The present disclosure describes a computer-implemented method to manage an industrial plant facility, the method including: monitoring multiple streams of input data from a network of sensors at the industrial plant facility, wherein the network of sensors include one or more camera devices; determining, by a server computer, an event during construction or operation of the industrial plant facility based on analyzing the multiple streams of input data in real-time; and based on the determined event, generating a notification to alert at least one operator of the industrial plant facility.

A video surveillance system includes a plurality of video surveillance cameras each for producing a corresponding video stream, a server configured to receive and store the video streams, and a first control room having a video wall. The video wall may be operatively coupled to the server and may be configured to concurrently display two or more of the video streams from two or more of the plurality of video surveillance cameras in a first arrangement. The video surveillance system may further include a remote virtual reality headset with a display and a virtual reality controller operatively coupled to the virtual reality headset and the server. The virtual reality controller may be configured to receive the same two or more video streams that are displayed on the video wall in the first control room and display them in the virtual reality headset.

A plant for manufacturing products, in particular for applying a coating on parts, includes apparatuses having radiofrequency transmitters, with a pre-set periodicity, of a radio signal containing a unique identifier of each apparatus; a portable device carried by an operator and receiving the radio signal; a program loaded on and performed by the portable device to extract a unique identifier of the apparatus and detect the operator-apparatus distance through an analysis of the trend of the radio signal, the radio-transmitters transmitting periodically their unique identifier and having a remote configuring/setting channel through radio-frequency communication with an external control device to exchange data packets; and a connecting procedure between the portable device and the radio-frequency transmitter to receive information on the operating status of the apparatuses, the signals being transmitted to a remote server or a cloud to monitor the operating conditions of the apparatuses.

A programmable data processing circuit is configured for receiving sensor signals indicative of gestures for identification by the processing circuit. The processing circuit applies to the sensor signals finite state machine processing resources to provide identification output signals indicative of gestures identified as a function of the sensor signals. A plurality of finite state machine processing programs loaded into the processing circuit include a data section and an instruction section. The data section including a fixed size part specifying respective processing resources used by the programs in the plurality of finite state machine processing programs and a variable size part with respective sizes for allocating the respective processing resources used by the programs in the plurality of finite state machine processing programs. The instruction section including conditions and commands for execution by the respective processing resources used by the programs by operating on data located in the respective data sections.

A video surveillance system includes a plurality of video surveillance cameras each for producing a corresponding video stream, a server configured to receive and store the video streams, and a first control room having a video wall. The video wall may be operatively coupled to the server and may be configured to concurrently display two or more of the video streams from two or more of the plurality of video surveillance cameras in a first arrangement. The video surveillance system may further include a remote virtual reality headset with a display and a virtual reality controller operatively coupled to the virtual reality headset and the server. The virtual reality controller may be configured to receive the same two or more video streams that are displayed on the video wall in the first control room and display them in the virtual reality headset.

A programmable data processing circuit is configured for receiving sensor signals indicative of gestures for identification by the processing circuit. The processing circuit applies to the sensor signals finite state machine processing resources to provide identification output signals indicative of gestures identified as a function of the sensor signals. A plurality of finite state machine processing programs loaded into the processing circuit include a data section and an instruction section. The data section including a fixed size part specifying respective processing resources used by the programs in the plurality of finite state machine processing programs and a variable size part with respective sizes for allocating the respective processing resources used by the programs in the plurality of finite state machine processing programs. The instruction section including conditions and commands for execution by the respective processing resources used by the programs by operating on data located in the respective data sections.

A video surveillance system includes a plurality of video surveillance cameras each for producing a corresponding video stream, a server configured to receive and store the video streams, and a first control room having a video wall. The video wall may be operatively coupled to the server and may be configured to concurrently display two or more of the video streams from two or more of the plurality of video surveillance cameras in a first arrangement. The video surveillance system may further include a remote virtual reality headset with a display and a virtual reality controller operatively coupled to the virtual reality headset and the server. The virtual reality controller may be configured to receive the same two or more video streams that are displayed on the video wall in the first control room and display them in the virtual reality headset.

A method includes identifying one or more first devices contained in at least one image captured by a mobile device. The method also includes obtaining data associated with at least one of: the one or more first devices and one or more second devices connected to or interacting with the one or more first devices. The method further includes presenting information overlaid over the at least one image by the mobile device to a user, where the presented information includes the data or information based on the data. The presented information varies based on perceived distance or proximity of the mobile device to the one or more first devices.

An intrinsically-safe handheld field maintenance tool includes a controller, a process communication module, and a display. The process communication module is configured to communicate with a field device using a process communication protocol. The display is coupled to the controller. A user interface module is also coupled to the controller and is configured to receive user input. The controller is configured to detect a user input help request and provide a video output on the display in response to the user input help request.

Drones (e.g., unmanned aerial vehicles, or UAVs) equipped with cameras and sensors may be configured to travel throughout the field environment of a process plant to monitor process plant conditions. Onboard computing devices associated with the drones control the movement of the drones through the field environment of the process plant. The onboard computing devices interface with the cameras and other sensors and communicate with user interface devices, controllers, servers and/or databases via a network. The onboard computing devices may receive drone commands from user interface devices and/or servers, or may access drone commands stored in one or more databases. The onboard computing devices may transmit data captured by the cameras and/or other sensors to UI devices, controllers, servers, etc. Accordingly, the user interface devices may display data (including live video feeds) captured by the drone cameras and/or drone sensors to an operator in a human machine interface application.