A system and method for optimizing the end-to-end latency transfer rates over an air interface employing a Multi-hop Relays (MHR). The present system and method provides fast signaling process when no Downlink/Uplink Bandwidth allocation changes are employed, thereby bypassing PHY/MAC/IP Stack processing. The solution is intended for the new generation of 5G millimeter band multi-hop relays.

An embodiment relates to a method for UE operation related to platooning in a wireless communication system, the method comprising: transmitting a negotiation message including first vehicle function information to one or more UEs corresponding to a platooning member by a UE corresponding to a platooning leader; receiving a negotiation response message including second vehicle function information from at least one UE among the one or more UEs; selecting a new platooning leader on the basis of the negotiation response message by the UE corresponding to the platooning leader; and transmitting, by the UE corresponding to the platooning leader, a notification message including information related to the new platooning leader, wherein the negotiation message is related to a request for changing the platooning leader.

Embodiments of the disclosure provide a Bluetooth network, a communication method, an apparatus, and a storage medium thereof. In the embodiments of the disclosure, a Bluetooth network comprises a Bluetooth node configured with a forwarding capability and serving as a non-leaf node, and a Bluetooth node functioning in a Bluetooth advertising mode to serve as a leaf node. Each leaf node is connected to at least one of one or more non-leaf nodes. Via the forwarding capability of the non-leaf node, the leaf node communicates with other leaf nodes or non-leaf nodes not within its signal coverage, thereby extending a communication range of a Bluetooth node.

Embodiments of the disclosure provide a Bluetooth network, a communication method, an apparatus, and a storage medium thereof. In the embodiments of the disclosure, a Bluetooth network comprises a Bluetooth node configured with a forwarding capability and serving as a non-leaf node, and a Bluetooth node functioning in a Bluetooth advertising mode to serve as a leaf node. Each leaf node is connected to at least one of one or more non-leaf nodes. Via the forwarding capability of the non-leaf node, the leaf node communicates with other leaf nodes or non-leaf nodes not within its signal coverage, thereby extending a communication range of a Bluetooth node.

A battery system may include: a master battery processor configured to transmit monitoring commands; and slave battery processors configured to be coupled to batteries, and to transmit battery information of the batteries coupled thereto, to the master battery processor in response to the monitoring commands. The master battery processor determines operation modes of the slave battery processors on the basis of the battery information transmitted from the slave battery processors, and the slave battery processors communicate with the master battery processor at different communication participation rates according to the determined operation modes.

A battery system may include: a master battery processor configured to transmit monitoring commands; and slave battery processors configured to be coupled to batteries, and to transmit battery information of the batteries coupled thereto, to the master battery processor in response to the monitoring commands. The master battery processor determines operation modes of the slave battery processors on the basis of the battery information transmitted from the slave battery processors, and the slave battery processors communicate with the master battery processor at different communication participation rates according to the determined operation modes.

A facility for operating a communication device is described. The facility joins a network to which one or more other communication devices are connected, and identifies a type of network service not being provided in the network. In response, the facility determines to provide the identified type of network service in the network, and proceeds to provide the identified type of network service in the network.

The operation has a plurality of points, each associated with a slave device, the devices being part of a SCADA network that includes a computer. The apparatus comprises: modules each including a sensor having a thermal imager and a transceiver coupled to the sensor to receive data and adapted for cellular communication; and functionality adapted to receive information via cellular network and to communicate with the SCADA. The functionality is couplable to the SCADA as a device and configured such that data delivered from the sensor to the transceiver is delivered as if from multiple points. The system comprises: a repository; a computer adaptation configured to permit conditions to be set which trigger alerts including a DNP point and a time stamp; and a further adaptation which, responsive to an alert, fetches from the repository an image file associated with the point and the stamp, and displays the image.

Presented herein are methodologies for managing radio resources in a venue that implements a high density wireless infrastructure. The methodology includes detecting, using wireless access points, neighbor awareness networking (NAN) communications broadcast by a mobile device, determining a wireless channel on which the mobile device is sending the NAN communications, predicting a destination of the mobile device based on a path, through a predetermined venue, being taken by the mobile device, the path being detected using the wireless access points; and implementing a radio resource management remediation technique to reduce radio interference that is expected to be caused by the NAN communications broadcast by the mobile device at the destination based on the wireless channel and the destination.

Devices communicating wirelessly may experience temporary disconnections. While disconnected, a device may be unable to notify the other device that an update has occurred and that data previously used for communication may no longer be current. An ephemeral characteristic can be used by a service device that is updated each time a change occurs on the service device that may impact communications. A client device can use cached service data to attempt to write to this ephemeral characteristic. If the write does not complete successfully, it can be determined that the cached data is no longer current and a service request change can be used to cause the client device to flush the cached data and request current data from the service device.