Provided is an information processing device including at least one processor which executes an obtaining process for obtaining sensor data transmitted from each of sensors included in a sensor group, a converting process for converting the sensor data, which has been obtained in the obtaining process, into a particular format, and a providing process for providing, to main equipment, the sensor data whose format has been converted in the converting process.

A device includes a master device, a set of slave devices and a bus. The master device is configured to transmit first messages carrying a set of operation data message portions indicative of operations for implementation by slave devices of the set of slave devices, and second messages addressed to slave devices in the set of slave devices. The second messages convey identifiers identifying respective ones of the slave devices to which the second messages are addressed requesting respective reactions towards the master device within respective expected reaction intervals. The slave devices are configured to receive the first messages transmitted from the master device, read respective operation data message portions in the set of operation data message portions, implement respective operations as a function of the respective operation data message portions read, and receive the second messages transmitted from the master device.

In a master device (control device) that employs a configuration list, setup change is performed easily without requiring a complicated operation with respect to a partial change in the configuration of a slave-side system on a slave side. A control unit (11) of a control device (10) is configured to perform communication for inquiring about device information to an address in an active configuration list through a communication unit (12), and determine to be abnormal when the result of the communication with respect to a common portion of a slave-side system (20) is different from the device information in the active configuration list.

In a master device (control device) that employs a configuration list, setup change is performed easily without requiring a complicated operation with respect to a partial change in the configuration of a slave-side system on a slave side. A control unit (11) of a control device (10) is configured to perform communication for inquiring about device information to an address in an active configuration list through a communication unit (12), and determine to be abnormal when the result of the communication with respect to a common portion of a slave-side system (20) is different from the device information in the active configuration list.

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 settings information generation device, for reducing the number of settings steps pertaining to a device in a superordinate device that communicates with a slave device to which the device is connected, includes: a selection unit for accepting a selection of a device to be connected; an acquisition unit for acquiring operational settings information including the input/output data length of the selected device; and a generation unit for generating, on the basis of the operational settings information, superordinate device settings information for setting a storage region for storing data exchanged with the device by a controller via a device management unit.

A device includes a master device, a set of slave devices and a bus. The master device is configured to transmit first messages carrying a set of operation data message portions indicative of operations for implementation by slave devices of the set of slave devices, and second messages addressed to slave devices in the set of slave devices. The second messages convey identifiers identifying respective ones of the slave devices to which the second messages are addressed requesting respective reactions towards the master device within respective expected reaction intervals. The slave devices are configured to receive the first messages transmitted from the master device, read respective operation data message portions in the set of operation data message portions, implement respective operations as a function of the respective operation data message portions read, and receive the second messages transmitted from the master device.

A process for integrating an industrial automation system with an Internet of Things (IoT) system may include providing access to a cloud-based platform, the cloud-based platform having a user interface. The user interface provides for easily displaying and changing configuration parameters describing a gateway module, a data acquisition module, and a sensor data channel associated with an industrial automation system wherein the data acquisition module can collect and process data from the sensor data channel and communicate that sensor data and any related processed information to a gateway module. The gateway module may also communicate configuration information to the data acquisition module and sensor data channel. The process may use the cloud-based platform to generate a memory map of the IoT system which can be used by a PLC or similar device of the industrial automation system to configure the IoT system and display data collected from the IoT system.

Described are platforms, systems, and methods to combine counts of activity correlations over time with a link salience method to identify collections of digital devices in an automated environment to identify sub-systems comprised of portions of the overall environment. The platforms, systems, and methods detect activity in a plurality of data sources associated with an automation environment; determine correlation in the detected activity between two or more of the data sources; store records of determined correlation in the detected activity over time in a data storage system; apply a link salience algorithm to the stored records of determined correlation in the detected activity to determine a salience property; and identify one or more subsystems in the automation environment based on the salience property.

A control system for operating a system having an operable component includes a master and a slave assigned to the component. The master and the slave each comprise a software processing part and a programmable logic part. The master is configured by its software processing part to: receive job data, transform the job data into component job data, and send the component job data to the slave. The master is configured by its programmable logic part to send information about a current job status to the slave. The slave is configured by its programmable logic part to receive the information about the current job status, and to send information about the current job status to its software processing part. The slave is configured by its software processing part to execute a job corresponding to the component job data using the current job status.