A method includes receiving one or more data files that have one or more user-selected input parameters associated with one or more electrical devices in an industrial system, one or more output parameters associated with the electrical devices, one or more input/output parameter tags, a frequency or a condition associated with data transmission for each electrical device, or a combination thereof. The electrical devices may communicate via a first communication network based on the International Electrotechnical Commission 61850 standard, and the controller may communicate via a different communication network. The method also includes automatically programming the controller to control one or more operations of each electrical device based on the data files and transmitting the data files to a gateway device communicatively coupled to the controller along a backplane of a chassis system. The gateway device is automatically configured based on the one or more data files.

A communication device for a control loop is provided having a control device and an actuator that is connected to the control device via a connection line and that has a sensor for determining a control variable. In this respect, the communication device has a first interface for connecting to the control line for a connection to the control device, a second interface for a connection to the actuator, and a third interface for a connection to a third system to transfer at least some of a communication on the connection line or data acquired therefrom to the third system.

A method includes receiving one or more data files that have one or more user-selected input parameters associated with one or more electrical devices in an industrial system, one or more output parameters associated with the electrical devices, one or more input/output parameter tags, a frequency or a condition associated with data transmission for each electrical device, or a combination thereof. The electrical devices may communicate via a first communication network based on the International Electrotechnical Commission 61850 standard, and the controller may communicate via a different communication network. The method also includes automatically programming the controller to control one or more operations of each electrical device based on the data files and transmitting the data files to a gateway device communicatively coupled to the controller along a backplane of a chassis system. The gateway device is automatically configured based on the one or more data files.

A smart gateway platform leverages pre-defined industrial expertise to identify limited subsets of available industrial data deemed relevant to a desired business objective, and to collect and model this relevant data to apply useful constraints on subsequent artificial intelligence or machine learning analytics applied to the data. This approach can reduce the data space to which AI analytics are applied, and assist data analytic systems to more quickly derive valuable insights and business outcomes. In some embodiments, the smart gateway platform can operate within the context of a multi-level industrial analytic system, feeding pre-modeled data to one or more AI or machine learning systems executing on one or more different levels of an industrial enterprise.

In one embodiment, a condition monitoring circuit can include a circuit controller and a node. The node can include a gate controller, a node controller and one or more gates. The node can be configured to detachably couple to a bus of a monitoring system associated with an industrial machine. The circuit controller can be configured to identify an operating parameter associated with the industrial machine. The gate controller can be configured to transfer, via the one or more gates, one or more data packets including data characterizing the operating parameter from the bus in the monitoring system. The one or more gates can be configured to prevent transfer of an outgoing data packet to the bus via the node.

A connecting unit to transmit process data of an automation process of an automation system to an external data infrastructure, configured as a field device for arrangement on a field level of the automation system. The connecting unit comprises a field bus module, network module and interface module. The field bus module is configured to interchange the process data via the field bus with a signal unit connected to the automation process via a field connection. The network module is configured to interchange the process data with the external data infrastructure, use the data network to transmit input process data to the external data infrastructure, and retrieve output process data from the external data infrastructure. The interface module is configured to interchange the process data between the field bus module and the network module. The interface module prompts interchange of the process data autonomously.

A method provides a synchronization cycle for updating changing component property values at a client and a gateway system. When the client receives a change to a value, it saves the change as a pending value in association with an existing value for the component property. The client sends a set of changes and an identifier to the gateway system. The gateway system updates its component property values accordingly. The gateway system accumulates changes to property values including changes from the client and other changes received via data bindings or other methods. The gateway system sends a message to the client including the accumulated property value changes and the identifiers associated with client-provided value changes that have been applied. The client updates its component property values according to the accumulated changes and removes references to pending values that are associated with identifiers sent back by the gateway system.

The present disclosure relates to condition monitoring of wireless networks in industrial plant, wherein a wireless network has two or more wired gateways and a plurality of access nodes connected wirelessly with at least one wired gateway. Here, each access node is associated with at least one field device of the industrial plant. The condition monitoring is performed with an industrial device connected with the two or more wired gateways. The condition monitoring comprises periodically receiving information associated with packet transfer, channel access, and connection links for each node of the plurality of access nodes and each wired gateway. One or more parameters are estimated based on the received information, to determine connectivity status of the field devices in the industrial plant. The connectivity status is rendered on a user interface of an industrial device.

In one embodiment, a condition monitoring circuit can include a circuit controller and a node. The node can include a gate controller, a node controller and one or more gates. The node can be configured to detachably couple to a bus of a monitoring system associated with an industrial machine. The circuit controller can be configured to identify an operating parameter associated with the industrial machine. The gate controller can be configured to transfer, via the one or more gates, one or more data packets including data characterizing the operating parameter from the bus in the monitoring system. The one or more gates can be configured to prevent transfer of an outgoing data packet to the bus via the node.

An edge gateway system securely delivers and exposes data generated by and/or related to a process plant for consumption by external systems, and includes a field-facing component that sends, to an edge-facing component of the system, a collection of data types defined based on configurations of the process plant and represented using a syntax that is native to the one or more external systems. The field-facing component streams process plant-related content data indicated by one or more interest lists to the edge-facing component, where the streamed data is expressed using the collection of data types. Each interest list may include multiple types of data (e.g., control, I/O, diagnostic, device, historical, etc.) that collectively represent a particular named entity of the plant. Accordingly, the streamed data is securely delivered and exposed, via the edge-facing component, to the external systems.