A geometric model-based evaluation method, system, and apparatus for a key performance indicator in a production procedure are disclosed. The method includes extracting a geometric characteristic and a characteristic attribute thereof from a product model; converting the geometric characteristic into a process characteristic so as to obtain the steps of a process related to a whole production procedure of producing a product, and devices corresponding to the steps of the process; and based on the steps of the process related to the production procedure and the devices corresponding to the steps of the process, simulating the whole industrial manufacturing procedure of the product, and outputting the KPI of the industrial manufacturing. At least one embodiment can evaluate the KPI of the whole industrial manufacturing procedure of the product according to the product model.

Various embodiments of the present technology relate to digital twins of devices and assemblies. More specifically, some embodiments relate to the orchestration of digital twin models for representing industrial systems based on characteristics of digital twins. In an embodiment, a method of operating an orchestration engine in an industrial automation environment comprises identifying a targeted outcome for modeling the industrial automation environment, configuring a digital twin environment corresponding to the industrial automation environment based at least on the targeted outcome, and executing a process associated with the industrial automation environment using the digital twin environment.

A computing system for building a virtual factory includes database and a virtual factory building module. The database stores modeling data. The virtual factory building module builds the virtual factory in which a progress situation of a work performed from a first portion to a second portion is displayed, based on the modeling data and a time difference between an output time of a first signal and an output time of a second signal, which is calculated based on the first signal output when a product is at a first portion on one or more facilities monitored from a first location present in an outside of the one or more facilities used in a real factory and the second signal output when the product is at a second portion on the one or more facilities monitored from a second location present in the outside of the one or more facilities. The first location is spaced from the second location, and the first portion is spaced from the second portion.

A production control system (1) having an arrangement of manufacturer-specific modules, comprising modules for controlling production units, modules for controlling logistics units and/or modules for providing and/or processing product data (6). Proprietary data models of manufacturer-specific modules are linked via at least one ontology unit.

The disclosure relates to a method for checking whether and/or how a technical process may be carried out using a technical system with two or more units having technical capabilities that are potentially relevant to the technical process. At least one ontology is used which describes the technical system and the technical process, and a constraint satisfaction problem is generated using the at least one ontology. In the method, solutions are found for the constraint satisfaction problem. The solutions may be stored or output.

A production control system (1) having an arrangement of manufacturer-specific modules, comprising modules for controlling production units, modules for controlling logistics units and/or modules for providing and/or processing product data (6). Proprietary data models of manufacturer-specific modules are linked via at least one ontology unit.

A visualization system computer communicating with a memory to execute a stored program contained in a fixed medium of the memory to display information regarding control components based on control component ontologies and knowledge bases. The visualization system includes an inspection agent configured to communicate with one or more autonomous control components of the manufacturing system to request control component information including a control component ontology including a listing of parameters and relations associated with the control component that define the operating characteristics of the control component and a knowledge base including a listing of current states for the parameters and relations of the control component. The visualization system further includes a visualization editor configured to generate a visualization interface representative of control component information received based on the request and an electronic web server configured to display the visualization interface in response to a received web page request.

A computing system for building a virtual factory includes database and a virtual factory building module. The database stores modeling data. The virtual factory building module builds the virtual factory in which a progress situation of a work performed from a first portion to a second portion is displayed, based on the modeling data and a time difference between an output time of a first signal and an output time of a second signal, which is calculated based on the first signal output when a product is at a first portion on one or more facilities monitored from a first location present in an outside of the one or more facilities used in a real factory and the second signal output when the product is at a second portion on the one or more facilities monitored from a second location present in the outside of the one or more facilities. The first location is spaced from the second location, and the first portion is spaced from the second portion.

The disclosure relates to a method for checking whether and/or how a technical process may be carried out using a technical system with two or more units having technical capabilities that are potentially relevant to the technical process. At least one ontology is used which describes the technical system and the technical process, and a constraint satisfaction problem is generated using the at least one ontology. In the method, solutions are found for the constraint satisfaction problem. The solutions may be stored or output.