Systems and methods for managing a network are disclosed. For example, systems and methods are disclosed for selectively disabling and/or otherwise configuring devices to avoid interference, overlapping service, and/or the like. Signal information for nearby devices can be detected and analyzed to determine device configuration settings.

Systems and methods for managing a network are disclosed. For example, systems and methods are disclosed for selectively disabling and/or otherwise configuring devices to avoid interference, overlapping service, and/or the like. Signal information for nearby devices can be detected and analyzed to determine device configuration settings.

Methods and apparatuses are described herein for accessing an unlicensed spectrum using portions of a carrier's bandwidth (BW). For example, a wireless transmit receive unit (WTRU) may access a serving cell through an initial bandwidth part (BWP). The WTRU may be configured with a plurality of BWPs within an unlicensed frequency spectrum. The WTRU may then determine any of at least one monitoring period and at least one offset per each BWP. The WTRU may then monitor the BWPs based on any of the at least one monitoring period and the at least one offset. The WTRU may receive at least one signal from the serving cell. The signal may be at least one of a downlink control information (DCI), a synchronization signal block (SSB), a reference signal, or a preamble.

Methods and apparatuses are described herein for accessing an unlicensed spectrum using portions of a carrier's bandwidth (BW). For example, a wireless transmit receive unit (WTRU) may access a serving cell through an initial bandwidth part (BWP). The WTRU may be configured with a plurality of BWPs within an unlicensed frequency spectrum. The WTRU may then determine any of at least one monitoring period and at least one offset per each BWP. The WTRU may then monitor the BWPs based on any of the at least one monitoring period and the at least one offset. The WTRU may receive at least one signal from the serving cell. The signal may be at least one of a downlink control information (DCI), a synchronization signal block (SSB), a reference signal, or a preamble.

Apparatuses, methods, and systems are disclosed for managing a C2 communication mode of operation. One apparatus includes a transceiver supporting a network interface that receives an application request to manage an operation mode of C2 communication for a first UAS. Here, the first UAS comprises a first UAV and a first UAV-C. The network interface receives a first report from an application of the first UAS, where the first application is located in one of the first UAV and the first UAV-C. The apparatus includes a processor that determines to switch the operation mode of C2 communication for the first UAS based on the received first report and transmits, via the network interface, a C2 communication switching instruction to the first UAS.

Apparatuses, methods, and systems are disclosed for managing a C2 communication mode of operation. One apparatus includes a transceiver supporting a network interface that receives an application request to manage an operation mode of C2 communication for a first UAS. Here, the first UAS comprises a first UAV and a first UAV-C. The network interface receives a first report from an application of the first UAS, where the first application is located in one of the first UAV and the first UAV-C. The apparatus includes a processor that determines to switch the operation mode of C2 communication for the first UAS based on the received first report and transmits, via the network interface, a C2 communication switching instruction to the first UAS.

A mechanism for distributing traffic between a macro access node and a micro access node in a heterogeneous network is described. The method, performed by a network node controller, comprises obtaining information of current traffic load in the heterogeneous network. The method further comprises distributing the traffic between the macro access node and the micro access node by adjusting cell shaping beams of the macro access node as a function of the current traffic load.

A computer implemented method allocates wireless network and adaptive video streaming resources in environments with high device density. The network has one or more access points and at least one user device. The stages of the method include obtaining the information from radio access network or video service telemetry; generating a resource allocation list between each user device and at least one channel with an associated representation index, distributing the resource allocation list, performing at least one handover and at least one video rate recommendation.

A method performed by a child Integrated Access Backhaul (IAB) node that comprises a IAB-Mobile Termination, IAB-MT includes transmitting, to a network node operating as a parent node with respect to the child IAB node, a Radio Resource Control (RRC) setup request message comprising an IAB indication that indicates that the transmission to the network node is by the child IAB node comprising the IAB-MT.

A method performed by a child Integrated Access Backhaul (IAB) node that comprises a IAB-Mobile Termination, IAB-MT includes transmitting, to a network node operating as a parent node with respect to the child IAB node, a Radio Resource Control (RRC) setup request message comprising an IAB indication that indicates that the transmission to the network node is by the child IAB node comprising the IAB-MT.