Abstract: The present disclosure relates to a method performed by a network node in a communications system for handling PUCCH resources in a frequency spectrum. The network node categorizes the PUCCH resources into a plurality of congestion level groups. The network node assigns the categorized PUCCH resources to different parts of the frequency spectrum. The first congestion level group is assigned to a first part of the frequency spectrum and the PUCCH resources categorized in the second congestion level group are assigned to a second part of the spectrum. The network node determines that the PUCCH resources categorized in the first congestion level group and assigned to the first part of the frequency spectrum should be used by the UE prior to using the PUCCH resources categorized in the second congestion level group and assigned to the second part of the frequency spectrum.

Abstract: Embodiments herein relate to a method implemented by a wireless communication device. The wireless communication device transmits data to a radio node of a wireless communication network. The wireless communication device monitors for a positive acknowledgement or a negative acknowledgement of the data from the radio node. The wireless communication device retransmits the data to the radio node when said monitoring indicates reception of a negative acknowledgement of the data. The wireless communication device refrains from retransmitting the data to the radio node when said monitoring indicates reception of a positive acknowledgement of the data. The wireless communication device also refrains from retransmitting the data to the radio node when said monitoring indicates neither reception of a positive acknowledgement of the data nor reception of a negative acknowledgement of the data.

Abstract: Embodiments herein relate to a method implemented by a wireless communication device. The wireless communication device transmits data to a radio node of a wireless communication network. The wireless communication device monitors for a positive acknowledgement or a negative acknowledgement of the data from the radio node. The wireless communication device retransmits the data to the radio node when said monitoring indicates reception of a negative acknowledgement of the data. The wireless communication device refrains from retransmitting the data to the radio node when said monitoring indicates reception of a positive acknowledgement of the data. The wireless communication device also refrains from retransmitting the data to the radio node when said monitoring indicates neither reception of a positive acknowledgement of the data nor reception of a negative acknowledgement of the data.

Abstract: The present disclosure provides systems and methods for scheduling transmissions to and/or transmissions from user equipment. The user equipment communicates with a network via a first radio processing function (RPF) and a second RPF. The method includes determining a first aggregate bit rate for the UE. The method provides for sending to the first RPF first aggregate bit rate information (ABRI) for the UE. The first ABRI: 1) indicates that the first aggregate bit rate satisfies a bit threshold condition, 2) indicates that the first aggregate bit rate does not satisfy the condition, or 3) identifies the determined first aggregate bit rate for the UE.

Abstract: Embodiments herein relate to a method implemented by a wireless communication device. The wireless communication device transmits data to a radio node of a wireless communication network. The wireless communication device monitors for a positive acknowledgement or a negative acknowledgement of the data from the radio node. The wireless communication device retransmits the data to the radio node when said monitoring indicates reception of a negative acknowledgement of the data. The wireless communication device refrains from retransmitting the data to the radio node when said monitoring indicates reception of a positive acknowledgement of the data. The wireless communication device also refrains from retransmitting the data to the radio node when said monitoring indicates neither reception of a positive acknowledgement of the data nor reception of a negative acknowledgement of the data.

Abstract: Embodiments herein relate to a method implemented by a wireless communication device. The wireless communication device transmits data to a radio node of a wireless communication network. The wireless communication device monitors for a positive acknowledgement or a negative acknowledgement of the data from the radio node. The wireless communication device retransmits the data to the radio node when said monitoring indicates reception of a negative acknowledgement of the data. The wireless communication device refrains from retransmitting the data to the radio node when said monitoring indicates reception of a positive acknowledgement of the data. The wireless communication device also refrains from retransmitting the data to the radio node when said monitoring indicates neither reception of a positive acknowledgement of the data nor reception of a negative acknowledgement of the data.

