Abstract: A method and transition device for enabling communication of data between a remote radio unit and a central baseband unit in a wireless network. When detecting a first interface configuration used by the remote radio unit and a second interface configuration used by the baseband unit, the transition device configures interface functions, based on the first and second interface configurations. The interface functions are selected from a set of predefined interface functions associated with different interface configurations. The transition device then establishes a data flow between the remote radio unit and the central baseband unit over the transition device, and performs conversion between the first interface configuration and the second interface configuration for data communicated in the data flow, using the selected interface functions.

Abstract: A method of operating a lower-layer split central unit, LLS-CU, includes allocating a plurality of downlink signals to a plurality of physical resource blocks, PRBs, of a physical downlink channel, generating a data-associated control information, DACI, message including a section description associated with the plurality of downlink signals, the DACI message including an indication of a plurality of sets of beamforming weights to be applied by a radio unit, RU, when transmitting the plurality of downlink signals to the UE, transmitting the DACI message to the RU, and transmitting the plurality of downlink signals to the RU for transmission to the UE.

Abstract: A method of operating a radio unit, RU, in a network node of a wireless communication system, the network node having a lower-layer split architecture and including a lower-layer split central unit, LLS-CU, includes receiving an uplink signal from a user equipment, UE, in response to the uplink signal, determining at the RU a set of beamforming weights defining an antenna beam from the RU to the UE, transmitting the uplink signal to the LLS-CU, and forming the antenna beam to the UE using the set of beamforming weights.

Abstract: Systems and methods for handling antenna signals are provided. In some embodiments, a method is performed by a first unit for handling antenna signals for transmission over a transmission connection with a second unit of the base station system. The base station system includes a base unit and a remote unit. The remote unit is arranged to transmit the antenna signals wirelessly to, and receive from, one or more wireless communication devices. The antenna signals each include a plurality of In-phase and Quadrature (IQ) samples. The first unit is the base unit and the second unit is the remote unit, or the first unit is the remote unit and the second unit is the base unit. In this way, quantization errors may typically add incoherently, i.e., adding quantization error power. Also, this may allow cancellation of quantization errors in certain directions depending on transformation type and transformation values.

Abstract: A method for transmitting user data from a lower-layer split central unit (LLS-CU) to a radio unit (RU) in a network node of a wireless communication system for transmission by the RU over a wireless interface includes mapping reference symbols to be transmitted by the RU to resource elements to provide mapped data. The mapped data including the references symbols is compressed using a bitmap representation of the mapped data to obtain compressed data. The compressed data is transmitted from the LLS-CU to the RU.

Abstract: A method of operating an LLS-CU includes providing downlink signals to be transmitted to a UE over a wireless radio interface, allocating the downlink signals to resource elements, REs, of a physical downlink channel, generating a data-associated control information, DACI, message including a section description associated with the downlink signals, the DACI message including a resource element mask that defines the location of one or more REs within a PRB of a downlink signal on the physical downlink channel, and an indication of beamforming weights to be applied by a radio unit, RU, when transmitting the downlink signals to the UE, wherein the beamforming weights are associated with resource elements according to the resource element mask, transmitting the DACI message to the RU, and transmitting the downlink signals to the RU for transmission to the UE.

Abstract: There is provided a method for controlling interference in a received signal when scheduling in a network node for wireless communication with a set of user equipment's, UEs, said set comprising a first UE and at least a second UE, wherein the interference is passive-intermodulation interference, PIM. The method comprises receiving a scheduling request from at least the first UE transmitting on a first frequency and scheduling at least the first UE based on an interference scenario report and available PIM cancellation resources to enable efficient PIM control. The method is performed by a control device.

Abstract: Method, devices and systems for operating a radio unit, RU, in a network node of a wireless communication system are provided. Operations of such methods include receiving a request from a lower-layer split central unit, LLS-CU. The request includes an indication regarding multiple identified channels for receiving the spatial information for determining a direction to a user equipment. Operations include providing, in the RU, a spatial information receiver that is configured to represent multiple spatial beam directions and/or receive paths responsive to the request from the LLS-CU. Operations include receiving, into the spatial information receiver and via multiple radio branches that correspond to multiple antennas, beam signal information corresponding to multiple ones of the antennas.

Abstract: A radio unit, RU, in a network node of a wireless communication system is operable to receive, at the radio unit and from a lower-layer split central unit, LLS-CU, a plurality of downlink signals that include reference symbols, RS, and user data downlink, UD-DL, messages to be transmitted to a user equipment, UE, over a wireless interface. The RU can accumulate received data corresponding to the plurality of downlink signals into a concentrated data format. The RU can further receive a data-associated control information, DACI, message including a section description associated with the plurality of downlink signals. The DACI message can include an indication of how to perform the accumulating data operation.

Abstract: One embodiment of the disclosure provides a method performed by a first component part of a base station. The first component part comprises one of a central unit and a radio unit. The base station further comprises a second component part, which comprises the other of the central unit and the radio unit.

