A mobile terminal assists in the updating of a neighbor cell list associated with a first cell of a wireless telecommunications network. The list comprises elements that identify other cells that have a neighbor cell relationship with the first cell. The mobile terminal comprises a radio transceiver; and a controller coupled to the radio transceiver.

A mobile terminal assists in the updating of a neighbor cell list associated with a first cell of a wireless telecommunications network. The list comprises elements that identify other cells that have a neighbor cell relationship with the first cell. The mobile terminal comprises a radio transceiver; and a controller coupled to the radio transceiver.

The present disclosure relates to apparatus, systems, and methods for providing a location information analytics mechanism. The location information analytics mechanism is configured to analyze location information to extract contextual information (e.g., profile) about a mobile device or a user of a mobile device, collectively referred to as a target entity. The location information analytics mechanism can include analyzing location data points associated with a target entity to determine features associated with the target entity, and using the features to predict attributes associated with the target entity. The set of predicted attributes can form a profile of the target entity.

In one example, requirement(s) are determined for data flows though different logical instances of mobile networks. The data flows are between UE(s) and the logical instances of the mobile networks. Information for the determined requirement(s) is sent to a multiple node controller to allow the multiple node controller to output information to enable configuration of RRC. The configuration causes the RRC to cause radio subflow(s), which flow through different radio legs and to the UE(s), to satisfy the requirement(s). In another example, mapping is received that maps different logical instances of mobile networks and their associated service flows to radio subflows that flow through different radio legs and to UE(s). The radio subflows, which flow through different radio legs and to the UE(s), are caused to satisfy the requirement(s) for the data flows. Apparatus, methods, programs, and program products are disclosed.

In one example, requirement(s) are determined for data flows though different logical instances of mobile networks. The data flows are between UE(s) and the logical instances of the mobile networks. Information for the determined requirement(s) is sent to a multiple node controller to allow the multiple node controller to output information to enable configuration of RRC. The configuration causes the RRC to cause radio subflow(s), which flow through different radio legs and to the UE(s), to satisfy the requirement(s). In another example, mapping is received that maps different logical instances of mobile networks and their associated service flows to radio subflows that flow through different radio legs and to UE(s). The radio subflows, which flow through different radio legs and to the UE(s), are caused to satisfy the requirement(s) for the data flows. Apparatus, methods, programs, and program products are disclosed.

The disclosed apparatus, systems, and methods relate to a location query mechanism that can efficiently determine whether a target entity is located within a region of interest (ROI). At a high level, the location query mechanism can be configured to represent a ROI using one or more polygons. The location query mechanism can, in turn, divide (e.g., tessellate) the one or more polygons into sub-polygons. Subsequently, the location query mechanism can use the sub-polygons to build an index system that can efficiently determine whether a particular location is within any of the sub-polygons. Therefore, when a computing device queries whether a particular location is within the region of interest, the location query mechanism can use the index system to determine whether the particular location is within any of the sub-polygons.

An example method is performed by a computing device for determining one or more tilt adjustments for cells included in a wireless communication network. The method includes receiving geo-located traffic data that includes a signal strength of a serving cell and a signal strength of a neighbor cell. The computing device then determines a number of occurrences that the neighbor cell has a signal strength greater than the serving cell based on the geo-located traffic data, and if the number of occurrences is greater than a dominance threshold, compares the signal strength of the serving cell with a signal strength threshold. A coverage adjustment is then generated that includes instructions to adjust a tilt angle of an antenna included in one or more of the serving cell or the at least one neighbor cell.

A mobile terminal assists in the updating of a neighbor cell list associated with a first cell of a wireless telecommunications network. The list comprises elements that identify other cells that have a neighbor cell relationship with the first cell. The mobile terminal comprises a radio transceiver; and a controller coupled to the radio transceiver.

A mobile terminal assists in the updating of a neighbor cell list associated with a first cell of a wireless telecommunications network. The list comprises elements that identify other cells that have a neighbor cell relationship with the first cell. The mobile terminal comprises a radio transceiver; and a controller coupled to the radio transceiver.

Method performed by a base station (111). The base station (111) determines (203) a reporting configuration for a UE (130) to report power headroom to the base station (111). The determining (203) is based on a power class of the UE (130). The reporting configuration comprises a plurality of reportable values. Each reportable value corresponds to a respective range of values of a power headroom. The respective range each reportable value corresponds to is a function of a power class of the UE (130). The base station (111) receives (204), from the UE (130), a reportable value from the plurality of reportable values. The respective range of values of the power headroom indicated by the received reportable value is based on the determined reporting configuration. A method performed by the UE (130) is also disclosed. The UE (130) obtains (302) the reporting configuration, and transmits (304), to the base station (111), the reportable value.