Abstract: A network node for a wireless communication system is configured to localize a user node in a first localization operation carried out at a first frequency; determine an accuracy value associated with the first localization operation; and adjust at least one beam parameter for radio beams to be used in a second localization operation based on the determined accuracy value, the second localization operation carried out at a second frequency that is greater than the first frequency. The network node is configured to determine the accuracy value associated with the first localization operation by tracking a rate of change of an angle of a radio beacon signal transmitted from the user node relative to the network node.

Abstract: The application relates to beam management for a client device in a power saving state. When the client device is in the power saving state, the client device monitors serving beams of a network access node based on a serving beam configuration. The serving beam configuration indicated the serving beams to be monitored by the client device in the power saving state. If the client device detects a beam failure during the serving beam monitoring in the power saving state, the client device performs a beam reconfiguration procedure. The beam reconfiguration procedure informs the network access node about the change in serving beam status and allows the network access node to update the serving beam configuration.

Abstract: The present disclosure relates to the field of wireless communications, and more particularly to a user node and a network node both so configured as to improve reliability of wake-up signaling and to enhance power consumption of the user node, as well as to corresponding methods for operating the user and network nodes. According to the present disclosure, a sequence of at least two wake-up signal instances is generated and transmitted through a burst transmission from the network node to the user node to cause the user node to wake up when there is payload data to be received from the network node.

Abstract: A network node for a wireless communication system includes a processor and a transceiver. The processor is configured to generate a plurality of random access grant signals. The random access grant signals include at least one unoccupied radio network temporary identifier and a resource allocation for an uplink communication request. The plurality of random access grant signals are assigned to one or more downlink transmit beams and the transceiver is configured to periodically transmit the plurality of random access grant signals on the one or more downlink transmit beams using a same time-frequency resource.

Abstract: Device, method and computer program to make better use of measurements of received signals for determining location are provided. A client device is configured to receive a signal that contains a reference symbol modulated onto a plurality of subcarriers. The client device determines a plurality of weights based on the reference symbol and line-of-sight channel frequency responses for the subcarriers, so that each of the plurality of weights is associated with one of the subcarriers. The client device determines a gain associated with the received signal using the plurality of weights. A network device may receive from the client device information indicative of gains, wherein a gain indicates a signal strength at which the client device was able to receive a respective signal. The location of the client device may be determined by using information about network device locations, transmission directions, and the gains.

Abstract: An access node comprises a processor and a transceiver. The transceiver is configured to receive at least one uplink reference signal corresponding to at least one user node. The processor is configured to determine, based on the at least one uplink reference signal, an estimated position of the at least one user node relative to the access node and at least one directional parameter corresponding to the estimated position of the at least one user node relative to the position of the access node. The transceiver is configured to send at least one downlink control information to the at least one user node, the at least one downlink control information including the directional parameters.

Abstract: An Access Node (ANd), for allocating a beacon resource pattern to a User Node (UNd), is configured to: detect the UNd by receiving an uplink beacon signal from the UNd; allocate a beacon resource pattern from a predetermined set of beacon resource patterns to the detected UNd; and signal information about the allocated beacon resource pattern to the UNd.

Abstract: The embodiment of the present invention relates to a control entity (101, 201, 301, 401, 501) for connecting to at least a first access node (ANd1) and at least a second access node (ANd2, ANd3, ANd4). According to the instructions of the control entity, key interference information is shared between ANds or ANd clusters, a Signal-to-Interference-plus-Noise Ratio (SINR) value is calculated based on the key interference information by the ANds or ANd clusters which received the shared key interference information, and a modulation and coding scheme (MCS) for each user is chosen based on the SINR by the ANds or ANd clusters.

Abstract: Methods, a user node and a network node are provided. The user node is configured to determine an indication of at least one wake-up latency of the user node, the at least one wake-up latency being a time period for the user node to wake-up and start to monitor a downlink channel transmitted by the network node of a wireless communication network; determine a message comprising the indication; and transmit the message to the network node. The network node is configured to receive from the user node a message, and set a wake-up offset for the user node based on the at least one wake-up latency comprised in the message, the wake-up offset being a time period between a wake-up signal transmission and a subsequent downlink channel transmission from the network node to the user node.

Abstract: The present disclosure relates to a network node having a processor and a transceiver. The processor is configured to select at least one user device if a Channel Estimation Timer (CET) for a radio channel between the network node and the at least one user device is valid, and to schedule data transmission to the at least one selected user device. The transceiver is configured to perform the scheduled data transmission to the at least one selected user device. The present disclosure also describes a corresponding method, a wireless communication system including such a network node, a computer program, and a computer program product.

