Module-based systems and methods are described for controlled roll-out of module classes for configuring a process plant. In various aspects the module-based systems and methods generate a second version of a module class based on a modification to a first version of the module class, where the module class is associated with one or more module instances that are each associated with a process control element of the process plant. The module-based systems and methods execute a roll-out instruction to update an upgraded process control element, where the upgraded process control element is associated with a new module instance based on the second version of the module class. The roll-out instruction is also designed to ignore or skip a non-upgraded process control element, where the non-upgraded process control element remains associated with a previous module instance based on the first version of the module class.

System for performance-based design space composition in engineering systems includes design configuration module, explainable recommendation module and user interface module. A list of one or more system configurations is generated, each system configuration having a unique set of components that satisfy system goals and system requirements. For each system configuration, system performance values are determined based on performance enabled by each system component. A design dashboard presents the system configurations in rank order and the system performance value for each of the system configuration components.

Module-based systems and methods are described for controlled roll-out of module classes for configuring a process plant. In various aspects the module-based systems and methods generate a second version of a module class based on a modification to a first version of the module class, where the module class is associated with one or more module instances that are each associated with a process control element of the process plant. The module-based systems and methods execute a roll-out instruction to update an upgraded process control element, where the upgraded process control element is associated with a new module instance based on the second version of the module class. The roll-out instruction is also designed to ignore or skip a non-upgraded process control element, where the non-upgraded process control element remains associated with a previous module instance based on the first version of the module class.

A configuration system for a process control system configured to perform process control. The configuration system includes, not limited to, a) a definition module, which is stored in a memory, for a part of an industrial plant based on design data. The definition module includes, not limited to, a-1) a control logic definition file configured to define a control logic for the part, and a-2) a data definition file configured to define data relating to the defined control logic.

A method for configuring a modular industrial plant using an engineering tool includes using a plant engineering facility of the tool to create a representation of the modular industrial plant identifying modules to be orchestrated in the modular industrial plant. The modules include at least one function module that includes control software for the modular industrial plant. The method further includes using a module engineering facility of the tool to configure the function module for use in the modular industrial plant by editing a placeholder configuration file created by the tool for defining the configuration of the function module. Editing the configuration file causes a representation of the function module in the plant engineering facility to be automatically updated to reflect adaptations made to the function module using the module engineering facility. The method includes instructing the tool to assign the function modules so configured to the modular industrial plant.

Among a plurality of synchronous control programs each configured to include a plurality of output software modules with respect to one driving software module, a synchronous control program of a multi-axis configuration, in which driving software modules are coupled together into a same axis, is displayed on one screen. On this display screen, display is switched between a parameter setting screen, status information on respective software modules, and a waveform graph of the driving software module and the output software modules, in order to enable work ranging from software designing to debugging to be efficiently performed.

The embodiments described herein include a system, non-transitory tangible computer-readable medium including executable code, and a method. In one embodiment, a non-transitory tangible computer-readable medium including executable code is provided. The executable code includes instructions for providing a batch commissioning system configured to operatively couple at least two field devices to a control system, and for providing a batch decommissioning system configured to operatively uncouple the at least two field devices from the control system. The executable code further includes instructions for providing a graphical user interface (GUI) configured to use the batch commissioning system, the batch decommissioning system, or a combination thereof, to select, on a display, the at least two field devices, and to communicatively interface with the control system to operatively couple, uncouple, or a combination thereof, the at least two field device from the control system.