Abstract: This disclosure provides a method of operating a transmitting node in a wireless telecommunications network, wherein the transmitting node is configured to transmit data to a first receiving node, the method including determining that a first spatial path count for transmissions between the transmitting node and first receiving node satisfies a first Signal to Interference plus Noise Ratio (SINR) threshold and a first capacity threshold; and causing the transmitting node to use the determined first spatial path count in transmissions to the first receiving node.

Abstract: This disclosure provides a method of configuring a wireless telecommunications network, the wireless telecommunications network including a first wireless transmitter. The method can include obtaining data indicating an amount of data transmitted by the first wireless transmitter in each Modulation and Coding Scheme (MCS) of a plurality of MCS; estimating a received signal strength change for the first wireless transmitter when using a first candidate configuration; estimating a first spectral efficiency for the first candidate configuration based on the amount of data transmitted by the first wireless transmitter in each MCS of the plurality of MCS and the received signal strength change for the first wireless transmitter when using the first candidate configuration; comparing the estimated first spectral efficiency for the first candidate configuration to a reference spectral efficiency; and causing a reconfiguration of the wireless telecommunications network based on the comparison.

Abstract: Examples describe a method of operating a distribution point unit (DPU) having a wireless backhaul connection, such as a 4G or 5G connection. The distribution point unit is reverse powered electrically by connected subscriber lines. The radio configuration (number of antennas, frequencies, etc.) used by the wireless backhaul connection is switched according to the power available from the subscriber lines. Changes to the available power can trigger a switch to a new radio configuration. Higher capacities (data rates) can be achieved with higher power radio configurations, which can be switched over to if the available power is sufficient. Similarly, when the available power drops, a switch can be made to an appropriate lower powered radio configuration.

Abstract: This disclosure provides a method of configuring a wireless telecommunications network, the wireless telecommunications network including a first wireless transmitter. The method can include obtaining data indicating an amount of data transmitted by the first wireless transmitter in each Modulation and Coding Scheme (MCS) of a plurality of MCS; estimating a received signal strength change for the first wireless transmitter when using a first candidate configuration; estimating a first spectral efficiency for the first candidate configuration based on the amount of data transmitted by the first wireless transmitter in each MCS of the plurality of MCS and the received signal strength change for the first wireless transmitter when using the first candidate configuration; comparing the estimated first spectral efficiency for the first candidate configuration to a reference spectral efficiency; and causing a reconfiguration of the wireless telecommunications network based on the comparison.

Abstract: A method of configuring a network slice subnet instance on a radio access node in a wireless telecommunications network. Transceiver data identifying one or more properties of the radio access node is received. The transceiver data is processed to determine capabilities of the radio access node, wherein the capabilities indicate, for a plurality of different counts of network slice subnet instances implementable on the radio access node, a set of operating values for one or more operating parameters. Based on the determined capabilities, a count of network slice subnet instances to implement on the radio access node and the operating values for one or more operating parameters for each network slice subnet instance are selected. One or more network slice subnet instances on the radio access node are configured based on the selection. This application also relates to a computer program and a network node.

Abstract: A method and a controller for controlling a transmitting node in a wireless telecommunications network, the wireless telecommunications network including a receiving node, wherein the transmitting node includes a plurality of antenna ports, the method including determining a count of antenna ports, being one or more of the transmitting node's plurality of antenna ports, to use in communications with the receiving node based on: a balance between a first performance metric related to a coherence interval and having a positive relationship with the count of antenna ports and a second performance metric related to the coherence interval and having a negative relationship with the count of antenna ports, and/or a measure of the coherence interval in communications with the receiving node; and causing the transmitting node to use the count of antenna ports in communications with the receiving node.

Abstract: Examples describe a method of operating a distribution point unit (DPU) having a wireless backhaul connection, such as a 4G or 5G connection. The distribution point unit is reverse powered electrically by connected subscriber lines. The radio configuration (number of antennas, frequencies, etc) used by the wireless backhaul connection is switched according to the power available from the subscriber lines. Changes to the available power can trigger a switch to a new radio configuration. Higher capacities (data rates) can be achieved with higher power radio configurations, which can be switched over to if the available power is sufficient. Similarly, when the available power drops, a switch can be made to an appropriate lower powered radio configuration.

Abstract: A method of operating a cellular telecommunications network, the cellular telecommunications network including a first base station, a User Equipment (UE) and a remote transceiver, wherein the first base station is adapted to send a signal to the UE, the method including receiving data from an external sensor indicating a first change in a propagation environment between the first base station and the UE; and, in response, the remote transceiver repeating a signal between the first base station and the UE.

Abstract: A method, user equipment (UE) and basestation are provided, wherein the UE is configured to send battery status data to the basestation and, in response, the basestation is adapted to improve the Quality of Service for the UE.

Abstract: An autonomous vehicle having wireless access communications access point equipment is arranged to set up a base station in a coverage “hole” by scanning to detect transmissions from another wireless communications access point, and determines a direction in which quality of coverage from the other wireless communications access point decreases, and directs the autonomous vehicle to move in the direction of decreasing coverage until it reaches a limit of coverage, at which point it hands over to another base station or, if no further base station is available, sets up as a wireless communications point connecting through the last base station to a backhaul connection.