Abstract: A method for configuring transmission order of uplink data, performed by an REC of an access node. The REC has an interface to an RE of the access node. The method comprises providing instructions to the RE how to prioritize transmission order of uplink data. The uplink data is received by the RE on a radio interface and is to be transmitted from the RE to the REC on the interface. The REC thereby configures the transmission order.

Abstract: There is presented mechanisms for providing information for determining beamforming weights or decoding user data for terminal devices. A method is performed by an RE of an access node. The RE has an interface to an REC of the access node. The method comprises obtaining information from the terminal devices to be used by the REC for determining the beamforming weights or decoding the user data. The method comprises selecting, according to a selection criterion, a part of the information to be provided to the REC in order for the REC to determine the beamforming weights or decode the user data based on the selected part of the information. The method comprises providing the selected part of the information to the REC over the interface.

Abstract: A method for operating a radio access system comprises configuring a first carrier and a second carrier for use for radio access in a first radio access system. The second carrier is configured for frequency division duplex signalling. A useful frequency band of the second carrier is defined to, at least partially, overlap in frequency with a useful frequency band of a third carrier of a second radio access system. At least a part of the useful frequency band of the second carrier overlaps in frequency with guard bands of the third carrier. A method for signal scheduling comprises scheduling, in a first radio access system having a first carrier with a first carrier frequency band and a second carrier with a second carrier frequency band, uplink signals in the second carrier. Network nodes for carrying out the methods are also presented.

Abstract: A method for configuring transmission order of uplink data, the method performed by a radio equipment (“RE”) of an access node. The RE has a RE controller (“REC”)-RE interface that communicatively couples the RE with a REC of the access node. The method includes receiving instructions from the REC that indicate a scheduling prioritization for transmission by the RE of uplink data between the RE and the REC over the REC-RE interface. The uplink data can be received by the RE on the radio interface. The method can further include transmitting the uplink data on the REC-RE interface according to the instructions, resulting in the scheduling prioritization of the uplink data.

Abstract: There is presented mechanisms for providing information for determining beamforming weights or decoding user data for terminal devices. A method is performed by an RE of an access node. The RE has an interface to an REC of the access node. The method comprises obtaining information from the terminal devices to be used by the REC for determining the beamforming weights or decoding the user data. The method comprises selecting, according to a selection criterion, a part of the information to be provided to the REC in order for the REC to determine the beamforming weights or decode the user data based on the selected part of the information. The method comprises providing the selected part of the information to the REC over the interface.

Abstract: Disclosed is receiving IQ samples of a first antenna signal related to wireless communication of a first antenna of the remote unit, and IQ samples of a second antenna signal related to wireless communication of a second antenna of the remote unit, transforming the received IQ samples of the first antenna signal into transformed IQ samples, using a first transformation value, and transforming the received IQ samples of the second antenna signal into transformed IQ samples, using a second transformation value different from the first transformation value.

Abstract: There is provided mechanisms for determining frequency location of a primary cell (PCell) for a wireless device in a carrier aggregation supported communications network having access to a group of low frequency bands and a group of high frequency bands. A method is performed by a network node. The method comprises acquiring an uplink load level for the group of low frequency bands. The method comprises acquiring a pathloss level between a wireless device served by the communications network and the network node. The method comprises selecting, from the acquired uplink load level and pathloss level, which one of the group of low frequency bands and the group of high frequency bands to place the frequency location of the PCell for the wireless device.

Abstract: There is presented mechanisms for providing information for determining beamforming weights or decoding user data for terminal devices. A method is performed by an RE of an access node. The RE has an interface to an REC of the access node. The method comprises obtaining information from the terminal devices to be used by the REC for determining the beamforming weights or decoding the user data. The method comprises selecting, according to a selection criterion, a part of the information to be provided to the REC in order for the REC to determine the beamforming weights or decode the user data based on the selected part of the information. The method comprises providing the selected part of the information to the REC over the interface.

Abstract: A method and transition device for enabling communication of data between a remote radio unit and a central baseband unit in a wireless network. When detecting a first interface configuration used by the remote radio unit and a second interface configuration used by the baseband unit, the transition device configures interface functions, based on the first and second interface configurations. The interface functions are selected from a set of predefined interface functions associated with different interface configurations. The transition device then establishes a data flow between the remote radio unit and the central baseband unit over the transition device, and performs conversion between the first interface configuration and the second interface configuration for data communicated in the data flow, using the selected interface functions.

Abstract: A method for evaluating performance between a network node and at least one test radio head, each one of the at least one test radio heads being located remotely from the network node. The method is performed in the network node, and comprises sending a loopback signal to at least one test radio head to add a loopback of its transmission signal on its receiving signal; sending a transmission signal to the at least one test radio head; receiving a received signal from the at least one test radio head; and determining a performance by comparing the received signal with the transmission signal.