The present disclosure relates to a method for starting up or servicing a field device: reading unique identification information assigned to the field device via a static code by means of a reading and/or operating tool; optically reading diagnostic information stored in the field device and which relates to at least one current and/or past event assigned to the field device, via a dynamic code generated by the field device by means of the reading and/or operating tool; transmitting the identification and diagnostic information from the reading and/or operating tool to a cloud-based service platform, transmitting device and/or application-specific information for remedying the event characterized by the diagnostic information from the cloud-based service platform to the reading and/or operating tool, and eliminating the event or effects of the event using the transmitted device-specific and/or application-specific information.

The present disclosure resides in a method for operating, installed in an automated plant, a field device, which is connected for communication with a field access unit by means of a first communication network, especially by means of a fieldbus of automation technology, comprising: invoking a link of the field device in a client computer, wherein the link is composed at least of a protocol field and a parameter field, wherein the invoking of the link initiates steps as follows: starting a first frame application associated with the protocol field of the link; transferring the link to the first frame application and extracting information contained in the parameter field by the first frame application; configuring a communication path between the client computer and the field device via the field access unit with application of the information; opening a device driver or a device description in the first frame application.

Disclosed herein are techniques for virtualizing the I/O of control modules that are to be implemented by a process controller in the runtime environment of a process plant. A configuration application identifies references to the I/O objects utilized by the control modules. In response, the configuration application generates virtual device signal tags (DSTs) to mimic the performance of the identified I/O objects. To facilitate testing and/or verification of the control module, e.g., during the commissioning of a back-end environment, the configuration application instantiates a virtual controller in a simulation environment. To generate the virtual controller, the configuration application replaces any references to the I/O objects with references to respective, generated virtual DSTs. Thus, by using the virtual DSTs as a proxy for the I/O to the field devices, the control module and/or controller may be tested prior to the field devices without the field environment being fully commissioned.

A method for operating a fieldbus controller (2) having a plurality of I/O modules (4) is provided, the fieldbus controller (2) being coupled to a valve assembly (6) via the plurality of I/O modules (4). The method includes providing a user interface (8) for wirelessly operating the fieldbus controller (2), wherein providing the user interface (8) includes: providing a configuration interface (14) for configuring an operating mode of the plurality of I/O modules (4); providing a monitor interface (16) for reading status information from the plurality of I/O modules (4); and providing a control interface (18) for controlling a state of the plurality of I/O modules (4), the state of the plurality of I/O modules affecting a state of the valve assembly (6).

A highly versatile process control or factory automation field device is configured with an interface and communication connection structure that enables the field device to operate as a data server that communicates with and supports multiple different applications or clients, either directly or indirectly, while simultaneously performing standard process and factory automation control functions. Moreover, various different process control and factory automation network architectures and, in particular, communication architectures, support the versatile field device to enable the versatile field device to simultaneously communicate with multiple different client devices or applications (each associated with a different system) via a common communication network infrastructure, using the same or different communication protocols.

A method and system for publish-subscribe communication architecture for highly-versatile (HV) field devices in control and automation system implements reception at an HV field device, from a client device or application, of a message indicating a selection of one of a plurality of publish categories. The publish category corresponds to a type of information desired by the client device or application. The field device transmits to the client device or application an identification of each of a plurality of publish lists corresponding to the selected publish category, which publish lists are each stored on the field device and each include a set of parameters associated with the field device. The field device receives, from the client device or application, a selection of one of the publish lists identified by the field device, and transmits to the client device or application the set of parameters associated with the selected publish list.

A plant device management system, which is configured to efficiently manage parameter information for field devices, in order for plant engineering, operation and maintenance is disclosed. The plant device management system includes, but is not limited to, a device parameter set manager, which is configured for creating class parameter set, configuring class parameter set, assigning class parameter set, auditing parameters and so forth. The device parameter set manager of the plant device management system may include, but is not limited to, a device parameter set creator tool, a device parameter set configuring tool, a device template manager and a device parameter auditor.

Disclosed is a system for collecting data from an automated plant having a field device connected for communication and for exchanging telegrams with a superordinate unit by means of a communication loop using a first protocol. The system includes a hat rail; and a terminal module mounted on the hat rail and embodied to monitor telegrams transmitted from the field device to the superordinate unit via the communication loop. The terminal module is further embodied to convert monitored telegrams into a second protocol and to output the converted telegrams. The system further includes a head module mounted on the hat rail and connected with the terminal module. The electronics unit of the head module is embodied to convert telegrams output from the terminal module into a third protocol to output them via the first network interface.

The present disclosure relates to a method for configuring step by step for transmission of data from a field device to at least one target system, comprising the steps of: creating a configuration comprising at least one subconfiguration for the field device and a subconfiguration for the target system; transmitting the configuration from the field device to the target system; and transmitting the data from the field device to the target system, wherein the data are forwarded, processed, stored or discarded based on the subconfiguration of the field device in the field device, and wherein the data are processed or stored in the target system based on the subconfiguration of the target system.

A system is provided to conduct communication in a facility with equipment in hazardous and safe areas. The system includes at least one field device in a hazardous area of the facility; one or more controllers, located in a safe area of the facility, for managing the at least one field device; and a field barrier, between the safe and hazardous areas, to limit at least electrical energy, which is supplied to the at least one device, at or below an electrical energy threshold in the hazardous area. The system also includes a bus system to supply electrical energy across the field barrier to the at least one field device using electrical wiring and to enable communication between the at least one field device and the one or more controllers across the field barrier using one or more fiber optic cables.