Methods, systems, and devices for wirelessly scanning frequency bands based on device location and/or mobility are presented. The method can include (i) scanning, by a mobile device and according to a first wireless scanning protocol, frequencies within first frequency bands that correspond to a first geographic region and second frequency bands that correspond to a second geographic region; (ii) determining at least one of an estimated location or an estimated mobility characteristic of the mobile device; (iii) determining, based on at least one of the estimated location or the estimated mobility characteristic, to adjust a scheduled time for the mobile device to initiate scanning according to a second wireless scanning protocol; (iv) and initiating at the scheduled time, scanning according to the second wireless scanning protocol.

A control plane (CP) entity is to adaptively reroute user plane traffic of a mobile node (MN) with use of a segment routing (SR) for IPv6. A message indicating an attachment of the MN to the mobile network is received selecting a first user plane (UP) anchor node. A first set of home network prefixes (HNPs) are allocated to the MN. An IP traffic flow using a first HNP prefix is established between the MN and a correspondent node (CN) along a first network pathdefined at least in part by the first UP anchor node and an anchor node of the CN. In response to a handover of the MN, a message indicating a subsequent attachment of the MN is received selecting a second UP anchor node. The second UP anchor node is instructed to host the first HNP prefix previously allocated by the first UP anchor node.

A first terminal device, for use in a wireless telecommunications system, including: a receiver; a transmitter; a storage medium operable to store mapping information identifying sets of predetermined radio resources and a predetermined geographical region associated with each respective set of predetermined radio resources; and a controller operable to: receive a geographical location, the geographical location of the terminal device being determined by a location unit; determine the predetermined geographical region of the received mapping information within which the determined geographical location is located; determine the set of predetermined radio resources associated with the determined geographical region using the received mapping information; control the receiver to receive signals from a second terminal device using the determined set of predetermined radio resources; and control the transmitter to transmit signals to the second terminal device using the determined set of predetermined radio resources.

There are provided measures for satellite coverage change handling. Such measures exemplarily include, at a network entity managing a first cell of a mobile network and a second cell of said mobile network, the first cell covering a geographical area, and the second cell covering said geographical area, maintaining assignment of a first satellite beam corresponding to a first passing satellite to said first cell, a first satellite beam coverage of said first satellite beam overlapping with said geographical area, determining entrance of a second satellite beam coverage of a second satellite beam corresponding to a second passing satellite into said geographical area, assigning said second satellite beam to said second cell, and deciding to trigger handover of a terminal located within said second satellite beam coverage within said geographical area and served by said first cell to said second cell.

Embodiments of the present disclosure relate to conditional handover. A method comprises: determining, at a first device, an ordered list of target cells for a second device to initiate handover to in order based at least in part on location-related data of the second device, the second device being served in a source cell of the first device; transmitting, to the second device, first information indicating the ordered list of target cells and radio configurations associated with each of the target cells; and causing second information indicating the ordered list of target cells to be transmitted to at least one third device serving target cells in the ordered list, to request allocation of resources for the handover by the at least one third device. In this way, a chain of target cells regarding future handover is determined in a predetermined order, which avoid multiple cells prepare for a same handover, thus reducing handover preparation latency and improving the service continuity.

Methods and systems for selecting access networks are disclosed. In one aspect, a method includes receiving, from a first plurality of mobile terminals, a corresponding plurality of motion information for a corresponding plurality of connection points for one or more corresponding wireless access networks, storing the plurality of motion information in a data repository, receiving from a second plurality of mobile terminals non-overlapping with the first plurality of mobile terminals, requests for different subsets of the plurality of motion information, reading the requested motion information from the data repository in response to the requests, and transmitting the requested motion information to the requesting mobile terminals.

There is provided a method for transmitting an uplink message, the method performed by a user equipment (UE). The method may comprise: receiving, by the UE, a request about a visited cell history; transmitting, by the UE, in response to the request, the visited cell history. Here, the cell visited history may include an identifier of a visited cell, and time information corresponding to the visited cell.

A connection management method includes: detecting relevant information about a terminal device; and based on the relevant information about the terminal device, determining whether to adjust the type of a connection path between the terminal device and a first forwarding plane, wherein the type of the connection path between the terminal device and the first forwarding plane at least includes: a first-type path being a connection path directly established, through an access network, between the terminal device and the first forwarding plane, and a second-type path being a connection path established, through the access network via a second forwarding plane, between the terminal device and the first forwarding plane.

Systems and methods relating to a cellular communications system having an architecture in which Serving Gateway (SGW) user plane functionality is separated from SGW control plane functionality are disclosed. In some embodiments, a cellular communications system having an architecture in which SGW user plane functionality is separated from SGW control plane functionality comprises a Serving Gateway Control plane entity (SGW-C) partitioned into a plurality of virtual SGW-Cs that correspond to a respective plurality of SGW User Plane (SGW-UP) service areas. The cellular communications system further comprises a plurality of SGW-UP pools each comprising one or more SGW User entities (SGW-Us), wherein each SGW-UP pool serves a respective one of the plurality of SGW-UP service areas. In this manner, the coordination problem between Tracking Areas (TAs) and the SGW-UP service areas is avoided.

A network controller including processing circuitry may be configured to receive dynamic position information indicative of a three dimensional position of at least one mobile communication node, compare fixed position information indicative of fixed geographic locations of respective access points of a network to the dynamic position information to determine a relative position of the at least one mobile communication node relative to at least one of the access points based on the fixed position information and the dynamic position information, and provide network control instructions to at least one network asset based on the relative position.