A driver device comprises a housing and a driving-bit socket in the housing. The driver device may comprise a first guide-leg track on the housing. A first guide leg may be inserted into the first guide leg track. The driver device may also comprise a first guide-leg foot at an end of the first guide leg. The first guide-leg foot may be configured to interface with a surface of the driving recipient. The first guide leg may retract into the first guide-leg track as the driver device drives a driving object into the driving recipient.

A machine learning device and a machine learning method are provided. A controller, which serves as the machine learning device and the machine learning method, is provided to perform machine learning of algorithms for arranging a flexible wire-like workpiece to a predetermined state using an industrial robot. In an embodiment, the machine learning device includes: an acquisition unit that acquires, as state variables, a state of the workpiece before arrangement starts and a state of the workpiece during arrangement; and a learning unit that performs machine learning of an algorithm for arranging the workpiece based on the state variables acquired by the acquisition unit.

An embodiment provides a method of operating wire harness manufacturing equipment, including: adding, using the manufacturing equipment, an element to a wire to form a combination of the element and the wire; capturing, using an imaging device, an upper image and a lower image of the combination; analyzing, using one or more processors operatively coupled to the imaging device, the upper image and the lower image to detect a defect; and thereafter indicating that the defect has been detected. Other embodiments are described and claimed.

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.

The invention relates to a device for plugging a plug-in region of an expansion board into a plug-in coupling, the plug-in coupling having a slot, which has a depth T along a depth axis TA and a length L along a longitudinal axis LA, and wherein the depth axis TA and the longitudinal axis LA define a plug-in plane, the device including: a first interface for providing the plug-in coupling; a second interface for providing the expansion board; a first robot manipulator having an effector; and a control unit for the open-loop/closed-loop control of the first robot manipulator, wherein the control unit is configured and designed to execute a control program having the following steps: the first robot manipulator picks up the expansion board at/from the second interface using the effector and guides the expansion board along the specified trajectory T with a specified target orientation O.sub.target(R.sub.T) of the plug-in region to the plug-in coupling provided at the first interface, wherein O.sub.target(R.sub.T) defines the target orientation of the plug-in region of the expansion board held by the effector along the trajectory T for locations R.sub.T of the trajectory T, wherein, in order to plug the plug-in region into the plug-in coupling using the first robot manipulator, force-controlled and/or impedance-controlled and/or admittance-controlled tilting motions of the plug-in region in the plug-in plane are carried out until a specified limit value condition G1 for a torque acting on the effector and/or a specified limit value condition G2 of a force acting on the effector is reached or exceeded and/or a provided force/torque signature and/or a position/velocity/acceleration signature is reached or exceeded at the effector, which indicates/indicate that the plugging of the plug-in region into the plug-in coupling is successfully completed within predefined tolerances.

A device and method for electrical testing of a component, the component including a contact point, wherein the device includes: an interface to provide the component; a robot manipulator having an effector configured to pick up, handle, and release the component; a receiving interface into which the component is insertable; a contacting device having a counter contact, the contacting device positioned in a first state so that the robot manipulator is able to insert/remove the component into/from the receiving interface, and positioned in a second state so that the counter contact is connected to the contact point of the component inserted into the receiving interface; an analysis unit connected to the counter contact and configured to perform electrical testing of the component using connection of the counter contact and the contact point in the second state; and a control unit to control the robot manipulator and the contacting device.

An embodiment provides a method of operating wire harness manufacturing equipment, including: adding, using the manufacturing equipment, an element to a wire to form a combination of the element and the wire; capturing, using an imaging device, an upper image and a lower image of the combination; analyzing, using one or more processors operatively coupled to the imaging device, the upper image and the lower image to detect a defect; and thereafter indicating that the defect has been detected. Other embodiments are described and claimed.

A method for operating a commercial shipping asset includes entering one of a docking and an undocking mode of operations using a vehicle controller of a commercial shipping asset, identifying at least one trusted video source remote from the commercial shipping asset, determining a distance between the commercial shipping asset and at least one object based at least in part on an image analysis of a video feed from the trusted video source, and responding to the determined distance by providing at least one of a warning to an operator of the commercial shipping asset and adjusting an automated or semi-automated operation of the commercial shipping asset.

The present method for moving a tip of a line-like object is a method for moving a tip of a line-like object grasped by a robot hand to a target position, the method including: measuring a position of the tip of the line-like object grasped by the robot hand; and moving the tip to the target position based on the measured position of the tip.

A machine integrated positioning system shows an operator where to place a raw part in the press brake or other machinery. Further, the operator is informed if the dimensions associated with the raw part are, or are not, correct to produce the planned finished part. The operator is visually shown how the raw part is to be oriented. The operator is informed if the raw part is right-side-up, along with other pre-final placement information. If these and other conditions are not met, the machine integrated positioning system may prevent the press brake and other machinery from cycling.