An industrial automation component may receive design information associated with an arrangement of one or more industrial automation components in an industrial automation system and identify a first portion of the industrial automation components in the industrial automation system that is unable to interface with a second portion of industrial automation components based on the design information. The industrial automation component may then generate a list of industrial automation components based on the first portion of the industrial automation components and the second portion of industrial automation components, wherein each of the list of industrial automation components is configured to translate a first set of data associated with the first portion of the industrial automation components to a second set of data configured to be at least partly interpretable by the second portion of industrial automation components.

An industrial automation component may receive design information associated with an arrangement of one or more industrial automation components in an industrial automation system and identify a first portion of the industrial automation components in the industrial automation system that is unable to interface with a second portion of industrial automation components based on the design information. The industrial automation component may then generate a list of industrial automation components based on the first portion of the industrial automation components and the second portion of industrial automation components, wherein each of the list of industrial automation components is configured to translate a first set of data associated with the first portion of the industrial automation components to a second set of data configured to be at least partly interpretable by the second portion of industrial automation components.

According to one embodiment, a control system comprises a plurality of devices and a controller. The controller stores first information representing a linkage of a plurality of functions that realize a single process and second information representing a correspondence between the devices and the functions, and controls the devices based on the first information and the second information to realize the single process.

A system includes a collaborative design system that includes a processor configured to display an industrial plant layout on a display. The processor is also configured to overlay the industrial plant layout onto a geographic image. Further, the processor is configured to receive one or more inputs from a plurality of remote users. In addition, the processor is configured to manipulate the layout with respect to the geographic image based on the one or more inputs. Moreover, the processor is configured to create an industrial plant design based on the industrial plant layout and the geographic image.

A hyperconverged industrial process control architecture is disclosed for controlling an industrial process within a physical process environment using a software-defined distributed control system (DCS) environment. The software-defined DCS environment may be implemented by virtualizing the hardware components of a DCS architecture on a server group to enable both software-defined process controllers and back-end DCS applications to run within the server group. This software-defined DCS network architecture reduces the hardware requirements of the process control system and reduces configuration complexity by implementing control components and higher-level components within a common environment within the server group.

A system for power plant management includes: a power plant data module for acquiring equipment data associated with power plant equipment and layout data associated with a plant layout; a database module for building a database according to the acquired equipment data; an unmanned aerial vehicle (UAV) route planning module for creating UAV route planning data, including a UAV route and photographing positions to be performed, according to the layout data; a UAV data acquisition module for acquiring UAV data including power plant images photographed at the photographing positions by a UAV and position data associated with the photographing positions; and a model building module for building a 3D virtual model of the power plant according to the database and the UAV data. The present application improves the experience of a user in managing a power plant and provides an economical power plant management solution.

A hyperconverged industrial process control architecture is disclosed for controlling an industrial process within a physical process environment using a software-defined distributed control system (DCS) environment. The software-defined DCS environment may be implemented by virtualizing the hardware components of a DCS architecture on a server group to enable both software-defined process controllers and back-end DCS applications to run within the server group. This software-defined DCS network architecture reduces the hardware requirements of the process control system and reduces configuration complexity by implementing control components and higher-level components within a common environment within the server group.

An industrial automation component may receive design information associated with an arrangement of one or more industrial automation components in an industrial automation system and identify a first portion of the industrial automation components in the industrial automation system that is unable to interface with a second portion of industrial automation components based on the design information. The industrial automation component may then generate a list of industrial automation components based on the first portion of the industrial automation components and the second portion of industrial automation components, wherein each of the list of industrial automation components is configured to translate a first set of data associated with the first portion of the industrial automation components to a second set of data configured to be at least partly interpretable by the second portion of industrial automation components.

A method for creating a virtual deployment of a distributed control system (DCS) for a given industrial process, comprising: providing a topology of the assets executing the industrial process, as well as control logic for controlling these assets; providing at least one I/O simulator that is configured to supply data; determining a topology of devices that form part of the DCS; establishing based at least in part on this topology of devices, at least one declarative and/or imperative description of the DCS that characterizes multiple devices of the DCS, their placement, and their connections; creating virtual instances of the devices of the DCS and their connections in a chosen environment.

An industrial automation component may receive design information associated with an arrangement of one or more industrial automation components in an industrial automation system and identify a first portion of the industrial automation components in the industrial automation system that is unable to interface with a second portion of industrial automation components based on the design information. The industrial automation component may then generate a list of industrial automation components based on the first portion of the industrial automation components and the second portion of industrial automation components, wherein each of the list of industrial automation components is configured to translate a first set of data associated with the first portion of the industrial automation components to a second set of data configured to be at least partly interpretable by the second portion of industrial automation components.