A system has a processor that may receive an order of an industrial device assembly having multiple industrial automation devices. The processor may also generate a first data file based on the order of the industrial device assembly. The first data file may have specification data associated with each industrial automation device and hierarchical information associated with each industrial automation device. Additionally, the processor may generate a second data file based on the first data file. The second data file has one or more control blocks of code associated with each industrial automation device. Further, the processor may transmit the second data file to a control system associated with the industrial device assembly. The control system is automatically programmed based on the second data file to control one or more operations of each industrial automation device in the industrial device assembly.

A system, method, and device for automated precision control of a computer numerical control (CNC) machine to a workpiece. The system receives via at least one visual input device at least one detectable marking on a workpiece. The system decodes the at least one detectable marking and determines a stored and pre-defined movement routine of a cutting element attached to the CNC machine relative to the workpiece based on the at least one marking. The system then determines, using the at least one visual input device and/or another visual input device, a current position of a working end of the cutting element relative to the at least one marking. Finally, the system performs the pre-defined movement routine including cutting into the workpiece with the cutting element.

There is described systems and methods for programming and configuring part-processing devices and production stations. Methods of programming the control system of a part-processing device for controlling one or more tooling components, sensors and/or motion systems includes the step of loading a software backplane onto the control system, the software backplane being configured to run on an operating system of the control system and to interface with one or more configurable applications. The method also comprises the step of loading one or more configurable applications associated with the one or more tooling components onto the control system, the one or more applications being configured to interface with the software backplane. The method also comprises the step of configuring the one or more configurable applications to control the one or more tooling components, sensors and/or motion systems pf the part-processing device.

A system and method for determining the operating conditions a machining operation includes a sensor array, a data acquisition system, and a computing device. The sensor array includes one or more sensors, such as a power, force, acoustic, fluid, or displacement sensor, configured to detect certain operational characteristics of the machining operating and machining tool. The sensor array is coupled to a computing device via a data acquisition system. The computing device runs software that outputs in human-readable format sensor data generated by the data acquisition system. The user can thereby detect anomalies in the machining operating, including errors or poor tolerances with the machining tool, such as a grinding of polishing wheel. The computing device can also send feedback signals to the machining tool to address detected anomalies. The computer software is configured to output up to eight (8) channels of data received from the sensor array.

A control system is configured by two-way communication conducted between a controller and a display terminal for displaying an operating state of the controller, and includes a processing time managing unit configured to measure time taken for processing pieces of data received from another end, and obtain from the other end and manage time taken on the other end for processing the pieces of data sent to the other end, and a congestion control unit configured to adjust a data sending amount to the other end per unit time based on the time taken for processing the pieces of data on the other end which are managed by the processing time managing unit.

A control system is configured by two-way communication conducted between a controller and a display terminal for displaying an operating state of the controller, and includes a processing time managing unit configured to measure time taken for processing pieces of data received from another end, and obtain from the other end and manage time taken on the other end for processing the pieces of data sent to the other end, and a congestion control unit configured to adjust a data sending amount to the other end per unit time based on the time taken for processing the pieces of data on the other end which are managed by the processing time managing unit.

An information processing device includes a command analysis unit configured to analyze a tendency of a command instruction for accessing a controller for each of applications, and a command delivery arbitration unit configured to arbitrate delivery of commands to the controller based on an analysis result by the command analysis unit.

An information processing device includes a command analysis unit configured to analyze a tendency of a command instruction for accessing a controller for each of applications, and a command delivery arbitration unit configured to arbitrate delivery of commands to the controller based on an analysis result by the command analysis unit.

A control device comprises a plurality of command application units, a plurality of platform units, and a shared memory. The command application units are each provided with a command mediation method designation unit that outputs, to the platform unit, identification information pertaining to a platform unit to be subject to cooperative control and a mediation method classification. The platform units are each provided with: an inter-platform communication unit that transmits a command value, the identification information, and the mediation method classification between the platform units via the shared memory; and a command mediation unit that acquires the command value, the identification information, and the mediation method classification from all platform units to be subject to cooperative control, mediates the command values on the basis of the identification information and the mediation method classification, and outputs the mediated command values to the shared memory.

A control device comprises a plurality of command application units, a plurality of platform units, and a shared memory. The command application units are each provided with a command mediation method designation unit that outputs, to the platform unit, identification information pertaining to a platform unit to be subject to cooperative control and a mediation method classification. The platform units are each provided with: an inter-platform communication unit that transmits a command value, the identification information, and the mediation method classification between the platform units via the shared memory; and a command mediation unit that acquires the command value, the identification information, and the mediation method classification from all platform units to be subject to cooperative control, mediates the command values on the basis of the identification information and the mediation method classification, and outputs the mediated command values to the shared memory.