Methods, systems, and computer program products for determining transit routes through crowd-sourcing, for determining an estimated time of arrival (ETA) of a vehicle of the transit route at a given location, and for providing predictive reminders to a user for catching a vehicle of the transit route. A server receives signal source information about wireless signal sources detected by user devices, including information about a first wireless signal source detected by some devices. The server determines that the first wireless signal source is moving. The server determines that the first wireless signal source is associated with a public transit route upon determining that the signal source information satisfies one or more selection criteria. The server stores information associating the first wireless signal source with the public transit route as transit movement data corresponding to the public transit route.

A method and device for accessing and obtaining user equipment (UE) context and UE identity are provided. The method for access includes: when a UE accesses a System Architecture Evolution (SAE) network, judging, by a network node, whether a Globally Unique Mobility Management Entity Identifier (GUMMEI) carried by the UE or a Mobility Management Entity Group Identity (MMEGI) in the GUMMEI is allocated or mapped by the SAE network; if the GUMMEI or MMEGI is allocated by the SAE network, selecting, by the network node, a Mobility Management Entity (MME) according to the GUMMEIA network device includes an identity attribute obtaining module and a network resource node allocation module. Therefore, the access of the UE is achieved.

A telecommunications system for communicating internet packet data in accordance with a first internet protocol (IPV6) via a packet radio network operable in accordance a second internet protocol (IPV4) includes a user equipment operable to request a bearer for communicating internet protocol data according to the second internet protocol (IPV4) to and from a gateway support node of the packet radio network. The gateway support node is operable to establish a tunnelling protocol bearer for communicating the internet packet data to and from the user equipment across the packet radio network. The user equipment is operable in combination with the gateway support node to form an address which is compatible with the first internet protocol (IPv6). The address includes an interface identifier having a tunnel end identifier of the tunnelling protocol bearer which ends at the gateway support node of the packet radio network. The internet packet data is communicated to and from a correspondent node via the gateway support node and the established bearer using internet protocol address which is compatible with the first internet protocol (Ipv6).

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.

A method of determining suitable communication paths between a first device and a second device, the first device being connected to a plurality of third devices to which the second device is also connected. The method comprises, at the first device: for each of the third devices, obtaining first information indicating a characteristic of communications between the first device and the second device via the third device, obtaining second information associated with first data to be transmitted from the first device to the second device, and determining, based upon the first and second information, whether any of the third devices should receive the first data for communication of the first data to the second device.

Techniques for employing a Mains Powered Device as a proxy for communicating on behalf of a Battery Powered Device are described herein. In some examples, the Mains Powered Device may be a parent node to the Battery Powered Device in a network which operates using a Routing Protocol for Low-Power and Lossy Networks (RPL). The Mains Powered Device may detect and/or forward a Destination Advertisement Object (DAO) transmitted from the Battery Powered Device to a DODAG root of the network, and begin to perform subsequent transmission of DAOs on behalf of the Battery Powered Device. In this way, the Mains Powered Device updates a routing table of the DODAG root periodically to include an indication of the Battery Powered Device as existing in the network, while extending the battery life of the Battery Powered Device by transmitting DAOs on behalf of the Battery Powered Device.

Aspects of the technology described herein identify a trusted group of devices that collaborate to minimize device limitations (e.g., data use, bandwidth, battery life, and the like). Personal assistant services or cloud-based services utilize user data (e.g., web browsing, calendar entries, communication data, social networks, and the like) and device data (e.g., location data, Bluetooth beacons, Wi-Fi, and the like) provided by user devices to identify devices in the trusted group of devices. A handshake between the devices establishes a means of communication and a selected topology. A hub device is selected from the trusted group of devices to upload or download relevant data based on the selected topology. The hub device shares the relevant data with the member devices via the established means of communication.

Embodiments of the present disclosure describe apparatuses and methods for mobility management entity (MME) overload or underload mitigation using an MME virtual network function (VNF). Various embodiments may include one or more processors to execute instructions to process a notification from a virtual network function manager (VNFM) to determine instantiation of a MME as a VNF, add the MME to an MME pool, and assign a value to an application parameter of the MME VNF. Other embodiments may be described and/or claimed.

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.

Techniques for modeling significant locations are described. A significant location can be a location that is significant to a user of a mobile device for a variety of reasons. The mobile device can determine that a place or region is a significant location upon determining that, with sufficient certainty, the mobile device has stayed at the place or region for a sufficient amount of time. The mobile device can construct a state model that is an abstraction of one or more significant locations. The state model can include states representing the significant locations, and transitions representing movement of the mobile device between the locations. The mobile device can use the state model to provide predictive user assistance.