An example method is provided in one example embodiment and may include determining that a user equipment (UE) is approximately stationary for a threshold period of time within a particular geographic area based, at least in part, on a radio access network (RAN) node to which the UE is attached; notifying the UE that the UE has been associated with the particular geographic area; and transitioning the UE into an idle mode from an active mode, wherein the transitioning is performed without notifying a core network that the UE has transitioned to the idle mode. Determining that the UE is approximately stationary can include monitoring mobility signaling from the UE and comparing an amount of time that the UE has been attached to the RAN node with a threshold period of time. The core network can be notified when the UE moves out of the particular geographic area.

Embodiments of this application provide a discontinuous reception DRX management method, including determining, by a base station, that a terminal has a voice service, and setting up, by the base station, a voice bearer for the terminal, and activating a DRX function of the terminal when setting up the voice bearer for the terminal. It can be learned that, in the method, the terminal does not activate the DRX function before setting up the voice bearer, and does not activate the DRX function until the voice bearer is set up, to effectively reduce a voice paging connection delay.

Wireless communication equipment includes a communication interface, a memory, and a processor electrically connected with the communication interface and the memory. The processor is configured to activate communication of the wireless communication equipment, to scan an external device for a network connection at a periphery of the wireless communication equipment, using the communication interface, to receive information including a mesh ID sent from the external device, using the communication interface, and to configure a mesh network with the external device by using the communication interface, when a designated string stored in the memory is included in the mesh ID.

A method and apparatus operate a device on a licensed spectrum and an unlicensed spectrum. The device can operate on a Wireless Wide Area Network (WWAN) channel using a WWAN base station using a WWAN Radio Access Technology (RAT). At least one Wireless Local Area Network (WLAN) base station that uses the WWAN RAT operating on a WLAN frequency can be detected. WLAN frequencies can be scanned. Information including information about the at least one WLAN base station using the WWAN RAT, the results of scanning the WLAN frequencies, and device specific information to a base station can be sent. A WLAN channel of the WLAN frequencies with a WLAN base station of the at least one WLAN base station using the WWAN RAT can be communicated on in response to sending the information.

An object of the present invention is to provide a mobile communication system, a detection server, a control apparatus, a mobile communication apparatus, a network optimizing method, and a program which can execute optimization of network processing based on a change of use characteristics. A mobile communication system according to the present invention includes: a detection server that detects a characteristics change of a mobile communication apparatus based on an event notice transmitted from the mobile communication apparatus; and a control apparatus that determines control contents related to the mobile communication apparatus based on the characteristics change of the mobile communication apparatus detected by the detection server, and sets the determined control contents to a processing node that executes data transfer processing between the mobile communication apparatus and another mobile communication apparatus or control processing related to the data transfer processing.

A system is provided which is capable of connecting a call without degrading the security level in a mobile terminal network, even when a call addressed to a user equipment (UE) arrives via the Internet or a home network. A femto base station receives a packet addressed to a UE via the Internet or a home network, and starts a paging procedure. The UE establishes an RRC connection to the femto base station. The UE transmits, to the femto base station, a paging response addressed to the SGSN. The femto base station performs NAS verification. If the femto base station detects the paging response to a paging request that the femto base station itself has issued, the femto base station changes the service type of the service request received from the UE from the paging response to signaling.

Certain aspects of the present disclosure generally relate to wireless communications and, more particularly, to techniques that may help optimize scheduling target wake-up times (TWTs) of wireless nodes.

A device, configured as a coordinator for a wireless IoT network, may include a memory configured to store instructions and a processor configured to execute the instructions to identify Internet of Things (IoT) devices associated with the wireless IoT network; determine a clock error rate for the wireless IoT network; determine a last synchronization time; determine a data time period during which one or more of the IoT devices are expected to send data to the device; and set a wakeup time period for the device based on the determined clock error rate, last synchronization time, and data time period. The processor may be further configured to enter a sleep mode; exit the sleep mode when the wakeup time period begins; and perform a clock synchronization between the device and the plurality of IoT devices during the wakeup time period.

A radio access network (RAN) operates by: determining an initial RU/UE association that allocates the plurality of UEs among the plurality of RUs via reference signal received power (RSRP) data received from the plurality of RUs; receiving RU conditions data corresponding to a set of RU conditions associated with the plurality of RUs; receiving RU constraint data associated with the plurality of RUs; assigning, via at least one iterative RU sleeping loop and based on the initial RU/UE association, the RU conditions data and the RU constraint data, an active mode to a first subset of the plurality of RUs and a sleep mode to a second subset of the plurality of RUs; and updating a dynamic RU/UE association based on the first subset of the plurality of RUs and the second subset of the plurality of RUs.

Systems and methods described herein provide improved access to wireless devices in Power Saving Mode (PSM) and extended Discontinuous Reception (eDRX) sleep. A mobility management entity (MME) receives a wake-up time request for a wireless device, wherein the wake-up time request includes a designated wake-up time for the wireless device to receive data services. The MME device stores the designated wake-up time when the designated wake-up time is after a current tracking area update (TAU) window for the wireless device and receives, after the storing, a TAU request for the wireless device. The MME device sends, in response to the TAU request, a TAU response that includes the designated wake-up time.