The present invention provides a method and system for managing the connections of multiple stations in a Wi-Fi mesh network, using station steering to optimize the overall throughput of the network.

The stations are proactively steered depending on the link quality, the network topology and wireless medium occupation, as well as the different equipment capabilities, to ultimately provide the best available throughput.

This invention also aims to detect crowded Access Points or frequency bands, and steer stations accordingly towards an efficient load control and traffic management between nodes/Access Points and improved quality of experience.

The present publication relates to the wireless signal technologies, and provides methods and systems for wireless signal reinforcement and wireless network load sharing and following. The method for wireless signal reinforcement comprising: a mobile wireless access point moving and measuring the wireless signal strength of other wireless access points received at the location the mobile wireless access point passes through; determining a first location where the wireless signal needs to be reinforced according to the measurement result; and the mobile wireless access point moving to a second location according to the first location, so that the strength of the wireless signal transmitted by the mobile wireless access point from the second location to the first location exceeding the strength of the wireless signal of other wireless access points at the first location. The implementation of the publication can adaptively change the distribution of the environment wireless signals as the environment changes, and realize efficient coverage of wireless signals at low cost.

A network controller may include a memory and a processor. The memory may include instructions executable by the processor to receive a message from an access point. The message may comprise an interference event detected on a particular channel, wherein the particular channel is part of a particular channel list associated with the access point and stored at the network controller in a wireless local area network (WLAN). The memory may further include instructions executable to remove the particular channel from the particular channel list associated with the access point. The memory may further include instructions executable to determine a channel plan for a plurality of access points in the WLAN based on a corresponding plurality of channel lists including the particular channel list and deploy the channel plan to the plurality of access points.

Embodiments of the present disclosure provide an information determination method, apparatus, device, and computer-readable storage medium. The method includes: obtaining a sidelink channel measurement result, and determining a timer length of a target DRX timer according to the sidelink channel measurement result; or receiving indication information from a second terminal and determining the timer length of the target DRX timer according the indication information from the second terminal; the indication information being used to indicate the timer length of the target DRX timer; wherein the first terminal communicates with the second terminal through a sidelink.

The invention proposes solutions for monitoring and controlling the maximum number of the UEs registered in a Network Slice, the maximum number of the established PDU Sessions in a Network Slice and the maximum number of the Uplink and Downlink data rates per UE in a Network Slice. The invention also enforces access and service restriction in a Network Slice when the Network Slice parameters boundaries have been reached.

A system is disclosed for providing Open RAN CU-UP high availability, the system comprising: at least one active CU-CP; at least one active CU-UP in communication with the at least one active CU-CP; and at least one standby CU-UP in communication with the at least one active CU-CP; wherein when a message may be received from a CU-CP that detects a failure of the at least one active CU-UP, the at least one standby CU-UP may be configured to take over and become an active CU-UP, thereby providing failover redundancy for the at least one active CU-UP.

A base station includes a communication unit configured to perform communication with a plurality of terminals through one or more cells, and a control unit configured to perform measurement of the number of active terminals in layer 2 measurement, wherein the control unit measures the number of the active terminals for each cell.

A base station for communication with a plurality of mobile terminals in a mobile communications network is disclosed. The base station includes a plurality of transmitters, in which each transmitter is configured to provide a transmit radio signal to a distinct space when compared to the other transmitters. A first transmitter is configured to provide to a first space, a transmit radio signal carrying a multicast service. A second transmitter is configured to provide to a second space, distinct from the first space, a transmit radio signal carrying a unicast service, and the second space shares a first boundary with the first space.

The present disclosure describes methods and apparatus for supporting QoS and media flow mapping over simultaneous connection for a user equipment (UE), when the simultaneous connections are established over heterogeneous systems having different QoS models, such as 3GPP LTE (4G) QoS model and 3GPP 5G QoS model. The 4G and 5G networks may share the user plane and/or share a policy server. In one aspect, methods for consolidating and distributing the QoS for the NGBR flow and bearer across simultaneous PDN connection over 4G and PDU session over 5G to the same data network (DN) or different DNs are provided. In another aspect, methods are provided for mapping one or more media flows of a multimedia session, such as an IMS session, over simultaneous 4G and 5G connections for a UE are provided, where the 4G connection and the 5G connection for the UE may or may not share the assigned IP address for the UE.

Methods and systems for improving and/or enabling wireless communication and data transfer between electronic devices worn by swimmers and both wireless networks and wireless headphones or other worn devices. The methods and systems disclosed detect when conditions are sufficient for wireless communication depending on the position of a worn electronic device relative to the surface of the water and/or wireless headphones and enables burst data transfer between devices and/or between a device and a wireless network during such times.