Provided is a transmission control method for a plurality of transmitting stations which are connected to a wireless communication partner receiving station by non-orthogonal multiple access, and each of which is capable of transmitting a same signal to the receiving station by repetition for a predetermined number of times at a predetermined cycle, wherein an information processing apparatus executes: acquiring information indicating a code word length for each of the plurality of transmitting stations to use for the repetition; and assigning, to each of the plurality of transmitting stations, transmitting power for ensuring a power difference which is required between transmitting stations, so that the shorter the code word length the higher the receiving power at the receiving station.

Aspects of the invention provide an external interference radar that remedies such shortcomings by providing a hybrid approach that provides an initial spectrum analysis to identify known interferences. The signal is also divided into physical resource blocks (PRB) to better identify interferences that occur intermittently. Once these intermittent interferences are illustrated, a signal pattern detection algorithm is applied to the identified signals and may further accurately identify the intermittent interferences. As part of the identification, the radar further provides a report that identifies whether the interference is a permanent or intermittent; a type of the interference and the severity of the interference.

Methods, systems, and devices for wireless communications are described. A base station and a user equipment (UE) may perform dynamic rank assignment in multiple-input multiple-output (MIMO) communications by leveraging channel reciprocity. For example, the base station and the UE may apply a common algorithm to enable dynamic rank assignment of allocated frequency resources within a communication slot. In some examples, at least one threshold may be utilized to assign different ranks to different frequency resources. Additionally or alternatively, a number of frequency resources assigned a lower rank may be indicated between the base station and the UE in accordance with a joint criteria. Further, dynamic rank assignment may allow the base station and the UE to account for channel fading, improving throughput over the channel without increasing signaling overhead.

Methods, systems, and devices for wireless communications are described. A base station and a user equipment (UE) may perform dynamic rank assignment in multiple-input multiple-output (MIMO) communications by leveraging channel reciprocity. For example, the base station and the UE may apply a common algorithm to enable dynamic rank assignment of allocated frequency resources within a communication slot. In some examples, at least one threshold may be utilized to assign different ranks to different frequency resources. Additionally or alternatively, a number of frequency resources assigned a lower rank may be indicated between the base station and the UE in accordance with a joint criteria. Further, dynamic rank assignment may allow the base station and the UE to account for channel fading, improving throughput over the channel without increasing signaling overhead.

A wireless entity, such as a user equipment (UE) or transmission reception point (TRP), receives and processes aggregated positioning reference signals (PRS) to increase the effective PRS bandwidth, thereby increasing positioning accuracy, such as time of arrival measurements. An aggregated PRS includes one or more PRS components that are transmitted from a same transmitting entity. Each PRS component may be, e.g., a separate PRS resource associated with a contiguous frequency-domain bandwidth or may be, e.g., a plurality of frequency-domain bandwidths spanned by a single PRS resource. PRS components of an aggregated PRS that are unpunctured, e.g., do not collide with higher priority signals, are aligned in time domain, and are configured with common constraints are processed jointly assuming that the PRS components are transmitted from a same antenna port, thereby increasing the effective PRS bandwidth.

Devices, methods, and systems for implementing an 802.11ax communication protocol. A first wireless connection is established between a first device and a network device in association with a first service set identifier. A second wireless connection is established between a second device and a network device in association with a second service set identifier. The network device communicates with the first device over the first wireless connection according to an 802.11ax communication protocol. Full allocation of remaining resource units to the second wireless connection according to the 802.11ax communication protocol is denied based on a priority status of the second service set identifier.

Various embodiments comprise systems, methods, and apparatus for enabling dynamic configuration of devices using encumbered shared spectrum (e.g., CBSDs using CBRS) so as to operate these devices in accordance with a most preferred operator preference of a plurality of operator preferences currently available in view of current wireless operating conditions, such as impacted by overlapping/proximate incumbent or priority users of the shared spectrum, or other changes in spectrum available conditions. Various embodiments further provide for an efficient return of these devices to a most preferred operator preference or steady-state configuration.

An electronic device includes a processor, a wireless communication device, and a hardware storage device. The hardware storage device has instructions stored thereon that, when executed by the processor, cause the electronic device to obtain a plurality of data channel personalities. Each of the data channel personalities includes a unique radio communication and network protocol for the wireless communication device. The instructions further cause the electronic device to select a data channel personality from the plurality of data channel personalities and transmit data to a host device using the wireless communication device and the radio communication and network protocol according to the selected data channel personality.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may identify a set of security levels for a set of physical uplink channels, wherein the set of physical uplink channels are overlapping in time. The UE may transmit one or more of the set of physical uplink channels based at least in part on the set of security levels for the set of physical uplink channels. Numerous other aspects are described.

The disclosure provides a user equipment (UE) and method thereof. The method including identifying a position of a first symbol in which a synchronization signal block is transmitted through cell specific configuration information based on at least one of system information block (SIB) information or higher layer signaling; determining whether a second symbol of an uplink channel configured based on at least one of the higher layer signaling or downlink control information overlaps with the first symbol in which the synchronization signal block is transmitted; transmitting the synchronization signal block without transmitting the uplink channel in response to the determination that the second symbol of the uplink channel does not overlap with the first symbol in which the synchronization signal block is transmitted; and determining whether to transmit the uplink channel according to a predetermined condition in response to the determination that the second symbol of the uplink channel overlaps with the first symbol in which the synchronization signal block is transmitted.