Abstract: This document describes techniques and devices for dynamic capability reporting based on position. A user equipment (UE) determines its current radio capability responsive to detecting a change in its position. If the current radio capability at a current position differs from a previous radio capability at a previous position, the UE modifies its radio capability based on the current position and informs a wireless communication network of the modification. The UE can inform the wireless communication network of this radio capability change using a tracking area update (TAU) message, a radio-link failure message, a reconfiguration failure message, or an attach-procedure message. The dynamic capability reporting enables the UE to change its radio capability as it moves to different positions that have different levels of network coverage within a same tracking area (TA) or a same radio access network (RAN) notification area.

Abstract: This document describes techniques and apparatuses for distributed network cellular identity management. In particular, a distributed-network cellular-identity-management (DNCIM) server includes a lookup table that stores and relates together a user-equipment (UE) public key associated with a UE private key, a core-network (CN) public key associated with a CN private key, and a subscriber identity. Using the DNCIM server, the UE and an authentication server respectively generate two different (e.g., asymmetric) cipher keys based on the UE private key and the CN public key, and the UE public key and the CN private key. The UE and the authentication server can also authenticate one another by referencing information in the lookup table of the DNCIM server. Using these cipher keys, the UE and the authentication server can establish secure communications with each other.

Abstract: This document describes methods, devices, systems, and means for enhanced beam searching for an active coordination set. A user equipment (110) receives an active-coordination-set beam-sweep (602) including multiple time slots (610), each of the multiple time slots including one or more candidate beams. The user equipment (110) determines a respective link-quality metric for each of the received one or more candidate beams in each of the time slots. Based on the link-quality metrics, the user equipment (110) selects the one or more candidate beams in a time slot (610) to use for wireless communication. The user equipment (110) transmits a beam-acquired indication (620) at a first time offset (604) after the time slot (610) in which the selected one or more candidate beams are received, the transmitting directing the base stations (120) to use the selected one or more candidate beams for the wireless communication.

Abstract: This document describes techniques and systems that enable user-equipment-initiated cancelation of a base station downlink transmission. The techniques and systems allow a user equipment (UE) to generate a downlink transmission cancelation request (DTCR) and send the DTCR to a base station to cancel or suspend an ongoing or scheduled downlink (DL) transmission from the base station. The UE can detect trigger events that can indicate that the DL transmission should be canceled or suspended. The UE can transmit the DTCR to the base station using a variety of techniques, including a physical uplink shared channel transmission or using a physical uplink control channel operation. These techniques allow the UE to cancel or suspend a DL transmission during the transmission or prior to a scheduled transmission, which can enable the UE to quickly mitigate adverse operating conditions such as excessive RF interference or low battery capacity.

Abstract: This document describes methods, devices, systems, and means for user-equipment-coordination-set (404) selective participation in which a coordinating user equipment (111) determines which user equipments in the user-equipment-coordination-set (404) participate in a joint communication with a base station (121). The coordinating user equipment (111) receives an indication from the base station (121) specifying multiple user equipments to include in the user-equipment-coordination set (702) and determines a first subset of the multiple user equipments to participate in the joint communication with the base station (121) (704). The coordinating user equipment (111) transmits one or more joint-communication-selection messages to the first subset of the multiple user equipments that directs the first subset of the multiple user equipments to participate in the joint communication with the base station (121) (706).

Abstract: This document describes methods, devices, systems, and means for user-equipment-coordination-set (404) control aggregation that facilitates more efficient control-plane signaling in comparison to conventional wireless communication systems. Overhead for control-plane signaling is reduced by communicating reports and control commands for the multiple user equipments (110) in the user-equipment-coordination-set (404) in a single message instead of communicating a single control message for each user equipment (110). Additionally, the user-equipment-coordination-set (404) uses joint-reception and joint-transmission, to increase the reliability of communicating reports and control commands, especially in the case of challenging radio communication conditions between a base station (121) and an individual UE (110) located near the edge of a cell provided by the vase station.

