A flexible monitoring system and corresponding methods of use are provided. The system can include a base containing backplane, and one or more monitoring circuits. The monitoring circuits can be designed with a common architecture that is programmable to perform different predetermined functions. As a result, monitoring circuits can be shared between different implementations of the flexible monitoring system. Multiple bases that can be communicatively coupled in a manner that establishes a common backplane between respective bases that is formed from the individual backplanes of each base. Each monitoring circuit is not limited to sending data to and/or receiving data from the backplane to which it is physically coupled but can instead can communicate along the common backplane. Computational processing capacity can be increased or decreased independently of input signals received by addition or removal of processing circuits from the monitoring system.

In one embodiment, a condition monitoring circuit can include a circuit controller and a node. The node can include a gate controller, a node controller and one or more gates. The node can be configured to detachably couple to a bus of a monitoring system associated with an industrial machine. The circuit controller can be configured to identify an operating parameter associated with the industrial machine. The gate controller can be configured to transfer, via the one or more gates, one or more data packets including data characterizing the operating parameter from the bus in the monitoring system. The one or more gates can be configured to prevent transfer of an outgoing data packet to the bus via the node.

An industrial information hub (IIH) and an industrial development hub (IDH) serve as an industrial ecosystem platform where multiple participants can deliver repeatable and standardized services relevant to their core competencies. The IIH system is centered around the development of an ecosystem that creates and delivers value to users—including industrial enterprises, OEMs, system integrators, vendors, etc.—through the aggregation of digital content and domain expertise. The IIH system serves as a trusted information broker between the ecosystem and the OT environments of plant facilities, and provides a platform for connecting assets, contextualizing asset data and providing secure access to the ecosystem. As part of this ecosystem, the IIH system uses a secure remote access architecture to allow users to remotely access data on their plant floor assets via a virtual private network connection.

A cloud-based industrial controller that controls devices, processes, and other assets of an industrial automation system via control algorithms that execute on a cloud platform is presented. A cloud-based collection component collects information from the industrial automation system via cloud gateways associated with the industrial automation system or extrinsic data sources. The cloud-based industrial controller can monitor and analyze the information, generate control instructions based on the analysis results, and communicate the control instructions to the devices, processes, and/or other assets of the industrial automation system to control operation of the industrial automation system. The cloud-based industrial controller also can interface with a industrial plant-based industrial controller, wherein the cloud-based industrial controller can determine supplemental control instructions to the industrial plant-based industrial controller, based on the information, including extrinsic information, to assist in controlling the industrial automation system and control decision-making.

A number of communications for transmitting update data from a control device to a client is decreased, and discrepancies in the content of the latest update data between the control device and the client are prevented. The control device has: an update data monitoring unit for monitoring the latest update data and monitoring whether there has been an update within a predetermined time thereafter; an update data confirmation unit which, if there has been no update in the predetermined time, transmits to the client a request to confirm an update data reception state; a reception state determination unit which, based on the update data reception state in the client and the latest update data, determines whether the client has received the latest update data; and a retransmission instructing unit which, if the client has not received the latest update data, re-transmits the latest update data to the client.

A technique for providing reliable control of a robot (304) in a cloud robotics system (300) is disclosed. A computing unit configured to execute a concealment component (100) for concealing delayed or lost commands sent to the robot (304) by a robot controller (302) in the cloud robotics system (300) comprises at least one processor and at least one memory, wherein the at least one memory contains instructions executable by the at least one processor such that the concealment component (100) is operable to detect a missing command expected to be received by the robot (304) from the robot controller (302), the missing command detected based on a delay or loss of the command in a communication path between the robot (304) and the robot controller (302), generate a substitutional command corresponding to an expected instruction of the missing command, and send the substitutional command to the robot (304).

In some embodiments, a method is performed at a computer system of a manufacturer. The manufacturer operates a manufacturing facility that includes equipment from an equipment supplier. In the method, a request is received for electronic access by the equipment supplier to the manufacturing facility to perform a remote support activity for the equipment. The request is routed to predefined approvers. Approval of the request is received from the predefined approvers. In response to receiving approval of the request from the predefined approvers, a connection is automatically created between an electronic device in the manufacturing facility and a computer system for the equipment supplier. The connection is used for the remote support activity. Upon completion of the remote support activity, the connection is automatically terminated.

System and Method for Factory Automation and Enhancing Machine Capabilities The present invention relates to system and method for factory automation and for enhancing machine capabilities. The system is configured to extract data from machine through data capturing module, data extraction module and data conversion module and jointly analyze them with data from other equipment and sensors through data analysis engine and transmitting to factory systems in user configured protocol through protocol conversion module. It also accepts machine control commands from the factory systems and executes them through command processor and mouse & keyboard simulator modules. It involves combining GUI from multiple equipments/sensors and sending to single display device through GUI manager and video output modules and mapping required actions of mouse clicks and keyboard entries from new to old user interfaces. GUI manager module detects GUI elements from captured images and applies user configuration to automatically

A tele-manufacturing system comprising a manufacturing environment containing equipment used for a manufacturing process; a plurality of sensors positioned within the manufacturing environment in proximity to the manufacturing equipment, wherein each sensor is configured to gather data from the manufacturing environment; at least one digitizer in communication with the sensors for receiving data from sensors and converting the data into one or more three-dimensional digital maps or point clouds; at least one processor in communication with the at least one digitizer, wherein the processor includes software for receiving and analyzing the digital maps or point clouds; and at least one manual controller in communication with the processor, wherein the manual controller receives motion input from a user, wherein the software on the processor mathematically transforms the motion input into corresponding motion commands that are sent to the manufacturing equipment by the processor, and wherein the manufacturing equipment, which is physically remote from the at least one controller, executes the motion commands in real-time during the manufacturing process.

A central controller for a data network includes an input interface for receiving a request signal, a control unit for generating a control signal depending on the request signal received, and at least one output interface for transmitting the control signal to at least one participant device. The control signal is set up to actuate the at least one participant device to emit a participant output signal for identifying a physical position of the at least one participant device.