A user interface for designing, configuring and/or editing a control flow representing a control strategy associated with a semiconductor manufacturing process, the user interface including: a library of control elements having at least a control element representing a task of simulation and each control element being selectable by a user; a control flow editor configured to organize the control elements into a control flow representing the control strategy; and a communication interface for communicating the control flow to a calculation engine configured to evaluate the control flow.

Disclosed are a computerized system and a method of programing a controller of an industrial system. The method may include: receiving, from the controller, data defining two or more controllable elements included in the industrial system; generating logical connections between the two or more controllable elements based on the received data and the graphical presentation; receiving, from a user interface included in the computerized system, one or more graphical markers presenting an operation sequence of the two or more controllable elements; and converting the graphical markers to an executable code configured to control a controller of the industrial system to control the two or more controllable elements according to the operation sequence.

An industrial integrated development environment (IDE) comprises a development interface that affords a user a great deal of control over the editing tools, workspace canvases, and project information rendered at a given time. The industrial IDE system automatically filters the tools, panels, and information available for selection based on a current project development task, such that a focused subset of editing tools relevant to a current development task or context are made available for selection while other tools are hidden. The development interface also allows the user to selectively render or hide selected tools or information from among the relevant, filtered set of tools. This can reduce or eliminate unnecessary clutter and aid in quickly and easily locating and selecting a desired editing function. The IDE's development interface can also conform to a structured organization of workspace canvases and panels that facilitates intuitive workflow.

An industrial integrated development environment (IDE) comprises a development interface that affords a user a great deal of control over the editing tools, workspace canvases, and project information rendered at a given time. The industrial IDE system automatically filters the tools, panels, and information available for selection based on a current project development task, such that a focused subset of editing tools relevant to a current development task or context are made available for selection while other tools are hidden. The development interface also allows the user to selectively render or hide selected tools or information from among the relevant, filtered set of tools. This can reduce or eliminate unnecessary clutter and aid in quickly and easily locating and selecting a desired editing function. The IDE's development interface can also conform to a structured organization of workspace canvases and panels that facilitates intuitive workflow.

An industrial IDE supports development of control programming using an industrial domain-specific language (DSL) that allows control programming to be written using a scripted programming language having features catered to the industrial domain. The industrial DSL can simplify and streamline development of industrial control code relative to using conventional graphics-based control programming formats such as ladder logic, since a script-based industrial DSL can be used to write programming code using fewer mouse clicks relative to traditional control programming environments. Editing tools inherent to the industrial DSL can provide dynamic programming feedback that guides the developer through the process of developing control code. A development interface of the industrial IDE can comprises two editing windows that render the control program in a graphical format and in a text-based format simultaneously, allowing the user to edit the program in either format on the same interface.

A method for automatically interpreting a piping diagram comprising objects, wherein at least two objects are each linked with operational requirements, an operational requirement is defined based on a predefined set of operating principles and based on a predefined set of boundary conditions, the operational requirements included in the piping diagram are successively evaluated during the automatic interpretation, an automation function is generated for an operational requirement and at least based on an operating principle that is included as an intended purpose in the operational requirement, and the automation function is connected to the objects linked via the underlying operational requirement.

A method, performed by at least one processor, comprising generating a first set of images representative of configuration data associated with an industrial automation system. An electronic display may display at least one image of the first set of images. The processor may detect a change in the configuration data and retrieve updated configuration data from the industrial automation system. The processor may encode the updated configuration data into a second set of images and display at least one additional image of the second set of images on the electronic display.

A system for controlling heating, ventilation, or air conditioning (HVAC) equipment of a building includes one or more processing circuits configured to generate simulated building data using a simulation model of the building, pre-train a reinforcement learning (RL) model using the simulated building data, operate the HVAC equipment of the building using the RL model, and retrain the RL model using actual building data generated responsive to operating the HVAC equipment using the RL model.

An industrial integrated development environment (IDE) identifies modifications to an industrial control program using a combination of program hashing and text differencing. The system performs deep-level hashing of the control program's text model to obtain hash data comprising rung-level hash values that collectively represent the current state of the program. When edits to the program are received, the modified text model is hashed again to yield modified hash data, and differencing analysis is performed on the initial and modified hash data. Differences between the two sets of hash values are used to identify portions of the control program that have been modified so that the targeted updates to a logic view of the program can be implemented. This allows the logic view to be updated without redrawing the entire view, and without the need to store multiple copies of the program's object model for comparison purposes.

An industrial integrated development environment (IDE) comprises a development interface that affords a user a great deal of control over the editing tools, workspace canvases, and project information rendered at a given time. The industrial IDE system automatically filters the tools, panels, and information available for selection based on a current project development task, such that a focused subset of editing tools relevant to a current development task or context are made available for selection while other tools are hidden. The development interface also allows the user to selectively render or hide selected tools or information from among the relevant, filtered set of tools. This can reduce or eliminate unnecessary clutter and aid in quickly and easily locating and selecting a desired editing function. The IDE's development interface can also conform to a structured organization of workspace canvases and panels that facilitates intuitive workflow.