In certain embodiments, initiation of a location-triggered communication with a user may be facilitated. Communication may be initiated with a user (e.g., on a mobile device) based on an occurrence of a location trigger corresponding to a destination location at which the communication is to be initiated. The occurrence of the location trigger indicates the user is likely on the way to the destination location. The occurrence may be predicted based on mobile device location-independent user location information obtained from a data stream of a real-time application. For example, an event location and an event time of an event associated with the user may be extracted from the data stream and used to predict the occurrence.

A network environment includes a first station, a second station, and a communication manager. The communication manager monitors a backhaul between the first station and the second station. In one arrangement, the first station is a wireless access point providing wireless connectivity to multiple mobile communication devices. During operation, the backhaul conveys communications between the first station and the second station. Based on the monitoring, the communication manager produces a metric indicating an ability of the backhaul to convey communications. Based on the metric, the communication manager determines a split of multiple processing layers in a wireless protocol stack. To accommodate the split, the communication manager assigns a first portion of multiple network communication layers to the first station for processing and a second portion of the multiple network communication layers to the second station for processing.

A network environment includes a first station, a second station, and a communication manager. The communication manager monitors a backhaul between the first station and the second station. In one arrangement, the first station is a wireless access point providing wireless connectivity to multiple mobile communication devices. During operation, the backhaul conveys communications between the first station and the second station. Based on the monitoring, the communication manager produces a metric indicating an ability of the backhaul to convey communications. Based on the metric, the communication manager determines a split of multiple processing layers in a wireless protocol stack. To accommodate the split, the communication manager assigns a first portion of multiple network communication layers to the first station for processing and a second portion of the multiple network communication layers to the second station for processing.

Embodiments include methods for beam-level mobility load balancing, MLB, in a radio access network, RAN. Optionally, such methods include receiving (1810) measurement reports from a plurality of user equipment, each measurement report comprising radio measurements related to a source beam associated with a source node and target beams associated with one or more target nodes. Such methods include exchanging (1820) beam-level load information with the target nodes and, based on the beam-level load information and (optionally) the reports, selecting (1830) one or more target beams, associated with a particular target node, for MLB operations with the source beam. Such methods include transmitting (1840), to the particular target node, a request including one or more handover offsets to be applied during MLB operations between a group of source beams associated with the source node, including the source beam, and a group of target beams associated with the particular target node, including the selected target beams.

The each AP includes a control unit that detects, as the wireless environment information, a signal detection level for one or more neighboring APs positioned in the neighborhood of the AP and notifies the detected signal detection level to the central coordinator, and controls the ATT value by the setting in the central coordinator; and the central coordinator includes a parameter calculation unit that calculates the ATT value for each the APs, based on the signal detection level for each the neighboring wireless access point notified from the plurality of APs and based on an RSSI threshold at which each the APs is able to secure a prescribed service area.

The present invention relates to a method and an apparatus for applying wireless resources in order to control inter-cell interference in a heterogeneous network system. The method for applying wireless resources provided by the present invention generates an almost blank subframe (ABS) pattern on the basis of the type of data transmitted from at least one of a first base station and a second base station, applies a non-ABS or an ABS to wireless resources of the first base station according to the generated ABS pattern, and performs data communication by using the wireless resources to which the ABS has been applied.

The present invention relates to a method and an apparatus for applying wireless resources in order to control inter-cell interference in a heterogeneous network system. The method for applying wireless resources provided by the present invention generates an almost blank subframe (ABS) pattern on the basis of the type of data transmitted from at least one of a first base station and a second base station, applies a non-ABS or an ABS to wireless resources of the first base station according to the generated ABS pattern, and performs data communication by using the wireless resources to which the ABS has been applied.

A communication system is disclosed. The communication system includes a plurality of cloud radio access networks (C-RANs), each C-RAN comprising a baseband controller and a plurality of radio points (RPs). Each RP in the plurality of C-RANs is located at a site and is configured to exchange radio frequency (RF) signals with a plurality of wireless devices at the site. The communication system also includes a dynamic sectorization system communicatively coupled to each baseband controller. The dynamic sectorization system is configured to determine at least one signature vector for each of the wireless devices at the site. The dynamic sectorization system also is configured to map each RP in the plurality of C-RANs to one of a number of sectors (K) based on the at least one signature vector for each of the wireless devices at the site.

Systems and methods are provided for adaptive bandwidth (BW) management configuring an element management control unit including a set of distribution/central units (DU/CU) for monitoring power and traffic loads at a plurality of cell sites in a network; communicating with a BW management unit coupled to the element management system to adapt BW for users at cell sites by moving users to a set of smaller bandwidth parts (BWPs) at a cell site in response to a set of conditions of AC power outages and reduced traffic loads detected by the BW management unit, and in response to at least one of the detected conditions, instructing based on data from the DU/CU to the BW management unit to move user traffic to a designated lower BWP of the set of smaller BWPs at the cell site while shutting down other BWPs at the cell site to save the power of an operating cell site.

Systems and methods are provided for adaptive bandwidth (BW) management configuring an element management control unit including a set of distribution/central units (DU/CU) for monitoring power and traffic loads at a plurality of cell sites in a network; communicating with a BW management unit coupled to the element management system to adapt BW for users at cell sites by moving users to a set of smaller bandwidth parts (BWPs) at a cell site in response to a set of conditions of AC power outages and reduced traffic loads detected by the BW management unit, and in response to at least one of the detected conditions, instructing based on data from the DU/CU to the BW management unit to move user traffic to a designated lower BWP of the set of smaller BWPs at the cell site while shutting down other BWPs at the cell site to save the power of an operating cell site.