A measurement system includes a plurality of reflectors of a robot, a measurement apparatus having a laser head which emits a laser beam toward the reflectors and which receives a reflected light from the reflectors, a head driving device which changes orientation of the laser head, and a robot control apparatus which controls the robot based on the calibration operation program and which sequentially places the distal end portion of the robot at a plurality of measurement positions for conducting calibration. The robot control apparatus conducts a head drive control process of receiving controller coordinate data of any one of the plurality of reflectors, which is used at the time of sequentially placing the distal end portion of the robot at plurality of measurement positions, and sending a control signal for changing the orientation of the laser head to the head driving device by using the received controller coordinate data.

An objective is to provide a position and posture adjustment method capable of promptly adjusting the position and the posture of a robot with respect to a workpiece while making variations caused by the operator small. The position and posture adjustment method includes provisional teaching step S1, marker installation step S2 of installing a marker having a head cut conical shape in the workpiece, an initial movement step S3 of moving an arm distal end portion such that the irradiated positions of three laser displacement gauges are arranged within the end surface of the marker, posture modification step S4 of moving the arm distal end portion such that the measured values of the three laser displacement gauges become close to one another, approach step S5 of bringing the arm distal end portion close to the marker along the Z axis, alignment step S6 of causing an axis of the arm distal end portion and a marker axis to coincide with each other by moving the arm distal end portion parallel along a plane perpendicular to the Z axis such that the measured values of the three laser displacement gauges become close to one another, and positioning step S7 of adjusting the position of the arm distal end portion by moving the arm distal end portion along the Z axis.

A calibration equipment of a mechanical system includes a light emitter emitting a light beam, a light sensing module, and an operating module. The light sensing module includes a carrier plate, and a plurality of light sensing units located on the carrier plate. The plurality of light sensing units receive the light beam and generate a plurality of image data. The operating module receives the plurality of image data and generates a calibrated kinematic parameter.

A method of operating a mobile construction robot includes placing an optical tracker on an architectural construction site and parking a driving platform of the robot on the site. An end effector of the robot is moved in first and second positions and the first and second positions of the end effector relative to the driving platform are measured. An optical marker mounted to the end effector is tracked in the first and second positions of the end effector with the optical tracker and the first and second positions of the optical marker relative to the optical tracker is measured with the optical tracker. A position and an orientation of the driving platform is determined based on the measured first and second position of the end effector relative to the driving platform and the measured first and second position of the optical marker relative to the optical tracker.

An apparatus includes a robotic manipulator with a stationary base, and an end effector actuated by the robotic manipulator, wherein the end effector is adjacent to a workpiece. A scanning laser head unit includes a laser and an optical train configured to move a laser beam over the workpiece. A control unit is configured to move the robotic manipulator such that movement of the end effector tracks movement of the laser beam.

A spatial accuracy correction apparatus performs a spatial accuracy correction of a positioner displacing a displacer to a predetermined set of spatial coordinates using a measurable length value measured by an interferometer and a measurable value of the set of spatial coordinates of the displacement body that is measured by the positioner. The measured length value and the measured value for each measurement point are acquired by displacing the displacement body to a plurality of measurement points in order, one or more repeated measurements are conducted for at least one of the plurality of measurement points being measured after conducting measurement of the measured length value and the measured value for each of the plurality of measurement points, and the plurality of points are measured again when a repeat error of the measured length value is equal to or greater than a threshold value.

A method that corrects an error in positioning in a positioning mechanism by using a measurable length value measured by a laser interferometer and a measured value for spatial coordinates measured by the positioning mechanism. The method includes a measurement step in which a retroreflector affixed to a displacer is displaced to a plurality of measurement points, and the measured length value and the measured value at each of the measurement points is acquired; and a parameter calculation step in which a correction parameter is calculated based on the measured value, the measured length value, and the coordinates of a rotation center of the tracking-type laser interferometer. A first correction constant is applied to the measured length value for each measurement line, and a second correction constant different from the first correction constant is applied to the coordinates of the rotation center of the interferometer for each measurement line.

A measurement system includes a plurality of reflectors of a robot, a measurement apparatus having a laser head which emits a laser beam toward the reflectors and which receives a reflected light from the reflectors, a head driving device which changes orientation of the laser head, and a robot control apparatus which controls the robot based on the calibration operation program and which sequentially places the distal end portion of the robot at a plurality of measurement positions for conducting calibration. The robot control apparatus conducts a head drive control process of receiving controller coordinate data of any one of the plurality of reflectors, which is used at the time of sequentially placing the distal end portion of the robot at plurality of measurement positions, and sending a control signal for changing the orientation of the laser head to the head driving device by using the received controller coordinate data.

Provided is a machine system having optical endpoint control and associated method for maintaining having is provided constant optical contact. Specifically, the machine system comprises a machine capable of movement in at least one direction. The machine is configured such that, during a calibration phase, a steerable retroreflective system is mounted upon the machine for movement therewith. A controller is configured to control the movement of the machine in at least one direction. The machine system may be configured to automatically adjust the feedrate of the machine, upon determining that a velocity required for the positioner to move the retroreflector to a desired position exceeds a certain segment feedrate threshold, such that an incident beam of light can maintain constant contact with the retroreflector throughout movement of the machine from the first position to the second position.

Methods of correcting positional misalignment of blades in robots, such as dual-bladed robots, are described. The methods include, in one or more embodiments, a robot including moveable arms and an end effector attached to one of the moveable arms, a flag disposed on one of the moveable arms or the end effector, a chamber adapted to be serviced by the end effector, a beam sensor positioned at a distance from the chamber, and correcting misalignment of the end effector wherein the misalignment occurs between an initial linear center-finding location and the estimated center of the chamber. Systems of such electronic device calibration are also disclosed. Numerous other aspects are provided.