A PLC system construction support program for creating a system configuration diagram depicting a configuration of a PLC system constructed causes a computing terminal to function as: an image acquisition section that acquires image data of an image of the PLC system; a system configuration recognition section that creates system configuration information including arrangement information and selected unit information; a system configuration diagram generation section that creates a system configuration diagram based on the system configuration information; and a system configuration diagram editor section that performs display processing for displaying the system configuration diagram on a display section.

A PLC system construction support program for creating a system configuration diagram depicting a configuration of a PLC system constructed causes a computing terminal to function as: an image acquisition section that acquires image data of an image of the PLC system; a system configuration recognition section that creates system configuration information including arrangement information and selected unit information; a system configuration diagram generation section that creates a system configuration diagram based on the system configuration information; and a system configuration diagram editor section that performs display processing for displaying the system configuration diagram on a display section.

Apparatus and associated methods relate to a safety control system having a processor that (1) automatically interrogates a portable data storage device, (2) determines whether a configuration profile of the safety control system matches a stored configuration profile in the portable data storage device, (3) obtains network settings of the safety control system, and (4) stores network settings into the portable data storage device. In an illustrative example, a safety control system may include a processor designed to perform operations to configure the safety control system with a configuration profile stored in the portable data storage device or download network settings of the safety control system to the portable data storage device under some predetermined conditions. By using the above method, the safety control system may be quickly configured, and network settings may be easily obtained and backed up.

Apparatus and associated methods relate to a safety control system having a processor that (1) automatically interrogates a portable data storage device, (2) determines whether a configuration profile of the safety control system matches a stored configuration profile in the portable data storage device, (3) obtains network settings of the safety control system, and (4) stores network settings into the portable data storage device. In an illustrative example, a safety control system may include a processor designed to perform operations to configure the safety control system with a configuration profile stored in the portable data storage device or download network settings of the safety control system to the portable data storage device under some predetermined conditions. By using the above method, the safety control system may be quickly configured, and network settings may be easily obtained and backed up.

A system for configuration and control of a device includes a device processor includes at least two processing cores. Device firmware executes on a first processing core and a device-based engineering server executes on a second processing core. A web server running on the device-based engineering server includes a webApp providing web-based functionality for configuration and control of the device. The webApp is downloaded from the web server to the user's browser. A hypervisor manages communication between the device firmware and the device-based engineering server. A communication path established in the hypervisor for communicating a configuration or control instruction to the device firmware. The configuration or control instruction is initiated by a user via a web browser. The users web browser may run on a computer workstation that does not otherwise meet processing requirements of an engineering system for the device.

Apparatus and associated methods relate to a safety control system having a processor that (1) automatically interrogates a portable data storage device, (2) determines whether a configuration profile of the safety control system matches a stored configuration profile in the portable data storage device, (3) obtains network settings of the safety control system, and (4) stores network settings into the portable data storage device. In an illustrative example, a safety control system may include a processor designed to perform operations to configure the safety control system with a configuration profile stored in the portable data storage device or download network settings of the safety control system to the portable data storage device under some predetermined conditions. By using the above method, the safety control system may be quickly configured, and network settings may be easily obtained and backed up.

Apparatus and associated methods relate to a safety control system having a processor that (1) automatically interrogates a portable data storage device, (2) determines whether a configuration profile of the safety control system matches a stored configuration profile in the portable data storage device, (3) obtains network settings of the safety control system, and (4) stores network settings into the portable data storage device. In an illustrative example, a safety control system may include a processor designed to perform operations to configure the safety control system with a configuration profile stored in the portable data storage device or download network settings of the safety control system to the portable data storage device under some predetermined conditions. By using the above method, the safety control system may be quickly configured, and network settings may be easily obtained and backed up.

Generic shadowing allows a shadowing device in a process plant to automatically discover, without pre-configuration or pre-definition, and without the use of a configuration tool, source control objects that are hosted at other devices and that are to be shadowed. Source control objects may utilize any data type, format, structure, language, etc. The shadowing device includes a shadow manager and a set of primitive components defining simple data types that are utilized to discover the configurations/definitions and data types of source control objects, and includes a shadow library in which signatures of discovered source control objects are stored. Signatures are instantiated and used by the shadowing device to provide dynamic data to recipient devices, applications, and/or control objects in the process control system, where the dynamic data is a mirror of data that is observed first-hand by the source control objects during their on-line operations at their host devices.

A system for configuration and control of a device includes a device processor includes at least two processing cores. Device firmware executes on a first processing core and a device-based engineering server executes on a second processing core. A web server running on the device-based engineering server includes a webApp providing web-based functionality for configuration and control of the device. The webApp is downloaded from the web server to the user's browser. A hypervisor manages communication between the device firmware and the device-based engineering server. A communication path established in the hypervisor for communicating a configuration or control instruction to the device firmware. The configuration or control instruction is initiated by a user via a web browser. The users web browser may run on a computer workstation that does not otherwise meet processing requirements of an engineering system for the device.

A method for configuring a process control system includes coupling an I/O module to a PLC coupled to field devices. For each field device, the PLC has registers storing data of values associated with the field device. The PLC is configured such that each field device is associated with a PLC control tag, and each control tag is associated with tag parameters corresponding to the registers for the field device. The method includes configuring the I/O module to associate the tag parameters with corresponding controller parameters such that, for each control tag, there is a set of controller parameters associated with the tag parameters for the control tag. The method includes instantiating an integration object and associating the integration object with one of the control tags. The integration object configures itself, according to the set of controller parameters that is associated with the tag parameters for the control tag, as an analog input function block, a discrete input function block, an analog output function block, or a discrete output function block.