A building management system (BMS) of a building for controlling a healthcare facility. The BMS including one or more processing circuits comprising one or more memory devices configured to store instructions thereon that, when executed by one or more processors, cause the one or more processors to: receive a signal indicating a code blue event in a room for a patient; and adjust at least one of a temperature, a pressure, a humidity level, a lighting system, or an air composition in the room automatically in response to the received signal.

In some examples, a system for comfort or security in a building and its premises includes a plurality of “first” devices configured to wirelessly communicate with a hub device that is a master for controlling the system for comfort or security in the building and premises, wherein the plurality of first devices and the hub device are configured to wirelessly communicate using either one of an IEEE 802.15.4 standard or a Bluetooth Low Energy (BTLE) 5.0 standard; a plurality of “second” devices that are battery powered and configured to wirelessly communicate with respective ones of the plurality of first devices, wherein the plurality of second devices and respective ones of the plurality of first devices are configured to communicate using the BTLE 5.0 standard, wherein the hub device and the plurality of second devices are configured to communicate with each other via respective ones of the plurality of first devices.

A building management system, such as a small or medium business, having one or more control devices. Assigning codes to devices, and reading and listing them may aid in configuring the devices. Templates may be used for dynamic configuration of devices and equipment. Representing terminal assignments and wiring diagrams of control devices may be intuitive in that they resemble real hardware for ease of complete installation. The present system and approach may provide an intuitive way of securely registering devices with cloud usage, for example, involving a mobile phone with no manual entry of data so that a user can complete this process with ease. An intuitive, automatic and asynchronous device configuration downloading may be seen, such as to multiple control devices in a single shot. There may be seamless configuration data synchronization, for example, in view of replacement devices, or so the latest data is readily available.

A building management system, such as a small or medium business, having one or more control devices. Assigning codes to devices, and reading and listing them may aid in configuring the devices. Templates may be used for dynamic configuration of devices and equipment. Representing terminal assignments and wiring diagrams of control devices may be intuitive in that they resemble real hardware for ease of complete installation. The present system and approach may provide an intuitive way of securely registering devices with cloud usage, for example, involving a mobile phone with no manual entry of data so that a user can complete this process with ease. An intuitive, automatic and asynchronous device configuration downloading may be seen, such as to multiple control devices in a single shot. There may be seamless configuration data synchronization, for example, in view of replacement devices, or so the latest data is readily available.

The present disclosure provides a preset management method of a gas pipeline network for a smart gas, which is performed by a smart gas management platform. The smart gas management platform comprises a smart user service management sub-platform, a smart operation management sub-platform and a smart gas data center. The method comprises: obtaining, by the smart gas data center, a region feature of each region within a target range through a smart gas sensing network platform; determining, by the smart operation management sub-platform, a gas demand degree of the each region based on the region feature of the each region; determining, by the smart operation management sub-platform, a region as a first-class region based on the gas demand degree in the region meeting a preset condition, and determining a gas pipeline network opening scheme for the region.

The embodiments of the present disclosure provide methods for controlling natural gas efficiency enhancement of smart gas, smart gas Internet of Things (IoT) systems and mediums. The method may comprise obtaining at least one user need through a smart gas user platform based on a smart gas service platform, the user need including a gas usage target need; determining at least one optimization objective based on the at least one user need; determining a target proportioning feature of a synergist according to the at least one optimization objective, the target proportioning feature including a proportioning vector and an addition proportion of the synergist; and configuring a target synergist that satisfies the target proportioning feature to enhance efficiency of natural gas by sending the target proportioning feature to a smart gas object platform through a smart gas sensor network platform.

A control device may be configured to delay an attachment procedure while attachment messages are being transmitted over the network. The control device may be configured to initiate an attachment procedure with a router device on a network at the end a back-off period of time. The attachment procedure may include transmitting attachment messages (e.g., parent request messages) that enable the control device to transmit and receive messages over the network through the router device. During the back-off period of time, the control device may determine an attachment message is received from another control device on the network. And, if an attachment message (e.g., a parent request messages and/or a link request message) is received from another control device, the control device may increase the back-off period of time (e.g., delaying when the control device initiates its attachment procedure).

A method is described of managing service events in a distributed computing system. The distributed computing system comprises a plurality of computing nodes able to perform a service using a service process. The method takes place at one of the computing nodes. A service event is received or created. This service event is identified by a combination of a node identifier, a time element, and a local counter value. The local counter value represents a number of service events performed by a service process for a user since a last reset. The identified service event is then stored in a service process database according to node identifier and local counter values. The service process database is used to manage service events in the distributed system. Service events are removed from the service process database when no longer valid using the time element

Systems and methods for controlling an Internet of Things (IoT) device through interaction with an augmented reality (AR) object includes pairing an AR object with an IoT device, presenting the AR object on a display of an AR camera device of a user, receiving an interaction signal indicating that the user has interacted with the AR object on the display of the AR camera device, and sending a control signal to the IoT device paired with the AR object in response to the interaction signal. A second user may request presentation of the AR object to the AR display of the AR camera device of the user when the user's AR camera device is located at particular world coordinates. Also, the control signal may be sent when a particular series of interactions with the AR object have been completed, as during game play.

Systems and methods for controlling an Internet of Things (IoT) device through interaction with an augmented reality (AR) object includes pairing an AR object with an IoT device, presenting the AR object on a display of an AR camera device of a user, receiving an interaction signal indicating that the user has interacted with the AR object on the display of the AR camera device, and sending a control signal to the IoT device paired with the AR object in response to the interaction signal. A second user may request presentation of the AR object to the AR display of the AR camera device of the user when the user's AR camera device is located at particular world coordinates. Also, the control signal may be sent when a particular series of interactions with the AR object have been completed, as during game play.