Embodiments of the present invention disclose a method and an apparatus for adjusting air interface capacity density, where the method includes: determining whether a target physical cell whose air interface capacity density needs to be adjusted exists in a logical cell, where the logical cell includes one or more physical cells, each physical cell includes a group of pico radio remote units pRRUs, and one physical cell corresponds to one baseband tributary; and when a determining result is that a target physical cell whose air interface capacity density needs to be adjusted exists in the logical cell, adjusting the air interface capacity density of the target physical cell. Therefore, by implementing the embodiments of the present invention, air interface capacity density of a physical cell in a logical cell can be dynamically adjusted according to an actual situation of the physical cell.

Embodiments of the present invention disclose a method and an apparatus for adjusting air interface capacity density, where the method includes: determining whether a target physical cell whose air interface capacity density needs to be adjusted exists in a logical cell, where the logical cell includes one or more physical cells, each physical cell includes a group of pico radio remote units pRRUs, and one physical cell corresponds to one baseband tributary; and when a determining result is that a target physical cell whose air interface capacity density needs to be adjusted exists in the logical cell, adjusting the air interface capacity density of the target physical cell. Therefore, by implementing the embodiments of the present invention, air interface capacity density of a physical cell in a logical cell can be dynamically adjusted according to an actual situation of the physical cell.

Some embodiments provide a method for performing cell reconfiguration in a network node, which is associated with at least two antennas. Each antenna is capable of transmitting a signal covering at least one sector. The method comprises switching (1212) from a first state (1210) wherein a multi-sector cell covering at least two sectors is active, to a second state (1220), wherein sector cells covering each of the at least two sectors are active in addition to the multi-sector cell. In the second state, the same antennas are utilized for the sector cells as for the multi-sector cell. The method further comprises switching (1222) from the second state to a third state (1230) wherein the multi-sector cell is deactivated and the sector cells are active.

Some embodiments provide a method for performing cell reconfiguration in a network node, which is associated with at least two antennas. Each antenna is capable of transmitting a signal covering at least one sector. The method comprises switching (1212) from a first state (1210) wherein a multi-sector cell covering at least two sectors is active, to a second state (1220), wherein sector cells covering each of the at least two sectors are active in addition to the multi-sector cell. In the second state, the same antennas are utilized for the sector cells as for the multi-sector cell. The method further comprises switching (1222) from the second state to a third state (1230) wherein the multi-sector cell is deactivated and the sector cells are active.

In one embodiment, a process obtains a first compensated directional reading from a first directional sensor of a directionally sensitive system, and obtains a second compensated directional reading from a second directional sensor of the directionally sensitive system. The process may then determine, a difference between the first compensated directional reading and the second compensated directional reading, and declares, in response to the difference being greater than an acceptable threshold, an inaccurate directional reading. As such, the process may then prevent performance of a directionally sensitive action by the directionally sensitive system in response to an inaccurate directional reading.

A process receives performance parameter measurements associated with multiple cell sectors of a group of multiple Remote Radio Units (RRUs) and determines a first set of cell sectors of the multiple cell sectors to include in a first cell sector cluster based on the measured performance parameters. The process configures connections, between the first set of cell sectors included in the first cell sector cluster and a first Baseband Unit (BBU) of multiple BBUs of a Centralized Radio Access Network (CRAN) hub, such that the first BBU processes traffic to and from the first set of cell sectors included in the first cell sector cluster.

A process receives performance parameter measurements associated with multiple cell sectors of a group of multiple Remote Radio Units (RRUs) and determines a first set of cell sectors of the multiple cell sectors to include in a first cell sector cluster based on the measured performance parameters. The process configures connections, between the first set of cell sectors included in the first cell sector cluster and a first Baseband Unit (BBU) of multiple BBUs of a Centralized Radio Access Network (CRAN) hub, such that the first BBU processes traffic to and from the first set of cell sectors included in the first cell sector cluster.

The disclosure refers to a method in a network entity for establishing network cells in a wireless communication system, wherein the network entity provides wireless network coverage to a plurality of network cells. The method comprising the method steps of: identifying a need of establishing network cells, accessing a network cell establishment list, wherein the network cell establishment list defines a number of network cells and an order in which respective network cell is to be established, and establishing network cells in accordance with the order provided by the network cell establishment list. The disclosure also refers to a network entity configured to perform such method.

The disclosure refers to a method in a network entity for establishing network cells in a wireless communication system, wherein the network entity provides wireless network coverage to a plurality of network cells. The method comprising the method steps of: identifying a need of establishing network cells, accessing a network cell establishment list, wherein the network cell establishment list defines a number of network cells and an order in which respective network cell is to be established, and establishing network cells in accordance with the order provided by the network cell establishment list. The disclosure also refers to a network entity configured to perform such method.

An unmanned aerial vehicle (UAV) calculates an estimated uplink interference caused by the UAV at a neighboring cell based on a downlink signal received from the neighboring cell. Based on the estimated uplink interference, the UAV monitors downlink messages transmitted from the neighboring cell. If the uplink interference experienced by the neighboring cell exceeds an interference threshold, the neighboring cell transmits a downlink message, which includes an uplink interference indicator, to the UAV. Upon receipt of the uplink interference indicator, the UAV transmits a measurement report, including the uplink interference indicator, to the serving cell. In some cases, the serving cell transmits a handover command to the UAV based at least partially on the measurement report. The serving cell may also maintain a mobility history for the neighboring cell. The mobility history indicates a history of uplink interference problems and/or UAV handover availability for the neighboring cell.