A board-level assembly that is useful to expand functions of a valve positioner on a valve assembly. The board-level assembly can incorporate a main circuit board and a peripheral smart circuit board. The main circuit board may be configured to communicate with the smart circuit board, find a storage memory on the second circuit board, retrieve data from the storage memory, and use the data to configure functions on the first circuit board. In one implementation, the smart circuit board can release and engage the main circuit board. This configuration can allow different configurations of the smart circuit board to swap into the board-level assembly, each of the different configurations providing data the main circuit board can exploit to change the functions of the valve positioner.

The invention relates to automatically integrating a device in a networked system so that a user does not have to set-up or configure the new device. A basic idea of the invention is to provide an automatic copying procedure of the functionality of a device of a networked system to a new device, which is integrated in the networked system. An embodiment of the invention provides a method for copying the functionality of a device of a networked system to a new device, comprising the automatically performed steps of detecting a new device to be integrated in the networked system, determining a reference device of the networked system, and copying the functionality of the reference device to the new device.

The invention relates to automatically integrating a device in a networked system so that a user does not have to set-up or configure the new device. A basic idea of the invention is to provide an automatic copying procedure of the functionality of a device of a networked system to a new device, which is integrated in the networked system. An embodiment of the invention provides a method for copying the functionality of a device of a networked system to a new device, comprising the automatically performed steps of detecting a new device to be integrated in the networked system, determining a reference device of the networked system, and copying the functionality of the reference device to the new device.

The invention relates to automatically integrating a device in a networked system so that a user does not have to set-up or configure the new device. A basic idea of the invention is to provide an automatic copying procedure of the functionality of a device of a networked system to a new device, which is integrated in the networked system. An embodiment of the invention provides a method for copying the functionality of a device (10; 12) of a networked system to a new device (14), comprising the automatically performed steps of: detecting a new device (14) to be integrated in the networked system (S10), determining a reference device (10; 12) of the networked system (S12; S13), and copying the functionality of the reference device to the new device (S14).

An arrangement is disclosed having an electromotive furniture drive with a control device, a power supply device, and at least one operating device; a piece of furniture into which the electromotive furniture drive is installed; and a data device, the electromotive furniture drive and the data device are in communicative connection with each other. The communication connection between the electromotive furniture drive and the data device has a first transmission path, which is provided for transmitting an identification code of the electromotive furniture drive, and a second transmission path, which is provided for transmitting control data and/or operating data of the electromotive furniture drive. There is further disclosed a method for establishing a communication connection between an electromotive furniture drive and the data device.

A wireless communication system for use in a process environment uses mesh and possibly a combination of mesh and point-to-point communications to produce a wireless communication network that can be easily set up, configured, changed and monitored, thereby making a wireless communication network that is less expensive, and more robust and reliable. The wireless communication system allows virtual communication paths to be established and used within the process control system in a manner that is independent of the manner in which the wireless signals are sent between different wireless transmitting and receiving devices within the process plant. Still further, communication analysis tools are provided to enable a user or operator to view the operation of the wireless communication network to thereby analyze the ongoing operation of the wireless communications within the wireless communication network.

Techniques for commissioning a process control device in a process plant include obtaining, at a portable computing device, commissioning data for commissioning the respective process control device for operation, such as a device tag. The portable computing device then transfers the commissioning data to a component in the same process control loop as the process control device via a wireless communication link. For example, the component includes a radio-frequency identification (RFID) or near field communication (NFC) unit for receiving RFID/NFC signals. When the portable computing device is within RFID/NFC communication range of the component, the commissioning data is transferred via an RFID/NFC signal to the component. The commissioning data is received while the component is in an unpowered state, where the RFID/NFC signal energizes the RFID/NFC unit at the component for receiving the signal.

A method for setting energy supply parameters of a field device electrical current supply module. The field device electrical current supply module is connected, in such case, exclusively to one field device. The connected field device can be supplied electrical energy by the field device electrical current supply module. In the method, a field device type of the connected field device is identified first by the field device electrical current supply module. Then, a parameter setting of at least one energy supply parameter of the field device electrical current supply module is automatically read out from a database and this is loaded into the field device electrical current supply module.

A master device is configured to perform a method that includes receiving highway addressable remote transducer (HART) device data of a HART slave device connected to PROFIBUS RIO Slave. The method also includes identifying a device description (DD) file associated with the HART slave device using the HART device data that is collected automatically based on the PROFIBUS slave Profile index before even configuring the HART device in the system. The method further includes performing one or more device communication functions with the HART slave device to collect the data automatically.

A system, method, and computer-readable medium for generation of a controlled device Module are provided. Various components are provided to a Module designer for selection, and the designer defines the interface APIs specifying the component functionalities. The designer may specify custom commands or events for the Module including Commands, Properties, and Parameters, and custom components corresponding to the custom commands are generated. A self-describing capabilities component is then generated for each component, and a composite capabilities component may then be generated from the capabilities components of each of the components. The completed Module package is then produced by an integrated development environment station.