Abstract:
A base station includes an antenna to receive frequency bands that include a first band associated with first signals carrying machine-two-machine (M2M) data and a second band associated with second signals carrying user equipment (UE) data. The base station further includes a baseband unit (BBU) that includes: a radio frequency (RF) interface configured to receive the first signals and the second signals, a digital front end (DFE) configured to generate first symbols based on the first signals and second symbols based on the second signals, a symbol processor configured to convert the first symbols into the M2M data and the second symbols into the UE data, and one or more processors configured to forward the M2M data to a first device and the UE data to a second device that differs from the first device.
Abstract:
A network device may determine a sequence. The sequence may identify an order in which particular unlicensed bands, of a plurality of unlicensed bands in an unlicensed spectrum, are to be assigned for the transmission of data flows. The network device may provide information identifying the sequence via a licensed band to a user device to cause the user device to transmit or receive the data flows via the particular unlicensed bands identified in the sequence in the order in which the particular unlicensed bands are to be assigned; and transmit or receive, to or from the user device, the data flows via the particular unlicensed and the licensed bands.
Abstract:
A network device may determine a sequence. The sequence may identify an order in which particular unlicensed bands, of a plurality of unlicensed bands in an unlicensed spectrum, are to be assigned for the transmission of data flows. The network device may provide information identifying the sequence via a licensed band to a user device to cause the user device to transmit or receive the data flows via the particular unlicensed bands identified in the sequence in the order in which the particular unlicensed bands are to be assigned; and transmit or receive, to or from the user device, the data flows via the particular unlicensed and the licensed bands.
Abstract:
A device may initiate a location determination for a user device. The device may receive information identifying a set of base stations for performing the location determination. The device may retrieve, from a data structure and utilizing the information identifying the set of base stations, particular base station information associated with the set of base stations. The particular base station information may include location information for the set of base stations. The device may determine one or more signal strength measurements for one or more signals provided by the set of base stations. The device may determine an approximate location for the user device based on the location information for the set of base stations and the one or more signal strength measurements. The device may provide information associated with the approximate location for the user device.
Abstract:
A system may include a plurality of wireless devices, each wireless device including a time source and configured to selectively communicate with at least one other of the plurality of wireless devices by way of a packet-based time precision protocol. The plurality of wireless devices may include a first wireless device and a second wireless device, the first wireless device being configured to determine whether the first wireless device and the second wireless device are in selective communication over a single-hop wireless link; determine a one-way delay over the single-hop wireless link by way of at least one packed-based time precision protocol message; and calculate a distance measurement between the first wireless device and the second wireless device based at least in part on the one-way delay.
Abstract:
A device may include a processor configured to receive a data stream connection request via a WIFI connection or a wired connection and establish a cellular wireless connection with a base station based on the data stream connection request. The processor may be further configured to determine a cellular wireless Quality of Service (QOS) class or network slice assigned to the cellular wireless connection by a core network associated with the base station; map the cellular wireless QoS class or network slice to a priority class associated with the WIFI connection or the wired connection; assign the priority class to a data stream associated with the data stream connection request; and process data units associated with the data stream based on the assigned priority class.
Abstract:
Systems and methods are provided to enable mobile network operators to dynamically determine when a Low-Latency, Low-Loss Scalable-Throughput (L4S) service shall be enabled for a data flow. A network device in a core network receives a request for a Quality of Service (QoS) flow associated with a user equipment (UE) device; determines whether to enable a LS4 service for the QoS flow; and notifies, based on the determining, a Session Management Function (SMF) to create the QoS flow with L4S service enabled.
Abstract:
A device may include a processor configured to monitor a data flow, associated with a user equipment (UE) device, in a Radio Access Network (RAN). The processor may be further configured to detect a congestion condition for the monitored data flow associated with the UE device; generate an Explicit Congestion Notification (ECN) in response to detecting the congestion condition; and mark packets associated with the data flow with the generated ECN.
Abstract:
A device receives a message associated with creating a session for a User Equipment device (UE), the messaging identifying a Quality of Service (QOS) for the UE. The device adjusts discontinuous reception (DRx) parameters for the UE based on the identified QoS for the UE and instructs the UE to increase or decrease a DRx wait time based on the adjusted DRx parameters.
Abstract:
A method, a device, and a non-transitory storage medium are described in which an admission and congestion control service is provided. The service may dynamically reconfigure admission control information of an end device. The admission control information may include one or multiple types of access class values of the end device or an application of the end device.