Abstract: Disclosed is a method and corresponding devices and computer programs for determining antenna weights for transmissions with punctured signals. The method comprises extracting, from a signal reception model for signals transmitted by at least two communication units, at least one of the communication units transmitting with punctured signals, a signal orthogonality loss quantity introduced by the punctured signals. The method also comprises calculating, based on the extracted signal orthogonality loss quantity, a covariance matrix quantifying the signal orthogonality loss between signals transmitted by the at least two communication units. The method also comprises determining, based on the covariance matrix, antenna weights for data symbols in the signals.

Abstract: Embodiments herein relate to a method implemented by a wireless communication device. The wireless communication device transmits data to a radio node of a wireless communication network. The wireless communication device monitors for a positive acknowledgement or a negative acknowledgement of the data from the radio node. The wireless communication device retransmits the data to the radio node when said monitoring indicates reception of a negative acknowledgement of the data. The wireless communication device refrains from retransmitting the data to the radio node when said monitoring indicates reception of a positive acknowledgement of the data. The wireless communication device also refrains from retransmitting the data to the radio node when said monitoring indicates neither reception of a positive acknowledgement of the data nor reception of a negative acknowledgement of the data.

Abstract: Embodiments herein relate to a method implemented by a wireless communication device (10). The wireless communication device (10) transmits data to a radio node (12) of a wireless communication network (1). The wireless communication device (10) monitors for a positive acknowledgement or a negative acknowledgement of the data from the radio node (12). The wireless communication device (10) retransmits the data to the radio node (12) when said monitoring indicates reception of a negative acknowledgement of the data. The wireless communication device (10) refrains from retransmitting the data to the radio node (12) when said monitoring indicates reception of a positive acknowledgement of the data. The wireless communication device (10) also refrains from retransmitting the data to the radio node (12) when said monitoring indicates neither reception of a positive acknowledgement of the data nor reception of a negative acknowledgement of the data.

Abstract: Disclosed is a method and corresponding devices and computer programs for determining antenna weights for transmissions with punctured signals. The method comprises extracting, from a signal reception model for signals transmitted by at least two communication units, at least one of the communication units transmitting with punctured signals, a signal orthogonality loss quantity introduced by the punctured signals. The method also comprises calculating, based on the extracted signal orthogonality loss quantity, a covariance matrix quantifying the signal orthogonality loss between signals transmitted by the at least two communication units. The method also comprises determining, based on the covariance matrix, antenna weights for data symbols in the signals.

Abstract: A method performed by a node in a wireless communication network of estimating parameters used for determining a signal-to-interference measure at a communication device served by a base station, and a node performing the method. The method comprises acquiring an estimate of channel condition between the communication device and the serving base station, and between the communication device and at least one base station of a neighbouring cell, estimating the signal-to-interference measure using the estimate of the respective channel condition, and acquired output power and Physical Resource Block (PRB) utilization of each of the base stations, and receiving an indication of quality of a channel via which the communication device is served by the base station. The method further comprises determining whether a change in the estimate of the signal-to-interference measure is required based on the indication of channel quality, and updating the estimate of the channel condition.

Abstract: Embodiments herein relate to a method performed by a first transmission point (12) out of at least two transmission points for estimating a channel quality gain of a wireless device (10) served by the first transmission point (12) in a wireless communication network (1). The first transmission point (12) coordinates transmissions with a second transmission point (13) out of the at least two transmission points in the wireless communication network (1). The first transmission point estimates the channel quality gain based on whether a first cell specific reference signal, CRS, configuration of the first transmission point (12) is using radio resources for a first CRS that are colliding or not with radio resources used for a second CRS of a second CRS configuration of the second transmission point (13) in the wireless communication network (1), and a utilization of frequency resources by the second transmission point (13).

Abstract: A network node identifies a fixed periodic pattern to be used for scheduling a half-duplex (HD) user equipment (UE), the fixed periodic pattern defining a sequence of at least one downlink (DL) subframe, then at least one guard period, and then at least one uplink (UL) subframe. The network node then performs DL assignments for the network node according to the fixed periodic pattern and transmits UL grants to the UE according to the fixed periodic pattern.

