Abstract: A network device may receive multi-access edge computing (MEC) proximity service information that identifies a set of MEC devices and a set of network services supported by respective MEC devices of the set of MEC devices. The network device may transmit, to a base station, at least a portion of the MEC proximity service information for broadcasting by the base station. The network device may receive, from a user device, a request to establish a peer-to-peer connection with a MEC device for the network service. The network device may authenticate the user device for access to the network service. The network device may transmit, to the user device and the MEC device, connection information that enables the user device and the MEC device to establish the peer-to-peer connection, based on authenticating the user device for access to the network service.

Abstract: A multi-access edge computing (MEC) node of a MEC network may receive, from a user device a first request to communicate via a peer-to-peer connection routed through a MEC network. The MEC node may identify one or more candidate devices that are available to communicate with the user device via the peer-to-peer connection. The MEC node may provide, to a particular candidate device of the one or more candidate devices, a second request to communicate via the peer-to-peer connection. The MEC node may receive, from the particular candidate device, an acceptance to communicate via the peer-to-peer connection. The MEC node may route data between the user device and the particular candidate device via the peer-to-peer connection.

Abstract: A system may use optical character recognition (“OCR”) techniques to identify license plates or other textual information associated with vehicles. Based on this OCR information, the system may determine additional information, such as users associated with the vehicles. The system may further obtain other information, such as history information associated with the vehicles and/or the users (e.g., via an “opt-in” data collection service). Ad content may be selected based on trends associated with the users and/or vehicles, and may be presented via “smart” billboards (e.g., billboards that may dynamically display different content).

Abstract: A device may receive channel data associated with a channel provided between a network and a user device, and may calculate, based on the channel data, key performance indicator data that includes a plurality of key performance indicators for the channel. The device may multiply the plurality of key performance indicators by factors to generate factored key performance indicator data that includes a plurality of factored key performance indicators. The device may apply weights to the plurality of factored key performance indicators of the factored key performance indicator data to generate factored weighted key performance indicator data that includes a plurality of factored weighted key performance indicators. The device may calculate a quality indicator for the channel based on the factored weighted key performance indicator data, and may perform one or more actions based on the quality indicator for the channel.

Abstract: A network device receives control plane (CP) traffic transiting a first mobile network. The network device determines CP traffic loads handled by network functions of the first mobile network and determines availability of CP resources within the first mobile network. The network device performs at least one of load balancing, network selection or overload protection, when switching the CP traffic from a source to a destination, based on the determined CP traffic loads and/or the determined availability of CP resources.

Abstract: A method, a device, and a non-transitory storage medium are described in which a network allocation service is provided. The network allocation service may use available network resource information of an application service layer network of a first type, such as a multi-access edge computing network, and application service demand information of an application to determine whether a performance metric of the application service would be satisfied. The performance metric may include a threshold service time that includes a processing time associated with a processing of an application service request and response, by the application service layer network, and a transit time associated the application service response from the application service layer network to an end device. The network allocation service may select the first type or a second type of application service layer network depending on the outcome of the determination.

Abstract: Systems and methods provide a latency certification service. One or more network devices in an application service layer network receive a service request for a latency certification service and instantiate a Transmission Control Protocol (TCP) proxy for a data session between an application server device and a user equipment (UE) device. The one or more network devices obtain a digital certificate for the TCP proxy. The one or more network devices receive, at the TCP proxy, a data packet from the UE device; apply a certified timestamp to the data packet to form a certified timestamped data packet; and forward the certified timestamped data packet to the application server device.

Abstract: A method may include receiving, at a first wireless station, first data wirelessly transmitted from first user equipment (UE) devices, wherein the first data includes quality of service (QoS) information, and forwarding the first data from the first UE devices to a second wireless station, wherein the first wireless station does not map the QoS information included with the first data. The method also includes receiving, by the second wireless station, the first data and second data transmitted from second UE devices, wherein the second data includes QoS information. The method may further include forwarding, by the second wireless station, the first and second data to a third wireless station, wherein the second wireless station does not map the QoS information included in the first or second data, and wherein the third wireless station is configured to forward the first and second data via a backhaul network.

Abstract: A device may perform a partial Random Access Channel (RACH) procedure for each wireless station of a plurality of wireless stations. Given a wireless station, the partial RACH procedure includes: starting a RACH procedure; receiving a Random Access Response (RAR) message from the wireless station; extracting a parameter value from the RAR message; receiving a Radio Resource Control (RRC) connection setup message from the wireless station verifying the RRC connection setup message; and terminating the RACH procedure in response to verifying the RRC connection setup message, before sending any message to the wireless station.

