The embodiment of the present disclosure provides an Industrial Internet of Things system for inspection operation management of an inspection robot and a method thereof. The system includes a user platform, a service platform, a management platform, a sensor network platform, and an object platform that are interacted sequentially from top to bottom. The management platform is configured to perform operations including: determining an inspection task, the inspection task including detecting at least one detection site; sending instructions to an inspection robot based on the inspection task to move the inspection robot to a target position to be inspected; obtaining detection data based on the inspection robot, and determining subsequent detection or processing operations based on the detection data.

A system and method for automatically managing a living space relates to Internet of Things (IoT) implementations within a commercial or residential location that allow for fully private management of collected data. Such a system enables users to automate many different functions within their homes and properties, including temperature management, room illumination, humidity, and more, in order to optimize for a chosen metric, such as comfort, energy efficiency, or cost efficiency. Because the user takes ownership over sensors, servers, and output devices, collected data may be parsed, organized, stored, applied, and otherwise utilized without risk of exposing collected data to external parties. This control enables users to develop various interfaces, algorithms, command signals, visuals, and more at will, thereby ensuring the user may customize a living space according to whatever desirable outcomes the user chooses. A user may add further subsystems and features at will, enabling complex and varied implementations.

A system and method for automatically managing a living space relates to Internet of Things (IoT) implementations within a commercial or residential location that allow for fully private management of collected data. Such a system enables users to automate many different functions within their homes and properties, including temperature management, room illumination, humidity, and more, in order to optimize for a chosen metric, such as comfort, energy efficiency, or cost efficiency. Because the user takes ownership over sensors, servers, and output devices, collected data may be parsed, organized, stored, applied, and otherwise utilized without risk of exposing collected data to external parties. This control enables users to develop various interfaces, algorithms, command signals, visuals, and more at will, thereby ensuring the user may customize a living space according to whatever desirable outcomes the user chooses. A user may add further subsystems and features at will, enabling complex and varied implementations.

In one embodiment, a controller in a network obtains information associated with one or more nodes connected to a particular node in the network. The controller sends a Manufacturer Usage Description request for the particular node that includes the information associated with the one or more nodes connected to the particular node. The controller receives, in response to sending the Manufacturer Usage Description request, operational parameter values for the particular node. The controller configures the particular node using the operational parameter values.

In one embodiment, a controller in a network obtains information associated with one or more nodes connected to a particular node in the network. The controller sends a Manufacturer Usage Description request for the particular node that includes the information associated with the one or more nodes connected to the particular node. The controller receives, in response to sending the Manufacturer Usage Description request, operational parameter values for the particular node. The controller configures the particular node using the operational parameter values.

Systems and methods for controlling an Internet of Things (IoT) device through interaction with an augmented reality (AR) camera includes pairing an interactable augmented reality (AR) overlay with the IoT device. The interactable overlay includes control information for generating a control signal for controlling the IoT device when the interactable overlay is interacted with by the AR camera. The interactable overlay is presented on a display of the AR camera when the IoT device is in a field of view of the AR camera. An indication that the user has pointed the AR camera at the interactable overlay associated with the IoT device on the display of the AR camera is provided, and a control signal associated with the interactable overlay pointed at by the AR camera is provided to the at least one IoT device associated with the interactable overlay pointed at by the AR camera.

Systems and methods for controlling an Internet of Things (IoT) device through interaction with an augmented reality (AR) camera includes pairing an interactable augmented reality (AR) overlay with the IoT device. The interactable overlay includes control information for generating a control signal for controlling the IoT device when the interactable overlay is interacted with by the AR camera. The interactable overlay is presented on a display of the AR camera when the IoT device is in a field of view of the AR camera. An indication that the user has pointed the AR camera at the interactable overlay associated with the IoT device on the display of the AR camera is provided, and a control signal associated with the interactable overlay pointed at by the AR camera is provided to the at least one IoT device associated with the interactable overlay pointed at by the AR camera.

A system and method are described for ensuring that a product has been transported in acceptable environmental conditions. For example, one embodiment of the invention comprises: one or more sensors to measure environmental conditions during transport of the IoT device from an origin location to a destination location; a sensor interface coupled to the one or more sensors to communicate environmental values associated with the environmental conditions; a storage device to store monitor application program code; a processor coupled to the sensor interface and storage device, the processor to process the monitor application program code to perform operations based on the environmental values including storing the environmental values on the storage device; and a wireless communication interface to connect to an Internet of Things (IoT) service at one or more intermediate locations between the origin location and the destination location and/or at the destination location, the wireless communication interface to transmit the environmental values and/or event data associated with the environmental values to the IoT service; wherein the IoT service is to provide the environmental values and/or event data associated with the environmental values to one or more apps running on one or more client devices, the one or more apps associated with one or more accounts on the IoT service.

This application discloses an object control system (OCS) to control navigation of a moving vehicle when exiting from its own road or freeway to a new road or freeway. The new road or freeway is an underpass or overpass and have no physical junction with the moving vehicle's own road or freeway. The moving vehicles obtains its navigation information data from the IoT network it is registered with and a plurality of stationary objects near and in vicinity of an exit. The stationary objects during the time slots assigned to them by OCS transmit variety of information data that assist moving vehicle navigating to the right lane and exit. These stationary objects also provide an operation information data that is used in the new road or freeway in case the vehicle exits to a road or freeway that belongs to a new cell with different operation information data.

This application discloses an object control system (OCS) to control navigation of a moving vehicle when exiting from its own road or freeway to a new road or freeway. The new road or freeway is an underpass or overpass and have no physical junction with the moving vehicle's own road or freeway. The moving vehicles obtains its navigation information data from the IoT network it is registered with and a plurality of stationary objects near and in vicinity of an exit. The stationary objects during the time slots assigned to them by OCS transmit variety of information data that assist moving vehicle navigating to the right lane and exit. These stationary objects also provide an operation information data that is used in the new road or freeway in case the vehicle exits to a road or freeway that belongs to a new cell with different operation information data.