The present disclosure relates to a control module circuit having a circuit communication input port, a circuit communication output port, a first controllable unit that has a first controller module, and a second controllable unit having a second controller module. The first controller module has a first communication input port connected with the circuit communication input port and a first communication output port. The second controller module has a second communication input port connected with the first communication output port and a second communication output port connected with the circuit communication output port. The first and second controllable units are adapted to be identified with a permanent identity by way of a transmittable data signal receivable at the communication input port and sequentially received by the first and second controllable units.

Systems and methods are provided for enabling coexistence of Information Technology (IT) systems and Operational Technology (OT) systems, where advanced computing functionality realized by the IT systems can be applied to legacy applications and incumbent hardware technologies resident in the OT systems. A distributed control node (DCN) implemented between the IT and OT systems may comprise a microcontroller system partitioned into two processor clusters. Microservices associated with the IT systems are provisioned to a high performance processor cluster, and legacy applications running bare metal associated with the OT systems are provisioned to a real-time processor cluster. Partitioning of the microcontroller system allows for interoperability between the microservices and the legacy applications.

The present disclosure relates to a control module circuit having a circuit communication input port, a circuit communication output port, a first controllable unit that has a first controller module, and a second controllable unit having a second controller module. The first controller module has a first communication input port connected with the circuit communication input port and a first communication output port. The second controller module has a second communication input port connected with the first communication output port and a second communication output port connected with the circuit communication output port. The first and second controllable units are adapted to be identified with a permanent identity by way of a transmittable data signal receivable at the communication input port and sequentially received by the first and second controllable units.

An industrial automation system employing a mesh topology of input/output allows flexibility in pairing field devices and controllers though the I/O mesh. Field devices can be connected to the geographically closest I/O module channel without regard to the location of the necessary controller. Modular prefabrication and deployment of the I/O modules becomes less complex and less time consuming thereby reducing costs.

The present disclosure relates to a control module circuit having a circuit communication input port, a circuit communication output port, a first controllable unit that has a first controller module, and a second controllable unit having a second controller module. The first controller module has a first communication input port connected with the circuit communication input port and a first communication output port. The second controller module has a second communication input port connected with the first communication output port and a second communication output port connected with the circuit communication output port. The first and second controllable units are adapted to be identified with a permanent identity by way of a transmittable data signal receivable at the communication input port and sequentially received by the first and second controllable units.

A motor control system includes a mechanical apparatus configured to be driven by a motor, a position detector configured to detect position information of the motor, circuitry configured to control the motor, at least one sensor configured to detect information relating to at least one of the mechanical apparatus and the motor, and an input and output device including input-and-output connectors. The position detector and the input and output device are connected to the circuitry through a same communication path. The at least one sensor is connected to the input-and-output connectors of the input and output device. The position information is configured to be transmitted from the position detector to the circuitry. The information relating to the at least one of the mechanical apparatus and the motor is configured to be transmitted from the at least one sensor to the circuitry through the input and output device.

The present disclosure relates to a function connection unit for connecting functional modules. The functional connection unit includes a plurality of functional module terminals configured to connect to the functional modules and to communicate according to a first communication protocol, and a service module that includes a service terminal configured to connect to at least one functional module terminal of the plurality of functional module terminals to communicate according to the first communication protocol. The service module also includes a communication terminal to communicate according to a second communication protocol. The service module is configured to supply parameter data available at the communication terminal according to the second communication protocol to the service terminal according to the first communication protocol. The function connection unit is configured to parameterize at least one functional module based at least in part on the parameter data.

An industrial automation system employing a mesh topology of input/output allows flexibility in pairing field devices and controllers though the I/O mesh. Field devices can be connected to the geographically closest I/O module channel without regard to the location of the necessary controller. Modular prefabrication and deployment of the I/O modules becomes less complex and less time consuming thereby reducing costs.

An information transfer mechanism includes processing apparatus and a head-mounted display, and transfers information of the processing apparatus to an operator. The processing apparatus has an information transmitter for transmitting positional information of the processing apparatus, individual identification information of the processing apparatus, and notice information to be notified to the operator. The head-mounted display receives the notice information of the processing apparatus which have entered a visual field thereof and displays the received notice information in overlapping relation to the scene of peripheral processing apparatus.

A motor control system includes a mechanical apparatus configured to be driven by a motor, a position detector configured to detect position information of the motor, circuitry configured to control the motor, at least one sensor configured to detect information relating to at least one of the mechanical apparatus and the motor, and an input and output device including input-and-output connectors. The position detector and the input and output device are connected to the circuitry through a same communication path. The at least one sensor is connected to the input-and-output connectors of the input and output device. The position information is configured to be transmitted from the position detector to the circuitry. The information relating to the at least one of the mechanical apparatus and the motor is configured to be transmitted from the at least one sensor to the circuitry through the input and output device.