A method and system for motion control of movers in an independent cart system is disclosed. In one implementation, the independent cart system includes a plurality of track segments, each section having a respective controller. One of the controllers receives a motion command for a plurality of carts, respectively. The controller generates a force command for each of the plurality of carts and transmits the respective commands to the track segments commutating the plurality of carts.

The present disclosure generally relates to systems and methods utilizing regenerative agriculture for the procurement, production, refinement and/or transformation of low carbon intensity transportation fuels, including low carbon intensity biodiesel and/or renewable diesel, low carbon intensity biogasoline, low carbon intensity aviation, marine and kerosene fuels as well as fuel oil blends, low carbon intensity ethanol, and low carbon intensity hydrogen, that may be beneficially commercialized directly to consumers. In further aspects, the systems and methods of the present disclosure advantageously generate low carbon intensity comestibles, including sustainably-sourced meal and/or feed. The disclosed systems and methods may be utilized and optimized such that the resulting fuels and foodstuffs are characterized by a reduction in greenhouse gas production and a diminution in the fertilizer, pesticide and water required for producing the associated crop feedstocks.

Provided herein are automated article dispensing systems having inventory management capabilities, and methods for managing inventory of articles in automated dispensing systems. In particular, the systems and methods disclosed herein utilize an inventory management assembly which includes one or more sensors configured to detect directly or indirectly one or more parameters related to quality and/or quantity the articles and an inventory management processing module configured to compute inventory related data based at least on the one or more parameters.

In a method for setting a mounting position of a target substrate, the test substrate is transferred to a second position deviated from a first position. A mask has expected arrangement position where a non-film formation region has a preset width when the target substrate is mounted at the first position and subjected to a film formation. The film is formed on the test substrate at the second position by using the mask. Width of the non-film formation region formed on the test substrate after the film formation is measured. Actual arrangement position of the mask is specified based on a direction and a distance of the deviation of the second position from the first position and the measured width of the non-film formation region. The first position is corrected such that the non-film formation region has the preset width based on the actual arrangement position of the mask.

Methods for manufacturing automation and a computer executed automated handling system for forming a device are presented. The method includes issuing a transfer request by a tool. The transfer request is processed by a production control system configured for tracking and controlling the flow of carriers. The processing of the transfer request includes selecting a carrier containing production material. A transport system having transport and load/unload (U/L) units in a production area to effect a transfer is controlled and the carrier is transferred by the transport system.

In a method for operating a technical plant, which includes a work area for producing ready-to-ship products from delivered goods and a plurality of load carriers, each including a control, a drive connected to the control, and a communication interface, for transporting goods and for transporting products, goods are delivered to the technical plant, delivered goods are transported into the work area by the load carriers, products are produced in the work area from the goods transported into the work area, produced products are transported out of the work area by the load carriers, and products transported out of the work area are shipped out from the technical plant. A technical plant, which includes a work area for producing ready-to-ship products made from delivered goods, is operable using the method.

A system for reconfiguring a factory having equipment at different workstations throughout the factory and a plurality of sensors disposed throughout the factory includes a factory configuration module configured to store a plurality of predetermined factory configurations and a plurality of mobile transporters configured to engage and transport the equipment to the different workstations throughout the factory based on the predetermined factory configurations and dynamic inputs, where the dynamic inputs include a status of the equipment, a status of the plurality of mobile transporters, sensor data output by the plurality of sensors, or a combination thereof.

A method includes defining a sensor layout of a digital twin based on one or more sensor parameters and one or more routing control locations of the digital twin. The method includes simulating a manufacturing routine of a plurality of pallets and a plurality of workstations based on one or more pallet parameters associated with the plurality of pallets and one or more workstation parameters associated with the plurality of workstations and calculating, for each routing control location from among the one or more routing control locations, a transient production value and a steady state production value based on the manufacturing routine. The method includes iteratively adjusting the sensor layout of the digital twin until each transient production value is less than or equal to a threshold transient production value and each steady state production value is less than or equal to a threshold steady state production value.

[Solving Means] A production processing apparatus according to the present technology includes a first robot arm and a plurality of first tilt tables. The first robot arm is capable of conveying a work. On each of the plurality of first tilt tables, the work conveyed by the first robot arm can be mounted. The plurality of first tilt tables are tilted a predetermined angle from a horizontal surface at positions on a circumference of a circle with the first robot arm being a center, and the work is subjected to production processing in a state where the work is mounted on one of the plurality of first tilt tables.

A method of processing objects is disclosed using a programmable motion device. The method includes the steps of acquiring an object from a plurality of mixed objects at an input area, perceiving identifying indicia in connection with the object, assigning an intermediate station to a destination location for the object responsive to the identifying indicia in connection with the object, and moving the acquired object toward the intermediate station.