Abstract: Systems and methods are provided for adaptive mini-slot management in a network, including an element management control unit comprising a set of distribution and central units (DU/CU) to monitor power and channel traffic at a plurality of cell sites in the network; a scheduler unit for user equipment (UE) to enable and disable a set of mini-slots in a downlink (DL) pattern and an uplink (UL) pattern including at least two concatenated patterns jointly repeated with periodicity in a slot configuration period for new radio (NR) communications by users at cell sites in the network; and in response to a request by a user, the scheduler unit reserves a number of mini-slots for use in each slot configuration period wherein a reserved slot number is responsive to at least one of a condition of an AC power outage, and reduced channel traffic based on data received by the DU/CU about the condition.

Abstract: An apparatus for a wireless network access device includes a first communication interface for wirelessly communicating with a wireless communication device. The apparatus includes a second communication interface for communicating with a network gateway device. The apparatus includes a control module configured to receive a first request for wireless uplink resources from the wireless communication device via the first communication interface. The control module is configured to provide a second request for wired uplink resources to the gateway device via the second communication interface based on the first request for wireless uplink resources. The second request for wired uplink resources is related to uplink resources of a wired uplink channel of the gateway device.

Abstract: A communications network controller module for storing media data in memory is disclosed. The module comprises a media access controller and a message handler. The message handler is configured, in response to receiving a frame comprising frame data from the media access controller, to identify a frame type for the frame, to identify a target queue in dependence upon the frame type, the target queue comprising a series of data areas in memory reserved for storing frames of the frame type, to obtain a current descriptor address of a current descriptor for the target queue, the current descriptor comprising a descriptor type field, a descriptor pointer field and a descriptor data size field, and to obtain an address in the series of data areas, to store a part of the frame data at the data area address.

Abstract: The method includes: receiving, by a second transmit end, policy information sent by a first transmit end, where the second transmit end belongs to a second BSS, the first transmit end is a transmit end that is in a first basis service set and that transmits data by using a first link, and the policy information is used to indicate a condition that the second transmit end needs to satisfy to transmit data by using a second link, or used to indicate whether the second transmit end is allowed to transmit data by using a second link; and determining, by the second transmit end based on the policy information, whether to transmit data by using the second link. According to the wireless communication method, a spatial reuse transmission policy can be adjusted dynamically based on an actual situation of a current network. This improves a system throughput.

Abstract: A method includes: obtaining user equipment distribution information of a beam domain, where there are at least two beam domains, and the beam domain is a vertical area in a physically vertical dimension of a cell coverage area; determining information about a concentrated beam domain based on the user equipment distribution information, where the concentrated beam domain is a beam domain in which a quantity of covered user equipments exceeds a quantity threshold; and compared with information about a historical concentrated beam domain, if the information about the concentrated beam domain satisfies a preset condition, adjusting a broadcast beam domain based on the information about the concentrated beam domain, so that a main lobe direction of the broadcast beam domain is adjusted to a beam domain corresponding to the concentrated beam domain.

Abstract: A method may include obtaining multiple first parameters associated with a wireless network. The first parameters include one or more environment-specific parameters and one or more packet-specific parameters. The method may include generating a metric from a combination of the first parameters. The method may include, in response to determining to adjust the performance of the wireless network based on the metric, determining one or more operating parameters to adjust. The method may include adjusting the performance of the wireless network by adjusting the one or more operating parameters.

Abstract: According to one embodiment, a wireless communication device includes: controlling circuitry configured to set at least one of: a first transmission prohibition period for a first network to which the wireless communication device belongs; or a second transmission prohibition period for a second network, and to determine, when a first frame addressed to another device is received in a case that the first transmission prohibition period is not set and the second transmission prohibition period is set, a state of a wireless medium based on comparing a reception level of the first frame with a threshold defined corresponding to one of the first network and the second network, to which a sender of the first frame belongs.

Abstract: Provided are a method and apparatus for transmitting and receiving a downlink signal for supporting effective multiplexing between data traffic having mutually different QoS requirements in a next generation/5G wireless access network (“New Radio” (NR)) for which discussion has begun in 3GPP. The method may include receiving configuration information for receiving downlink pre-emption indication data from a base station; monitoring the downlink pre-emption indication data based on the configuration information; and receiving the downlink pre-emption indication data through a multicast or unicast signal, wherein the downlink pre-emption indication data indicates superposed radio resources for providing a first service and for providing a second service.

Abstract: In one embodiment, a method includes receiving an association request from a nearby electronic device via a local wireless network connection, transmitting a position coordinate associated with a first node via the local wireless network connection to the nearby electronic device, receiving location information of one or more peer nodes from the nearby electronic device, adding the location information of the one or more peer nodes into a log included in the first node, and determining that at least two nodes are within Line-of-Sight (LOS) communication range of the first node based on the log, wherein the at least two nodes are included in the one or more peer nodes.

Abstract: The present disclosure provides a signal interference avoidance method and a network device, so as to prevent the occurrence of a self-interference for a UE. The signal interference avoidance method includes, when the self-interference occurs for the UE connected concurrently to a first network device and a second network device, transmitting first interference avoidance indication information to the second network device. The first interference avoidance indication information is used to enable the second network device to communicate with the UE through a first time-domain resource and/or a first frequency-domain resource. The first interference avoidance indication information includes identification information about the UE.

