Abstract: A cellular network supports radio communication based on a first configuration which organizes a time-frequency space in first resource elements and radio communication based on a second configuration which organizes the time-frequency space in second resource elements and assigns at least one of the second resource elements to a utilization which is in conflict with the radio communication based on the first configuration. A node (100-A) of the cellular network sends an indication (20) to a communication device (10-A, 10-B). The indication (20) comprises time domain and/or frequency domain information for defining a pattern comprising at least one of the first resource elements which is to be disregarded by the communication device (10-A, 10-B) when performing radio communication with the cellular network based on the first configuration and/or the second configuration.

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 first network node (110; 111; 112; 130), a wireless device (120) and methods thereof, for managing one or more uplink resources between the wireless device (120) and a wireless communication network (100) are provided. The first network node (110; 11; 112; 130) compiles (204; 401) resource information about uplink resources available for the wireless device (120) to select and request for uplink scheduling. Said resource information associates each one of multiple such uplink resources with one or more downlink reference signals. The first network node (110; 111; 112; 130) sends (205; 402) the compiled resource information to the wireless device (120). The wireless device (120 ) 10 is thereby enabled to select, based on the resource information, e.g. ASRT information and said one or more downlink reference signals, at least one of said uplink resources to request for uplink scheduling.

Abstract: A wireless device 130 and a method for performing Channel-State Information (CSI) measurements. The wireless device 130 and a Radio Network Node (RNN) 110 serving the wireless device 130 are operating in a wireless communications system 100. The wireless device 130 receives, from the RNN 110, information relating to a first resource for CSI measurement and an indication to determine a second resource for CSI measurement, which indication relates to the first resource for CSI measurement. Further, the wireless device 130 determines the second resource for CSI measurement based on the information relating to the first resource and on information comprised in the indication, which second resource for CSI measurement is different from the first resource for CSI measurement. Furthermore, the wireless device 130 performs an CSI measurement on the second resource.

Abstract: The invention relates to network nodes, a wireless communication device, WCD, and methods therein for handover. The method in the WCD comprises obtaining, from a source network node, information comprising at least part of a WCD Context related to the WCD. The method further comprises connecting to a target network node, and forwarding the obtained information to the target network node, enabling the target network node to derive the WCD Context based on the information.

Abstract: A method performed by a radio-network node for handling a data transmission in a number of subframes from the radio-network node to a wireless device in a wireless communication network. The radio-network node transmits data over the number of subframes to the wireless device. Each subframe comprises a control part associated with the data of the subframe. Each respective control part comprises a feedback index indicating a transmission time offset of a feedback message. The feedback message is to comprise a respective feedback indication of the number of subframes to be transmitted simultaneously from the wireless device to the radio-network node in the feedback message.

Abstract: A method performed by a radio-network node for handling a data transmission from the radio-network node to a wireless device in a wireless communication network is provided. The radio-network node transmits (401) data over a number of subframes to the wireless device (10), and a respective control part, associated with the data of each respective subframe, the respective control part comprising a feedback index indicating a transmission time of a feedback indication. The radio-network node receives (402) from the wireless device the feedback indication in the feedback message common for the subframes of the data transmission according to the control parts of the transmitted subframes. The feedback indication indicates feedback for each subframe of the data transmission received and the number of NACKed subframes out of the number of subframes of the data transmission.

Abstract: The setting of a value of the transmission control parameter for a transmission of data on a multi-hop relay radio link of a cellular network is controlled. Said controlling is based on a route time of a packet transmitted between end nodes of the multi-hop relay radio link. E.g., the transmission control parameter may relate to a property of an Automatic Repeat Request protocol.

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: There is provided a method and corresponding device for enabling channel state feedback for multi-user transmission in a wireless communication system. The method comprises performing (S1), for each of a number of users, a classification of the user into one of at least two groups based on a measure of the speed of the temporal channel variation for the user. The method also comprises selecting (S2), for each of the users, a channel state feedback mechanism based on the classification.

