In some aspect, a method includes receiving data characterizing user selection of a industrial machine via a web-based graphical user interface (GUI) associated with an industrial enterprise including a plurality of industrial machines. The web-based GUI includes a first portion and a second portion. The first portion includes a first interactive graphical object indicative of a industrial machine of the plurality of industrial machines. The method also includes retrieving the data associated with the industrial machine from a first monitoring system configured to monitor the industrial machine. The method further includes generating a first visual representation of the data associated with the industrial machine. Generating the first visual representation is based on a first visual framework associated with a first identifier characteristic of the industrial machine. The method also includes displaying, in the second portion of the web-based GUI, the first visual representation.

An open application protocol for industrial equipment is disclosed. Disclosed techniques include: opening a connection between (a) an open application associated with a manufacturing execution system and (b) an instance of a data sharing interface operating on an industrial machine used in a surface mounting process, the open application being configured to communicate with any machine that implements the data sharing interface, regardless of machine type or manufacturer; discovering, by the open application via the connection, discoverable information associated with the industrial machine, the discoverable information including one or more of data items, events, commands, or alarms; and controlling, by the open application via the connection, operation of the industrial machine to control at least a portion of the surface mounting process.

A computer system for controlling an industrial automation environment comprising a plurality of industrial components is provided. The computer system includes a machine interface, a user interface, a hardware memory, and a processor. The processor is configured to select an industrial component for configuration based on a user input. The processor is also configured to determine a context of the selected industrial component and display a plurality of interface modules to the user for the selected industrial component based on the context of the selected industrial component. The processor is further configured to receive a selection of an interface module by the user through the user interface, and add the selected interface module to a human-machine interface.

Flexible graphic element objects in a process plant are configurable both in a run-time operating environment in which a process is being controlled and in a configuration environment. An instantiated flexible graphic element object may be a display view or may be another graphic element included on a display view. A graphic element object may be linked to and/or derived from another graphic element object, and changes to a particular graphic element object may be propagated to its derivations, e.g., according to a distribution policy. Changes to definitions corresponding to a particular graphic element object (e.g., to the definition of a graphic element attribute such as a shape, animation, event handler or property) may be overridden or modified in another object derived from the particular graphic element object. The modified derived object may be renamed and saved separately from the particular graphic element object.

A method for verifying process orchestration logic for a modular plant includes generating a plant execution model representing the process orchestration logic; analyzing the plant execution model to identify one or more potential failure scenarios; and generating one or more test cases based on the one or more identified failure scenarios.

An industrial integrated development environment (IDE) supports collaborative tools that allow multiple designers and programmers to remotely submit design input to the same automation system project in parallel while maintaining project consistency. These collaborative features can include, for example, brokering between different sets of design input directed to the same portion of the system project, generating notifications to remote designers when a portion of the system project is modified, sharing of development interfaces or environments, facilitating involvement of outside technical support experts to assist with design issues, and other collaborative features.

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.

System and Method for Factory Automation and Enhancing Machine Capabilities The present invention relates to system and method for factory automation and for enhancing machine capabilities. The system is configured to extract data from machine through data capturing module, data extraction module and data conversion module and jointly analyze them with data from other equipment and sensors through data analysis engine and transmitting to factory systems in user configured protocol through protocol conversion module. It also accepts machine control commands from the factory systems and executes them through command processor and mouse & keyboard simulator modules. It involves combining GUI from multiple equipments/sensors and sending to single display device through GUI manager and video output modules and mapping required actions of mouse clicks and keyboard entries from new to old user interfaces. GUI manager module detects GUI elements from captured images and applies user configuration to automatically

Techniques for presenting historized process parameter values in a process plant include presenting, via a user interface of an operator application, indications of process control elements in a first display region within a layout of a display view. Each of the process control elements is associated with one or more process parameters. The operator application also presents a trend display view in a second display region within the layout of the display view. The trend display view includes sets of historized process parameter values for process parameters presented in the first display region. For example, the trend display view in the second display region is linked to the display view in the first display region. In this manner, the trend display view presents charts or other graphical depictions of historized process parameter values for process parameters included in the first display region.

A method for configuring an industrial automation system for internet-of-things accessibility involves a computing device which a) receives a first user input indicative of a functional object representing one or more low-level devices and/or automation devices and/or supervising and production control devices. The computing device also b) receives) a second user input indicative of a cloud object representing a cloud service provider being external to the industrial automation system. The computing device further c) receives a third user input indicative of a user terminal object representing a user terminal device being external to the industrial automation system. The computing device then d) causes the cloud service provider to enable communication between the user terminal device and at least one of the devices in the industrial automation system as represented by the functional object via the cloud service provider.