Systems and method for cell site inspection by a cell site operator using an Unmanned Aerial Vehicle (UAV) and a processing device include creating an initial computer model of a cell site and surrounding geography at a first point in time, wherein the initial computer model represents a known good state of the cell site and the surrounding geography; providing the initial computer model to one or more of the UAV and the processing device; capturing current data of the cell site and the surrounding geography at a second point in time using the UAV; comparing the current data to the initial computer model by the processing device; and identifying variances between the current data and the initial computer model, wherein the variances comprise differences at the cell site and the surrounding geography between the first point in time and the second point in time.

The remote unit for the distribution of radio-frequency signals comprises: a plurality of electronic devices or modules operatively connected to each other for the processing of a radio-frequency signal to distribute within a coverage area, characterized in that it comprises: a first section having at least one of the electronic devices or modules; a second section having at least one of the electronic devices or modules; a connection element having a first portion associated integral with the first section and a second portion, substantially opposite to the first portion and associated integral with the second section; wherein the first section and the second section are arranged substantially aligned to each other along a longitudinal axis.

The remote unit for the distribution of radio-frequency signals comprises: a plurality of electronic devices or modules operatively connected to each other for the processing of a radio-frequency signal to distribute within a coverage area, characterized in that it comprises: a first section having at least one of the electronic devices or modules; a second section having at least one of the electronic devices or modules; a connection element having a first portion associated integral with the first section and a second portion, substantially opposite to the first portion and associated integral with the second section; wherein the first section and the second section are arranged substantially aligned to each other along a longitudinal axis.

Method and a network node (110, 910) for enabling position determination of a measurement performed by a user equipment (120) served by a base station (110). The user equipment (120) and the base station (110) are comprised in a cellular communications network (100). A measurement report comprising measurement data associated with the measurement and a time of measurement thereof is received (301, 801) from the user equipment (120). One or more first type of data associated with the user equipment (120) at a respective point in time are retrieved (302, 802), which first type of data is localization corresponding data. Based on the time of measurement, first type of data that corresponds to the time of measurement is determined (303, 803) from the retrieved one or more first type of data. The determined first type of data is associated (304, 804) with the measurement data. The position of the measurement may then be determined based on the first localization corresponding data associated with the measurement data.

The invention relates to a method for the navigation of a vehicle (1) in a road network on which an edge node network (100) is provided which comprises a plurality of stationary edge nodes (101) and a plurality of mobile edge nodes (102), the vehicle (1) being designed to transfer computing power to at least one of the stationary edge nodes (101) and/or mobile edge nodes (102) of said edge node network (100), involving the following steps: 1) suggesting at least one route (R) on said road network to a user of the vehicle (1), and 2) associating the at least one route (R) and at least one item of current or prognostic information (I) relating to the stationary edge nodes (101) and the mobile edge nodes (102) of the edge node network (100) along said at least one route (R).

The invention relates to a method for the navigation of a vehicle (1) in a road network on which an edge node network (100) is provided which comprises a plurality of stationary edge nodes (101) and a plurality of mobile edge nodes (102), the vehicle (1) being designed to transfer computing power to at least one of the stationary edge nodes (101) and/or mobile edge nodes (102) of said edge node network (100), involving the following steps: 1) suggesting at least one route (R) on said road network to a user of the vehicle (1), and 2) associating the at least one route (R) and at least one item of current or prognostic information (I) relating to the stationary edge nodes (101) and the mobile edge nodes (102) of the edge node network (100) along said at least one route (R).

Point cloud data between a base station device and a terminal station device is acquired as a point cloud data group. A radius of a first Fresnel zone defined by the base station device and the terminal station device at each position where the point cloud data group is acquired is calculated. A region specified by the radius at each position where the point cloud data group is acquired is scanned to detect the point cloud data, and a non-line-of-sight region is extracted. A ratio of a total area of all the extracted non-line-of-sight regions to an area of a region constructed by the first Fresnel zone is calculated. A received power is estimated based on the calculated ratio between the areas. Whether or not there is a line of sight between the base station device and the terminal station device is determined based on the received power.

Point cloud data between a base station device and a terminal station device is acquired as a point cloud data group. A radius of a first Fresnel zone defined by the base station device and the terminal station device at each position where the point cloud data group is acquired is calculated. A region specified by the radius at each position where the point cloud data group is acquired is scanned to detect the point cloud data, and a non-line-of-sight region is extracted. A ratio of a total area of all the extracted non-line-of-sight regions to an area of a region constructed by the first Fresnel zone is calculated. A received power is estimated based on the calculated ratio between the areas. Whether or not there is a line of sight between the base station device and the terminal station device is determined based on the received power.

There is provided a method for shaping cells in a wireless communications network. The method is performed by a network node. The method comprises acquiring previously stored spatial channel characteristics for wireless devices (WDs), the WDs being associated with a set of radio access network nodes (RANNs), the of the WDs being measured between the at least one WD and at least two RANNs in the set of RANNs. The method comprises determining beam forming parameters for shaping cells for at least one RANN in the set of RANNs based on the acquired spatial channel characteristics such that at least a predetermined share of the WDs has a network coverage probability being higher than a predetermined threshold value. The method comprises notifying at least one of the RANNs in the set of RANNs of the determined beam forming parameters.

There is provided a method for shaping cells in a wireless communications network. The method is performed by a network node. The method comprises acquiring previously stored spatial channel characteristics for wireless devices (WDs), the WDs being associated with a set of radio access network nodes (RANNs), the of the WDs being measured between the at least one WD and at least two RANNs in the set of RANNs. The method comprises determining beam forming parameters for shaping cells for at least one RANN in the set of RANNs based on the acquired spatial channel characteristics such that at least a predetermined share of the WDs has a network coverage probability being higher than a predetermined threshold value. The method comprises notifying at least one of the RANNs in the set of RANNs of the determined beam forming parameters.