The invention relates to a method for calibrating a virtual force sensor of a robot manipulator, wherein the following steps are carried out in a plurality of poses: applying an external wrench to the robot manipulator, ascertaining an estimate of the external wrench, ascertaining a first calibration matrix based on the ascertained estimate and a specified external wrench, ascertaining a second calibration matrix by inverting the first calibration matrix, and storing the respective second calibration matrix in a data set of all of the second calibration matrices, thereby assigning each second calibration matrix to the respective pose for which each second calibration matrix was ascertained.

A deburring device includes a robot program creating unit that creates a program from data of an object, a deburring part detecting unit that detects a position for a deburring part on the object, and a robot program updating unit that updates the program by the detected position of the deburring part. The deburring device also includes a force control unit that controls to yield a predetermined pressing force, an actual path acquiring unit that acquires an actual path of a robot when controlled at the predetermined pressing force by the updated program, and a path correction parameter calculating unit that calculates a correction parameter for the position for the deburring part on the object from the path of the robot from the visual sensor and the actual path.

A robot balance control method includes: obtaining force information associated with a left foot and a right foot of the robot; calculating a zero moment point of a center of mass (COM) of a body of the robot based on the force information; calculating a first position offset and a second position offset of the robot according to the zero moment point of the COM of the body; updating a position trajectory of the robot according to the first position offset and the second offset to obtain an updated position of the COM of the body; performing inverse kinematics analysis on the updated position of the COM of the body to obtain joint angles of the left leg and the right leg of the robot; and controlling the robot to move according to the joint angles.

A method of adjusting an action parameter includes a positional posture determination step of making a robot execute a task a plurality of times in a plurality of positional postures different in positional posture of an object when starting the task to obtain evaluation values of the respective tasks, comparing the evaluation values of the tasks out of the evaluation values of the respective tasks with a reference evaluation value, and determining an evaluation positional posture from the positional postures in the tasks in which the evaluation value is no higher than the reference evaluation value, an updating step of making the robot operate with a tentative action parameter using the evaluation positional posture as a starting positional posture in the task to measure a time taken for the task or a vibration of the robot, and updating the tentative action parameter based on a measurement result, and a determination step of repeatedly performing the updating step until the time taken for the task or the vibration of the robot measured is converged to determine latest one of the tentative action parameters as an action parameter when actually performing the task.

A system for assembling a vehicle platform includes a robotic assembly system having at least two robotic arms, a vision system capturing images of an assembly frame, and a control system configured to control the robotic assembly system to assemble the vehicle platform based on images from the vision system, force feedback from the at least two robotic arms, and a component location model. The control system is further configured to identify assembly features of a first component and a second component of the vehicle platform from the images, operate the robotic arms to orient the first component and the second component to respective nominal positions based on the images and the component location model, and operate the robotic arms to assemble the first component to the second component based on the force feedback.

A force sensor unit includes a force sensor, a casing housing the force sensor within a space surrounded by one end portion, another end portion, and a side portion, an attachment member having a first attachment portion that can be attached to a robot arm of a robot and a second attachment portion detachably attached to the one end portion of the casing in a position different from that of the first attachment portion, and a wiring cable connected to the force sensor and routed from inside the casing to outside of the casing, wherein a positioning portion for positioning with respect to the robot arm is provided in the first attachment portion, and a part of the wiring cable is provided along a circumferential direction of the side portion.

A control device of a robot includes a robot control section configured to control the robot so as to sequentially position the robot at a plurality of target positions, which are set based on shape data representing a shape of a workpiece, and cause the robot to execute a work along a work target portion on the workpiece, and cause the robot to continue the work beyond a final target position of the plurality of target positions after the robot reaches the final target position, the final target position being set to correspond to an end of the work target portion in the shape data.

A device for a robot is disclosed. In the device for a robot, a first signal is transmitted from a robot control device to the robot, a second signal is transmitted from the robot control device to the device for a robot, and a third signal is transmitted from the robot control device to the device for a robot, the third signal being transmitted from the robot control device in a case where there is a communication error between the robot control device and the device for a robot so that the device for a robot is restarted via a reset circuit.

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 robot system capable of reliably detecting contact between a robot or a workpiece and an external object. The robot system includes: a robot including a handling part; a handling force-detection part that detects a handling force applied to the handling part; an operation controller that causes the robot to operate in accordance with the handling force; an external force-detection part that detects an external force acting on the robot; and a contact force-calculation part that calculates a contact force by subtracting the handling force from the detected external force.