One aspect provides a modular infrastructure asset inspection robot, including: a plurality of modules for use in fluid conveyance infrastructure assets; each of the plurality of modules including at least one standardized electromechanical connection permitting a connection to be established with another of the plurality of modules; the plurality of modules being interchangeable and allowing reconfiguration of said modular infrastructure asset inspection robot to perform one or more of: two or more deployment methods for a first infrastructure asset type; and one deployment method for the first infrastructure asset type and a second infrastructure asset type. Other aspects are described and claimed.

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.

A computer-implemented system and method for configuring a plurality of field devices enables a user to perform both device parameter editing and marking device parameters for bulk transfer in a simple an easy manner. The system and method provide a single application or utility that enables a user to view and make configuration changes as well as to view and change bulk transfer status for individual field device parameters while providing the user contextual information regarding the field device components to which the field device parameters belong or relate. The system and method provide the user with typical or standard configuration screens that enable the user to perform configuration activities in a simple and well-known format, but that include contextual indications of the various field device components to which the displayed field device parameters relate. This functionality enables the user to view and change the bulk transfer status of the individual parameters, without needing to go to a separate application or screen.

A method for storing data for at least one of a device state, device diagnosis and calibration of a field device in a cloud, with the field device having a self-monitoring functionality. The method includes device-internal registering of first data for at least one of a device state, device diagnosis and calibration by the field device and transfer of the device-internally registered first data from the field device to the cloud. Moreover, the method includes registering second data for at least one of a device state, device diagnosis and calibration of the field device using an external service computer and transferring the second data from the external service computer to the cloud. Both the first data as well as also the second data are stored in the cloud.

Recently, there is a desire to accurately share information concerning the presence or absence and content of a change in a setting parameter value. Provided is a change detection apparatus including a parameter acquiring section that acquires a value of at least one setting parameter of a field device, at predetermined time intervals; a change detecting section that detects whether the value of the setting parameter has been changed; and a change information output section that outputs change information, in response to a change in the value of the setting parameter having been detected.

A method for storing data for at least one of a device state, device diagnosis and calibration of a field device in a cloud, with the field device having a self-monitoring functionality. The method includes device-internal registering of first data for at least one of a device state, device diagnosis and calibration by the field device and transfer of the device-internally registered first data from the field device to the cloud. Moreover, the method includes registering second data for at least one of a device state, device diagnosis and calibration of the field device using an external service computer and transferring the second data from the external service computer to the cloud. Both the first data as well as also the second data are stored in the cloud.

A computer-implemented system and method for configuring a plurality of field devices enables a user to perform both device parameter editing and marking device parameters for bulk transfer in a simple an easy manner. The system and method provide a single application or utility that enables a user to view and make configuration changes as well as to view and change bulk transfer status for individual field device parameters while providing the user contextual information regarding the field device components to which the field device parameters belong or relate. The system and method provide the user with typical or standard configuration screens that enable the user to perform configuration activities in a simple and well-known format, but that include contextual indications of the various field device components to which the displayed field device parameters relate. This functionality enables the user to view and change the bulk transfer status of the individual parameters, without needing to go to a separate application or screen.

The invention relates to a method for operating a processing device (2) that comprises a control unit (4) and at least one field device (8, 10, 12) connected to said control unit (4) for the purpose of exchanging data via a data exchange connection (6), in which a field device (10) to be exchanged is replaced by another field device (12) to be inserted, and which comprises the steps of: generating an exchange signal (AS) using an exchange signal generator (14), and transmitting said exchange signal (AS) to the control unit (4). The invention also relates to a corresponding processing device and a control unit, field device, and exchange signal generator, as well as a computer program.

Recently, there is a desire to accurately share information concerning the presence or absence and content of a change in a setting parameter value. Provided is a change detection apparatus including a parameter acquiring section that acquires a value of at least one setting parameter of a field device, at predetermined time intervals; a change detecting section that detects whether the value of the setting parameter has been changed; and a change information output section that outputs change information, in response to a change in the value of the setting parameter having been detected.

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.