A workpiece processing apparatus includes two workpiece conveyance robots capable of traveling on the same traveling table and capable of carrying a workpiece into and out of a processing section, and a control device for performing movement control of the workpiece conveyance robot. The two workpiece conveyance robots include a first robot and a second robot. The control device includes a first determination section configured to determine, from a first difference between a first robot next instruction value which is an instruction value related to a movement control instruction issued to the first robot immediately after a time when a determination as to whether the first robot starts the traveling starts and indicates a movement destination position of the first robot and a second robot movement destination position which is a value related to a movement control instruction executed by the second robot at the time when the determination starts and indicates a movement destination position of the second robot, movability of the first robot by the movement control instruction.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for logging real-time data of a robot control system. One of the systems comprises a real-time robotic control system comprising one or more computers, programmed to perform operations comprising i) software module loops and ii) real-time data logging, wherein each software module loop comprises a plurality of software modules executed repeatedly in a predetermined sequence, each software module executes within a predetermined time window, and the real-time data logging comprises copying segments of real-time data used by a particular software module to a buffer accessible by a non-real-time downstream system, wherein each segment of real-time data is copied at a respective predetermined time relative to execution of the software modules in the software module loop; and the non-real-time downstream system comprising one or more computers, the non-real-time downstream system programmed to perform operations that consume the real-time messages.

A system including a controller, and at least two agents that communicatively access the controller. At least one of the agents is a robot. The system includes at least one processor communicatively coupled to the agents, and at least one storage device, communicatively coupled to the processor(s), that stores processor-executable instructions which, when executed, cause the processor(s) to: receive first job set of instructions provided by the controller, for a first agent included in at least two agents; and send, on behalf of the first agent, a sham status message before actual completion of the first job. The processor-executable instructions may, when executed, further cause the at least one processor to: update a data store to reflect the first job set of instructions; and receive for a second one of the at least two agents a second job set of instructions before completion of the first job.

A robot including a motor is used to machine a workpiece. The robot further includes the following components: a controller configured to output a speed command and commanded-position information; an encoder; a position sensor configured to output, as a differential signal, the amount of displacement of the position of the workpiece W from a predetermined position; a servo driver configured to control the motor upon receiving the speed command, the output signal of the encoder, and the differential signal; and a safety unit configured to detect a fault in the encoder. When controlling the motor based on the speed command, the output signal, and the differential signal, the servo driver sends the differential signal to the controller. The controller sends the safety unit new commanded-position information, which is generated by adding a correction value based on the differential signal to the commanded-position information.

An approach to positioning one or more robotic arms in an assembly system may be described herein. For example, a system for robotic assembly may include a first robot, a second robot, and a control unit. The control unit may be configured to receive a first target location proximal to a second target location. The locations may indicate where the robots are to position the features. The control unit may be configured to calculate a first calculated location of the first feature of the first subcomponent, measure a first measured location of the first feature of the first subcomponent, determine a first transformation matrix between the first calculated location and the first measured location, reposition the first feature of the first subcomponent to the first target location using the first robot, the repositioning based on the first transformation matrix.

An articulated arm system is disclosed that includes an articulated arm including an end effector, and a robotic arm control systems including at least one sensor for sensing at least one of the position, movement or acceleration of the articulated arm, and a main controller for providing computational control of the articulated arm, and an on-board controller for providing, responsive to the at least one sensor, a motion signal that directly controls at least a portion of the articulated arm.

A brake piloting system including a robotic device having at least one movable element, at least one brake which, when activated from an open configuration to an activated configuration, enables a deceleration or immobilization of the at least one movable element, at least one position sensor aimed at measuring a real time position of the at least one movable element and at least one the microcontroller being configured to activate in real time the at least one brake into a determined configuration.

A robot system including a robot and a control device that controls the robot. The robot includes a first member, a second member that is rotationally driven around a predetermined first axis relative to the first member, and a first torque detector that detects a torque around the first axis. The control device includes an external-force upper-limit-value estimator that estimates an external-force upper limit value serving as an assumable upper limit value for an external force acting on the second member based on the torque detected by the first torque detector, and controls the robot to avoid an increase in the external force when the estimated external-force upper limit value is larger than a predetermined threshold value.

A method of correcting an angular transmission error for a reducer of creating correction data for correction of an angular transmission error of the reducer in a robot system including an arm, the reducer having an input shaft and an output shaft, a motor, an encoder, and an inertial sensor, includes rotating the arm in an input rotation angular range smaller than a necessary input rotation angular range, measuring and recording the angular transmission error, determining whether or not an accumulated value of measurement times is equal to or larger than a predetermined value, when the accumulated value is smaller than the predetermined value, measuring the angular transmission error of the reducer and updating a record, and, when the accumulated value is equal to or larger than the predetermined value, creating the correction data based on the recorded angular transmission error of the reducer.