An industrial integrated development environment (IDE) provides a development framework for designing, programming, and configuring multiple aspects of an industrial automation system using a common design environment and data model. Projects creating using embodiments of the IDE system can be built on an object-based model rather than, or in addition to, a tag-based architecture. To this end, the IDE system can support the use of automation objects that serve as building blocks for this object-based development structure. These automation objects represent corresponding physical industrial assets and have associated programmatic attributes relating to those assets. Automation objects can be maintained in shared libraries that can be referenced by system projects. The IDE system can notify projects that reference these automation objects of updates to the object libraries, including edits to existing objects or addition of new objects.

A method of configuring an HVAC system uses a Specifier Library including specifier options for a plurality of HVAC components and a Shapes Library including a plurality of representative Shapes. An engineering tool accepts a selection from a user of an HVAC component and automatically loads one or more Shapes from the Shapes Library into a configuration project, the one or more Shapes corresponding to the user-selected HVAC component. The engineering tool displays one or more options for the selected HVAC component and accepts selections of one or more options by the user. The engineering tool automatically loads additional Shapes from the Shapes Library into the configuration project, the additional Shapes corresponding to one or more of the accepted selections of the one or more options and combines the loaded Shapes within the configuration project to automatically generate a graphical representation of the HVAC system.

A method for configuring an industrial control apparatus, the method including: starting a detection mode; selecting a stock control apparatus; opening a stock configuration of the stock control apparatus; selecting and buffer-storing at least one feature of the stock configuration; starting a transfer mode; selecting at least one target control apparatus; and transferring the at least one selected and buffer-stored feature of the stock configuration to the target control apparatus.

A method of configuring an HVAC system uses a Specifier Library including specifier options for a plurality of HVAC components and a Shapes Library including a plurality of representative Shapes. An engineering tool accepts a selection from a user of an HVAC component and automatically loads one or more Shapes from the Shapes Library into a configuration project, the one or more Shapes corresponding to the user-selected HVAC component. The engineering tool displays one or more options for the selected HVAC component and accepts selections of one or more options by the user. The engineering tool automatically loads additional Shapes from the Shapes Library into the configuration project, the additional Shapes corresponding to one or more of the accepted selections of the one or more options and combines the loaded Shapes within the configuration project to automatically generate a graphical representation of the HVAC system.

An industrial integrated development environment (IDE) provides a development framework for designing, programming, and configuring multiple aspects of an industrial automation system using a common design environment and data model. Projects creating using embodiments of the IDE system can be built on an object-based model rather than, or in addition to, a tag-based architecture. To this end, the IDE system can support the use of automation objects that serve as building blocks for this object-based development structure. These automation objects represent corresponding physical industrial assets and have associated programmatic attributes relating to those assets. Automation objects can be maintained in shared libraries that can be referenced by system projects. The IDE system can notify projects that reference these automation objects of updates to the object libraries, including edits to existing objects or addition of new objects.

This disclosure provides a device and method for implementing legacy and improved control functions in controllers, including but not limited to in industrial control systems and other systems. A method includes maintaining, by a device having a controller and a memory, a function library having a plurality of legacy control functions and a plurality of improved control functions. The method includes receiving a process to be executed by the controller. The method includes, when calling a function of the process, determining whether a device setting indicates that the function is to be executed by one of the plurality of improved control functions. The method includes, when the device setting indicates that the function is to be executed by one of the plurality of improved control functions, executing the function using the one of the improved control functions, and otherwise executing the function using one of the legacy control functions.

This disclosure provides a device and method for implementing legacy and improved control functions in controllers, including but not limited to in industrial control systems and other systems. A method includes maintaining, by a device having a controller and a memory, a function library having a plurality of legacy control functions and a plurality of improved control functions. The method includes receiving a process to be executed by the controller. The method includes, when calling a function of the process, determining whether a device setting indicates that the function is to be executed by one of the plurality of improved control functions. The method includes, when the device setting indicates that the function is to be executed by one of the plurality of improved control functions, executing the function using the one of the improved control functions, and otherwise executing the function using one of the legacy control functions.

A user interface system for a process plant includes a graphic display editor to configure a process graphic display having a graphic display element representative of a process plant element of the process plant. The process graphic display is specified via configuration information set forth in a declarative language. A graphics rendering engine generates a depiction of the process graphic display during runtime based on commands derived from the configuration information set forth in the declarative language. The configuration information for the process graphic display may be stored as an object, which, for instance, may include first and second portions to define a graphical parameter and identify a data source, respectively. The graphical parameter may be directed to defining a graphical depiction of the process plant element and, to this end, may be set forth in a formal in accordance with the declarative language. The data source may specify a location or path for data indicative of on-line operation of the process plant element to be displayed via the graphical depiction.

A controller configuration for a drive system with a drive is determined using at least one simulation model. One or more controlled system measurement results are received. One or the respective controlled system measurement result is obtained by measuring an RPM speed control loop of the drive system. A simulation model with a drive unit submodel and with one or more controlled system submodels is created for the or the respective RPM speed control loop. A system identification is carried out using the or the respective controlled system measurement result in order to obtain the or the respective controlled system submodel. A controller configuration is determined for the drive system using the simulation model.