One variation of a method for manipulating a multi-link robotic arm includes: accessing a virtual model of the target object; extracting an object feature representing the target object from the virtual model; at the robotic arm, scanning a field of view of an optical sensor for the object feature, the optical sensor arranged on a distal end of the robotic arm proximal an end effector; in response to detecting the object feature in the field of view of the optical sensor, calculating a physical offset between the target object and the end effector based on a position of the object feature in the field of view of the optical sensor and a known offset between the optical sensor and the end effector; and driving a set of actuators in the robotic arm to reduce the physical offset.

An arrangement for the model-based calibration of a mechanism in a workspace with calibration objects that are either directed laser radiation patterns together with an associated laser radiation-pattern generator or radiation-pattern position sensors. Functional operation groups made up of at least one laser radiation pattern and at least one position sensor interact in such a way when a radiation pattern impinges on the sensor that measured sensor position information values are passed along to computing devices that determine the parameters of a mathematical mechanism model with the aid of these measured values. In the process, at least two different functional operation groups are used to calibrate the mechanism, and at least two calibration objects from different functional operation groups are rigidly connected to one another.

A method and system are disclosed herein. The system includes a measuring device detecting a position and a travel distance of movement of the robot, a communication circuit, a memory, and a processor. The processor implements the method, including: specifying a robot coordinate system of the robot based on the measured position data, generating, using the processor, robot reference position data by converting the measured position data based on the specified robot coordinate system, performing, using the processor, position-based parameter optimization based on the robot reference position data, and storing, using a memory, a parameter optimized through the position-based parameter optimization; and transmitting, using a communication circuit, the stored optimized parameter to the robot to actuate movement of the robot based on the stored optimized parameter.

For calibration on a single camera or a stereo camera, a calibration range is set in advance in an image coordinate system and the calibration is performed in an arbitrary range. A visual sensor controller is a calibration device that associates a robot coordinate system at a robot and an image coordinate system at a camera by placing a target mark at the robot, moving the robot, and detecting the target mark at multiple points in a view of the camera. The calibration device comprises: an image range setting unit that sets an image range in the image coordinate system at the camera; and a calibration range measurement unit that measures an operation range for the robot corresponding to the image range before implementation of calibration by moving the robot and detecting the target mark.

A jig according to the present disclosure includes N planes (N is an integer equal to or larger than 4) respectively attached with patterns, in which

90<<90(1)

00(2)

where is an angle formed by, with respect to a reference normal vector perpendicular to a jig reference plane, the jig reference plane being one plane among the N planes, and having a direction from the jig reference plane toward a space in which the stereo camera is disposed, a non-reference normal vector perpendicular to a non-reference plane different from the jig reference plane among the N planes and having a direction from the non-reference plane toward the space in which the stereo camera is disposed. Non-reference normal vectors corresponding to N1 non-reference planes among the N planes have directions different from one another with respect to the reference normal vector and do not have directions symmetrical with respect to the reference normal vector.

Systems and methods for automating robotic end effector alignment using real-time data from multiple distance sensors to control relative translational and rotational motion. In accordance with one embodiment, the alignment process involves computation of offset distance and rotational angles to guide a robotic end effector to a desired location relative to a target object. The relative alignment process enables the development of robotic motion path planning applications that minimize on-line and off-line motion path script creation, resulting in an easier-to-use robotic application. A relative alignment process with an independent (off-board) method for target object coordinate system registration can be used. One example implementation uses a finite-state machine configuration to control a holonomic motion robotic platform with rotational end effector used for grid-based scan acquisition for non-destructive inspection.

Provided is a teaching position correction device including a vision sensor attached to a tip end of an arm of a robot; a measurement unit measuring a three-dimensional position of the tip end of the robot when the sensor is arranged at a predetermined position with respect to each of reference points provided on an object or a holding device and not arranged on one straight line; and a calculation unit calculating relative positions of the reference points based on the measured three-dimensional position while the sensor is translated, where a teaching point position in an operation program of the robot is corrected in such a way that a change in relative positions of the robot and the holding device is compensated for, based on the relative positions of the reference points calculated before and after relocation of at least one of the robot and the holding device.

A measurement system including: reflectors mounted on a robot; a measuring apparatus including a laser head, wherein the measuring apparatus includes a controller, the controller is configured to conduct: a coordinate relationship acquisition process for acquiring a position and a direction of a measuring-apparatus coordinate system with respect to a robot coordinate system by emitting a laser beam from the laser head toward reference reflection portions provided in a base portion of the robot, and based on a reflected light; and a head drive control process which controls a direction of the laser head by receiving coordinate data of the reflector recognized by a controller of the robot, and by making a control command to change the direction of the laser head using the coordinate data which is received and the position and the direction of the measuring-apparatus coordinate system with respect to the robot coordinate system.

A method for manipulating a multi-link robotic arm includes: at a first time, recording a first optical image through an optical sensor arranged proximal a distal end of the robotic arm proximal an end effector; detecting a global reference feature in a first position in the first optical image; virtually locating a global reference frame based on the first position of the global reference feature in the first optical image; calculating a first pose of the end effector within the global reference frame at approximately the first time based on the first position of the global reference feature in the first optical image; and driving a set of actuators within the robotic arm to move the end effector from the first pose toward an object keypoint, the object keypoint defined within the global reference frame and representing an estimated location of a target object within range of the end effector.

Disclosed are systems and methods to provide a method for calibrating a touchscreen coordinate system of a touchscreen with an industrial robot coordinate system of an industrial robot for industrial robot commissioning and industrial robot system and control system using the same. In one form the systems and methods include attaching an end effector to the industrial robot; (a) moving the industrial robot in a compliant way until a stylus of the end effector touches a point on the touchscreen, (b) recording a position of the stylus of the end effector in the industrial robot coordinate system when it touches the point of the touchscreen; (c) recording a position of the touch point on the touchscreen in the touchscreen coordinate system; and calculating a relation between the industrial robot coordinate system and the touchscreen coordinate system based on the at least three positions of the end effector stylus and the at least three positions of the touch points.