Abstract: A method performed by a node in a wireless communication network of estimating parameters used for determining a signal-to-interference measure at a communication device served by a base station, and a node performing the method. The method comprises acquiring an estimate of channel condition between the communication device and the serving base station, and between the communication device and at least one base station of a neighbouring cell, estimating the signal-to-interference measure using the estimate of the respective channel condition, and acquired output power and Physical Resource Block (PRB) utilization of each of the base stations, and receiving an indication of quality of a channel via which the communication device is served by the base station. The method further comprises determining whether a change in the estimate of the signal-to-interference measure is required based on the indication of channel quality, and updating the estimate of the channel condition.

Abstract: In certain embodiments, a network node serves a wireless device capable of carrier aggregation involving a primary cell, PCell, and at least one secondary cell, SCell. The network node determines (304) a target quality for the wireless device to achieve with respect to at least the PCell; determines (308) a PCell interruption probability (e.g., probability of missed ACK/NACK in uplink) corresponding to an SCell measurement cycle that can be used by the wireless device for measuring on one or more cells of a secondary component carrier, SCC, with a deactivated SCell; adapts (312) a parameter related to the CA configuration to make it feasible to achieve the target quality, the parameter adapted based on a comparison between the target quality and the PCell interruption probability; and configures (316) the wireless device with the adapted parameter.

Abstract: Disclosed is a network node and a method performed by a network node in a wireless communication network for determining signal to noise ratio of a signal received at a receiver from a first mobile station, which signal may include both noise and interference. The method comprises obtaining a plurality of measured noise and interference power values, IN values, of signals received at the receiver in one or more frequency sub-bands, determining IN for a lowest X percentile of the measured IN values, and applying the determined IN for the lowest X percentile as a measure of the noise. The method further comprises obtaining a measured signal strength value for a signal received at the receiver from the first mobile station, and determining SNR for the signal from the first mobile station by applying the determined noise measure.

Abstract: Embodiments herein relate to a method performed by a first transmission point (12) out of at least two transmission points for estimating a channel quality gain of a wireless device (10) served by the first transmission point (12) in a wireless communication network (1). The first transmission point (12) coordinates transmissions with a second transmission point (13) out of the at least two transmission points in the wireless communication network (1). The first transmission point estimates the channel quality gain based on whether a first cell specific reference signal, CRS, configuration of the first transmission point (12) is using radio resources for a first CRS that are colliding or not with radio resources used for a second CRS of a second CRS configuration of the second transmission point (13) in the wireless communication network (1), and a utilization of frequency resources by the second transmission point (13).

Abstract: A network node identifies a fixed periodic pattern to be used for scheduling a half-duplex (HD) user equipment (UE), the fixed periodic pattern defining a sequence of at least one downlink (DL) subframe, then at least one guard period, and then at least one uplink (UL) subframe. The network node then performs DL assignments for the network node according to the fixed periodic pattern and transmits UL grants to the UE according to the fixed periodic pattern.

Abstract: A network node and a method performed thereby for controlling operation of a low power node are provided. The network node and the low power node are operable in a wireless communication network, wherein the low power node has at least two modes of operation, an active mode where the low power node is in full operation, and a passive mode where the low power node is discoverable by wireless devices in the network but not available for initial access or incoming handovers. The method comprises receiving (210) a measurement report from at least one wireless device, the measurement report comprising a measurement related to the low power node; and determining (220) the operation mode of the low power node based on the received measurement report. The method further comprises when the current operation mode of the low power node is passive and the determined operation mode is active, changing (230) the operation mode of the low power node to active mode.

Abstract: A method for selecting wireless communication devices for measurement configuration in a wireless communication network comprises a step of obtaining at least one report on signal strength and/or signal quality from a wireless communication device in the wireless communication network. The method further comprises a step of determining whether or not to select the wireless communication device for measurement configuration, where the measurement configuration comprises configuring the wireless communication device to provide measurement reports on received power from serving cells and neighbour cells in the wireless communication network, and where the step of determining is based on the at least one obtained report on signal strength and/or signal quality.