Abstract: Exemplary embodiments include methods for receiving one or more physical downlink control channels (PDCCHs) using a selectable number of available antennas and receive chains. Embodiments can include receiving a configuration associated with one or more PDCCHs, wherein the configuration includes, for each PDCCH, a search space comprising a plurality of PDCCH candidate. Embodiments can include selecting a first number of antennas and receive chains for PDCCH reception, wherein the first number comprises the minimum number of the available antennas and receive chains needed to meet one or more PDCCH performance metrics. Embodiments can include selecting, for PDCCH reception, either the first number of antennas and receive chains, or a greater second number of antennas and receive chains. Embodiments can include receiving the PDCCH using the selected number of antennas and receive chains, Other embodiments include UEs configured to perform operations corresponding to the exemplary methods.

Abstract: Methods and apparatus in a communication system for search space switching are disclosed. A method performed by a network node in a communication system that includes more than one search space group includes generating a downlink control information, DCI, message, and transmitting the DCI message on a downlink control channel, wherein the DCI message causes a user equipment, UE, to switch from monitoring a first search space group to monitoring a second search space group in response to successfully decoding the DCI message. A method performed by a UE in the communication system, wherein the UE is configured to monitor a first search space group, includes receiving a DCI message on a downlink control channel; and switching from monitoring the first search space group to monitoring a second search space group in response to successfully decoding the DCI message.

Abstract: Methods and apparatus are provided. In an example aspect, a method in a wireless device of transmitting data on a first channel in unlicensed spectrum is provided. The method comprises determining that a transmitter is transmitting a first signal on the first channel in unlicensed spectrum, transmitting a second signal to cause the transmitter to cease transmitting the signal, and transmitting the data on the first channel in unlicensed spectrum.

Abstract: In a wireless communication system, an access point (10) contends with at least one further access point (10) for a set of transmission resources. In response to winning contention for the set of transmission resources, the access point (10) shares at least a subset of the transmission resources with the at least one further access point (10). In addition, the access point (10) exchanges information with the at least one further access point (10). Based on the exchanged information, the access point (10) coordinates wireless transmissions on the shared subset of transmission resources.

Abstract: A method is disclosed—for a wireless communication device served by a network access node—of keeping a time reference at the wireless communication device. The wireless communication device is configured for operation according to at least first and second operational modes, the second operational mode having lower power consumption than the first operational mode. The method comprises (during operation according to the first operational mode) determining (for the second operational mode) desired timings of timing signals to be transmitted from the network access node, and transmitting a request signal to the network access node, wherein the request signal carries information of the desired timings of timing signals to be transmitted from the network access node. In some embodiments, the method further comprises receiving a response signal from the network access node, wherein the response signal carries information of actual timings of timing signals to be transmitted from the network access node.

Abstract: A technique of selectively transmitting a skip signal indicative of skipping a downlink control channel from an access in node (100; 600; 712; 820) to a radio device (791; 792; 830) is provided. As to a method aspect, a method (200) of selectively transmitting a skip signal indicative of skipping a downlink control channel comprises or initiates determining (202), for the radio device (791; 792; 830), whether a criterion for at least one of skipping the downlink control channel and transmitting the skip signal indicative of skipping the downlink control channel is fulfilled. The method (200) further comprises or initiates transmitting (204), to the radio device (791; 792; 830), the skip signal indicative of skipping the downlink control channel if the criterion has been determined (202) to be fulfilled for a predefined duration.

Abstract: A broadcast signal transmission occurs concurrently with device-specific, directional transmissions but without substantially interfering with the directional transmissions, based on transmitting the broadcast signal in the null spaces of the directional transmissions. Specifically, transmission of the broadcast signal relies on beamforming precoder values formed from one or more orthonormal basis vectors for the null space of a channel estimate matrix representing the channels between a multi-element antenna array and the wireless devices targeted by the device-specific transmissions. The approach concentrates most of the broadcast signal energy for each subcarrier on a single antenna element for good broadcast-signal coverage while still yielding a beamforming solution that substantially avoids broadcast-signal interference at the devices targeted for directional transmission.

Abstract: A method, system, network node and wireless device are disclosed. In one or more embodiments, A network node configured to communicate with a wireless device is provided. The network node includes processing circuitry configured to: determine a short DRX configuration based at least on a delay value constraint associated with the wireless device, and transmit an indication of the short DRX configuration and a long DRX configuration where the short DRX configuration corresponds to a shorter cycle length than a cycle length of the long DRX configuration.

