Systems and methods described herein provide an intelligent MEC resource scheduling service. A network device in a MEC network stores, in a memory, threshold values indicating overload conditions for resource usage by a first MEC cluster; monitors resource usage in the first MEC cluster; determines, based on the monitoring, when one of the threshold values is reached; identifies available resources in a second MEC cluster; and re-directs, based on the identifying, at least some of the resource usage from the first MEC cluster to the second MEC cluster.

Resource load balancing for eNodeB includes identifying reduced workload conditions for an underutilized processor (CPU) core and transferring dedicated traffic channel (DTCH) communication to a target CPU core. Upon migrating each DTCH from the selected CPU core, the underutilized CPU core is caused to go into sleep mode, not to receive DTCH request until activated.

Provided are an apparatus and a method for allocating a bandwidth for providing a low-latency fronthaul service in a passive optical network. An bandwidth allocating method performed by a bandwidth allocating apparatus included in an OLT includes receiving an actual report message requesting bandwidth allocation from at least one ONU for wired subscribers connected to the OLT, receiving radio scheduling information for at least one ONU for mobile connected to the OLT from a central unit (CU)/digital unit (DU), generating a virtual report message using the radio scheduling information received from the CU/DU, allocating a transmission bandwidth for the at least one ONU for wired subscribers and the at least one ONU for mobile through the received actual report message and the generated virtual report message, and transmitting the allocated transmission bandwidth to the ONU for wired subscribers and the ONU for mobile using a grant message.

Systems and methods for balancing load in an area of a wireless network comprising first nodes operating according to a first Radio Access Technology and at least one second node operating according to a second Radio Access Technology. The method comprises establishing a connection between a user device and a first node; receiving an indication of an entry threshold for establishing a connection between the user device and a second node during a current time period, wherein the entry threshold is determined in dependence on an expected usage requirement for the area of the wireless network during the current time period; determining, by the user device, whether a parameter of a signal received from the second node exceeds the entry threshold; and responsive to determining that the parameter of the signal received from the second node exceeds the entry threshold, establishing, by the first node, a dual connectivity session between the user device and both the first and the second nodes.

Techniques are described herein for using unlicensed assisted access aggregated band to improve direct communication channel bandwidth reliability in a vehicle-to-everything (V2X) communication. The techniques include a (wireless communication) device that uses a first licensed band to perform a cellular network communication through a first interface (e.g., Uu), and further uses a shared spectrum to perform the V2X communication through a direct communication channel interface. The device then monitors and compares a bandwidth requirement of the V2X communication with a bandwidth of the shared spectrum. In response to the bandwidth that is less than the bandwidth requirement, the device selects at least one second licensed band to be aggregated with the shared spectrum to generate the unlicensed assisted access aggregated band. In some embodiment, the device adjusts the first licensed based on the selected least one second licensed band to avoid channel interference.

Techniques are described herein for using unlicensed assisted access aggregated band to improve direct communication channel bandwidth reliability in a vehicle-to-everything (V2X) communication. The techniques include a (wireless communication) device that uses a first licensed band to perform a cellular network communication through a first interface (e.g., Uu), and further uses a shared spectrum to perform the V2X communication through a direct communication channel interface. The device then monitors and compares a bandwidth requirement of the V2X communication with a bandwidth of the shared spectrum. In response to the bandwidth that is less than the bandwidth requirement, the device selects at least one second licensed band to be aggregated with the shared spectrum to generate the unlicensed assisted access aggregated band. In some embodiment, the device adjusts the first licensed based on the selected least one second licensed band to avoid channel interference.

Methods, systems, and devices for wireless communications are described that support resource utilization based event triggering. A wireless node in a wireless communications system may establish a connection with a core network via a path that includes one or more relay nodes. The wireless node may determine that a network load associated with one or more paths between the wireless node and the core network has changed, or that a difference between two or more network loads of different paths has changed. Based on such a determination, the wireless node may transmit a report to the network. In some cases, the network may receive the report from the wireless node, and may initiate a path change based on the report.

A backhaul bandwidth management method for a wireless network is provided. Firstly, a backhaul connection mode is adjusted by a network device in a backhaul network according to a wireless capability. Then, a backhaul guaranteed bandwidth is guaranteed by the network device according to at least one of a dedicated service set identifier (SSID), a dedicated radio frequency (RF) band and a dedicated wireless mode. Then, a bandwidth allocation algorithm is executed by the network device to ensure that at least one backhaul transmission connection has the backhaul guaranteed bandwidth. Finally, a backhaul SSID is set to a first wireless network standard only mode by the network device to ensure that data transmission will not be interfered with by other network devices transmitting data according to a second wireless network standard in the backhaul network.

A data router serves User Equipment (UEs) over network connections to network slices. The router executes an operating system, and in response, executes router applications in containers. The router applications receive a container configuration, a connection configuration, and a slice configuration from the wireless communication network. The router applications transfer the container configuration to the operating system. The operating system controls processing qualities of the containers based on the container configuration. The router applications generate and transfer the performance information for the network connections to the wireless communication network. The router applications prioritize the network connections to the network slices based on the slice configuration. The router applications exchange user data with the UEs and exchange the user data with the network slices over the network connections using service qualities based on the connection configuration.

A system, method, and computer-readable medium are disclosed for performing an intelligent connectivity operation. The intelligent connectivity operation includes: identifying context aware information associated with an information handling system; identifying network infrastructure operational information, the network infrastructure operational information including access point (AP) usage information; and, selecting an access point and a channel within the network infrastructure for use by the information handling system based upon the context aware information and the network infrastructure operational information.