A method and apparatus of routing a call in a femtocell network are disclosed. In one example call routing method, a call is originated from the mobile station via a femtocell access point and the call is transmitted to a femtocell gateway, a mobile switching center and a carrier gateway server and onto an enterprise gateway server to obtain policy information. A routing policy is determined based on the obtained policy information and the call is routed to its destination based on the routing policy. The call may be routed via local media from a femtocell access point directly to the enterprise gateway server. The call routing procedures may implement the Iuh protocol and/or the session initiation protocol (SIP) for call signaling in the femtocell network. Call routing may be performed in a wireless cellular communications network or an enterprise network environment.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may connect to a set of source cell groups (CGs). The UE may receive a target cell group setup information, the target cell group setup information being associated with a set of target CGs. The UE may connect to the set of target CGs based at least in part on the target cell group setup information during a handover from the set of source CGs to the set of target CGs. The UE may disconnect from the set of source CGs after connecting to the set of target CGs. Numerous other aspects are provided.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may receive an indication of one or more SNPN roaming groups associated with a network to which the UE is subscribed. The UE may determine that a transmission from an SNPN identifies a roaming group identifier associated with an SNPN roaming group of the one or more SNPN roaming groups. The UE may register with the SNPN based at least in part on determining that the transmission identifies the roaming group identifier. Numerous other aspects are provided.

Disclosed here is a system and method to determine which wireless telecommunication network functionalities are impaired when using end-to-end encryption and to ameliorate the impairment of the functionality. The system receives a request from a sender device to communicate with a receiver device, where the request indicates whether the sender device is capable of an end-to-end encryption. The system determines whether the receiver device is capable of the end-to-end encryption, and whether the receiver device is associated with a functionality provided by a wireless telecommunication network that is impaired when the end-to-end encryption is used. Upon determining that the receiver device is not capable of the end-to-end encryption or that the receiver device is associated with the functionality that is impaired, the system performs an action to ameliorate the impairment to the functionality.

Disclosed herein are systems and methods related to reducing or making more efficient handovers from one cell to another cell in a communications network. The method includes receiving mobility data for a device being serviced by a first cell, classifying the device based on the mobility data to yield a classification and making a handoff decision when handing off the device from the first cell to a second cell based at least in part on the classification. An example of the mobility data is a speed at which the device is moving or time a device is in a cell.

The present disclosure provides a method of sending an inter-base station message between a first and second base station in a cellular telecommunications network, wherein the inter-base station message is transmitted via a relay component, the method including the relay component receiving a first inter-base station message from a first base station, wherein the first inter-base station message includes: a first address portion identifying a second and third base station, and a first content portion; the relay component transmitting a second inter-base station message to the second base station, the second inter-base station message including: a second address portion identifying the second base station, and a second content portion; and the relay component transmitting a third inter-base station message to the third base station, the third inter-base station message including: a third address portion identifying the third base station, and a third content portion, wherein the second and third content portions include the first content portion.

A method for reactivating a wireless communication network in accordance with one of the IEEE 802.11 standards is described. The communication network includes a plurality of gathering nodes, each gathering node includes at least one access-point and/or user radio-frequency interface and/or a user of a so-called backhaul wireless network associated with the communication network, which are deactivated in sending mode, A beacon frame sent by a master node of the reactivation method is propagated gradually in order to reactivate all the nodes in the network.

A respective preferred installation height above ground level is determined for each of a plurality of locations for a subscriber module for receiving a radio link from an access point in a wireless network, the access point having a given height above ground level and a specified location, and the subscriber module being situated within a given geographical area including the location of the access point. The method comprises accessing elevation data for the given geographical area, processing the elevation data to generate a preferred height data file representing a preferred height for a subscriber module to be wirelessly visible by the access point at each of the plurality of locations and processing the required height data file to provide output data indicating the preferred height of the subscriber module as a function of location.

A device within a small cell may establish a first secure communication channel between the device and a network device based on a first type of encryption. The device within the small cell may transmit data between the small cell and a core network via the first secure communication channel. The device within the small cell may receive information associated with a second type of encryption, wherein the second type of encryption is different from the first type of encryption. The device within the small cell may terminate the first secure communication channel. The device within the small cell may establish a second secure communication channel between the device and the network device based on the information associated with the second type of encryption. The device within the small cell may transmit further data between the small cell and the core network via the second secure communication channel.

Spectrum and radio resources associated with a 5G radio unit (RU) of a host network are dynamically allocated amongst one or more guest networks. A provisioning plane receives inputs from a guest network operator that identifies desired times, locations and/or frequency bands for desired network coverage. The provisioning plane responsively identifies bandwidth allocations that meet the requested parameters for exclusive use by the guest network. User equipment (UE) associated with each guest network maintains time and frequency synchronization with the host network, but otherwise limits its communications to the frequency bands allocated to the guest network. By dynamically obtaining physical radio and spectrum resources from a host provider and by scaling backend network capabilities using cloud resources, guest networks for any number of different purposes can be quickly deployed or modified as desired.