A method of estimating one or more mass characteristics of a payload manipulated by a robot includes moving the payload using the robot, determining one or more accelerations of the payload while the payload is in motion, sensing, using one or more sensors of the robot, a wrench applied to the payload while the payload is in motion, and estimating the one or more mass characteristics of the payload based, at least in part, on the determined accelerations and the sensed wrench.

A robot control apparatus includes a robot control part that controls a robot; and a force detection information acquisition part that acquires force detection information from a force detection unit. The robot control part, in which a range of control values for operating a robot by force control based on the force detection information is designated, operates the robot based on the control values and the designated range.

A manipulator is provided. The manipulator includes a gripper, a depth sensor, a force sensor configured to sense an external force acting on the gripper; a memory storing instructions; and a processor configured to execute the instructions to: control the gripper to grasp an object, acquire first information on the object based on a first sensing value obtained by the force sensor while grasping the object, control the gripper such that a first area of the object comes into contact with a surface on which the object is to be placed, acquire location information on a contact area between the first area and the surface, acquire a rotation direction to rotate the object based on the location information and the first information on the object, control the gripper to rotate the object in the rotation direction around the contact area, and based on a second area of the object being in contact with the surface, control the gripper to release the object.

A method for supporting creation of a program for supporting creation of a program for a robot that performs work on an object by force control for controlling a force acting on the object to be a target force, includes displaying a mark having an aspect indicating the target force on a display device, changing the aspect of the mark according to an operation on an input device by a user, and presenting a parameter in the force control corresponding to the aspect of the mark to the user.

There is provided a control method for a robot including a robot arm, the control method including a first step in which the robot arm grips a first target object and performs work for assembling the first target object and a second target object while changing a position or a posture of the first target object, a second step for setting, based on information concerning the position or the posture of the first target object during the work in the first step, a determination reference serving as a reference for starting the change of the position or the posture of the first target object or ending the change of the position or the posture of the first target object.

In the present invention, a tool tip point can be easily and intuitively defined without having to operate a robot. This robot control device comprises an acquisition unit for acquiring force data indicating an external force applied to a tool mounted to a robot as sensed by a sensor equipped to the robot, a point-of-action calculation unit for calculating the point of action of the external force on the basis of the force data as acquired by the acquisition unit, and a configuration unit for defining the point of action of the external force as a tool tip point of the robot.

The objective of the present invention is to provide a deburring control device capable of easily identifying the cause of a deburring failure. A deburring control device according to one aspect of the present disclosure controls deburring processing for removing burrs on a workpiece by moving a deburring tool along a ridge line of the workpiece by means of a robot, and is provided with: an offset amount calculating unit for calculating an offset amount between the actual path of the robot and a taught path thereof; a pressing force acquiring unit for acquiring the pressing force of the deburring tool; a rotational speed acquiring unit for acquiring the rotational speed of the deburring tool; a failure detecting unit for detecting a deburring failure, in which the deburring processing could not be performed appropriately, on the basis of the offset amount, the pressing force, and the rotational speed; and a recording unit for recording a failure reason, which is the reason for the failure detecting unit determining the deburring failure, when the deburring failure is detected.

A device for determining, in at least three spatial directions, a force acting on a body includes at least one sensor element for attaching to the surface of the body, which element includes at least three individual sensor elements, each individual sensor element being designed to determine an individual force in one direction, or which includes at least one individual sensor element which is used to determine an individual force in three spatial directions, and an evaluation/control unit which records the individual force determined by each individual sensor element and is designed to calculate the force acting on the sensor element in at least three spatial directions by projecting the individual forces onto a virtual point of the sensor element. A method for determining a force acting on a body in at least three spatial directions and a method for controlling the movement of a body is disclosed.

Robotic medical systems can be capable of contact sensing and contact reaction. A robotic medical system can include a robotic arm and one or more sensors. The robotic medical system can be configured to detect, via the one or more sensors, a contact force or torque that is exerted on the robotic arm by an external object. In response to detecting the contact force or torque, and in accordance with a determination that a magnitude of the contact force or torque is between a lower contact force or torque limit and an upper contact force or torque limit, the robotic medical system can enable a first set of controlled movements on the robotic arm in accordance with the detected contact force or torque.

Methods and robot, where payload information of a payload attached to a robot tool flange of a robot arm are obtained by arranging the robot tool flange in a plurality of different orientations in relation to gravity; obtaining the force and the torque provided to the robot tool flange by gravity acting on the payload using a force torque sensor arranged at the robot tool flange; obtaining the mass of the payload based on the obtained forces obtained at at least two of the different orientations. The dependent claims describe possible embodiments of the robot and methods according to the present invention.