Abstract: A method performed by a wireless communication device includes determining whether to transmit a first Sidelink Synchronization Signal (SLSS) according to a priority parameter when an occasion of the first SLSS collides with a Physical Sidelink Feedback Channel (PSFCH) that carries Sidelink Feedback Control Information (SFCI). The priority parameter is associated with a Physical Sidelink Shared Channel (PSSCH) that corresponds to the PSFCH.

Abstract: A signal sending method, a signal receiving method, and a device for signal transmission or receiving are provided. A part that is of a first signal and that is carried on a kth subcarrier in an ith subcarrier group in N subcarrier groups is xi,nid(k), and a sequence {si,nid(k)} related to xi,nid(k) is one of enumerated sequences. The enumerated sequences are sequences with relatively good cross-correlation. Therefore, for two subcarrier groups, provided that selected {si,nid(k)} is two of the enumerated sequences, cross-correlation between signals carried in the two subcarrier groups can be ensured to be relatively good, thereby reducing interference between the signals and improving channel estimation performance.

Abstract: Systems, apparatuses, and methods are described for wireless communications. A base station may transmit indications of target received powers for a random access procedure and a beam failure recovery procedure. A wireless device may transmit a random access preamble and a beam failure recovery preamble using different transmission powers based on the indications of target received powers.

Abstract: A high frequency data network access system leverages commodity WiFi chipsets and specifically multi spatial stream (e.g., 802.11 ac) chipsets in combination with phased array antenna systems at the aggregation nodes. Examples can be very spectrally efficient with both polarization and frequency diversity.

Abstract: Systems, devices, and methods for performing coordinated clear channel assessments (CCAs) in a shared radiofrequency band are provided. In one aspect, a method of wireless communication performed by a first wireless communication device includes: receiving a control signal indicating a CCA trigger associated with the first wireless communication device and a second wireless communication device; performing, based on the CCA trigger, a CCA; transmitting, to the second wireless communication device based on the CCA, a first CCA success signal; receiving, from the second wireless communication device, a second CCA success signal; initiating, based on the first CCA success signal and the second CCA success signal, a channel occupancy time (COT); and amplifying and forwarding a communication in the COT.

Abstract: Aspects of the present disclosure involve systems, methods, computer program products, and the like, for utilizing a CIC value field in signaling information of a communication to provide an identification of the ingress network to an egress or receiving network of a long distance telecommunications network. The system and method provides for the provisioning of a signaling CIC for an ingress trunkgroup or network to a telecommunications network for downstream signaling purposes by overriding a received CIC value with a provisioned CIC value specific to the ingress network. This provisioned CIC value identifies the ingress network to the long distance network to the egress network for use by the egress network.

Abstract: A mechanism for adaptively performing in-band network telemetry (INT) by a network controller is disclosed. The mechanism includes receiving one or more congestion indicators from a collector. An adjusted sampling rate is generated. The adjusted sampling rate is a specified rate of insertion of instruction headers for INT and is generated based on the congestion indicators. The adjusted sampling rate is transmitted to a head node, which is configured to perform INT via instruction header insertion into user packets.

Abstract: Systems and methods for timing over a Metro Transport Networking (MTN) path include detecting a specific block in a stream of blocks, wherein each block is encoded based on a line code, and sampling an output of a clock to determine a timestamp reference based on detection of the specific block, and transmitting timing information based on the timestamp reference. The specific block can be a control block. The timing information can be transmitted via a Precision Time Protocol (PTP) message. The timing information can be transmitted via a plurality of subsequent specific blocks.

Abstract: A control plane system for providing data exchange between a plurality of gateway endpoints using a secure tunnel between the gateway endpoints. The system includes an end-user device, a cloud control plane, and a cloud provider. The end-user device includes a client endpoint providing a request for accessing data using a gateway device by sending data packets. The cloud control plane uses a data plane and a control plane for provisioning the request. The control plane is isolated from the data plane. Routing information of network traffic is received, a tenant associated with the request is identified and isolated. A network policy associated with the access to the data is identified based on the network patterns. The network policy specifies routing for access to the data and the secure tunnel. The access to the data is provided from the cloud provider to the client endpoint on the gateway device.

Abstract: Embodiments of the present disclosure provide a communication method and device for uplink power control. The method comprises receiving a plurality of sets of power control parameters from a network device, each of the plurality of sets being associated with a corresponding one of a plurality of sets of candidate beam patterns for the terminal device. The method further comprises selecting, based on a beam pattern for the terminal device, one of the plurality of sets of power control parameters for uplink transmit power control, the beam pattern for the terminal device being included in the set of candidate beam pattern that is associated with the selected set of power control parameters.

