A moveable head of a computer numerically controlled machine may deliver electromagnetic energy sufficient to cause a first change in a material at least partially contained within an interior space of the CNC machine. A feature of the material may be imaged using at least one camera present inside the interior space to update a position of the material, and the moveable head may be aligned to deliver electromagnetic energy sufficient to cause a second change in the material such that the second change is positioned on the material consistent with the first change and with an intended final appearance of the material. Methods, systems, and article of manufacture are described.

A computer numerically controlled machine may include a movable head configured to deliver electromagnetic energy to a part of a working area in which the movable head may be commanded to cause delivery of the electromagnetic energy. The interior space may be defined by a housing and may include an openable barrier that attenuates transmission of light between the interior space and an exterior of the computer numerically controlled machine when the openable barrier is in a closed position. The computer numerically controlled machine may include an interlock that prevents emission of the electromagnetic energy when detecting that the openable barrier is not in the closed position. The commanding may result in the computer numerically controlled machine executing operations of a motion plan for causing movement of the movable head to deliver the electromagnetic energy to effect a change in a material at least partially contained within the interior space.

In some embodiments, systems, devices, and methods described herein provide digitized ecosystem architectures connecting systems and processes within and among various entities using Internet-of-Things (IoT) to integrate physical assets of the entities. In some embodiments, one or more blockchain applications and/or smart contracts and further define and manage system integration.

Method for setting up a redundant communication connection, and failsafe control unit, wherein a transport and/or networking functional unit of a communication device utilizes at least one communication network address associated with a primary control device and/or a secondary control device to set up two communication connections to a failsafe control unit that includes the primary control device and the secondary control device, where data transmitted via a first communication connection are forwarded from the primary control device to the secondary control device via a first synchronization connection such that data transmitted via a second communication connection are forwarded from the secondary control device to the primary control device via a second synchronization connection.

In some embodiments, systems, devices, and methods described herein provide digitized ecosystem architectures connecting systems and processes within and among various entities using Internet-of-Things (IoT) to integrate physical assets of the entities. In some embodiments, one or more blockchain applications and/or smart contracts and further define and manage system integration.

A highly versatile process control or factory automation field device is configured with an interface and communication connection structure that enables the field device to operate as a data server that communicates with and supports multiple different applications or clients, either directly or indirectly, while simultaneously performing standard process and factory automation control functions. Moreover, various different process control and factory automation network architectures and, in particular, communication architectures, support the versatile field device to enable the versatile field device to simultaneously communicate with multiple different client devices or applications (each associated with a different system) via a common communication network infrastructure, using the same or different communication protocols.

An execution plan segment of an execution plan can be received at a control unit of a computer numerically controlled machine from a general purpose computer. The execution plan segment can define operations for causing movement of a moveable head of the computer numerically controlled machine to deliver electromagnetic energy to effect a change in a material within an interior space of the computer numerically controlled machine. The execution plan segment can include a predefined safe pausing point from which the execution plan can be restarted while minimizing a difference in appearance of a finished work-product relative to if a pause and restart are not necessary. Operations of the computer numerically controlled machine can be commenced only after determining that the execution plan segment has been received up to and including the predefined safe pausing point by the computer numerically controlled machine.

A field device includes components to communicate with a control and/or asset management system of a process control system or with other field devices using any of several different communication protocols such as several different internet protocol (IP) protocols. This architecture allows for a single version of a field device to be provided in automation or plant control systems that use any of these communication protocols, thus saving on inventory and product development costs. Moreover, the multi-protocol field device or a system using the multi-protocol field device can manage the asset (read and write parameterized data from and to the asset) using one protocol while at the same time communicating real-time process/factory automation information using a second and different protocol. Moreover, the field device may be able to communicate to other devices including other field devices and host devices using both of these protocols or other protocols for different purposes.

A device may receive a hash table that includes lists of protocol detectors, wherein the hash table is generated based on historical process data identifying potential process variables associated with an industrial control system. The device may receive a packet identifying potential process variables associated with the industrial control system, and may extract, from the packet, packet data identifying a source address, a destination address, a port, and a transport protocol. The device may compare the packet data with data in the hash table to identify a set of lists of protocol detectors, and may process the packet data, with the set of lists of protocol detectors, to determine a matching protocol, no matching protocol, or a potential matching protocol for the packet. The device may perform one or more actions based on determining the matching protocol, no matching protocol, or the potential matching protocol for the packet.

An assembly line apparatus for the automatic application of different types of labels or cushions or glue (stickers) on a workpiece has a transportation device, a plurality of application devices, a central control device, and a first expansive cooperation device. The central control device has first and other communication ports which may each function in accordance with different protocols and standards. The central control device is electronically connected to the transportation device via the first communication port and electronically connected to the application devices via a second or further communication ports. The first expansive cooperation device generates first and second control signals to instruct, via the central control device, the transportation device to move or to stop and to the application devices to apply or not to apply certain stickers on a certain area of a workpiece.