Various systems and methods for implementing a software defined industrial system are described herein. For example, an orchestrated system of distributed nodes may run an application, including modules implemented on the distributed nodes. In response to a node failing, a module may be redeployed to a replacement node. In an example, self-descriptive control applications and software modules are provided in the context of orchestratable distributed systems. The self-descriptive control applications may be executed by an orchestrator or like control device and use a module manifest to generate a control system application. For example, an edge control node of the industrial system may include a system on a chip including a microcontroller (MCU) to convert IO data. The system on a chip includes a central processing unit (CPU) in an initial inactive state, which may be changed to an activated state in response an activation signal.

A data collecting apparatus (10) is connected to a device (20) via a network (31, 32), and includes a collector (142, 142), a communication controller (130), and a process execution controller (110). The collector (141, 142) collects data from the device (20) based on collection setting information, converts format of the data collected, and outputs the data whose format is converted. The communication controller (130) manages an addition of the collector (141, 142), provides the collection setting information to the collector (141, 142), and outputs data collected by the collector (141, 142). The process execution controller (110) manages processing of data outputted from the communication controller (130). The collector (141, 142) is provided as plug-in software (121, 122) containing information regarding a parameter setting item for when data is collected. The collection setting information is information in which a setting value is added with respect to the parameter setting item.

A method of operating a refinery including at least one coke drum coupled to a coker fractionator. A pump characteristics curve is provided for a fractionator bottom pump coupled to the coker fractionator comprising a net positive suction head required (NPSHr) curve as a function of a pump flow rate. Fog computing utilizes the pump characteristics curve along with at least one sensed input parameter including a real-time value for the pump flow rate to control the fractionator bottom pump to dynamically control a column pressure (Pc) in the coker fractionator. A reduction in Pc is obtained that reduces an available NPSH (NPSHa) which lessens a difference between the NPSHa and the NPSHr.

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

Systems and methods for controlling lab equipment such as transmitters are provided that includes a mini automation controller (MAC). The system provides a control system, user interface, and interfaces, including network interfaces usable for interfacing equipment, MAC, and user interfaces over a network, which provide a variety of functions including automation and monitoring of transmission sequences and receiver events. An exemplary MAC may include an Ethernet controller capable of converting an Ethernet signal to a serial signal. The MAC may also include a receiver monitor section comprising a fiber optic receiver input, a copper cable receiver input, and a monostable multivibrator. In addition to the receiver monitor section, the MAC may have a transmitter control section including a transmitter control pulse and a power output. An exemplary MAC may have a microcontroller coupled to the Ethernet controller, the receiver monitor section, and the transmitter control section.

Systems and methods for controlling lab equipment such as transmitters are provided that includes a mini automation controller (MAC). The system provides a control system, user interface, and interfaces, including network interfaces usable for interfacing equipment, MAC, and user interfaces over a network, which provide a variety of functions including automation and monitoring of transmission sequences and receiver events. An exemplary MAC may include an Ethernet controller capable of converting an Ethernet signal to a serial signal. The MAC may also include a receiver monitor section comprising a fiber optic receiver input, a copper cable receiver input, and a monostable multivibrator. In addition to the receiver monitor section, the MAC may have a transmitter control section including a transmitter control pulse and a power output. An exemplary MAC may have a microcontroller coupled to the Ethernet controller, the receiver monitor section, and the transmitter control section.

Each of communication control units that perform communication using EtherNet/IP executes data processing for reading of a state value stored in a state value management unit and/or writing of the state value to the state value management unit on the basis of first setting information, and executes exchange of frame data including the state value with the communication control unit of a communication partner on the basis of second setting information. If one communication control unit has failed the data processing, this information processing device displays, on a display, the first setting information of the one communication control unit and the second setting information of the communication control unit in a comparable manner, and if a pair of communication control units have failed exchange of frame data, the information processing device displays, on the display, the second setting information of one communication control unit and connection information in a comparable manner.

A method of communication with a programmable logic controller (PLC) system, performed by a computing device. The method includes converting a plurality of tags into a same operation unit, including blocking the plurality of tags by aligning each tag according to an offset, and putting the blocks in a window corresponding to a protocol data unit (PDU). A determination may be made whether or not to split a block that is put in the window.

An abnormality determination system includes motor control circuitry that controls a motor of a motor-driven machine based on a motor control command, and compares operation data of the motor obtained in controlling the motor with reference data stored in a storage to determine whether the motor driven machine has an operation abnormality, upper-level control circuitry that transmits the motor control command to the motor control circuitry, and data transceiver circuitry that transmits and receives the reference data and the operation data to and from the motor control circuitry.

Various systems and methods for implementing a software defined industrial system are described herein. For example, an orchestrated system of distributed nodes may run an application, including modules implemented on the distributed nodes. In response to a node failing, a module may be redeployed to a replacement node. In an example, self-descriptive control applications and software modules are provided in the context of orchestratable distributed systems. The self-descriptive control applications may be executed by an orchestrator or like control device and use a module manifest to generate a control system application. For example, an edge control node of the industrial system may include a system on a chip including a microcontroller (MCU) to convert IO data. The system on a chip includes a central processing unit (CPU) in an initial inactive state, which may be changed to an activated state in response an activation signal.