Abstract: Reservations of resources within a dynamic workspace are made and facilitated including by pushing configurations specific to a worker for whom a reservation is made to the resource for a limited time period for the reservation. When the worker arrives for the reservation and checks in, configurations associated with the worker are obtained and pushed to the resource to configure the resource for use by the worker for a time period of the reservation. In some cases, an identity of the worker may be verified to complete the check in process for the reservation. In response to an end time of the reservation being determined, such as based on a scheduled end time for the reservation or based on a determination that the resource has gone unused for some amount of time, the configurations are removed from the resource to prepare the resource for use by a next worker.

Abstract: A wireless device may receive at least one control message. The at least one control message may comprise at least one pathloss reference parameter that may indicate a downlink carrier.

Abstract: Systems and methods for transferring data via a two-way radio transmission are described herein. An example method commences with collecting asset data, determining conditions for transmission of the asset data to a data server, and determining a mode for the transmission of the asset data. The method continues with preprocessing the asset data for the transmission. The preprocessing includes determining that the conditions for transmission of the asset data satisfy predetermined criteria and setting priorities for one or more parts of the asset data. The priorities are set based at least on a type of the data and a location of the data collection device. The method further includes transmitting the asset data to a data server. The asset data is transmitted based on the mode for the transmission and the priorities via at least one of the one or more communication channels.

Abstract: This disclosure describes systems, methods, and devices related to scheduled multi-user multiple-input multiple-output (MU-MIMO) acknowledgement. A device may determine a block acknowledgment schedule associated with one or more destination devices. The device may cause to send a multi-user multiple-input multiple-output (MU-MIMO) frame including the block acknowledgment schedule. The device may identify one or more acknowledgment frames received from at least one of the one or more destination devices based on the block acknowledgment schedule.

Abstract: Inventive technology is directed to a control method for a terminal device in a non-terrestrial cellular data communication network. In an embodiment, the network includes at least one airborne or spaceborne base station moving along a flight trajectory for connecting the terminal device to the network. The method includes steps of: providing flight trajectory data for the base station in a memory element of the terminal device; providing terminal location data in a memory element of the terminal device; using a data processing unit, determining at least one time slot during which a wireless communication channel between the terminal device and the base station is estimated to be available, based on the flight trajectory data and on the terminal location data. The method also includes scheduling a data reception or transmission between the terminal device and the base station during the determined time slot.

Abstract: An airborne or spaceborne base station for a non-terrestrial cellular data communication system is disclosed. In one embodiment, the base station includes: a data transmission unit, a data reception unit, a memory element, and a data processing unit. The data transmission unit and the data reception unit are configured to establish one or more inter base station communication links with neighboring base stations of the non-terrestrial cellular data communication system. The data processing unit is configured to, in the memory element, store identifiers of neighboring airborne or spaceborne base stations of the non-terrestrial cellular data communication system with which the base station can exchange data via the one or more inter base station communication links. Furthermore, the data processing unit is configured to periodically update data describing a set of currently neighboring airborne or spaceborne base stations with which the base station can exchange data.

Abstract: Implementing a circuit design using time-division multiplexing (TDM) can include determining a net signature for each of a plurality of nets of a circuit design. For each net, the net signature specifies location information for a driver and one or more loads of the net. The plurality of nets having a same net signature can be grouped according to distance between drivers of the respective nets. One or more subgroups can be generated based on a TDM ratio for each group. For one or more of the subgroups, a TDM transmitter circuit is connected to a TDM receiver circuit through a selected interconnect, the drivers of the nets of the subgroup are connected to the TDM transmitter circuit, and loads of the nets of the subgroup are connected to the TDM receiver circuit.

Abstract: A system receives a first request from a first instance of a network function associated with a first address. The system may determine the first address and, based at least in part on the first address, may identify a second address with which to respond to the first request. The system may then send, to the first instance of the network function, a response to the first request specifying the second address. The system may also receive a second request from a second instance of the network function associated with a third address. The system may determine a fourth address with which to respond to the second request, and may thereafter send a response to the second request to the second instance of the network function, with the response specifying the fourth address.

Abstract: A method for processing clock drift implemented by a first network element includes: receiving a first notification message transmitted by a second network element, the first notification message including a first clock difference between a first clock domain and a second clock domain acquired by the second network element, transmission of the first notification message being triggered by a clock drift between the first clock domain and the second clock domain being greater than a drift amplitude value, which is a maximum value of a change amplitude of a clock difference between the first and second clock domain; determining first time sensitive communication assistance information (TSCAI) according to the first clock difference; and transmitting the first TSCAI to a radio access network (RAN) device, the first TSCAI being used by the RAN device to perform time control on a data stream in the first clock domain.

Abstract: A network element includes a port; and a device with circuitry configured to encode data for communication to a second device via a plurality of physical channels, and utilize one of the plurality of physical channels as a dedicated timing channel with encoding thereon different from encoding on the other plurality of physical channels, and interface encoded data via the plurality of physical channels with the port for transmission and reception with a second device.