A control device includes a robot control section that controls a robot including a hand and a force detecting section; and a operation-mode switching section that switches, when storing a position and a posture of the robot, a first mode for moving the robot by the robot control section until an external force applied to the hand satisfies a predetermined condition and a second mode for moving the robot by the robot control section on the basis of an external force applied to a first part included in the robot.

A robot control device includes a learning control unit for calculating a learning correction amount, a position storage unit for storing a position of a leading end of a robot mechanism part during the learning control, and a speed storage unit for storing a speed of the leading end of the robot mechanism part during the learning control. The robot control device determines, while the robot mechanism part is operated by a position command after the learning control, whether or not the position and the speed of the leading end are in an abnormal state based on errors with respect to the position and the speed of the leading end stored during the learning control. The robot control device switches a determination as to whether the learning correction amount is applied in accordance with this determination result.

A robot control device includes a learning control unit for calculating a learning correction amount, a position storage unit for storing a position of a leading end of a robot mechanism part during the learning control, and a speed storage unit for storing a speed of the leading end of the robot mechanism part during the learning control. The robot control device determines, while the robot mechanism part is operated by a position command after the learning control, whether or not the position and the speed of the leading end are in an abnormal state based on errors with respect to the position and the speed of the leading end stored during the learning control. The robot control device switches a determination as to whether the learning correction amount is applied in accordance with this determination result.

Systems and methods of operating power tools. The method includes receiving a command to start a recording mode at a first electronic processor of a first power tool, and receiving at the first electronic processor, a measured parameter from a sensor of the first power tool while a first motor of the first power tool is operating. The method also includes generating a recorded motor parameter by recording the measured parameter, on a first memory of the first power tool, when the first power tool operates in the recording mode, and transmitting, with a first transceiver of the first power tool, the recorded motor parameter. The method further includes receiving the recorded motor parameter at an external device, transmitting the recorded motor parameter to a second power tool via the external device, and receiving the recorded motor parameter via a second transceiver of the second power tool.

This invention relates to force/torque sensor and more particularly to multi-axis force/torque sensor and the methods of use for directly teaching a task to a mechatronic manipulator. The force/torque sensor has a casing, an outer frame forming part of or connected to the casing, an inner frame forming part of or connected to the casing, a compliant member connecting the outer frame to the inner frame, and one or more measurement elements mounted in the casing for measuring compliance of the compliant member when a force or torque is applied between the outer frame and the inner frame.

This invention relates to force/torque sensor and more particularly to multi-axis force/torque sensor and the methods of use for directly teaching a task to a mechatronic manipulator. The force/torque sensor has a casing, an outer frame forming part of or connected to the casing, an inner frame forming part of or connected to the casing, a compliant member connecting the outer frame to the inner frame, and one or more measurement elements mounted in the casing for measuring compliance of the compliant member when a force or torque is applied between the outer frame and the inner frame.

A device for robotic direct lead-through teaching includes a robot, a replacing member and a lead-through teaching member. The robot has an operation member coupled with the replacing member. The lead-through teaching member mounted replaceably at the replacing member has a force sensor. The force sensor has six-axis load information. A path teaching is executed manually upon the operation member of the robot so as to store coordinate information. In additional, a method for robotic direct lead-through teaching is also provided.

A device for robotic direct lead-through teaching includes a robot, a replacing member and a lead-through teaching member. The robot has an operation member coupled with the replacing member. The lead-through teaching member mounted replaceably at the replacing member has a force sensor. The force sensor has six-axis load information. A path teaching is executed manually upon the operation member of the robot so as to store coordinate information. In additional, a method for robotic direct lead-through teaching is also provided.

The present invention relates to a method and to a device for defining a movement sequence for a multi-axis manipulator of a robot system, which manipulator has a plurality of elements which form different rotational axes, and an end element for interaction with an effector, wherein the effector is intended to carry out at least one arbitrary operation in a working space, and wherein in order to carry out the at least one arbitrary operation the end element of the manipulator is to be transferred into an arbitrary target pose with respect to the working space, wherein the manipulator moves in a plurality of steps to the target pose while approaching the end element, and for each step at least one defined impedance pattern and/or admittance pattern is defined with respect to at least one axis which forms the axis of a coordinate system which is linked to the manipulator.

The present invention relates to a method and to a device for defining a movement sequence for a multi-axis manipulator of a robot system, which manipulator has a plurality of elements which form different rotational axes, and an end element for interaction with an effector, wherein the effector is intended to carry out at least one arbitrary operation in a working space, and wherein in order to carry out the at least one arbitrary operation the end element of the manipulator is to be transferred into an arbitrary target pose with respect to the working space, wherein the manipulator moves in a plurality of steps to the target pose while approaching the end element, and for each step at least one defined impedance pattern and/or admittance pattern is defined with respect to at least one axis which forms the axis of a coordinate system which is linked to the manipulator.