Abstract: Identification of network nodes (110a-c) of a first Radio Access Technology, “RAT”, and of a wireless communication network (100), which network nodes (110a-c) are at least potentially neighboring each other. Multiple information sets associated with multiple communication devices (120a-c), respectively, are obtained (204a-b; 401). Each communication device (120a-c) supports both the first RAT and another, second RAT. Each information set, thus associated with a communication device (120a), identifies a network node (110a) of the first RAT, and one or more network nodes (111a) of the second RAT that have been identified by the communication device (120a) when the communication device (120a) was associated with a communicative connection to said identified network node (110a) of the first RAT. The network nodes (110a-b) of the first RAT that are at least potentially neighboring each other are then identified (205; 402) based on the obtained multiple information sets.

Abstract: Systems and methods relating to the use of Beam Reference Symbols (BRSs) and BRS Received Power (BRS-RP) reporting for the selection of a beam for transmission to a wireless device from a first Radio Access Network (RAN) operating according to a first Radio-Access Technology (RAT) in a dual connectivity scenario in which control signaling (e.g., BRS-RP reporting) from the wireless device to the first RAN of the first RAT is transmitted via a second RAN of a second RAT. In particular, embodiments are disclosed for resolving timing and/or node ambiguity with respect to BRS-RP reporting.

Abstract: The present embodiments herein provide methods, apparatuses and a system for the purpose of scheduling resources to a UE (11) by a network node (12). The UE or CE (11) is configured to receive (210), from the network node (12), a control message, comprising information about a resource allocation as well as an indicator indicating whether a single-subframe scheduling scheme or a multi-subframe scheduling scheme. The CE (11) then retrieves the indicator and act according the information associated with the indicator.

Abstract: Method of connecting a user equipment, UE, to a telecommunication network via an access node comprised in said network, said method comprising the steps of receiving, by said access node, a connection request from said UE, determining, by said access node, connection configuration parameters for said UE, comprising checking whether connection configuration parameters for said UE related to a prior connection between said UE and said telecommunication network are available for re-use, and connecting, by said access node, said UE to said telecommunication network via said access node by setting up said determined connection configuration parameters for said U E.

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 method performed by a wireless device for determining channel state measurements in a wireless communications network is provided. The wireless device obtains at least two channel state measurements performed by the wireless device on measurement resources allocated for the at least two channel state measurements. The wireless device also receives information indicating how the wireless device is to combine the obtained at least two channel state measurements into at least one combined channel state measurement. Then, the wireless device determines at least one combined channel state measurement based on the received information and the obtained at least two channel state measurements. A wireless device for determining channel state measurements in a wireless communications network is also provided. Further, a network node and a method therein for enabling a wireless device to determine channel state measurements in a wireless communications network are also provided.

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: Embodiments herein relate to a method performed by a first radio network node for enabling a mobility procedure of a wireless device between the first radio network node and a second radio network node in a wireless communication network. The first radio network node transmits a first indication to the second radio network node, which first indication indicates a position of the wireless device. The first radio network node further receives a second indication from the second radio network node, which second indication indicates one or more beams used at the second radio network node. The first radio network node sends to the wireless device measurement information indicating the one or more beams to perform measurement on and thereby enabling the mobility procedure.

Abstract: There is provided a method for determining radio resource usage. The method is performed by a network node. The method comprises associating a bearer of a terminal device with a target bitrate. The method comprises estimating a spectral efficiency of the bearer. The method comprises acquiring a maximum radio resource usage. The method comprises determining radio resource usage of the bearer based on the target bitrate, the maximum radio resource usage, and the estimated spectral efficiency. A corresponding network node and a corresponding computer program are also provided.

Abstract: Embodiments herein relate to a method performed by a first radio network node (12) for enabling a mobility procedure of a wireless device (10) between the first radio network node (12) and a second radio network node (13) in a wireless communication network (1). The first radio network node (12) determines to delegate a handover decision for the wireless device (10) to the second radio network node (13). The first radio network node (12) transmits an indication to the second radio network node (13), which indication indicates a delegation of the handover decision for the wireless device (10) thereby enabling the mobility procedure of the wireless device (10).