In a robot system, a control section causes a first gripping section to grip a connector of a cable, at one end of which the connector is provided and the other end of which is fixed, causes an imaging section to image the connector, causes, based on a result of the imaging by the imaging section, a second gripping section to grip the connector in a state in which the position of the first gripping section is maintained, causes the first gripping section to release the gripping of the connector, causes, based on the imaging result, the second gripping section to adjust a posture of the connector, and causes the first gripping section to grip the connector, the posture of which is adjusted, again.

A method, system and computer program product are provided for correction of automated insertion of a wire contact into a target hole of a connector. Methods include controlling a robot having an end-effector to: align the wire contact with the target hole of the connector; advance the wire contact toward and into the target hole of the connector; cease insertion in response to a force between the wire contact and the connector exceeding a predefined value; determining a depth of insertion; in response to the depth of insertion being above a predefined depth, perform a pull test on the inserted wire contact; in response to the depth of insertion being below a predetermined depth, identify an error condition using visual feedback; determine a number of corrective operations performed and perform error correction if the number is below a predefined number, while withdrawing the wire contact otherwise.

A cable terminal end detection method includes a gripping step for gripping, using a hand including a first gripping section and a second gripping section disposed to be separated on an X axis and configured to open and close in a direction along a Z axis, a cable in two places separated in a longitudinal direction with the first gripping section and the second gripping section, a moving step for, in a state in which the cable is gripped by the hand, moving the cable to the first gripping section side in a direction along the X axis relatively to the hand, and a detecting step for detecting, with a tactile sensor disposed in the second gripping section to be in contact with the cable, that the cable has slipped out from the second gripping section and detecting that a terminal end of the cable is located between the first gripping section and the second gripping section.

A method, system and computer program product are provided for correction of automated insertion of a wire contact into a target hole of a connector. Methods include controlling a robot having an end-effector to: align the wire contact with the target hole of the connector; advance the wire contact toward and into the target hole of the connector; cease insertion in response to a force between the wire contact and the connector exceeding a predefined value; determining a depth of insertion; in response to the depth of insertion being above a predefined depth, perform a pull test on the inserted wire contact; in response to the depth of insertion being below a predetermined depth, identify an error condition using visual feedback; determine a number of corrective operations performed and perform error correction if the number is below a predefined number, while withdrawing the wire contact otherwise.

An operation tool includes a grasping mechanism that grasps a wire harness. The grasping mechanism includes a plurality of chuck parts that grasp a wire member, and two clamping members that are arranged so as to face each other in order to sandwich the wire member. A drive device of the grasping mechanism includes a movement mechanism that moves the second clamping member toward the first clamping member. The drive device includes a rotation mechanism that moves the first clamping member so as to rotate the wire member while the wire member is grasped by the chuck parts.

A robot hand according to an embodiment of the present technology includes a finger unit and a guide member. The finger unit is capable of holding a flexible linear member such that the linear member is slidable in a longitudinal direction of the linear member, the linear member being a linear member whose one end is fixed. The guide member is mounted on the finger unit, and includes a guide section that guides the linear member to a predetermined position.

A robot system that performs work of coupling a cable to a connector provided on a board, includes a robot in which a gripping unit that grips the cable and a force detection unit that detects a force acting on the gripping unit are provided, and a robot control apparatus that controls the robot, wherein the robot control apparatus controls the robot to perform a conveyance action for the gripping unit to grip the cable with a first gripping force and convey the cable onto the board, a correction action for the gripping unit to grip the cable with a second gripping force and correct a posture of the cable based on the force acting by pressing the cable against the connector, and an insertion action for the gripping unit to grip the cable with a third gripping force and insert the cable into the connector.

An operation tool includes a grasping mechanism that grasps a wire harness. The grasping mechanism includes a plurality of chuck parts that grasp a wire member, and two clamping members that are arranged so as to face each other in order to sandwich the wire member. A drive device of the grasping mechanism includes a movement mechanism that moves the second clamping member toward the first clamping member. The drive device includes a rotation mechanism that moves the first clamping member so as to rotate the wire member while the wire member is grasped by the chuck parts.

In a robot system, a control section causes a first gripping section to grip a connector of a cable, at one end of which the connector is provided and the other end of which is fixed, causes an imaging section to image the connector, causes, based on a result of the imaging by the imaging section, a second gripping section to grip the connector in a state in which the position of the first gripping section is maintained, causes the first gripping section to release the gripping of the connector, causes, based on the imaging result, the second gripping section to adjust a posture of the connector, and causes the first gripping section to grip the connector, the posture of which is adjusted, again.

A robot hand according to an embodiment of the present technology includes a finger unit and a guide member. The finger unit is capable of holding a flexible linear member such that the linear member is slidable in a longitudinal direction of the linear member, the linear member being a linear member whose one end is fixed. The guide member is mounted on the finger unit, and includes a guide section that guides the linear member to a predetermined position.