Systems and methods are provided for improving spectral efficiency in a wireless network. The methods include determining that one or more reduced capability devices are using a network slice. The methods further include determining that the spectral efficiency of the network slice has dropped below a spectral efficiency threshold. The methods further include reducing a radio resource partitioning ratio of the one or more reduced capability devices to non-reduced capability devices.

Aspects of the subject disclosure may include, for example, adjusting bandwidth allocated for a first group of communication devices communicatively coupled to a first communication network from a bandwidth limited allocation to a no bandwidth limited allocation, and measuring a first group of metrics associated with the first group of communication devices associated with the first communication network. Further embodiments include computing a second group of metrics associated with a second group of communication devices communicatively coupled to a second communication network according to the first group of metrics, the second group of communication devices have the no bandwidth limited allocation, and allocating a first group of network resources for the second group of communication devices according to the second group of metrics. Other embodiments are disclosed.

Solutions are disclosed that perform network load balancing based on device type and/or history. Current fair criteria, such as round-robin selection, that select user equipment (UEs) for off-loading to lower-bandwidth frequency layers do not take into account bandwidth usage history and device type, even though human users using enhanced Mobile Broadband (eMBB) devices are typically more delay-sensitive than fixed wireless access (FWA) UEs, even while an FWA may consume as much network bandwidth as 10 eMBBs. Example solutions determine UE device type and/or bandwidth usage history, and prioritize certain UEs (e.g., eMBB) for higher-bandwidth frequency layers than other UE types (e.g., FWA) and/or UEs that have a history of heavy bandwidth use. This enhances the user experience for a larger number of delay-sensitive users.

Systems, methods, and computer software are disclosed for providing an Open Radio Access Network (RAN) networking infrastructure. In one embodiment a method is disclosed, comprising: providing real-time OpenRAN controller responsible for radio connection management, mobility management, QoS management, edge services, and interference management for the quality of end user experience; and providing a non-real-time controller in communication with the real-time OpenRAN controller, the non-real-time controller providing functionality such as configuration management, device management, fault management, performance management, and lifecycle management for all network elements in a network.

According to various embodiments of the present disclosure, an electronic device may include: a communication circuit and a processor operatively connected to the communication circuit, wherein the processor may be configured to: receive capability information including a maximum bandwidth of an external electronic device, determine a recommended bandwidth based on a comparison result of a first data rate according to interference in the maximum bandwidth of the external electronic device and a second data rate according to interference in at least one reference bandwidth, and perform a wireless communication connection with the external electronic device using the recommended bandwidth.

A system and method for managing handoff in software-defined wide area network (SD-WAN) in aero or mobility situations, where terminal is capable of switching across multiple high throughput satellite (HTS), low-latency wireless spot beams and cell. The system receives at least one packet for upstream/downstream transmission over communication network. The system classifies packets based on data types associated with packets and assigns wireless path associated with first network transport modem for upstream/downstream transmission of packets classified as interactive traffic data type. Furthermore, system assigns satellite path associated with second network transport modem for upstream/downstream transmission of packets classified as bulk traffic data type. Further, system estimates available capacity for upstream/downstream transmission of packets associated with first and/or second network transport modem. Furthermore, system adjusts rate limited priority queue for continuity of TCP connection corresponding to packets, responsive to change in network conditions of communication network during the upstream/downstream transmission.

A method for orchestrating use of a communications network for conveying a plurality of data streams transmitted by a plurality of applications includes attributing levels of importance to individual or groups of data streams, determining based at least in part on the levels of importance and on network capacity requirements of the data streams an ordered list of data streams to be curtailed or stopped in case of a shortage of bandwidth in the communications network, providing the list to a management entity that monitors available bandwidth, compares available bandwidth to a combined bandwidth requirement and, in response to determining that the available bandwidth is, or is imminent to become, less than the combined bandwidth requirement, curtails or stops data streams in the order given by the list so as to bring the combined bandwidth requirement back to or below the available bandwidth.

A computer-implemented method includes obtaining, by a centralised controller, network topology information, wherein the network topology information comprises information on network paths between a core network, one or more scheduler devices and a plurality of radio devices, wherein the one or more scheduler devices are operable to schedule operation of the plurality of radio devices based on a scheduling capacity for each of the plurality of radio devices, and wherein two or more of the plurality of radio devices share at least part of the same network path to the core network; and generating, by the centralised controller and based on the network topology information, a cluster scheduling plan comprising an updated scheduling capacity for each of the plurality of radio devices, sending, by the centralised controller and to the one or more scheduler devices, the updated scheduling capacity for each of the plurality of radio devices.

Disclosed are a method (1) of and a management entity (23) for optimizing a radio performance of a wireless network (2). The wireless network (2) comprises a plurality (C) of communication channels and a plurality (N) of configurable radio access entities (21). The method (1) comprises determining (11), by a respective configurable radio access entity (21, i) of the plurality of configurable radio access entities (21), a respective set of receivable radio access entities (21, 22, j) in a particular communication channel of the plurality of communication channels. The method (1) further comprises collecting (12), by a management entity (23), the respective set of the receivable radio access entities (21, 22, j) determined by the respective configurable radio access entity (21, i) of the plurality of configurable radio access entities (21, i). The method (1) further comprises optimizing (13), by the management entity (23), the radio performance of the wireless network (2) in accordance with the respective set of the receivable radio access entities (21, 22, j) collected from the plurality of configurable radio access entities (21, i). The resulting channel allocation is quickly obtainable, straightforward to understand, and therefore enables users with even a little radio communications background to quickly and safely carry out a professional frequency optimization.

Adapting transmission schedules in a Radio Frequency (RF) environment may be provided. A Central Network Controller (CNC) of a Time Sensitive Network (TSN) may determine that a data path to a client device comprises a wireless link. The CNC of the TSN may generate a proposed transmission schedule for the time sensitive traffic to the client device through the wireless link in response to determining that the data path to the client device comprises the wireless link. The CNC may provide the proposed transmission schedule to a Wireless Network Controller (WLC) of the wireless link. The CNC may receive a confirmation from the WLC that the proposed transmission schedule can be met. The proposed transmission schedule may be configured in response to receiving the confirmation.