A processing system including a singulation system is disclosed. The singulation system includes a conveying system for moving objects to be processed from a source area along a first direction, a detection system for detecting objects at the conveying system, and for selecting certain selected objects for redistribution on the conveying system, and a movement redistribution system for redistributing the certain selected objects on the conveying system for providing a singulated stream of objects.

A robot control apparatus includes a workpiece orientation calculation unit, an arrival prediction unit, a robot orientation calculation unit, and a trajectory data generation unit. The arrival prediction unit obtains a picking prediction position at which a workpiece that is conveyed by a conveyance apparatus may be picked up by a picking apparatus or the like, based on conveyance speed information supplied by the conveyance apparatus or the like and the sensing information supplied by an image acquisition apparatus.

A method and system for picking articles from a collection of articles and arranging articles into placement locations, includes capturing an image with a first vision system from a collection of articles at a first pick location and determining coordinate data for at least some of the articles in the collection of articles. The coordinate data for an article in the collection of articles is provided to a first robotic manipulator. That article is picked from the collection of articles with the first robotic manipulator according to the coordinate data for that article and that article placed at a first place location. The position and orientation data of that article are obtained at a second pick location and provided along with a desired position and orientation of that article at a second place location to a second robotic manipulator. That article is picked with the second robotic manipulator using the position and orientation data of that article at the second pick location and that article is placed at the second place location at the desired position and orientation.

A method includes: receiving a recycled wood workpiece populated with a set of metal fasteners; accessing an internal imaging scan; detecting the set of metal fasteners embedded in the recycled wood workpiece based on internal features detected in the internal imaging scan; for each metal fastener in the set of metal fasteners, extracting an initial position and an initial orientation of the metal fastener from the internal imaging scan; generating a virtual model of the recycled wood workpiece based on the internal imaging scan; accessing an image captured by an optical sensor; detecting a first metal fastener in the recycled wood workpiece; deriving a first position and a first orientation of the first metal fastener; and, in response to identifying the first metal fastener analogous to an initial metal fastener in the virtual model, isolating the first metal fastener in the virtual model and generating a fastener removal schedule.

A robot system includes a sensor, a robot equipped with a gripping device capable of gripping a detected article, and a controller. The controller includes a gripping area setting unit that, for each article, sets a gripping area in which the gripping device is to be positioned when it grips the article, a determination unit that determines presence or absence of interference between the gripping area and other articles, a storage unit that stores a result of determination on the presence or absence of interference determined by the determination unit in association with each detected article, a robot control unit that causes the gripping device to pick up an article for which no other article interferes with the gripping area thereof, and an updating unit that updates the result of determination stored in the storage unit every time an article is picked up by the gripping device.

A production line for manufacturing a building block, which includes at least one component, the production line including: a central conveyor line; at least one feeding line for feeding the at least one component to the central conveyor line; a manufacturing tool set for processing the at least one component; and a control unit for controlling the central conveyor line, the feeding line, and/or the manufacturing tool set. The controlling at least one of the central conveyor line, the feeding line, and/or the manufacturing tool set includes: retrieving an asset-information about the at least one component and/or the manufacturing tool set, conveying the at least one component according to the asset-information by the feeding line to the central conveyor line, retrieving a processing-information and/or a manufacturing tool set information about processing the at least one component, and processing the at least one component by the manufacturing tool set.

A counter unit, a counter unit control method, a control device, and a control system are provided. A counter unit (10) executes an output to an actuator (40) at a time point when a waiting time indicated by a timing adjustment value (Ta) received from PLC (20) has elapsed since it was determined that an actual measurement value obtained by using a pulse signal has matched with a target value.

A work robot system includes, a work robot and a work robot control unit that perform work on a target part of an object conveyed by a conveyer device, a measurement robot, a sensor that is attached to the measurement robot and that detects a position of a detection target of the object conveyed by the conveyer device, a measurement robot control unit that moves, through control of the measurement robot, the sensor in accordance with conveyance of the object, in order to detect the position, and a force detector that is used when force control is performed. When the work robot performs the work, the work robot control unit performs force control while performing control of the work robot based on a detection result of the sensor.

In some embodiments, apparatuses and methods are provided herein useful to track objects on a moving conveyor system. In some embodiments, an RFID based tracking system comprises a conveyor system to move and transport objects along a conveyance path, wherein each object includes a near field only RFID tag associated therewith and identifying the object. Each near field only RFID tag is not coupled to a far field antenna such that it is not readable in a far field of RFID communication and communicates only in a near field of RFID communication. An RFID tag reader is positioned to attempt to read the near field only RFID tag of each object. And a control circuit processes reads of the near field only RFID tags by the first RFID reader to determine an order of the objects being conveyed.

A method of processing objects using a programmable motion device is disclosed. The method includes the steps of providing an input conveyance system by which input bins of objects may be provided to a processing station that includes the programmable motion device that includes an end effector, perceiving at the processing station identifying indicia representative of an identity of a plurality of objects at an input area of the input conveyance system, grasping the an acquired object using the end effector, moving the acquired object toward an identified processing container using the programmable motion device, the identified processing container being associated with the identifying indicia and said identified processing container being provided as one of a plurality of processing containers at the processing station, and providing an output conveyance system in communication with the processing station, by which processing containers that contain processed objects may be provided.