Abstract: Techniques and apparatuses are described for enabling base station-user equipment messaging regarding deep neural networks. A network entity (base station 121, core network server 320) determines a neural network formation configuration (architecture and/or parameter configurations 1208) for a deep neural network (deep neural network(s) 604, 608, 612, 616) for processing communications transmitted over the wireless communication system. The network entity (base station 121, core network server 302) communicates the neural network formation configuration to a user equipment (UE 110). The user equipment (UE 110) configures a first neural network (deep neural network(s) 608, 612) based on the neural network formation configuration. In implementations, the user equipment (UE 110) recovers information communicated over the wireless network using the first neural network (deep neural network(s) 608, 612).

Abstract: The present disclosure describes methods, devices, systems, and procedures for detecting a proximity of an object (301) in a near-field region of an electromagnetic field of a transmitting antenna array (204; 304; 404) using a voltage standing wave ratio (VSWR). In aspects, a forward signal for transmission by the antenna elements (308) is generated, at least one VSWR detector (210; 310) coupled to the antenna array (204; 304; 404) measures a power of the forward signal, the forward signal is transmitted, the at least one VSWR detector (210; 310) measures a power of a reflected signal, and the VSWR detector (210; 310) calculates a VSWR. Detected changes in the calculated VSWR are then utilized to detect object (301) proximity in the near-field region. Beamforming weights may be applied to the forward signal and a machine-learned model can be utilized to detect object (301) proximity in the near-field region.

Abstract: A high-altitude platform (HAP) node provides communication service during an emergency. The HAP node uses a first network to provide communication services for handling calls initiated by at least one user equipment (UE). The HAP node detects that an emergency disruption has occurred that prevents the use of the first network. In response to detecting the occurrence of the emergency disruption, a mobile terminal (MT) in the HAP node searches for a second network able to accept emergency calls. The HAP node determines whether the second network will handle all calls initiated by the at least one UE or only emergency calls generated by the at least one UE. The HAP node handles the calls based on the determining and through the use of the second network.

Abstract: This document describes techniques and apparatuses that include a three-dimensional (3D) antenna module for transmitting or receiving electromagnetic millimeter waves (mmWaves). In general, a user equipment (UE) may include the 3D antenna module in a corner of a housing of the UE. The 3D antenna module may include three antenna panels that are generally planar and generally orthogonal to three respective axes of a Cartesian-coordinate system. The 3D antenna module may transmit and receive the electromagnetic mmWaves as part of a wireless link between the UE and another device, such as a satellite that is part of a wireless-communication network. In general, the 3D antenna module may mitigate propagation losses and allow the UE to maintain a link-budget for the wireless link.

Abstract: This document describes network slicing for WLAN in cellular networks. The techniques described enable the use of WLAN network slices (216c) with cellular networks (202) and mobility management of user equipment (102) between cellular networks (202) and WLAN networks (206). An Access and Mobility Function-Aggregation Proxy (AMF-AP) (218) connects one or more WLAN networks (206) to the cellular core network (110) of a network operator via the Access and Mobility Function (AMF) (212) in the core network (110). The AMF-AP (218) acts as a proxy and a firewall to protect the AMF (212) and other entities in the cellular core network (110) from malicious actors.

Abstract: This disclosure provides systems, methods, and apparatus for reducing or avoiding interference between communications of one base station-user equipment pair and communications of another base station-user equipment pair. A first user equipment can monitor a timing offset between the communications and send the timing offset to a first base station that services the first user equipment. The first base station time advances a window of time during which it receives uplink signals from the first user equipment. The base station also sends a time advance value and instructions to the first user equipment to advance a window of time during which the first user equipment transmits uplink signals to the first base station. The timing advance value is based on the timing offset value determined by the first user equipment. Thus, a gap period between uplink and downlink windows is increased, thereby reducing interference.

