A velocity control-based robotic system is disclosed. In various embodiments, sensor data is received from one or more sensors deployed in a physical space in which a robot is located. A processor is used to determine based at least in part on the sensor data an at least partly velocity-based trajectory along which to move an element comprising the robot. A command to implement the velocity-based trajectory is sent to the robot.

A box handling system is disclosed for use in an object processing system. The box handling system includes a box tray including a recessed area for receiving a box, and the recessed area includes a plurality of floor and edge portions for receiving the box that contains objects to be processed.

A robot includes an arm via which the robot is configured to perform an operation on a workpiece conveyed in a conveyance direction on a conveyor, and a visualizer which is configured to visualize positional deviation of the robot from the conveyor in at least one of a first direction perpendicular to the conveyance direction and a second direction perpendicular to both the conveyance direction and the first direction.

Methods and systems for sorting hides are provided. In particular, one or more embodiments comprise a tanning control system that enhances the traceability of hides by capturing and utilizing data related to the unloading, tanning, sorting, and packaging of hides. Furthermore, one or more embodiments enable the tanning control system to improve efficiency by sorting hides based, at least in part, on data generated during prior tanning processes. Additionally, one or more embodiments facilitate the tanning control system in customizing the sorting and packaging of hides based, at least in part, on one or more hide characteristics and/or customer specifications.

A processing line for performing processing operations on products or parts thereof to be conveyed in the processing line comprises a plurality of processing modules configured to perform different processing operations on the products. Each processing module comprises a transport receipt interface, a transport delivery interface, a transport device to move a product in a product carrier along a transport trajectory from the transport receipt interface to the transport delivery interface, and, along the trajectory, a first detector to detect presence or absence of a product in a product carrier, a processing station to perform a processing operation on a product, an evaluation station to evaluate the result of the processing operation on the product, a removal station to discharge the product from the processing module, and a controller configured to control the operations of the processing station, the evaluation station, and the removal station.

A controller of a material handling system performs a method of creating a multidrop pattern of articles for robotic placement in layers on a pallet. A pattern is presented on a user interface of any currently positioned representations of articles on a pallet. A control affordance for inputting drag'n'drop and numeric inputs is presented on the user interface for robotic control operations to perform a multidrop of the more than one article in an end effector of a robotic arm for placement of the more than one article. User inputs are received that indicate placement position of a first subset of the more than one article. User inputs are received that indicate placement position of a second subset, which is mutually exclusive of the first subset, of the more than one article. The user inputs are converted into a place sequence of robotic control operations to perform a multidrop of the articles by the robotic arm.

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.

The present disclosure provides a control method of a robotic system that implements a high degree of cooperation between units including a robot and increases a storage efficiency of an operation object sufficiently.

A control method includes: deriving an approach location at which the end effector grips an operation object; deriving a scan location for scanning an identifier of the operation object; and based on the approach location and the scan location, creating or deriving a control sequence to instruct the robot to execute the control sequence. The control sequence includes (1) gripping the operation object from a start location; (2) scanning an identifier of the operation object with a scanner located between the start location and a task location; (3) temporarily releasing the operation object from the end effector and regripping the operation object by the end effector to be shifted, at a shift location, when a predetermined condition is satisfied; and (4) moving the operation object to the task location.

Feedback information is an important aspect in all machine learning systems. In robot systems that are picking objects from a plurality of objects this has been arranged by acquiring images of objects that have been picked. When images are acquired after picking they can be imaged accurately and the information about picking and also dropping success can be improved by using acquired images as a feedback in the machine learning arrangement being used for controlling the picking and dropping of objects.

A machine system includes a transport control section which controls transport of a workpiece based on a transport deceleration line provided upstream of an operation limit line of a machine in a direction of travel of the workpiece and a transport acceleration line provided upstream of the transport deceleration line, wherein the transport control section reduces a transport speed of the workpiece when the workpiece passes through the transport deceleration line in an incomplete operation state and increases the transport speed of the workpiece after the operation on the workpiece present between the operation limit line and the transport acceleration line has completed.