A Building Management System (BMS) generates and presents a user interface to a user. The user interface displays building automation and control logic as human-readable text including interactive text modifiable by the user. The user interface allows the user to more easily understand complex control logic and make modifications to the control logic. The BMS is also presents equipment graphics on the user interface based on metadata read from controllers. The controller metadata includes information about building equipment operated by the controller and one or more sensors associated with the building equipment.

A system receives operations data and determines operations indicator(s) from the operations data. An operator on a manufacturing line reports a downtime event via a human machine interface device. The system receives downtime event and uptime information. The system calculates an operations indicator, such as an overall equipment effectiveness indicator, from the downtime event and uptime information. A user interface of the system includes the operations indicator(s) and visualizations. Some visualizations include a timeline indicating downtime events and other operations events. Additional downtime and uptime information is received by the system in substantially real-time. The system dynamically calculates updated operations indicator(s) from the additional downtime and uptime information.

Techniques to facilitate programming industrial control systems to operate machinery in an industrial automation environment are disclosed herein. In at least one implementation, a user interface is displayed for a control program editor comprising programming logic associated with at least one machine system. Operational data associated with operating the at least one machine system controlled by an industrial controller executing the programming logic is received. The programming logic and the operational data are processed to determine contextual associations between the programming logic and the operational data. In the user interface for the control program editor, the operational data is displayed in context with the programming logic associated therewith based on the contextual associations.

The present invention addresses the problem whereby the number of commands to be transmitted increases in accordance with an increase in the number of devices to be backed up and restored, and processing becomes complex. An IO-Link master is provided with: an upper-level communication control unit which receives an instruction to execute backup in which setting information is acquired from IO-Link devices, and stored in a storage unit; and a backup control unit which executes backup of the plurality of IO-Link devices in accordance with the one received instruction.

Systems and methods for human-machine interaction. An adaptive behavioral control system of a human-machine interaction system controls an interaction sub-system to perform a plurality of actions for a first action type in accordance with a computer-behavioral policy, each action being a different alternative action for the action type. The adaptive behavioral control system detects a human reaction of an interaction participant to the performance of each action of the first action type from data received from a human reaction detection sub-system. The adaptive behavioral control system stores information indicating each detected human reaction in association with information identifying the associated action. In a case where stored information indicating detected human reactions for the first action type satisfy an update condition, the adaptive behavioral control system updates the computer-behavioral policy for the first action type.

The present disclosure is directed to systems, methods and devices for facilitating object-based cross-domain industrial automation control. An object library comprising a plurality of objects may be maintained. One or more of the objects may represent physical counterparts for use in an industrial automation process. Each object of the plurality of objects in the object library may have at least one property that an automated control device operation can be programmed to act on. Each object of the plurality of objects may also have at least one property that a human machine interface component can utilize in generating display elements corresponding to the objects for display on the human machine interface. When modifications to objects in the object library are received, those modifications may be automatically deployed and incorporated in controller logic and HMI graphics and control.

Techniques to facilitate extraction of display objects for human-machine interface (HMI) displays are disclosed herein. In at least one implementation, a selection of a user-defined area is received that identifies at least a portion of a piping and instrumentation diagram (P&ID) associated with an industrial automation environment. The user-defined area of the P&ID is analyzed to identify at least one object within the user-defined area of the P&ID. The at least one object identified within the user-defined area of the P&ID is extracted to generate a static graphic object. Edit instructions are received that describe at least one modification to a visual appearance of the static graphic object. The edit instructions are applied to the static graphic object to generate an HMI graphic object comprising the at least one modification to the visual appearance of the static graphic object.

A controllable device, such as a set top box, responds to a transmission received from a one of a plurality of controlling devices of differing capabilities by entering into a one of a plurality of operating modes wherein the one of the plurality of operating modes entered into corresponds to the capabilities of the controlling device from which the transmission originated.

A computing system has a processor that receives client data defining one or more electrical loads of an industrial automation project. The computing system generates one or more motor control lineups based on the client data and historical data associated with a plurality of previous industrial automation projects. The computing system receives a selection of a motor control lineup form a plurality of motor control lineups. A visual representation of the selected motor control lineup is generated and transmitted for display on a graphical user interface.

Devices, methods, and systems for voice control of components of a facility are described herein. One computing device apparatus includes a memory, and a processor configured to execute executable instructions stored in the memory to receive a voice command or voice query from a user, determine location context information associated with the computing device, and determine which component or components of the facility are associated with the voice command or voice query based, at least in part, on the location context information associated with the computing device.