Abstract: Methods and apparatus are described for implementing a wireless local area network (WLAN) Proximity Service (ProSe) connection in a WLAN ProSe capable wireless transmit receive unit (WTRU). The WLAN ProSe capable WTRU requests an establishment of a WLAN ProSe connection with other WLAN ProSe capable WTRU(s), where a ProSe discovery process determines the presence of other WLAN ProSe capable WTRU(s). Configuration information is received, via a non-access stratum or a radio resource control message, from a network node to facilitate the WLAN ProSe connection to the other WLAN ProSe capable WTRU(s). The configuration information includes one of a WLAN ID of the other WLAN ProSe capable WTRU(s), a medium access control ID of the other WLAN ProSe capable WTRU(s), a WLAN access point Service Set Identification (SSID) or Basic SSID, a frequency or channel number, a beacon interval, and timing information.

Abstract: According to an embodiment of the present invention, a method by which a base station receives a measurement report in a wireless communication system using a carrier integration technique comprises the steps of: generating a cell list for a second cell according to whether the second cell to be added from a first cell belongs to the same cell group as the first cell; transmitting, to a terminal, a measurement report command including configuration information related to the cell list; and receiving, from the terminal, a measurement report of the second cell on the basis of the configuration information, if the second cell belongs to the same cell group as the first cell.

Abstract: Methods, systems, and devices for wireless communications are described. A user equipment (UE) may receive, from a base station and while operating in a dual connectivity mode, an uplink grant in a first subframe of a set of subframes. The uplink grant may schedule transmission of uplink data. The UE may determine a second subframe of the set of subframes to transmit the uplink data and a third subframe of the set of subframes to monitor for feedback associated with transmission of the uplink data. The second subframe and the third subframe may be determined based on combinations of a primary cell time division duplex (TDD) uplink-downlink (UL-DL) configuration and a DL-reference UL-DL configuration. each of the combinations may have at least three uplink transmission subframes or three downlink monitoring subframes within a ten-subframe cycle. The UE may thus perform wireless communications in accordance with the transmission timelines.

Abstract: Example signal receiving methods and apparatus are described. One example method includes receiving a time-domain signal sent by a sending device. The time-domain signal is replicated to obtain N time-domain signals. N window functions are configured, where the N window functions are in a one-to-one correspondence with the N time-domain signals. An operation is performed on each of the N time-domain signals based on a corresponding window function to obtain N windowed time-domain signals. The N windowed time-domain signals are separately converted to obtain N frequency-domain signals. An RB corresponding to an interference frequency is determined. One or more RBs are selected from each of the N frequency-domain signals and are arranged in sequence based on indexes to obtain a target frequency-domain signal.

Abstract: Embodiments described herein relate to methods and apparatus for performing cell measurements. A method in a wireless device comprises receiving a first control message from a base station instructing the wireless device to transition from a first mode of operation to a second mode of operation; and responsive to the control message comprising information relating to at least one first cell measurement parameter, performing a cell measurement according to the at least one first cell measurement parameter.

Abstract: The present disclosure provides a radio link monitoring method and a UE. The radio link monitoring method includes: determining configuration information for performing a radio link monitoring operation on one or more BWPs of a system bandwidth; and performing the radio link monitoring operation on one or more target BWPs in accordance with the configuration information.

Abstract: Example methods are provided a first host to perform packet flow monitoring in a software-defined networking (SDN) environment. One example may comprise the first host receiving a request to monitor a packet flow and triggering a telemetry process based on a predetermined event associated with the packet flow. The method may also comprise: in response to the triggered telemetry process and detecting an egress packet associated with the packet flow, generating an encapsulated packet by encapsulating the egress packet with an outer header; configuring a telemetry instruction in the outer header; and sending the encapsulated packet with the telemetry instruction to the second host via one or more intermediate network devices. The telemetry instruction may be configured to cause the one or more intermediate network devices to add, to the encapsulated packet, metadata associated with a network state experienced by the encapsulated packet.

Abstract: In one illustrated example, automated or semi-automated system operations for Massive IoT (MIoT) deployment may involve the automatic assignment of external IDs, subscriber IDs (e.g. IMSIs), and mobile network IDs (e.g. MSISDNs) to IoT devices of a group, followed by the provisioning of assigned identities at the relevant network nodes and the IoT devices themselves. The process may continue seamlessly with network slice orchestration for the creation of a network slice instance (NSI) and the provisioning of its associated Network Slice Selection Assistance Information (NSSAI) and NSI ID at the relevant network nodes. Network Slice Selection Policies (NSSP) may be derived and sent to a policy function and subsequently to IoT devices of the group. Signaling efficiency may be achieved by performing operations on a group basis.

Abstract: Methods, systems, and apparatus, including computer programs encoded on computer storage media for characterizing radio propagation channels. One method includes receiving, at a first modem, a first unit of communication over a radio frequency (RF) communication path from a second modem, wherein the first modem and the second modem process information for RF communications. The first modem identifies fields in the first unit of communication, the fields used to analyze the RF communication path. The first modem extracts data from the fields. The first modem accesses a channel model for approximating a channel representative of the RF communication path from the first modem to the second modem, wherein the channel model includes machine learning models. The first modem trains the channel model using the extracted data. The first modem applies the trained channel model to simulate a set of channel effects associated with the communication path.

Abstract: A method of determining an ambiguous period, a terminal and a network-side device are provided. The method includes: determining, by a terminal, the ambiguous period, where the ambiguous period corresponds to a processing time for a PDCCH, or the ambiguous period corresponds to a processing time for an MAC CE; and determining by the terminal, according to a control message which is received, whether to send an uplink signal at a current time, where a difference between a receiving time of the control message and the current time is greater than or equal to the ambiguous period.