Abstract: A passive fiber optic switching (“PFOS”) device may provide failover in a fiber optic network by switching a working path between different fibers of a redundant set of fibers. The PFOS device may operate passively (e.g., without an active, external, and/or continuous power supply) by harvesting the power that it needs from the light that passes over any one or more fibers that are connected to the PFOS device. The PFOS device may detect issues that disrupt signaling and/or light transmission on the working path based on quality (e.g., signaling and/or light properties) of the working path, and/or diagnostic messaging received from other devices on the working path. The PFOS device may include an optical switch, such as a Micro-Electro-Mechanical System (“MEMS”) mirror switch, that can change the working path by switching light to any fiber of the redundant set of fibers.

Abstract: A user equipment (UE) device may determine its location with a high degree of precision, beyond the capability of other current methodologies. Specifically, a UE device may obtain High Precision (HIP) coordinates of its location based on Random Access Channel (RACH) messages that the UE device exchanges with multiple wireless stations. Using RACH messages to obtain HIP coordinates imposes little communication overhead or computational burden on the UE device and the network.

Abstract: Systems and methods provide decentralized MEC compute services. A network device receives, from a user device associated with a user account, an access request for Multi-access Edge Computing (MEC) services. The user account includes a MEC service token that indicates parameters for the MEC services. The network device validates a user of the user device to access MEC services for the user device; removes, after the validating, the MEC service token from the first user account; and grants, based on the removing, access to a MEC cluster by the user device, wherein granting access includes granting access according to the parameters.

Abstract: A user equipment (UE) device may include a memory and one or more processors. The one or more processors operate to determine one or more of a signal strength or signal quality for each of a plurality of networks available for connection via the communication interface and the antenna assembly. Virtual user equipment (VUE) for two or more of the identified plurality of networks are allocated and the UE device connects to the two or more networks using the respective VUEs.

Abstract: A mobile device may receive user input for requesting personal information for a subject in proximity of a mobile device and based on the user input, selecting one of available functions. The functions may include a first function for obtaining personal information using a first identifier. The functions may also include a second function for obtaining the personal information using the first identifier. The mobile device may output the personal information as an image to a display or as speech to speaker.

Abstract: A method for determining a Quality of Service (QoS) policy can be based on requested bandwidth. The method may initially receive a connection request which includes a requested bandwidth that corresponds to an application. The method may then determine a policy for an application data flow associated with the application based on the connection request. A bandwidth designation, which is based on the requested bandwidth, may be assigned to the application data flow based on the determined policy. Finally, the policy and the bandwidth designation may be provided so that a bearer can be assigned.

Abstract: A system described herein may provide a mechanism for identifying unique sources of interference in a wireless telecommunication network. A unique noise signature, associated with a particular source of radio frequency (“RF”) interference, may be identified by detecting physical resource blocks (“PRBs”), in a sector, that exhibit excessive interference, as compared to surrounding PRBs. The unique noise signature may be detected across multiple sectors, and a location of the interference source may be determined. Corrective action may be taken once an interference source is detected, such as by ceasing to utilize, or by reducing the utilization of, affected PRBs.

Abstract: A system includes a phased array antenna. The phased array antenna includes a rear panel that has: a first array of phase shift elements; and a second array of rear antenna elements. The phased array antenna also includes a front panel that has a third array of front antenna elements. Each of the front antenna elements is electrically coupled to a corresponding one of the rear antenna elements through one of the phase shift elements. When the second array of rear antenna elements receives a radio signal from a base station and the first array of phase shift elements receives an optical control beam from the base station, the third array of antenna elements radiates an output radio signal in a direction indicated by the optical control beam.

Abstract: A user equipment (UE) device may include a memory, a communication interface, an antenna, and one or more processors. The one or more processors operate to identify a plurality of networks available for connection via the communication interface and the antenna assembly. Virtual user equipment (VUE) for two or more of the identified plurality of networks are allocated and the UE device connects to the two or more networks using the respective VUEs. Network characteristics are identified for the connections with the plurality of networks. Data flows for the device are identified. The identified data flows are assigned to the VUEs based on the identified network characteristics.

Abstract: A passive fiber optic switching (“PFOS”) device may provide failover in a fiber optic network by switching a working path between different fibers of a redundant set of fibers. The PFOS device may operate passively (e.g., without an active, external, and/or continuous power supply) by harvesting the power that it needs from the light that passes over any one or more fibers that are connected to the PFOS device. The PFOS device may detect issues that disrupt signaling and/or light transmission on the working path based on quality (e.g., signaling and/or light properties) of the working path, and/or diagnostic messaging received from other devices on the working path. The PFOS device may include an optical switch, such as a Micro-Electro-Mechanical System (“MEMS”) mirror switch, that can change the working path by switching light to any fiber of the redundant set of fibers.

Abstract: A device may perform a Random Access Channel (RACH) procedure for each of multiple wireless stations and apply multilateration based on results of performing the RACH procedure for each of the multiple wireless stations.