Manufacturing of article of footwear include temporarily mating a sole and an upper to determine processes to be performed to the sole and/or the upper before permanently mating. As specific operations are determined based on the particular combination of a sole and an upper, the sole and upper are individually tracked through the subsequent processes to ensure the correct pairing is achieved at the time of permanent mating. The tracking may leverage identifiers in the tooling supporting the upper and in the sole.

Disclosed are various embodiments for a mobile storage unit. The mobile storage unit includes a plurality of walls forming an interior region to store a plurality of items. The mobile storage unit also includes a base supporting the plurality of walls. The mobile storage unit may further include wheels to allow for transport from one location to another location.

A method of identifying an article on a production line, the production line comprising a plurality of articles along its length, the relative positions of the plurality of articles along the length of the production line being predetermined, the method comprising: receiving location information of an object which executes the same motion with respect to at least a first subset of the plurality of articles on the production line; for at least a second subset of the plurality of articles, determining from the location information the location of the object at a predetermined interaction between the object and the article; and identifying an article of the plurality of articles at a specified location of the object in dependence on (i) a known location of any one article of the plurality of articles at any one time, and (ii) the locations of the object at the predetermined interactions between the object and the at least second subset of the plurality of articles.

A method for tracking a component in a production line having a plurality of processing systems includes processing and/or testing, by each of the processing systems, the component, providing a processing signal characterizing the processing and/or testing for a higher-level electronic computing unit, and tracking, by the computing unit based on the received processing signals, the component through the production line. A query signal characterizing a component property of one of the processing systems of the production line is received by the computing unit. The component is ascertained by the computing unit and at least one component information signal characterizing the component property of the ascertained component is provided.

A weigh-in-motion scale system for a linear synchronous motor conveyor and a method for weighing objects on a linear synchronous motor conveyor are described herein. In one embodiment, the weigh-in-motion scale system includes a support structure for supporting the following: a weigh cell, a section of a linear synchronous motor conveyor track, a vehicle for transporting an object, and an object; and a weigh cell on the support structure on which a section of a linear synchronous motor conveyor track rests directly or indirectly. In one embodiment, the method includes transporting a vehicle with an object thereon along a section of a linear synchronous motor conveyor track; and at a weighing station while the vehicle with the object thereon is being transported, weighing the section of a linear synchronous motor conveyor track, vehicle, and object to determine the weight of the object.

The traceability system for injected parts comprises a traceability calendar (1) that indicates a date and time visibly placed on an injecting machine; a data control module (2) connected to the traceability calendar (1); and one or more date stamps (3) that mark the day and/or the month and/or the year on an injected piece. It allows providing a traceability system for injected parts that is sufficiently reliable and that facilitates or makes the task of changing the date of the date stamp as accurate as possible.

The present technology relates to a spatial address-based management system, and the management system includes a spatial address-related information reception part configured to receive spatial address-related data assigned to each of segments generated by dividing a workspace into a plurality of rows and columns, a controller configured to process the spatial address-related data received from the spatial address-related information reception part and transmit the processed data to a spatial address-related data storage part, and the spatial address-related data storage part configured to store the spatial address-related data transmitted from the controller as spatial address data, wherein the spatial address data includes information on a unique position of the spatial address, information on a workpiece that is placed at the spatial address, and information on attributes or properties of the spatial address.

The invention relates to a method for the harmonization of color in manufactured items, which allows color tolerances to be established based on pre-defined values and visual observations for the different parts that form the item and the operating conditions for the manufacture of said parts by which means the colors falling within said tolerances can be obtained as well as the acceptance of the color harmonization of the final product by means of the use of algorithms and visual examination by a person or a machine.

Manufacturing of article of footwear include temporarily mating a sole and an upper to determine processes to be performed to the sole and/or the upper before permanently mating. As specific operations are determined based on the particular combination of a sole and an upper, the sole and upper are individually tracked through the subsequent processes to ensure the correct pairing is achieved at the time of permanent mating. The tracking may leverage identifiers in the tooling supporting the upper and in the sole.

Embodiments generally relate to robots and enabling robots to locate objects in a physical environment. In some embodiments, a method includes charging a radio-frequency identification (RFID) tag with an RFID reader, where the RFID tag is coupled to an object, and where the RFID reader is coupled to a robot arm. The method further includes receiving a plurality of responses from the RFID tag, where each response includes a power value to which the RFID tag was charged and a time value for charging the RFID tag to the power value. The method further includes moving the RFID reader to a plurality of RFID reader positions using the robot arm, where each RFID reader position is associated with one of the responses of the plurality of responses. The method further includes determining a plurality of distances from the RFID reader to the RFID tag based on power values and the time values of the respective responses at the respective RFID reader positions. The method further includes determining a location of the RFID tag based on the plurality of distances.