Abstract: Embodiments include methods for a user equipment (UE) to perform different operations based on detection of wake-up signal (WUS) transmissions from a network node in a radio access network (RAN). Such methods include determining whether a WUS transmission, from the network node, is detected during a particular WUS monitoring occasion (WMO). Such methods also include, based on determining that the WUS is detected during the particular WMO, performing one or more first operations during a first time period associated with the particular WMO; and based on determining that the WUS is not detected during the particular WMO, performing one or more second operations during a second time period. Various first and second operations can be performed, with the first and second operations differing in some manner. The first and second time periods can be the same or different. Embodiments also include complementary methods performed by a network node.

Abstract: Embodiments include methods, performed by a user equipment (UE), for communication with a network node in a radio access network (RAN). Such methods include receiving, from the network node, an indication that a minimum scheduling offset, between a scheduling physical downlink control channel (PDCCH) and a signal or channel scheduled via the scheduling PDCCH, will change after a first duration. Such methods also include subsequently monitoring, during the first duration, for a scheduling PDCCH based on a first operating configuration; and in response to the end of the first duration, monitoring for a scheduling PDCCH based on a second operating configuration. The first duration can be related to time required, by the UE, to switch from the first to the second operating configuration. Embodiments also include UEs configured to perform such methods.

Abstract: A method in a User Equipment (UE), the method comprising determining one or more parameters of an expected signal; calculating a performance metric for each of a plurality of receiver modes of the UE, based on the determined one or more parameters; selecting a first receiver mode among the plurality of receiver modes based on the calculated performance metrics.

Abstract: A system, network node and wireless device a provided. The wireless device receives, during an active time, downlink control information, DCI, having a predefined DCI format from the network node. The predefined DCI format includes at least one bit indicating that the DCI includes a go-to-sleep, GTS, indication. The wireless device is caused to enter a sleep state based at least in part on the GTS indication.

Abstract: A method by a wireless device (510) configured for Discontinuous Reception, DRX, includes monitoring (1602) for a first wakeup signal, WUS, during a first WUS monitoring occasion. In response to the wireless device detecting the first WUS during the first WUS monitoring occasion, the wireless device monitors (1604) a downlink control channel during a downlink control channel monitoring occasion associated with the detected first WUS and abstains (1604) from monitoring fora second WUS in a second WUS monitoring occasion based on a condition.

Abstract: A method, system and apparatus are disclosed. In one or more embodiments, a network node configured to communicate with a wireless device (WD) is provided. The network node is configured to, and/or comprising a radio interface and/or comprising processing circuitry configured to signal a configuration to the WD to cause the WD to transition to or remain in an RRC Inactive state if a predefined criterion is met.

Abstract: Exemplary embodiments include methods for receiving one or more physical downlink control channels (PDCCHs) using a selectable number of available antennas and receive chains. Embodiments can include receiving a configuration associated with one or more PDCCHs, wherein the configuration includes, for each PDCCH, a search space comprising a plurality of PDCCH candidate. Embodiments can include selecting a first number of antennas and receive chains for PDCCH reception, wherein the first number comprises the minimum number of the available antennas and receive chains needed to meet one or more PDCCH performance metrics. Embodiments can include selecting, for PDCCH reception, either the first number of antennas and receive chains, or a greater second number of antennas and receive chains. Embodiments can include receiving the PDCCH using the selected number of antennas and receive chains, Other embodiments include UEs configured to perform operations corresponding to the exemplary methods.

Abstract: There is disclosed a method of operating a radio node in a wireless communication network. The method includes transmitting pulse-shaped signaling based on a pulse-shaped waveform using a transmission power, the transmission power being based on an Error Vector Magnitude (EVM) parametrisation for pulse-shaped signaling. The disclosure also pertains to related devices and methods.

Abstract: There is disclosed a method of operating a radio node in a wireless communication network. The method includes transmitting pulse-shaped signaling based on a pulse-shaped waveform using a transmission power, the transmission power being based on an Error Vector Magnitude (EVM) parametrisation for pulse-shaped signaling. The disclosure also pertains to related devices and methods.

Abstract: A broadcast signal transmission occurs concurrently with device-specific, directional transmissions but without substantially interfering with the directional transmissions, based on transmitting the broadcast signal in the null spaces of the directional transmissions. Specifically, transmission of the broadcast signal relies on beamforming precoder values formed from one or more orthonormal basis vectors for the null space of a channel estimate matrix representing the channels between a multi-element antenna array and the wireless devices targeted by the device-specific transmissions. The approach concentrates most of the broadcast signal energy for each subcarrier on a single antenna element for good broadcast-signal coverage while still yielding a beamforming solution that substantially avoids broadcast-signal interference at the devices targeted for directional transmission.