Abstract: There is provided a method, and a network node for implementing the method, in a cellular telecommunications network. The cellular telecommunications network includes a first and second base station, the first base station having a first interface for communicating with a first cellular core networking node and a second interface for wirelessly communicating with the second base station, the second base station being mobile and having a first interface for wirelessly communicating with the first base station and a second interface for communicating with a User Equipment (UE), wherein the UE's user traffic is transmitted between the first cellular core networking node and the UE via the first and second base stations.

Abstract: This disclosure provides a base station for a cellular network, and a method of operating the base station in the cellular network, the cellular network also including a second base station, wherein the first and second base stations include first and second oscillators providing a first and second periodic timing pulse respectively, the method including determining a relative timing offset between a first instance of the first periodic timing pulse for transmission of a frame from the first base station and a first instance of the second periodic timing pulse for transmission of a frame from the second base station; determining that the relative timing offset is changeable; and adjusting the first periodic timing pulse to maintain the relative timing offset by varying a first period between instances of the first periodic timing pulse such that the rate of change of the relative timing offset over time is reduced.

Abstract: There is provided a method, and a network node for implementing the method, in a cellular telecommunications network. The cellular telecommunications network includes a first and second base station, the first base station having a first interface for communicating with a first cellular core networking node and a second interface for wirelessly communicating with the second base station, the second base station being mobile and having a first interface for wirelessly communicating with the first base station and a second interface for communicating with a User Equipment (UE), wherein the UE's user traffic is transmitted between the first cellular core networking node and the UE via the first and second base stations.

Abstract: An autonomous vehicle having wireless access communications access point equipment is arranged to set up a base station in a coverage “hole” by scanning to detect transmissions from another wireless communications access point, and determines a direction in which quality of coverage from the other wireless communications access point decreases, and directs the autonomous vehicle to move in the direction of decreasing coverage until it reaches a limit of coverage, at which point it hands over to another base station or, if no further base station is available, sets up as a wireless communications point connecting through the last base station to a backhaul connection.

Abstract: A method of operating a cellular telecommunications network, the cellular telecommunications network including a first base station, a User Equipment (UE) and a remote transceiver, wherein the first base station is adapted to send a signal to the UE, the method including receiving data from an external sensor indicating a first change in a propagation environment between the first base station and the UE; and, in response, the remote transceiver repeating a signal between the first base station and the UE.

Abstract: This disclosure relates to a method of operating a cellular telecommunications network, and to a first base station and a UE for implementing the method, the method including receiving data from an external sensor indicating a first change in a propagation environment between the UE and the base station; and, in response, reconfiguring a connectivity property for the UE.

Abstract: In a wireless network formed of short range femtocells, each femtocell provides wireless connectivity to user equipment devices and the user equipment can move around the topographical range covered by the network by handing over to a neighboring femtocell. Due to the limited range of a femtocell, there will be coverage gaps. If the device moves to a location not covered by a femtocell, it will try to connect to a macrocell of a different wide area cellular network until it is within range of another femtocell network. To minimize handovers from the femtocell network to the macrocell network, each femtocell is arranged to analyze historic log data to detect coverage gaps experienced by the user equipment as it moves along a user equipment route and try to close the gaps by increasing the coverage range of femtocells on either side of the coverage gap to close the gap.

Abstract: This disclosure provides a device and method of aligning a transmission frame in a Time Division Duplexing network, wherein the transmission frame includes a sequence of units separated by transition points, wherein each unit includes one or more resource slots in a transmission direction, the method comprising: allocating a transmit power level to a plurality of resource slots in a unit, wherein a transmit power for a first resource slot of the plurality of resource slots is greater than the transmit power for a second resource slot of the plurality of resource slots; measuring the transmit power of a TDD transmission received from an external node to determine a peak transmit power of the received TDD transmission; and substantially aligning the first resource slot to coincide with the peak transmit power of the received TDD transmission.

Abstract: This disclosure provides a base station for a cellular network, and a method of operating the base station in the cellular network, the cellular network also including a second base station, wherein the first and second base stations include first and second oscillators providing a first and second periodic timing pulse respectively, the method including determining a relative timing offset between a first instance of the first periodic timing pulse for transmission of a frame from the first base station and a first instance of the second periodic timing pulse for transmission of a frame from the second base station; determining that the relative timing offset is changeable; and adjusting the first periodic timing pulse to maintain the relative timing offset by varying a first period between instances of the first periodic timing pulse such that the rate of change of the relative timing offset over time is reduced.

Abstract: This disclosure provides a method of allocating a resource in a network of small cells, and a device for implementing the method, the method comprising: a first small cell detecting that its resource demand exceeds its resource allocation; the first small cell selecting a new resource that is being used by a second small cell; and the first small cell allocating the new resource to either the first or second small cell, wherein the probability the new resource is allocated to the first small cell is based on the first small cell's resource demand.