A system for controlling the position of an articulated robotic arm includes a robotic catheter procedure system having the articulated robotic arm and a controller coupled to the articulated robotic arm. The system further includes a tracking system coupled to the controller and configured to measure a change in a position of a patient table positioned proximate to and separate from the articulated robotic arm. The controller is configured to adjust the position of the articulated robotic arm based on the measured change in position of the patient table.

A system for controlling the position of an articulated robotic arm includes a robotic catheter procedure system having the articulated robotic arm and a controller coupled to the articulated robotic arm. The system further includes a patient table positioned proximate to and separate from the articulated robotic arm and a tracking system coupled to the controller and configured to measure a change in a position of the patient table. The controller is configured to adjust the position of the articulated robotic arm based on the measured change in position of the patient table.

A long member assembling device has hand parts configured to grip a long member, arm parts and trunk parts configured to adjust a position of each of the hand parts, a hand part configured to grip the long member, the hand part numbering less than the hand parts, an arm part and a trunk part configured to move the hand part and adjust a position of the hand part gripping the long member, the arm part and the trunk part having higher positioning accuracy than the hand parts, and a control unit configured to, on the basis of an original shape of the long member stored in a memory, drive the arm parts and the trunk parts to adjust the positions of the hand parts and the hand part such that the shape of the long member gripped by the hand parts matches the original shape.

An object of the present invention is to provide an assembly manufacturing device and an assembly manufacturing method capable of reducing error when the actual position of a long member is detected, and precisely setting a reference point and a coordinates system. The long member assembly apparatus provides a plurality of hand parts for gripping a long member, a touch plate for securing the first end of the long member and restricting the movement of the long member in the longitudinal direction, a laser tracker for detecting the installation position of the touch plate, and a reference determining part for determining reference coordinates or reference point to be used in for adjusting the position of the hand parts, based on the installation position of the touch plate detected by the laser tracker.

A system for controlling the position of an articulated robotic arm in a robotic catheter procedure system, includes an articulated robotic arm, a first controller coupled to the articulated robotic arm and a patient table. The patient table includes a user interface and a second controller coupled to the user interface and the first controller. The second controller is programmed to generate a control signal in response to a user input received using the patient table user interface, the user input indicating a change in position of the patient table. The second controller is also programmed to transmit the control signal to the patient table and to transmit the control signal to the first controller.

Pre-plating systems and related methods are disclosed. A pre-plating system includes a press, an infeed robot configured to deliver a structural member to the press, and an outfeed robot configured to remove the structural member from the press. The press is configured to secure a plate to the structural member while the structural member is held in position by at least one of the infeed robot or the outfeed robot. A pre-plating system includes a press, a transfer pedestal, a plate picking robot, and a press loading robot. The plate picking robot is configured to pick a plate from a container and position the plate on the transfer pedestal. The press loading robot is configured to transfer the plate to the press. The press is configured to press the plate into a structural member positioned within the press.

A robot control unit for an assembly robot includes a force detecting device configured to detect forces applied to first and second works and, when the first work is fitted to the second work by a first robotic arm, a storage device stores a deflection amount table associating a force applied when fitting with the deflection amount of the robotic arm in a direction of the fitting, a deflection-amount acquiring process configured to calculate the deflection amount of the robotic arm in the direction of the fitting by using a value detected by the force detecting device and the deflection amount table, a work-position acquiring process configured to calculate a work position as the position of the first work relative to the second work in the direction of the fitting based on operation information about the robotic arm, and a real-fitting-amount acquiring process configured to correct the work position based on the calculated deflection amount.

A substrate assembling device includes a first end effector attached to a first arm, a second end effector attached to a second arm, and a controller. The second end effector includes a pair of grippers configured to grip a second substrate, and a placing part where threaded elements are placed. The controller is adapted to control operations of the first arm and the second arm to position the second substrate on a first substrate while gripping the second substrate, by using the pair of grippers of the second end effector, and hold the threaded element placed on the placing part of the second end effector and fasten the held threaded element, by using the first end effector, to join the first substrate and the second substrate together.

A method of assembling a component includes gripping a first subcomponent with a first end-of-arm tool and grasping a second subcomponent with a second end-of-arm tool. The first tool is attached to a first robot arm and the first subcomponent defines a first plurality of locating holes. The second tool is attached to a second robot arm and the second subcomponent defines a second plurality of locating holes. After grasping, the method includes aligning at least one of the first locating holes adjacent to at least one of the second locating holes to set an initial position of the second subcomponent with respect to the first subcomponent without releasing the first and second subcomponents. After aligning, the method includes forming a joint between the first and second subcomponents with a joining tool attached to a joining robot arm to thereby assemble the component. A component assembly system is also disclosed.

Drilling apparatus and method, the apparatus comprising: a first robot (10); a first member (30) (e.g. a pressure foot) and a drilling tool (38) both coupled to the first robot (10); a second robot (12); and a second member (52) coupled to the second robot (12); wherein the apparatus is arranged to press the members (30, 52) against opposite sides of a part to be drilled (2, 100) (e.g. an aircraft panel) so as to hold the part (2, 100) and prevent deflection of at least a portion of the part (2, 100); and the first member (30) and the drilling tool (38) are arranged such that the drilling tool (38) may drill into the portion of the part (2, 100) of which deflection is opposed from the side of the part (2, 100) pressed against by the first member (30). The robots (10, 12) may be robotic arms.