Abstract: A method performed by a wireless device for handling two or more beamformed communication links initialized with one or more network nodes in a wireless communications network is provided. The wireless device determines at least one compatibility state for the two or more beamformed communication links based on one or more current radio signal characteristics at the wireless device for the two or more beamformed communication links, wherein the at least one compatibility state indicates if the wireless device currently is able to simultaneously receive transmission beams of the two or more beamformed communication links or not. The wireless device transmits information indicating the at least one determined compatibility state for the two or more beamformed communication links to at least one of the one or more network nodes. A wireless device as well as a network node and method of operation thereof are also disclosed.

Abstract: Embodiments herein relate to method performed by a radio-network node for handling a data transmission, from a wireless device to the radio-network node, in a wireless communication network. The radio-network node schedules one or more resources for carrying an uplink data transmission from the wireless device over a channel, and for carrying a feedback transmission, of a downlink data transmission from the radio-network node, over the same channel. The radio-network node transmits a control message to the wireless device, which control message indicates the one or more resources scheduled for carrying the uplink data transmission and the feedback transmission over the same channel.

Abstract: The present disclosure is directed to a method and apparatus for controlling a Hybrid Automatic Repeat Request, HARQ, retransmission round-trip time for transmission in a wireless network. The method comprises to estimate (S41) one or more latency related transmission parameters and to select (S43) one or more of a plurality of predefined HARQ relaxation techniques based on the estimated one or more latency related transmission parameters. Transmission is scheduled (S44) using the selected one or more HARQ relaxation technique.

Abstract: A network node (100), a wireless terminal (102) and methods therein, for supporting beam tracking in the wireless terminal (102) when a selected network beam (Bc) and a selected terminal beam (Tc) are used. The network node (100) identifies a set of candidate network beams (B) having spatial characteristics similar to the selected network beam (Bc), and signals the candidate network beams to the wireless terminal (102). When the network node (100) transmits beam reference signals in the candidate network beams using beam sweeping, the wireless terminal (102) measures received power using different candidate terminal beams (T) and estimates received power of combinations of beam reference signal and candidate terminal beam that have not been measured, based on the measured combinations of beam reference signal and candidate terminal beam.

Abstract: Systems and methods are disclosed for providing efficient downlink Hybrid Automatic Request (HARQ) feedback. In some embodiments, a method of operation of a wireless device in a cellular communications system comprises receiving a downlink control information message comprising a HARQ feedback buffer index and storing a downlink HARQ feedback flag in a position within a HARQ feedback buffer that corresponds to the HARQ feedback buffer index. In this manner, multiple downlink HARQ feedback flags can be stored in the HARQ feedback buffer and subsequently transmitted to a network node in an efficient manner.

Abstract: A Network Node (NN) 208 and a method therein for beam selection. When an upcoming ability to serve a Wireless Device (WD) 210 using a current NN beam is predicted to be lost based on historic data, the NN selects an upcoming NN beam out of one or more candidate NN beams that are able to serve the WD when the NN has lost ability to serve the WD using the current NN beam. The NN configures a dedicated Beam Reference Signal (BRS) for the upcoming NN beam, which is to be detected in beam selection by the WD when the NN loses ability to serve the wireless device using the current NN beam. By means of the current NN beam, the NN transmits, to the WD, a configuration of the dedicated BRS. Further, by means of the upcoming NN beam, the NN transmits, to the WD, the dedicated BRS.

Abstract: Embodiments herein relate to a method performed by a radio-network node (12) for handling access to the radio-network node (12) from a wireless device (10) in the wireless communication network (1). The radio-network node determines one or more preamble configuration parameters indicating a length of a preamble for a physical random-access channel, PRACH, for the wireless device (10) based on one or more signal strength or quality measurements, and/or a load in the wireless communication network (1). The radio network node further transmits an indication of the determined one or more preamble configuration parameters to the wireless device.

Abstract: Embodiments herein relate to a method performed by a wireless communication device 615, for performing random access. The wireless communication device 615 is configured with a first Random-Access (RA) configuration. The method comprises obtaining an indication of a failure of a beam-tracking process. The method further comprises adapting the RA configuration of the wireless communication device 615 based on the obtained indication, wherein the adapting comprises switching from the first RA configuration to a second RA configuration having more frequently occurring RA resources than the first RA configuration. The method further comprises transmitting, to a network node 611, 612, a RA message using a RA resource, which RA resource is based on the adapted RA configuration. Embodiments herein further relate to a method performed by a serving network node 611, as well as a wireless communication device 615 and a serving network node 611 for performing the methods.

Abstract: Systems and methods are disclosed for providing efficient downlink Hybrid Automatic Request (HARQ) feedback. In some embodiments, a method of operation of a wireless device in a cellular communications system comprises receiving downlink control information from a radio access node in a first subframe T. The downlink control information comprises an indication of a HARQ timing offset K. The method further comprises transmitting downlink HARQ feedback to the radio access node in a subframe T+K. In this manner, HARQ feedback can be directly scheduled by the network, which in turn enables efficient HARQ feedback.

Abstract: A wireless device (14) is configured to receive, from network equipment (12), a tracking process base signal (18) using a receiver configuration (16) with tunable beamforming, and transmit a report (20) to the network equipment (12) indicating reception of the tracking process base signal (18). The wireless device (14) is further configured to, responsive to transmitting the report (20), configure the wireless device (14) with a tracking process (26) for the wireless device (14) to track a reference signal (24) by tuning the receiver configuration (16) with which the wireless device (14) received the tracking process base signal (18). The wireless device (14) is also configured to, based on receiving a reference signal (24) identified as being a reference signal (24) to be tracked by the tracking process (26), track the reference signal (24) by tuning beamforming of the receiver configuration (16).

