The disclosure relates to a pre-5.sup.th-Generation (5G) or 5G communication system is provided for supporting higher data rates Beyond 4.sup.th-Generation (4G) communication such as Long Term Evolution (LTE). The disclosure provides a method and apparatus for effectively performing cell reselection in a wireless communication system. The disclosure relates to an operation method for a terminal in a wireless communication system, and the method includes determining to initiate a cell reselection in a radio resource control inactive state (RRC_Inactive state), discovering for a first cell that satisfies a first condition and a second condition, among a plurality of neighboring cells, if the first cell is discovered, camping on the first cell, and if the first cell is not discovered, camping on a second cell that satisfies the first condition and does not satisfy the second condition, among the plurality of neighboring cells, wherein the terminal is in the RRC_Inactive state.

The disclosure relates to a pre-5.sup.th-Generation (5G) or 5G communication system is provided for supporting higher data rates Beyond 4.sup.th-Generation (4G) communication such as Long Term Evolution (LTE). The disclosure provides a method and apparatus for effectively performing cell reselection in a wireless communication system. The disclosure relates to an operation method for a terminal in a wireless communication system, and the method includes determining to initiate a cell reselection in a radio resource control inactive state (RRC_Inactive state), discovering for a first cell that satisfies a first condition and a second condition, among a plurality of neighboring cells, if the first cell is discovered, camping on the first cell, and if the first cell is not discovered, camping on a second cell that satisfies the first condition and does not satisfy the second condition, among the plurality of neighboring cells, wherein the terminal is in the RRC_Inactive state.

Many network devices initially connect to a network using a wireless frequency band that may not provide the best network performance. A wireless management module can determine that a network device, such as a mobile phone, is connected to the wireless network using an inferior wireless frequency band, for example, the 2.4 GHz wireless frequency band, even though a superior wireless frequency band, for example, the 5 GHz wireless frequency band is available or accessible. Based on a device setting, the wireless management module can automatically switch the mobile network device to the higher frequency wireless frequency band without requiring any user intervention. Additionally, or in the alternative, the wireless management module can prompt the user to allow switching to a different wireless frequency band. Switching to the higher frequency band improves network performance for the network device.

Systems and methods for dynamic client segregation in 802.11ax networks includes determining, for each access point of a plurality of access points in a network, a ratio comprising a number of fully uplink multi-user capable client devices to a total number of client devices connected to the access point; and steering, based on at least the ratio, client devices of the network to particular access points of the plurality of access points.

Systems and methods for dynamic client segregation in 802.11ax networks includes determining, for each access point of a plurality of access points in a network, a ratio comprising a number of fully uplink multi-user capable client devices to a total number of client devices connected to the access point; and steering, based on at least the ratio, client devices of the network to particular access points of the plurality of access points.

A system and method of a base station are configured to enable a multi-shot network parameter optimization. The method includes generating one or more specified Key Performance Indicators (KPI) constraints based on a selected set of KPIs. The method also includes adjusting common beam parameters to tune a common beam based on the selected set of KPIs. The common beam is tuned to satisfy the one or more specified KPI constraints. The method also includes adjusting handover A2 and A5 parameters based on searching within a three-dimensional space defined by specified A2 and A5 thresholds. The method further includes transmitting one or more signals based on the adjusted the common beam parameters and the adjusted handover A2 and A5 parameters.

A method can include, by operation of first communication circuits, determining a quality of a plurality of communication frequencies according to wireless communications of a first protocol type; recording a quality of the communication frequencies; selecting communication frequencies for use by second communication circuits based on the quality of the communication frequencies; and wirelessly transmitting and receiving data with the second communication circuits according to a second protocol different than the first protocol; wherein the first and second communication circuits are collocated on the same device. Related devices and systems are also disclosed.

A user equipment according to the present invention performs a handover from a first system to a second system. When a user equipment receives a command to hand over to the second system, while using a plurality of protocol data unit (PDU) sessions for the same data network (DN) in the first system, the user equipment transmits first session information of a first PDU session among the plurality of PDU sessions, establishes a packet data network (PDN) connection with the second system, on the basis of the first session information, and maps the first PDU session to the PDN connection. When the user equipment is required to establish a dedicated bearer for a PDU session (second PDU session) other than the first PDU session among the plurality of PDU sessions, the user equipment transmits a bearer generation request message requesting to generate a dedicated bearer for the PDN connection.

A network slice controller obtains health information of an active network slice provided by a first vendor and health information of a set of backup network slices provided by a second vendor. The network slice controller evaluates, using a set of policies corresponding to management of the active network slice, the health information of the active network slice to determine whether the active network slice has failed. As a result of the failure of the active network slice, the network slice controller identifies one or more backup network slices of the set of backup network slices to serve as new active network slices. The network slice controller activates these one or more backup network slices to serve as the new active network slices for the network.

Disclosed herein is a wireless device including a display, a wireless communication interface configured to wirelessly perform communication with an external device, and a processor configured to activate any one of a first connection mode in which connection with the external device is established through an access point or a second connection mode in which direct connection with the external device is established, based on a network environment and receive, from the external device, image data corresponding to a source image being displayed on the external device according to the activated connection mode and display, on the display, a mirroring image based on the received image data.