A robot controller includes a storage unit that stores load information including a mass and a center of gravity position of a load to be attached to a robot; a lead-through control unit that controls the robot comprising a sensor that detects an external force, based on the external force detected by the sensor and the load information stored in the storage unit; and a load suitability determining unit that determines whether or not the load information stored in the storage unit is suitable. In response to the load suitability determining unit determining that the load information has a possibility of being unsuitable, the lead-through control unit performs a restriction on a movement of the robot.

A robot teaching device capable of simplifying a work involved in teaching a robot. The robot teaching device includes a position data storing section configured to store target position data for a robot; an operation instruction storing section configured to store an operation instruction for arranging the robot at a target position, the operation instruction not including the target position data; and a position data writing section configured to acquire current position data of the robot when the operation instruction is input, the position data writing section further configured to write, to the position data storing section, the current position data as the target position data together with a unique identifier, in which the identifier of the target position data is automatically given to the operation instruction being input to teach an operation to the robot.

A system for performing an input on a robotic manipulator, wherein the system includes: a robotic manipulator having a plurality of limbs connected to one another by articulations and having actuators; a sensor unit configured to record an input variable, applied by a user by manually guiding the robotic manipulator, on the robotic manipulator, wherein the input variable is a kinematic variable or a force and/or a moment, and wherein the sensor unit is configured to transmit the input variable; and a computing unit connected to the robotic manipulator and to the sensor unit, the computing unit configured to transform the input variable received from the sensor unit via a predefined input variable mapping, wherein the input variable mapping defines a mathematical mapping of the input variable onto a coordinate of a graphical user interface or onto a setting of a virtual control element.

A substrate mapping device 4 maps a plurality of substrates 10 inside a container where the substrates 10 are accommodated so as to be arrayed in a given arrayed direction. The substrate mapping device 4 includes a sensor 16 configured to detect a state of the substrate 10, a manipulator 14 configured to move the sensor 16, and a control device 18 configured to control the manipulator 14 to move the sensor 16 along a mapping course. The control device 18 sets a first mapping position and a second mapping position different in the position in the arrayed direction of the substrates 10 from the first mapping position, and sets the mapping course based on the first mapping position and the second mapping position.

A robot control device executes assist control for generating an assist force in a direction of an external force applied to a robot in a case where a position of the robot is located in a first area set in a work area of the robot when the external force is applied to the robot. The robot control device stops the execution of the assist control in a case where the position of the robot is located in a second area set outside the work area of the robot. The robot control device restricts the execution of the assist control in a case where the position of the robot is located in a third area set outside the first area and inside the second area.

A teaching method for detecting external force applied to a robot arm, driving the robot arm with force control based on the external force, and teaching a position and a posture of the robot arm, the teaching method including gradually relaxing, according to an elapsed time from when operation of the robot arm is started or a movement amount of the robot arm from when the operation of the robot arm is started, a restrictive condition for restricting the driving of the robot arm.

This patent defines a method for making robot programming more intuitive for tasks such as welding. The method further is an enhancement of manual guiding methods of robot positioning and can improve situations in which finer resolution or control of the robot end-effector is required. A motion sensor is mounted in series with the n−1 joint and in parallel with the n.sup.th joint, where n is the number of degrees of freedom or number of joints of the serial manipulator. The motion sensor is further mounted directly in-line with the n.sup.th joint and becomes part the opposing portion of the n.sup.th joint. The motion sensor further is uniquely adapted to apply to non-spherical wrist robots. The motion sensor senses input movements by a robot operator and controls the output tool motion in a controlled manner with resolution defined by user input at the motion sensor.

An automatic teaching system for a substrate processing apparatus, the automatic teaching system comprising a frame having a workpiece load station with a predetermined load station reference location, a robot transport mounted to the frame and having a movable transport arm with an end effector having a predetermined end effector reference location, and a drive section driving the movable transport arm in at least one degree of freedom motion relative to the frame, a machine vision system including both at least one fixed imaging sensor and at least one movable imaging sensor removably connected to the frame and configured to image at least one target of the machine vision system, a load jig disposed for removable engagement with the workpiece load station, with both the at least one fixed imaging sensor and the at least one movable imaging sensor mounted to the load jig, the fixed imaging sensor.

A robot system with a hand-guiding function is disclosed. The robot system selects the hand-guiding function or non-hand-guiding function of an enable device by a mode option mechanism during the operation of a teach mode or an automatic mode. When selecting the hand-guiding function, the enable device has both the enabling and the hand-guiding function to easily hand-guiding the robot to operate.

An automatic teaching system for a substrate processing apparatus, the automatic teaching system comprising a frame having a workpiece load station with a predetermined load station reference location, a robot transport mounted to the frame and having a movable transport arm with an end effector having a predetermined end effector reference location, and a drive section driving the movable transport arm in at least one degree of freedom motion relative to the frame, a machine vision system including both at least one fixed imaging sensor and at least one movable imaging sensor removably connected to the frame and configured to image at least one target of the machine vision system, a load jig disposed for removable engagement with the workpiece load station, with both the at least one fixed imaging sensor and the at least one movable imaging sensor mounted to the load jig, the fixed imaging sensor.