A mechanism (30) and a method for inserting an elongate member (35) through an aperture of a body, along a longitudinal axis (35), the mechanism comprising a feed portion (42) comprising a feed actuator (43) configured to engage with and drive the elongate member along the longitudinal axis; and, a twist portion (44) comprising a twist actuator (82) configured to engage with the feed portion and rotate the elongate member about the longitudinal axis.

A device for ensuring safe operation of a robot used for cosmetics applications, including the retrofitting of robots not originally design for such applications. In some embodiments, the robot is used for the automatic placement of eyelash extensions onto the natural eyelashes of a subject. In some embodiments, a safety barrier is provided by a physical barrier or light curtain. In other embodiments, readily deformable end effectors are used.

A device for ensuring safe operation of a robot used for cosmetics applications, including the retrofitting of robots not originally design for such applications. In some embodiments, the robot is used for the automatic placement of eyelash extensions onto the natural eyelashes of a subject. In some embodiments, a safety barrier is provided by a physical barrier or light curtain. In other embodiments, readily deformable end effectors are used.

Approaches presented herein enable maneuvering collaborative robots to rescue persons in a hydrological disaster. A plurality of robots are dispersed in a body of water to spread out and seek victims using cooperative foraging techniques within resource constraints. A location of victims located by a robot using sensing techniques is communicated to other robots. A situational assessment is performed using victim location information to determine a number of robots to deploy to the location. The deployed robots are directed to perform coordinated maneuvers to create a connected floatation unit to support floatation of victims for rescue.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

An attachment module constructed to enable a vehicle charging robot to attach to a vehicle and to thereafter insert its charging connector into the vehicle's charging socket. Once the vehicle is charged and the charging connector is disconnected from the charging socket, the attachment module is further constructed to enable the robot to detach from the vehicle.

A robotic system for fueling or charging a vehicle having a vehicle connector, the robotic system including a robotic arm having a plurality of sequentially arranged articulated links and at least one group of operating cables extending from a proximal end of the arm to terminate at a control link, for controlling the position of that link, the cables each having a path comprising a passage in each successive more proximal link for closely receiving the cable, a flexible conduit operably connected with the robotic arm for delivering a fluid or an electrical current, respectively, to a vehicle, the conduit being connected to a source at a first end and a delivery connector at a second end, and a control system for operating the robotic arm and the hose or cable, wherein the control system directs the robotic arm to engage the vehicle connector with the delivery connector and, upon engagement of the vehicle connector and delivery connector, the control system relaxes the robotic arm to an under-constrained condition.

Technology is provided for controlling the motion of soft growing robots during retraction to prevent uncontrollable buckling or bending. A double walled flexible tubular robot is provided with an inside wall, an outside wall, and a folded tip. A retraction device located at the folded tip has a routing aperture sized to encompass the inside wall and for routing the inside wall through the retraction device. The retraction device further has a retraction mechanism inside the retraction device to controllably retract material of the inside wall through the routing aperture in the direction away from the folded tip, thereby decreasing the outside wall, creating more inside wall, and as such shortening the length of the flexible robot. This technology enables behaviors, such as (1) growing in one direction, and then retracting and growing in a different direction, and (2) retracting through a confined space without applying