque to the joint assembly and the first and second support members, and a length adapter coupled to the passive actuator operable to selectively direct the output of the stored energy of the passive actuator.

Abstract: A technology is described for redundant network communication in a robot. An example of the technology can include a main robotic controller, a local controller in network communication with the main robotic controller, and instructions that, when executed by the processor, transfer first and second data signals between the main robotic controller and the local controller via first and second network channels. The first data signal is sent over the first network channel, and the second data signal is sent over the second network channel. The instructions compare the first data signal with the second data signal to determine signal integrity of the data signals; determine degradation of the first data signal if the signal integrity is less than the signal integrity of the second data signal; and select the second data signal for processing if degradation of the first data signal is determined.

Abstract: A robot system, comprising a robot capable of gait or gait-like operations, stance or stance-like operations, or a combination of these. The robot can comprise at least one ground-contacting appendage configured to facilitate locomotion of the robot. The system can further comprise a sole supported on the ground-contacting appendage that is operable to interface with a ground surface. The sole can comprise a robot interface facilitating attachment of the sole to the robot, a first sole component having a ground-contacting surface, the first sole component defining a first compliant zone, and a second sole component having a ground-contacting surface, the second sole component defining a second compliant zone. The first sole component can comprise a compliance the same or different than the second sole component.

Abstract: A teleoperated robotic system that includes master control arms, slave arms, and a mobile platform. In use, a user manipulates the master control arms to control movement of the slave arms. The teleoperated robotic system can include two master control arms and two slave arms. The master control arms and the slave arms can be mounted on the platform. The platform can provide support for the master control arms and for a teleoperator, or user, of the robotic system. Thus, a mobile platform can allow the robotic system to be moved from place to place to locate the slave arms in a position for use. Additionally, the user can be positioned on the platform, such that the user can see and hear, directly, the slave arms and the workspace in which the slave arms operate.

Abstract: A system for neutralization of a target aerial vehicle comprises a plurality of counter-attack unmanned aerial vehicles (UAVs) and an aerial vehicle detection system comprising at least one detection sensor operable to detect the target aerial vehicle in flight. The system also comprises an aerial vehicle capture countermeasure in the form of a net tethering the plurality of counter-attack UAVs to one another. The counter-attack UAV(s) are operable to capture and neutralize the target aerial vehicle with the net. The system can comprise at least one net storage device associated with a structure and configured to store at least a portion of the net when in a stowed position, and to facilitate deployment of the net when moved to a deployed position via coordinated flight of the plurality of counter-attack UAVs based on the detected target aerial vehicle.

Abstract: An exoskeleton operable to prevent unsafe operation can comprise a plurality of joint mechanisms and a plurality of sensors comprising configured to generate sensor output data associated with at least two joint mechanisms. The exoskeleton can comprise a controller configured to receive the sensor output data; combine the sensor output data; and determine whether the combination of the sensor output data from the first and second sensors satisfies an error condition in relation to at least one defined criterion. The existence of an error condition can be indicative of an anomalous operating state of the exoskeleton, such as a malfunction or an (impending) anomalous kinematic movement. The controller can also combine command signals to be transmitted to two or more joint mechanisms to determine another anomalous operating state to prevent unsafe operation. Associated software and methods are provided.

Abstract: A robotic joint system is provided that facilitates efficient movement of a ground-contacting robotic system, such as during a gait cycle. The robotic joint system can comprise a first support member, a second support member, and a joint assembly rotatably coupling the first support member to the second support member about an axis of rotation. The joint assembly can comprise a passive actuation system coupled between the first and second support members. The passive actuation system can comprise a passive actuator operable to store energy and to release energy to apply a torque to the joint assembly and the first and second support members, and a length adapter coupled to the passive actuator operable to selectively direct the output of the stored energy of the passive actuator.

Abstract: A method for operating a robotic joint of a robotic system comprising selectively operating a clutch mechanism of a clutched joint module in an engaged state to cause a quasi-passive elastic actuator to enter an elastic state, the clutched joint module operating about and defining a joint of the robotic system. The method comprising effecting a first rotation of the joint to cause the quasi-passive elastic actuator to store energy during at least a portion of the rotation of the joint. The method comprising effecting a second rotation of the joint and causing the stored energy from the quasi-passive elastic actuator to be released in the form of an augmented torque applied to an output member of the clutched joint module. The method comprising selectively operating the clutch mechanism in a disengaged state to cause the quasi-passive elastic actuator to enter an inelastic state.

Abstract: A robotic system comprising a master robotic system, and a first robotic system comprising a first mobile platform operable to move about a surface, and comprising a first manipulator. The robotic system can comprise a second robotic system comprising a second mobile platform operable to move about the surface, and comprising a second manipulator. A control module can be associated with the master robotic system and the first and second robotic systems, and can be operable in a paired control mode to facilitate paired control of the first and second robotic systems to move about the ground surface, and operable in an unpaired control mode to facilitate non-paired control of a selected one of the first or second robotic systems.

Abstract: A method for operating a robotic joint of a robotic system comprising selectively operating a clutch mechanism of a clutched joint module in an engaged state to cause a quasi-passive elastic actuator to enter an elastic state, the clutched joint module operating about and defining a joint of the robotic system. The method comprising effecting a first rotation of the joint to cause the quasi-passive elastic actuator to store energy during at least a portion of the rotation of the joint. The method comprising effecting a second rotation of the joint and causing the stored energy from the quasi-passive elastic actuator to be released in the form of an augmented torque applied to an output member of the clutched joint module. The method comprising selectively operating the clutch mechanism in a disengaged state to cause the quasi-passive elastic actuator to enter an inelastic state.