Abstract: A radio device (100) sends a radio transmission (503, 507) to a further radio device (150). Further, the radio device (100) receives a further radio transmission (505, 509) from the further radio device (150). The further radio transmission (505, 509) comprises an indicator of reception success. In response to the indicator being toggled with respect to a previous state of the indicator, the radio device (100) determines that the radio transmission (509) was successfully received by the further radio device (150). In response to the indicator not being toggled with respect to the previous state of the indicator, the radio device (100) determines that the radio transmission (503) failed.

Abstract: Embodiments described herein are directed to methods for controlling user equipment (UE) beamforming in a wireless network. According to certain embodiments, a (UE) can receive one or more beam reference signals included in a restricted set of useable beam reference signals for adjusting the UE beamforming. Further, the UE can receive one or more beam reference signals outside of the restricted set. It can be determined whether to update the restricted set to include a subset of the one or more beam reference signals outside of the restricted set, based on predetermined criteria. The UE beamforming can be adjusted based on beam reference signals in the restricted set.

Abstract: A method of connecting a User Equipment, UE, with a radio access network, RAN, in a telecommunication network, wherein said RAN comprises a plurality of Baseband Units, BBU's, wherein said UE comprises two multi layered protocol stacks that can be used for same type of connections with BBU's and wherein said UE is connected to a first BBU using a first of said two protocol stacks for communication with said first BBU, said method comprising the steps of receiving, by a second BBU, from a network node in said telecommunication network, a Stack Selector parameter, wherein said Stack Selector parameter indicates which of said two protocol stacks are to be used by said UE for said communication with said second BBU, transmitting, by said second BBU, to said UE a downlink grant message, wherein said downlink grant message comprises said Stack Selector parameter.

Abstract: A method and wireless communication device (120) for managing system information provided by a wireless communication network (100) that the wireless communication device (120) is configured to operate with. The wireless communication device (120) receives (801; 901) a broadcasted first part of system information from the wireless communication network (100). The wireless communication device (120) then obtains (802; 902) a further, second part of system information based on which of at least two different information formats that is used in the first part.

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: Embodiments herein relate a method performed by a first radio-network node (12) for managing signaling in a wireless communication network, the first radio-network node provides radio coverage over a first service area in the wireless communication network. The first radio-network node transmits a first beam reference signal, BRS, in the first service area, which first BRS comprises a number of repetitive sequences of samples, of equal length, over an original time-domain representation of the first BRS.

Abstract: Systems and methods are disclosed for providing efficient downlink Hybrid Automatic Request (HARQ) feedback. In some embodiments, a method of operation of a wireless device in a cellular communications system comprises receiving downlink control information from a radio access node in a first subframe T. The downlink control information comprises an indication of a HARQ timing offset K. The method further comprises transmitting downlink HARQ feedback to the radio access node in a subframe T+K. In this manner, HARQ feedback can be directly scheduled by the network, which in turn enables efficient HARQ feedback.

Abstract: A system and method of Random-Access Response, RAR, messaging when a base station employs narrow beamforming. Multiple RAR messages are successively transmitted from the base station to a User Equipment, UE, before any response to a RAR message is received from the UE. Thus, despite any calibration mismatch between Uplink, UL, and Downlink, DL, beams in the beamformed system, a RAR message is not only received by the UE, but is received over the most-suitable DL beam for that UE. Each RAR message may contain a message-specific scheduling-delay indicator in the UL grant carried in the RAR message to provide an adjustable time delay for the UE's uplink transmission scheduled by the UL grant. Multiple RAR transmissions can schedule a single UL transmission at a specific time instance or different UL transmissions at different time intervals. The UE may report to the base station the best DL RAR transmission detected by the UE.

Abstract: A radio node (e.g., a base station) (12) is configured to generate a reference signal (16) in an Orthogonal Frequency-Division Multiplexing (OFDM) system (10). The radio node (12) in this regard is configured to generate a reference signal (16) that comprises a sequence of reference symbols distributed respectively on spaced OFDM subcarriers (18) within a transmission bandwidth such that the sequence successively repeats an integer number n of times in the time domain over an OFDM symbol period (22). Adjacent ones of the spaced OFDM subcarriers (18) that do not straddle a center OFDM subcarrier have z intermediate OFDM subcarriers (20) therebetween, where z>0. By contrast, adjacent ones of the spaced OFDM subcarriers (18) that do straddle the center OFDM subcarrier have z+n intermediate OFDM subcarriers (20) therebetween, where n>1. The center OFDM subcarrier is at the center of the transmission bandwidth with no signal to be transmitted thereon.

Abstract: A method performed by a radio network node for receiving reference signals from a wireless device in a wireless communications network is provided, the network node and the wireless device operating in the wireless communications network. The radio network node decides (901) whether reference signals to be sent by the wireless device shall be assigned (1) according to a first way by assigning the reference signals to channel resources in the same frequency allocation for subsequent Orthogonal Frequency-Division Multiplex, OFDM, symbols, or (2) according to a second way by assigning reference signals to channel resources in offset frequency allocations for subsequent OFDM symbols. The radio network node then sends (902) an indication to the wireless device. The indication indicates whether to assign the reference signals according to the decided any one out of the first way and the second way.