A control method for a robot system including a moving stage, a tool attached to the moving stage, and a robot arm holding one of the moving stage and an object and performing predetermined work on the object using the tool, includes performing the work while moving the tool relative to the object by the moving stage with the robot arm stopped, wherein a portion having a larger curvature has a smaller range of the work than a portion having a smaller curvature of the object.

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.

Embodiments of the present disclosure are directed to methods, computer program products, and computer systems of a robotic apparatus with robotic instructions replicating a food preparation recipe. In one embodiment, a robotic control platform, comprises one or more sensors; a mechanical robotic structure including one or more end effectors, and one or more robotic arms; an electronic library database of minimanipulations; a robotic planning module configured for real-time planning and adjustment based at least in part on the sensor data received from the one or more sensors in an electronic multi-stage process file, the electronic multi-stage process recipe file including a sequence of minimanipulations and associated timing data; a robotic interpreter module configured for reading the minimanipulation steps from the minimanipulation library and converting to a machine code; and a robotic execution module configured for executing the minimanipulation steps by the robotic platform to accomplish a functional result.

In accordance with certain implementations of the present approach, a reduced, element-by-element, data set is transmitted between a robot having a sensor suite and a control system remote from the robot that is configured to display a representation of the environment local to the robot. Such a scheme may be useful in allowing a human operator remote from the robot to perform an inspection using the robot while the robot is on-site with an asset and the operator is off-site. In accordance with the present approach, an accurate representation of the environment in which the robot is situated is provided for the operator to interact with.

One variation of a method for autonomously scanning and processing a part includes: collecting a set of images depicting a part positioned within a work zone adjacent a robotic system; assembling the set of images into a part model representing the part. The method includes segmenting areas of the part model—delineated by local radii of curvature, edges, or color boundaries—into target zones for processing by the robotic system and exclusion zones avoided by the robotic system. The method includes: projecting a set of keypoints onto the target zone of part model defining positions, orientations, and target forces of a sanding head applied at locations on the part model; assembling the set of keypoints into a toolpath and projecting the toolpath onto the target zone of the part model; and transmitting the toolpath to a robotic system to execute the toolpath on the part within the work zone.

In a packaging line (1) comprising a plurality of robots (7), in order to be able to replace a faulty unit, in particular robot (7), quickly and with minimal, preferably no manpower, in particular during running operation of the packaging line (1), the unit to be changed is automatically decoupled from the power and data feeds and from the purely mechanical connections and is removed from the packaging line (1), preferably transversely to the throughput direction (10′) of the packaging line (1), and the new unit is automatically introduced in the opposite direction, is positioned, and is mechanically fixed, and the energy and data supplies are automatically coupled.

A method for operating a robotic system includes determining a discretized object model representative of a target object; determining a discretized platform model representative of a task location; determining height measures based on real-time sensor data representative of the task location; and dynamically deriving a placement location based on (1) overlapping the discretized object model and the discretized platform model for stacking objects at the task location and (2) calculating a placement score associated with the overlapping based on the height measures.

A storage, retrieval and processing system is disclosed for processing objects. The system includes a plurality of bins including objects to be distributed by the processing system, said plurality of bins being provided in at least a partially generally circular arrangement, a programmable motion device that includes an end effector for grasping and moving any of the objects, said programmable motion device being capable of reaching any of the objects within the plurality of bins, and a plurality of destination containers for receiving any of the objects from the plurality of bins, said plurality of destination containers being provided in a region that is generally within the at least partially generally circular arrangement of the plurality of bins.

Methods are described that perform a dispatched consumer-to-store return or swap logistics operation for an item being replaced using a modular autonomous bot apparatus assembly and a dispatch server. The method begins with receiving a return operation dispatch command that includes identifier information, transport parameters, and designated pickup information for the item being replaced/returned, along with authentication information related to an authorized supplier of the item being replaced. Modular components of the bot apparatus are verified to be compatible with the dispatched logistics operation. The MAM then autonomously causes the bot apparatus to move to the designated pickup location, notifies the authorized supplier of an approaching pickup, receives supplier authorization input to permissively allow access to a payload area within the bot apparatus, monitors loading as the item being replaced is received along with return documentation, and then autonomously causes movement of the bot apparatus back to the origin location.

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.