Abstract: The present disclosure describes techniques and systems for wireless communications between a base station [120] and a user equipment [110] using an uplink-enhanced idle mode. The described techniques and systems enable a user equipment [110] to receive resources [402] and a user-equipment-specific identifier [404] and, in response, enter the uplink-enhanced idle mode [406]. While in the uplink-enhanced idle mode, the user equipment may transmit an uplink message [408] through the resource [402] and using the user-equipment-specific identifier [404].

Abstract: Techniques and apparatuses are described for enabling base stations (121, 122) to coordinate for canceling cross-link interference (380). The techniques and apparatuses described herein overcome challenges that a single base station (121) might otherwise face in trying to compensate a reception (131) by the base station (121) for cross-link interference (382) from a transmission (132) by another base station (122). The techniques and apparatuses described herein enable the base stations (121, 122) to form coordination sets to exchange information to enable the base stations (121, 122) to accurately reconstruct cross-link interference (380) and ultimately cancel the cross-link interference (380) to improve link quality.

Abstract: The present disclosure describes techniques and systems for beam search pilots for paging channel communications. In some aspects, a user device receives, from a base station of a wireless network, a beam search pilot on a beam. The user device determines that a signal quality of the beam search pilot meets a signal quality threshold. Based on this determination, the user device transmits, to the base station, an indication that the beam search pilot meets the signal quality threshold. The user device then receives a paging channel communication on the beam provided by the base station.

Abstract: This document describes monitoring and managing wireless backhaul integrated with mobile access in fifth generation new radio (5G NR) wireless networks. The techniques described employ an Integrated Backhaul-Access and Mobility Function (IB-AMF) to enable authorization of a base station to access a 5G network through another base station. The techniques described also monitor channel conditions and traffic loads to manage backhaul links and facilitate handovers of base station backhaul connections between other base stations.

Abstract: The present disclosure describes techniques and systems for wireless communications between a base station [120] and a user equipment [110] using an enhanced radio-resource control idle mode. The described techniques and systems enable a user equipment [110] to receive a radio-resource control release message [410] that includes a cell radio-network temporary-identifier and, in response, enter [415] the enhanced radio-resource control idle mode. While in the enhanced radio-resource control idle mode, the user equipment [110] may receive a message [420] in accordance with the cell radio-network temporary-identifier and present the received message.

Abstract: Methods, systems, and apparatus, including computer programs encoded on a computer storate medium, for switching between transmission technologies within a spectrum based on network load are described. In one aspect, a method includes obtaining first network load information that indicates network load for a first access point operating using listen before talk (LBT) and second network load information for a second access point using LBT, determining if at least one of the first network load information or the second network load information satisfies a network load threshold, and in response to determining that that the network load information satisfies the network load threshold, providing an instruction to the first access point to operate using frequency domain multiplexing.

Abstract: Techniques and apparatuses are described for machine-learning architectures for simultaneous connection to multiple carriers. In implementations, a network entity determines at least one deep neural network (DNN) configuration for processing information exchanged with a user equipment (UE) over a wireless communication system using carrier aggregation that includes at least a first component carrier and a second component carrier. At times, the at least one DNN configuration includes a first portion for forming a first DNN at the network entity, and a second portion for forming a second DNN at the UE. The network entity forms the first DNN based on the first portion and communicates an indication of the second portion to the UE. The network entity directs the UE to form the second DNN based on the second portion, and uses the first DNN to exchange, over the wireless communication system, the information with the UE using the carrier aggregation.

Abstract: The present disclosure describes techniques and systems for handing over a connection of a user device, within a wireless network, based on qualities of downlink signals and qualities of uplink signals. These techniques and systems include a base station and a neighboring base station negotiating handover parameters, based on the qualities of downlink signals as detected by a user device and the qualities of uplink signals as detected by the base station and the neighboring base station. The base station and neighboring base station negotiate the handover parameters via an interface connecting the base station to the neighboring base station.