Abstract: The present invention relates to a network node and a user device. The network node comprises a transceiver configured to receive a plurality of reference signals associated with a plurality of user devices; a processor configured to group the plurality of user devices into at least one group of user devices based on the plurality of received reference signals, assign radio resources for grant-free data transmission to the group of user devices, compute a receiver filter for the group of user devices based on the plurality of received reference signals and the assigned radio resources; wherein the transceiver is configured to receive a plurality of grant-free data transmissions from user devices in the group of user devices in the assigned radio resources, wherein the processor is configured to separate the grant-free data transmissions from the user devices in the group of user devices based on the computed receiver filter.

Abstract: An access node in a wireless communication system includes a transceiver configured to receive one or more uplink pilots associated with a user node via a radio link, and a processor configured to determine, based on the one or more uplink pilots, a location of the user node and whether the radio link is a line of sight radio link or a non-line of sight radio link. When the radio link is a line of sight radio link, the processor determines a position based precoding vector based on the location of the user node, and generates a precoded downlink control signal based on the determined position based precoding vector. The transceiver transmits the precoded downlink control signal to the user node.

Abstract: A client device is configured to receive an indication of a first network SINR for a first data transmission from a network node, and to derive the first network SINR based on the indication of a first network SINR. The client device is further configured to estimate a SINR adjustment for a second data transmission from the network node, and to compute a SINR difference value between the first network SINR and the SINR adjustment. Furthermore, the client device is configured to transmit at least one first control message having an indication of the SINR adjustment to the network node if the SINR difference value is larger than a threshold value.

Abstract: A network node for a wireless communication system is configured to localize a user node in a first localization operation carried out at a first frequency; determine an accuracy value associated with the first localization operation; and adjust at least one beam parameter for radio beams to be used in a second localization operation based on the determined accuracy value, the second localization operation carried out at a second frequency that is greater than the first frequency. The network node is configured to determine the accuracy value associated with the first localization operation by tracking a rate of change of an angle of a radio beacon signal transmitted from the user node relative to the network node.

Abstract: The embodiments of the present invention relates to a first communication device, a second communication device, and a control device. According to the embodiments of the present invention beacon signals are broadcasted by first communication devices in a wireless communication system. The broadcasted beacon signals are used for calculation of received power or pathloss by second communication devices. The calculated received power or pathloss is used for estimating interference in the wireless communication system by control devices. Furthermore, the embodiments of the present invention also relates to corresponding methods, a computer program, and a computer program product.

Abstract: The present disclosure relates to a device, and a method and a network node for a wireless communication system. The device includes: a transceiver and a processor, and the transceiver is configured to receive a first control signal from a network node where the first control signal includes a measurement request for a first reference signal, and receive the first reference signal from the network node, the processor is configured to measure the first reference signal according to the measurement request, and the transceiver is further configured to transmit a second control signal to the network node where the second control signal includes a measurement report indicating the measurement of the first reference signal, and transmit a second reference signal to the network node where the measurement report indicates a transmitted power of the second reference signal.

Abstract: A user device is provided. The user device comprises a transceiver configured to: receive a first Radio Network Temporary Identifier (RNTI), wherein the first RNTI is valid for a first set of network nodes of a radio communication network; receive at least one second RNTI, wherein the second RNTI is valid for a second set of network nodes of the radio communication network, and wherein the first set of network nodes and the second set of network nodes are different sets of network nodes; transmit data to the radio communication network, or receive data from the radio communication network, using the first RNTI or the second RNTI. Furthermore, a network node and corresponding methods, a computer program, and a computer program product are provided.

Abstract: The present disclosure relates to a user device, an access node device and a central network controller. The user device comprises a transceiver configured to synchronise with a radio communication network; said transceiver further being configured to broadcast a beacon signal comprising at least one reference signal to one or more access node devices of said radio communication network. The access node device comprises a transceiver configured to receive a broadcast beacon signal from a user device synchronised with said radio communication network; and further a processor configured to derive information from said received broadcast beacon signal and to use said derived information in a network procedure of said radio communication network. Furthermore, the present disclosure also relates to corresponding methods, a computer program, and a computer program product.

Abstract: A transmitter, a receiver and a method for communicating data packets. The method comprises receiving a data packet and determining if it is a re- or new transmission; and, when it is a retransmission: combining the received data packet with oldest unsuccessfully decoded data packet stored in a second memory, and decoding the combined data packet; when it is a new transmission: decoding the received data packet; checking if the decoding is successful; deleting the oldest stored data packet in the first memory; storing the decoded data packet in the first memory when the decoding is successful or storing the decoded data packet in the second memory when the decoding is not successful; and transmitting feed-back information to the transmitter.

Abstract: Implementations described herein relate generally to a user device, to an access node, and to methods for a user device and for an access node. The user device includes a receiver configured to receive at least one downlink signal from an access node. The user device further includes a processor configured to measure the at least one downlink signal at two time instants, to determine if a difference of the measured at least one downlink signal at the two time instants exceeds a threshold, and to generate, when the difference exceeds the threshold, at least one uplink transmission. The user device further includes a transmitter configured to transmit the at least one uplink transmission over an uplink random access channel.