Controlling and communicating with separate sets of industrial process control devices via separate data protocols simultaneously with a single processing device that utilizes redundancy and task-splitting to increase availability. An exemplary system includes a device integrator processor configured to receive and transmit electronic data via a plurality of protocols simultaneously. In one form, the device integrator processor includes a primary module that primarily controls communications and synchronizes itself with a shadow module of the processor. In another form, the processor includes multiple cores that each control a set of devices. Moreover, the cores implement a redundancy scheme.

A circuit for coupling a field bus and a local bus. A field bus controller is equipped to send and receive process data over the field bus. A local bus controller is equipped to send and receive the process data over the local bus. A data management unit is connected to the field bus controller and the local bus controller. The data management unit is equipped to transfer the process data between field bus controller and local bus controller. A memory area connected to the data management unit for copying and storing the process data. A processor connected to the data management unit and connected to the memory area. The processor is equipped to set up the data management unit to copy the process data into the memory area and the processor is equipped to read out the process data copied in the memory area.

The invention relates to a conveying device for conveying objects comprising a plurality of conveyor segments, each conveyor segment having a control unit for controlling the conveyor drive, and a bus communication, wherein each control unit is connected to the bus communication. Each control unit has a microprocessor for processing control signals, a first electronic memory connected to the microprocessor, in which a first control configuration is stored, and a second electronic memory in which a second control configuration is stored. The microprocessor is adapted to control the conveyor drive in a first operating mode with the control configuration stored in the first memory, to load the second control configuration from the second memory into the first memory when a configuration change command is received, and to control the conveyor drive in a first operating mode with the control configuration stored in the first memory.

Provided is a process, including: receiving, via the network interface, from a remote user device, a command to change a state of the fluid-handling device to a target state; translating the received command into a translated command operative to cause a local controller of the fluid-handling device to drive the fluid-handling equipment to the target state, the local controller being responsive to the command and feedback from the fluid-handling device indicative of whether the fluid-handling device is in the target state; and sending the translated command to the local controller.

The invention relates to a project planning device and a method for configuring and/or parameterizing automation components of an automation system. The project planning device of the invention has a user interface and a network interface via which it can be connected to a network of an actual automation system. The project planning device is operable to create a target configuration and/or a target parameterization for an automation system, and to analyze a connected actual automation system with respect to the actual configuration and/or actual parameterization thereof. According to the invention, the project planning device is configured for automatically detecting accesses to the target configuration and/or the target parameterization based on predefinable access types, and for automatically initiating and performing the analyzing in response to a detected access and/or in response to a signal which is a predefinable regularly recurring signal.

The disclosure relates to a function connection unit for connecting at least one parameterizable functional module, including at least one functional module connection configured to connect to the at least one parameterizable functional module; a communication interface that is configured to receive first parameter data records, the first parameter data records including parameter data for parameterizing the at least one parameterizable functional module and first parameter indices that index a memory area for the parameter data; and a processor configured to convert the first parameter indices into second parameter indices to obtain second parameter data records, the second parameter indices indexing a predetermined memory area of the at least one parameterizable functional module for storing the parameter data in the at least one parameterizable functional module

Provided is a process, including: receiving, via the network interface, from a remote user device, a command to change a state of the fluid-handling device to a target state; translating the received command into a translated command operative to cause a local controller of the fluid-handling device to drive the fluid-handling equipment to the target state, the local controller being responsive to the command and feedback from the fluid-handling device indicative of whether the fluid-handling device is in the target state; and sending the translated command to the local controller

Provided is a process, including: receiving, via the network interface, from a remote user device, a command to change a state of the fluid-handling device to a target state; translating the received command into a translated command operative to cause a local controller of the fluid-handling device to drive the fluid-handling equipment to the target state, the local controller being responsive to the command and feedback from the fluid-handling device indicative of whether the fluid-handling device is in the target state; and sending the translated command to the local controller

A device control apparatus periodically transmits a status confirmation signal to a control source device described in a cooperation control table and receives a response signal with respect to the status confirmation signal. Device control apparatus determines whether or not a status included in the response signal matches a status described in the cooperation control table. If they match, a control destination device, an operation and a control command corresponding to the operation are specified using the cooperation control table. A configuration for transmitting a control command with respect to the control destination device is provided. Therefore, even in a case where a communication protocol and the control command are different from one another in makers of devices, it is possible to realize cooperation control.

Provided is a process, including: receiving, via the network interface, from a remote user device, a command to change a state of the fluid-handling device to a target state; translating the received command into a translated command operative to cause a local controller of the fluid-handling device to drive the fluid-handling equipment to the target state, the local controller being responsive to the command and feedback from the fluid-handling device indicative of whether the fluid-handling device is in the target state; and sending the translated command to the local controller.