Aspects of the subject disclosure may include, for example, attaching a mobile device to an initial bearer at a base station of a mobility network, monitoring a performance parameter for communication by the mobile device on the initial bearer, requesting, by the mobile device, information about other bearers at the base station of the mobility network, wherein the requesting is responsive to the performance parameter failing to exceed a predetermined performance threshold, receiving at the mobile device, network information about other bearers at the base station of the mobility network, the network information including current capacity information for the other bearers, selecting, by the mobile device, a selected alternative bearer based on the information about other bearers, and communicating, to the mobility network, a user equipment (UE) capabilities message identifying the selected alternative bearer and omitting the initial bearer to change bearers to obtain better communication performance at the mobile device. Other embodiments are disclosed.

A system for managing QoS provided to user equipment included in an unmanned autonomous vehicle (UAV) by a wireless communication system comprising base stations, each providing radio coverage over a corresponding cell. The system comprises one or more computing devices to execute: a setup module to receive data identifying a predetermined path, and send a request of allocating dedicated radio resources for wireless links, the requested dedicated radio resources being expected sufficient to guarantee a QoS not lower than a predefined QoS value, and a QoS verify module to receive QoS data indicative of measured QoS and position data indicative of an actual position of the UAV during traveling, and verify whether the QoS actually during travelling is not lower than the predefined QoS value of the received QoS data and verify whether an actual path followed by the UAV corresponds to the predetermined path of the received position data.

Estimating transmit symbol vectors transmitted in an overloaded communication channel includes receiving a signal represented by a received signal vector, the received signal vector corresponding to a superposition of signals representing transmitted symbols selected from a constellation of symbols and transmitted from one or more transmitters.

One embodiment according to the present specification relates to a method for performing low latency communication. A transmitting STA can transmit a low latency communication notification frame including information related to a section for low latency communication. The transmitting STA and a receiving STA can perform low latency communication in the section for low latency communication on the basis of the low latency communication notification frame. Afterward, the transmitting STA can transmit a low latency communication termination frame. The transmitting STA and the receiving STA can terminate the section for low latency communication on the basis of the low latency communication termination frame.

A method performed by a system having a plurality of base station systems, each base station system comprising a baseband unit, BBU and a radio unit, RU interconnected via a fronthaul connection that is shared between the base station systems. Fronthaul capacity information on transmission capacity of the shared fronthaul connection and information on required capacity for transmission and/or reception of wireless signals by the RU of the respective base station system are obtained. Time unit transmission restrictions for the respective base station system is determined based on the fronthaul capacity information and on the information on required capacity, which time unit transmission restrictions results in fronthaul usage below the transmission capacity of the part of the fronthaul connection. Information on the determined time unit transmission restrictions is sent to the BBU of the respective base station system.

Embodiments of the present disclosure provide a medium access control protocol data unit (MAC PDU) processing method, a terminal and a medium. The method includes: a terminal determining a preorganized MAC PDU that needs to be transmitted on a subsequent resource; updating, with latest uplink control information, content of a media access control control element (MAC CE) in an MAC subPDU corresponding to the MAC CE in the preorganized MAC PDU.

Disclosed are a communication technique which merges, with IoT technology, a 5G communication system for supporting a data transmission rate higher than that of a 4G system, and a system therefor. The present disclosure can be applied to intelligent services (for example, smart homes, smart buildings, smart cities, smart cars or connected cars, healthcare, digital education, retail, security- and safety-related services, and the like) on the basis of 5G communication technology and IoT-related technology. Disclosed are a method and apparatus for driving a PDCP layer apparatus during data decompression failure in a next-generation mobile communication system.

Methods and apparatuses for facilitating extension of the duration of a target wake time (TWT) service period (SP) for TWT operation of wireless devices in a wireless local area network (WLAN). A station (STA) device comprises a transceiver and a processor operably coupled to the transceiver. The transceiver is configured to establish a TWT schedule with an access point (AP), the TWT schedule having a TWT SP with a duration that ends at a nominal SP end time, and to remain in an awake state for the duration of the TWT SP. The processor is configured to determine to extend the duration of the TWT SP to a new SP end time that is after the nominal SP end time.

A method, apparatus, and computer program product provide for generating and providing a signaling indicator to manage quality of service notifications in a network. In the context of a method, the method receives a signaling indicator from a user device. The signaling indicator includes data associated with one or more preferences of the user device. The method further receives a quality of service notification associated with the user device. The method also determines, based on the signaling indicator, whether to provide the quality of service notification to the user device.

A multi-band network node has selectable backhaul/fronthaul configurations. Network nodes provide multi-band operation to take advantage of higher Internet speeds and to support lower latency (> 2 Gbps, < 4 ms latency) applications. A greater Wi-Fi device count (capacity) is supported by implementing communication over additional bands. Increased bandwidth is made available between connected nodes by selectively combining backhaul throughputs. Hardware quality-of-service (QoS) is provided by splitting traffic flows for low latency and data applications. Network coverage is extended by dynamic assignment of backhaul connections and by configuring unused backhauls as fronthauls.