A network device receives a location update message from a mobile network switch. The location update message indicates that a mobile device is registered with the mobile network switch. The location update message includes an international mobile subscriber identity (IMSI) associated with the mobile device. The network device determines, based at least on the IMSI, a plurality of MSISDNs associated with the mobile device, including a first MSISDN that is enabled for calling and a second MSISDN that is not enabled for calling. The network device transmits, in response to the location update message, subscriber data to a database associated with the mobile network switch, which associates the IMSI with the first MSISDN.

An inter-vehicle communication system includes: multiple vehicle communication devices for multiple vehicles; and a wireless base station. Each of the multiple vehicle communication devices includes a wide area communication portion that communicates with a different device, a wide area communication control portion that executes a wide area periodic transmission process of multicasting a vehicle information packet towards a different vehicle, a narrow area communication portion, and a narrow area communication control portion that executes a narrow area periodic transmission process of multicasting the vehicle information packet towards the different vehicle. The wide area communication control portion transmits a vehicle status report to the wireless base station. The wide area communication control portion pauses the wide area periodic transmission process. The wireless base station includes an in-cell vehicle management portion that manages position information of a vehicle existing in a charge cell, an encounter determination portion that determines whether a transmission source vehicle has a possibility of encountering the different vehicle, and a device control portion that instructs a transmission source device to pause the wide area periodic transmission process.

The present application is at least directed an apparatus including a non-transitory memory and a processor that is operably coupled to the non-transitory memory for managing a server transition with a service for user equipment (UE). The processor is configured to perform the instructions of receiving, at a core network, a first request from a first server to switch responsibility of the service to a second server to communicate with the UE. The processor is also configured to perform the instructions of determining a first core network terminating point needs updating to a second core network terminating point. The processor is further configured to perform the instructions of selecting the second core network terminating point sends a result of the determination to the user equipment. The processor is still further configured to perform the instructions of sending, to the service, a notification the user equipment is associated with the second core network terminating point. The processor is still yet even further configured to perform the instructions of transmitting, to the UE, a second message notifying the UE characteristics of a session have changed.

An information processing apparatus includes a transmitting unit, a receiving unit, and a converting unit. The transmitting unit transmits advertisement information to an apparatus provided for presenting an advertisement. The receiving unit receives operation information from the apparatus. The converting unit performs conversion after the receiving unit receives the operation information, the conversion leading to reduction of an amount of the advertisement information. The transmitting unit transmits, to the apparatus, the advertisement information having undergone the conversion performed by the converting unit.

Apparatuses, systems, and methods to perform attachment of a wireless device to a next generation gateway via either a base station of a next generation radio access network (RAN) or a mobility management entity of a legacy RAN. An apparatus may be configured to receive an attachment request from a wireless device, determine authentication information via communication with a home subscriber server, determine, based at least in part on the authentication information, whether the wireless device is capable of communicating via the next generation RAT, and send, in response to determining the wireless device is capable, a connection request to a gateway of the next generation RAN. The authentication information may include subscription information associated with the wireless device.

A method for performance adjustment, an apparatus, a terminal, a storage medium, and an electronic device, the method includes: performing statistics on first usage information of a first terminal, to obtain usage preference information corresponding to the first usage information; adjusting the communication performance of the first terminal based on the usage preference information.

In a method for accessing a legacy wireless network, a radio access network (RAN) node in the legacy wireless network receives an access message sent by a User Equipment (UE) attempting to access the legacy wireless network. The access message includes mobility management entity (MME) information identifying an MME accessed by the UE in an evolved network. The MME information is added by the UE from a temporary identity (ID) allocated by the MME to a first P-Temporary Mobile Station Identity (P-TMSI) in the access message. The RAN node selects a corresponding Serving GPRS Support Node (SGSN) in the legacy wireless network for the UE according to the first P-TMSI in the access message.

A location system is disclosed for commercial wireless telecommunication infrastructures. The system is an end-to-end solution having one or more location centers for outputting requested locations of commercially available handsets or mobile stations (MS) based on, e.g., CDMA, AMPS, NAMPS or TDMA communication standards, for processing both local MS location requests and more global MS location requests via, e.g., Internet communication between a distributed network of location centers. The system uses a plurality of MS locating technologies including those based on: (1) two-way TOA and TDOA; (2) pattern recognition; (3) distributed antenna provisioning; (5) GPS signals, (6) angle of arrival, (7) super resolution enhancements, and (8) supplemental information from various types of very low cost non-infrastructure base stations for communicating via a typical commercial wireless base station infrastructure or a public telephone switching network. Accordingly, the traditional MS location difficulties, such as multipath, poor location accuracy and poor coverage are alleviated via such technologies in combination with strategies for: (a) automatically adapting and calibrating system performance according to environmental and geographical changes; (b) automatically capturing location signal data for continual enhancement of a self-maintaining historical data base retaining predictive location signal data; (c) evaluating MS locations according to both heuristics and constraints related to, e.g., terrain, MS velocity and MS path extrapolation from tracking and (d) adjusting likely MS locations adaptively and statistically so that the system becomes progressively more comprehensive and accurate. Further, the system can be modularly configured for use in location signaling environments ranging from urban, dense urban, suburban, rural, mountain to low traffic or isolated roadways. Accordingly, the system is useful for 911 emergency calls, tracking, routing, people and animal location including applications for confinement to and exclusion from certain areas.

The present application is at least directed a system for managing a server transition associated with user equipment. The system includes a non-transitory memory and a processor that is operably coupled to the non-transitory memory. The processor is configured to perform the instructions of receiving a relocation request from a first server to switch to another server. The processor is also configured to verify credentials of the first server. The processor also determines whether a first core networking terminating point associated with the first server is appropriate for the other server to communicate with the user equipment. Further, the processor sends a result of the determination to the user equipment.

A data processing method when the handover or change appears between systems includes: a Mobility Management network element sends a data forwarding tunnel identifier of a target side processing network element to a user plane anchor network element, obtains a data forwarding tunnel identifier of the user plane anchor network element, and sends the data forwarding tunnel identifier of the user plane anchor network element to a source data forwarding network element.