A system for determining a health condition and an anomaly of a field equipment 104 is provided. The system includes sensors 106A-N which sense information associated with the equipment 104, a field device 110 which receives the sensor data from sensors 106A-N, a camera unit 108 that captures visual data of the equipment 104 and a server 112. The server 112 includes a database 114 that stores the sensor data and the visual data. The server 112 further includes a fault detection module 202 that processes the sensor data to determine a fault or the health condition of the equipment 104, an image processing module 204 that is trained to detect the irregularities/anomaly in the equipment 104 by processing the visual data, and a report generation module 206 that generates an automated health report 212 based on the detected anomaly and the health condition of the equipment 104.

A hyperconverged industrial process control architecture is disclosed for controlling an industrial process within a physical process environment using a software-defined distributed control system (DCS) environment. The software-defined DCS environment may be implemented by virtualizing the hardware components of a DCS architecture on a server group to enable both software-defined process controllers and back-end DCS applications to run within the server group. This software-defined DCS network architecture reduces the hardware requirements of the process control system and reduces configuration complexity by implementing control components and higher-level components within a common environment within the server group.

The present disclosure includes a method and a system for remote-controlled servicing of a field device of process automation, including establishing a communication connection between a service unit and the field device via a first network, sending via a second network an access request from a computer unit to an application program executed on the service unit, wherein the application program serves for servicing the field device, approving the access request via the application program, and establishing access of the computer unit to the application program via the second network upon approval of the access request, wherein, after established access, the servicing of the field device occurs from the computer unit.

A hyperconverged industrial process control architecture is disclosed for controlling an industrial process within a physical process environment using a software-defined distributed control system (DCS) environment. The software-defined DCS environment may be implemented by virtualizing the hardware components of a DCS architecture on a server group to enable both software-defined process controllers and back-end DCS applications to run within the server group. This software-defined DCS network architecture reduces the hardware requirements of the process control system and reduces configuration complexity by implementing control components and higher-level components within a common environment within the server group.

A method for creating a virtual deployment of a distributed control system (DCS) for a given industrial process, comprising: providing a topology of the assets executing the industrial process, as well as control logic for controlling these assets; providing at least one I/O simulator that is configured to supply data; determining a topology of devices that form part of the DCS; establishing based at least in part on this topology of devices, at least one declarative and/or imperative description of the DCS that characterizes multiple devices of the DCS, their placement, and their connections; creating virtual instances of the devices of the DCS and their connections in a chosen environment.

A system for testing a distributed control system of an industrial plant is provided. The distributed control system includes at least two industrial control devices and at least one data communication device. The system includes at least one engineering computer that includes an engineering data storage unit for storing engineering data of at least one part of the distributed control system, and at least one human machine interface for manipulating the engineering data. The system also includes at least one remote data processing server connected to the at least one engineering computer via a remote data connection and including an emulating virtual machine on which a soft emulator is installed for emulating one of the at least two industrial control devices and the at least one data communication device.

An address detective method is executed by a parallel connection LED lighting system, and the parallel connection LED lighting system includes a plurality of the LED devices and a main controller. The main controller generates a testing signal to determine whether the LED devices are abnormal. The main controller further generates a reminder signal to remind a user where an abnormal LED device is. Then, the main controller replaces the address code in an address table which corresponds to the abnormal LED device with the address code of a new LED device. Therefore, the parallel connection LED lighting system can still control each of the LED devices to display a plurality of frames for showing dynamic lighting effects according to the address table. Namely, the user can easily fix the parallel connection LED lighting system.

This invention relates to a transponder key testing device and to a method of testing a transponder key. The transponder key may be used with any article using transponder key technology, typically a motor vehicle. The transponder key testing device has a first memory (30) in which is stored data relating to an article signal emitted by each one of a number of articles (10) and a second memory (32) in which is stored data relating to a response signal emitted by each one of a number of transponder keys (20). The testing device has a receiver (24) adapted to receive the article signal and the response signal. The testing device compares the article signal with data in the first memory, compares the response signal with data in the second memory, and determines whether or not the transponder key (20) is compatible with the article (10). There is also provided a method of testing a transponder key for compatibility with a particular article.

A testing method adapted for an electronic device operating an operating system at a particular temperature environment is provided. The method includes the steps of: determining whether an operating command is received; when the operating command is received, deriving a test, executing the test, and disabling a fan of the electronic device, wherein the test corresponds to one of a plurality of system states of an operating system, and includes a temperature threshold value corresponding to the system state and an entering action of the system state; and when the system state of the test corresponds to a work mode of the operating system, the test includes: continuously monitoring a temperature value of the central processing unit; and when the temperature value of the central processing unit reaches the temperature threshold value, enabling the fan and executing the entering action of the system state.

The present disclosure includes a method and a system for remote-controlled servicing of a field device of process automation, including establishing a communication connection between a service unit and the field device via a first network, sending via a second network an access request from a computer unit to an application program executed on the service unit, wherein the application program serves for servicing the field device, approving the access request via the application program, and establishing access of the computer unit to the application program via the second network upon approval of the access request, wherein, after established access, the servicing of the field device occurs from the computer unit.