Various embodiments described herein relate to techniques for object height detection for palletizing operations and/or depalletizing operations. In this regard, an automated industrial system comprises at least a column portion, a robot arm portion, and an end effector configured to grasp an object. An image-capturing device is mounted onto the automated industrial system and is configured to rotate, based on movement of the robot arm portion, to scan the object grasped by the end effector and to generate image-capturing data associated with the object. Furthermore, a processing device is configured to determine height data for the object based on the image-capturing data. The processing device is also configured to determine location data for the object with respect to a conveyor system based on the height data.

A system includes a robotic system including a robot disposable at a mobile workstation, where the robot is configured to perform an automated operation on a workpiece. The system includes one or more transfer robots configured to transfer the robotic system to or from the mobile workstation. The system includes a control system configured to command the transfer robot to perform a transfer operation of the robotic system, where the transfer operation includes at least one of disposing the robotic system at the mobile workstation or retrieving the robotic system from the mobile workstation. The control system is configured to control the mobile workstation and the robotic system based on image data from the one or more infrastructure sensors, position data from the one or more on-board position sensors, the automated operation to be performed by the robot, or a combination thereof.

A manufacturing process adopting the reconfigurable robotic manufacturing cells that can work conjointly and yet have the capabilities to be reconfigured to disconnect from other cells and handle multiple tasks. The reconfigurable robotic cell is not dependent on any other robotic cells to complete work in progress.

Example implementations described herein involve systems and methods for operation of a robot configured to work on a first process and a second process, which can involve receiving sensor data indicative of a status of one or more of the first process and the second process; for the status indicative of the first process waiting on the robot, controlling the robot to work on the first process; and for the status indicative of the first process not waiting on the robot, controlling the robot to conduct one or more of work on the second process or return to standby.

An article supplying apparatus includes a retention unit configured to retain an article, a robot hand configured to insert the article retained in the retention unit into a container, and a control unit configured to control operation of the robot hand. The robot hand has a holding portion for holding the article. The control unit executes holding control in which the article is held by the holding portion; and stand-by insertion control in which after the holding portion is temporarily disposed at a stand-by position different from a position immediately above an article insertion port in the container and set on a movement path from a start position of the holding through the holding control to the position immediately thereabove, the holding portion is moved to the position immediately thereabove, and the article is inserted into the container via the article insertion port.

In some implementations, a system may receive, from a camera, an image that depicts an object on a conveyor. The system may cause, based on an image processing model indicating that the image depicts the object, a robotic arm to attach to a label printer. The system may determine, using the image processing model, an object position of the object on the conveyor. The system may cause the robotic arm to move the label printer into an application position that corresponds to the object position on the conveyor. The system may cause the label printer to print a label. The system may cause the label printer to apply the label to the object.

A method for picking and placing items includes the steps of: providing a picking conveyor transporting items to be picked; providing a placing conveyor to which the items are to be placed; and providing a plurality of robots configured to move the items from pick positions on the picking conveyor to place positions on the placing conveyor. For at least one of the plurality of robots there is defined an actual work area A.sub.ac that fulfils the condition A.sub.ac<A.sub.th−(A.sub.ol+A.sub.ex), wherein A.sub.th is a theoretical work area, A.sub.ol is an overlapping work area and A.sub.ex is an excessive work area of the respective robot. By limiting the actual work area A.sub.ac of the robots more than what is done conventionally, the total workload between the robots in pick and place systems may be balanced.

A robot system including a robot, an image capturing device, and a controller. The controller and the image capturing device have clocks, the controller conducts transmission of, to the image capturing device, an image-capturing instruction including a predetermined waiting time, the predetermined waiting time being a time between a time of the transmission and an image capturing time, or a required time obtained by subtracting, from the waiting time, a difference time between the time of the transmission and receiving time of the image-capturing instruction, the image capturing device conducts image capturing of an image of the workpiece at time when the required time elapses from the receiving time and transmits image data, and the controller controls the robot based on position information of the robot at time when the waiting time elapses from the time of the transmission and the image data.

A dynamic movement analytics system is disclosed that includes a programmable motion device including an end-effector, and a perception transfer system for receiving an object from the end-effector and for moving the object toward a distribution conveyance system moving in a first direction at a first speed. The perception transfer system includes at least one perception system for providing perception data regarding any of weight, shape, pose authority, position authority or identity information regarding the object and for moving the object along the first direction at the first speed for transferring the object to the distribution conveyance system.

A waste sorting robot can include a manipulator comprising a suction gripper for interacting with one or more waste objects to be sorted within a working area, and wherein the manipulator is moveable within the working area. There is a controller configured to send control instructions to the manipulator. At least one pressure sensor is in fluid communication with the suction gripper and configured to generate a pressure signal in dependence on a fluid pressure in the suction gripper. The controller is configured to receive the pressure signal and to determine manipulator instructions in dependence on the pressure signal.