Abstract: Techniques disclosed herein involve network-side and device-side operations that provide for the advantageous use of a reduced set of precoders within a larger full set of precoders. The reduced set is identified dynamically, based on characteristics of the channel between a radio network node and a wireless device, and the use of a defined mapping function that maps the reduced set of precoders within the larger full set to a reduced set of index values. Reporting precoders from the reduced set offers significant reductions in signaling overhead because of the smaller size of the index values used to index the reduced set, while simultaneously offering the ability to choose from precoders matched to current channel conditions.

Abstract: Culling a set of precoders down to a smaller set using a comparatively simple first-pass evaluation allows a wireless device or other entity to reduce an overall computational burden associated with identifying a currently preferred precoder. An example approach involves selecting a reduced set of precoders from a full set of precoders, based on performing preliminary evaluations of precoders in the full set, and selecting a preferred precoder or precoders from the reduced set, based on performing further evaluations of precoders in the second set. On a per precoder basis, the further evaluations are more complex than the preliminary evaluations. One may view the approach as using less complex first-pass evaluations to reduce the precoder search space, and then using more complex second-pass evaluations to identify a currently preferred precoder or precoders within the reduced search space.

Abstract: A first Network Node (NN) 206 and a method therein for enabling handover of a first and a second wireless device 210,212 from the first NN to a second NN 208. The first NN determines that the second wireless device is to refrain from transmitting an uplink synchronization signal. Based on the determination, the first NN configures the first wireless device to transmit an uplink synchronization signal and to synchronize to a first downlink synchronization signal, an configures the second wireless device to synchronize to a second downlink synchronization signal. The first NN receives, from the second NN, information relating to a measurement performed on the uplink synchronization signal transmitted only from the first wireless device. Based on the received information, the first NN requests the second NN to perform the handover of the first and second wireless devices.

Abstract: There is provided mechanisms to obtain, report and/or use measurement information representing so-called UE-to-UE interference between UEs (10, 20) to enable interference-aware configuration of at least one transmission and/or interference suppression in a cellular communication system.

Abstract: Techniques disclosed herein involve network-side and device-side operations that provide for the advantageous use of a reduced set of precoders within a larger full set of precoders. The reduced set is identified dynamically, based on characteristics of the channel between a radio network node and a wireless device, and the use of a defined mapping function that maps the reduced set of precoders within the larger full set to a reduced set of index values. Reporting precoders from the reduced set offers significant reductions in signaling overhead because of the smaller size of the index values used to index the reduced set, while simultaneously offering the ability to choose from precoders matched to current channel conditions.

Abstract: There is provided mechanisms for precoding matrix indicator (PMI) reporting for a set of ports. A method is performed by a wireless device. The method comprises receiving reference signals, the reference signals having been transmitted from a set of ports of a network node. The method comprises determining PMI information for the received reference signals. The method comprises transmitting the PMI information in a report to the network node, wherein the report comprises a combination of identifications of ports from the set of ports and identifications of the reference signals such that an identification of each port is paired with a respective identification of at most one of the reference signals.

Abstract: A radio network node (110) manages (A010) establishment of a current radio session between a user equipment (120) and the radio network node (110), wherein the current radio session is associated with a current set of characteristics relating to the radio network node (110) and/or the user equipment (120). During establishment of the current radio session, a core network node (130) retrieves (A080), based on the current set of characteristics, an indication about the MCS offset from a memory (141, 142) accessible by the core network node (130). Then, the core network node (130) sends (A090), to the radio network node (110), the indication about the MCS offset. The indication is derived from a previous radio session, wherein the previous radio session is associated with a previous set of the characteristics, wherein the previous set of the characteristics matches the current set of the characteristics.

Abstract: To perform handover in a multi-carrier network, a node that is currently serving a user equipment, UE, informs the neighboring nodes about the UE position and UE capabilities in terms of supported carriers. The neighboring nodes reply with a figure of merit indicative of connection efficacy, or data from which connection efficacy can be estimated, such as predicted signal quality and strength for each specified carrier. The serving node then determines, based on these predicted values, how to restrict mobility reference signal, MRS, measurements to promising candidate combinations of neighboring nodes and their carriers. Turning on of reference signals is thus limited, excluding nodes and carriers that will not be able to accept handover on technical or policy grounds, as well as nodes or carriers which have poor predicted signal quality.

Abstract: A first Network Node (NN) 206 and a method therein for enabling handover of a first and a second wireless device 210,212 from the first NN to a second NN 208. The first NN determines that the second wireless device is to refrain from transmitting an uplink synchronization signal. Based on the determination, the first NN configures the first wireless device to transmit an uplink synchronization signal and to synchronize to a first downlink synchronization signal, an configures the second wireless device to synchronize to a second downlink synchronization signal. The first NN receives, from the second NN, information relating to a measurement performed on the uplink synchronization signal transmitted only from the first wireless device. Based on the received information, the first NN requests the second NN to perform the handover of the first and second wireless devices.

Abstract: A method performed by a network node for determining a beam to direct a signal to be transmitted from the network node to a user equipment in a wireless communications network. The network node obtains (302) information related to a sequence of beams associated with the user equipment. The network node further determines (304) the beam based on the information related to the sequence of beams.

Abstract: A signal quality associated with radio transmissions from a first device (100) to a second device (10) is determined. Further, an uncertainty of the determined signal quality is determined. Depending on the determined signal quality and uncertainty, a beamforming configuration, applied by the first device (100) for performing the radio transmissions to the second device (10), is adapted.

Abstract: Radio link failures, “RLF”, of a wireless device served by a wireless communication network are managed. A first, default, RLF procedure is associated with at least a first type of wireless devices supported by the wireless communication network. The wireless device obtains, e.g. received from a network node information indicative of a second RLF procedure based on that the wireless device is of a second type having an improved radio coverage capability compared to the first type. The wireless device applies, based on the obtained information, said second RLF procedure.

Abstract: There is provided a method and corresponding apparatus for determining a beamforming configuration for a multi-antenna system according to an embodiment. In general, the multi-antenna system has at least two antennas and a port-to-antenna mapping between antenna ports and antennas. The method comprises obtaining (S1) first feedback information originating from a wireless device relating to a multi-antenna transmission based on a first beamforming configuration including a first port-to-antenna mapping, and obtaining (S2) second feedback information originating from the wireless device relating to a multi-antenna transmission based on a second, different beamforming configuration including a second, different port to-antenna mapping. The method also comprises determining (S3), based on the first feedback information and the second feedback information, a third beamforming configuration for the multi-antenna system including a third port-to-antenna mapping to enable beamforming according to a third beam form.

Abstract: There is provided mechanisms for precoding matrix indicator (PMI) reporting for a set of ports. A method is performed by a wireless device. The method comprises receiving reference signals, the reference signals having been transmitted from a set of ports of a network node. The method comprises determining PMI information for the received reference signals. The method comprises transmitting the PMI information in a report to the network node, wherein the report comprises a combination of identifications of ports from the set of ports and identifications of the reference signals such that an identification of each port is paired with a respective identification of at most one of the reference signals.

Abstract: There is provided mechanisms for adaptive beamforming. A method is performed by a first network device. The method comprises acquiring beamforming information indicating spatial directions in which an identification signal is to be transmitted. The method comprises transmitting the identification signal in a transmission pattern using directional beams in the spatial directions towards second network devices. The identification signal is transmitted such that the identification signal occupies a larger portion of communications resources when transmitted in spatial directions with high second network device presence than in spatial directions with low second network device presence.