Abstract: Techniques for neutralizing malicious malware embedded in a media item being sent to a user equipment (UE) are discussed herein. A network device may receive (e.g., intercept) a medial file in transit via a wireless communication network being sent to a UE. The media file may include some type of perceptible content (e.g., audio, video, image data, etc.) as well as malware embedded in the media file. The network device may generate a transcoded media file based on the received media file that includes the perceptible content while neutralizing the malware.

Abstract: A telecommunications system including a base station has a transceiver associated with a cellular network and a wireless access point. The system receives a request from a client device that includes a service set identifier (SSID). The system determines whether the SSID is registered for virtual wireless services and provisions a virtual router accessible through the wireless access point and identifiable using the SSID. The system may then authenticate and associate the client device with the virtual router.

Abstract: A mobile sensor reader for Internet of Things (IoT) devices includes a wireless communications system, a memory configured to store sensor data received via the wireless communications system from an IoT device, and a processor. The processor is configured to monitor for remote electronic data collectors that come within a communication range of the wireless communications system as at least one of the mobile sensor reader or one of the remote electronic data collectors move to different locations; determine a first parameter of a remote electronic data collector that has come within the communication range of the wireless communications system; determine a second parameter of the mobile sensor reader or the sensor data; and forward the sensor data to the remote electronic data collector, via the wireless communications system, at least partly in response to the first parameter and the second parameter satisfying a set of one or more conditions.

Abstract: A data link error feedback signaling system includes a transmitting network device and a receiving network device. The receiving network device may be operable to receive a network data unit from the transmitting network device over a data link, detect an error in the network data unit, and provide data link integrity information based on the error to the transmitting network device. The receiving network device may provide the data link integrity information by marking the data link flawed in a routing protocol, transmitting the data link integrity information via an informational protocol, and so on. The transmitting network device may respond to the data link integrity information, such as by marking the data link less preferred, marking the data link down, transmitting an alarm regarding the data link to a network operator, omitting taking an action upon determining that errors are below an error threshold, and so on.

Abstract: A router in a switching network has input interfaces communicatively coupled to other routers and first and second output interfaces communicatively coupled to other routers in the switching network. First and second output interface queues, respectively associated with the first and second output interfaces, store data packets awaiting transmission respectively on the first and second output interfaces. A routing table maps first and second destination addresses to the first output interface as a primary interface and maps the first destination address to the second output interface as an alternate interface. A route controller assigns, using the routing table, data packets having one of the first or second destination address to the primary output interface for transmission, the primary output interface being the first output interface.

Abstract: A label switching router for a switching network configured for source routing can be configured to modify one or more reported properties of a link associated with that router based on one or more link quality metrics. For example, a router can include a link with available bandwidth of 10 Gbps, a value that can be used by a headend when evaluating nodes of the network against a set of constraints required by a particular requested connection or tunnel. A link of that router may exhibit an increased bit error rate which can be used by the label switching router to artificially deflate available bandwidth, thereby reducing the number of label switching paths including the router are selected by the headend.

Abstract: Techniques for monitoring and configuring a mesh network are discussed herein. A centralized database may receive, from one or more access points that make up the mesh network, conditions data associated with the access points and the backhaul links between the access points. The centralized database may determine a radio frequency (RF) resource that should be used for the backhaul links to optimize the mesh network and send an instruction to the access point to operate using the RF resource.

Abstract: A data link error feedback signaling system includes a transmitting network device and a receiving network device. The receiving network device may be operable to receive a network data unit from the transmitting network device over a data link, detect an error in the network data unit, and provide data link integrity information based on the error to the transmitting network device. The receiving network device may provide the data link integrity information by marking the data link flawed in a routing protocol, transmitting the data link integrity information via an informational protocol, and so on. The transmitting network device may respond to the data link integrity information, such as by marking the data link less preferred, marking the data link down, transmitting an alarm regarding the data link to a network operator, omitting taking an action upon determining that errors are below an error threshold, and so on.

Abstract: An unmanned aerial vehicle (UAV) is disclosed. The UAV includes a flight system, a communications system, and a processing system. The communications system includes a cellular radio configured to support multiple contemporaneous communications connections, including at least a first communications connection with a cellular radio access network, at least a second communications connection with a second UAV in a set of one or more UAVs, and at least a third communications connection with a user equipment (UE) in a set of one or more UEs. The processing system is configured to control the flight system and relay communications between the cellular radio access network, the set of one or more UAVs, and the set of one or more UEs, in accordance with a mesh network protocol.

Abstract: The disclosed technology includes at least one method performed by a system of a telecommunications network. The system can establish a communications link between the wireless device and a network access node (NAN) of the 5G network. While connected over a non-mmW band, the wireless device autonomously schedules data downloads to occur when the wireless device is on an mmW band. The system then receives a request from the wireless device to perform the data downloads, which can be enabled by a packet gateway (PGW) upon receiving a confirmation by the NAN that the wireless device can connect over the mmW band. Otherwise, the PGW denies the wireless device's request to perform the data downloads, which can be enforced by the NAN.

Abstract: A label switching router for a switching network configured for source routing can be configured to modify one or more reported properties of a link associated with that router based on one or more link quality metrics. For example, a router can include a link with available bandwidth of 10 Gbps, a value that can be used by a headend when evaluating nodes of the network against a set of constraints required by a particular requested connection or tunnel. A link of that router may exhibit an increased bit error rate which can be used by the label switching router to artificially deflate available bandwidth, thereby reducing the number of label switching paths including the router are selected by the headend.

Abstract: Systems and methods for improved content streaming and downloading. The system enables content to be transmitted to wireless base stations (WBSs) using unicast on the core network side of a cellular network to avoid incompatibilities associated with network broadcast technologies such as Evolved Multimedia Broadcast Multicast Services (eMBMS) and Long-Term Evolution Broadcast (LTE-B). At the same time, the system enable content to be broadcast, or transmitted to multiple user equipment (UE) in a single transmission to reduce wireless bandwidth consumption. The system can include a commodity server to receive requests from WBSs, place them in a chronological list based on network latency, and then transmit content to each WBS in a synchronized unicast manner. Each WBS can then transmit the content to a plurality of UEs with minimal buffer required due to the “pre-synchronization.

Abstract: The present disclosure may describes systems and methods for continuous biometric authentication for an electronic device. A continuous biometric authentication may include biometric sensors, processing systems, biometric data, an accelerometer, and other input/output devices. An accelerometer or other input/output devices may be configured to capture information concerning an electronic device, such as an acceleration of the electronic device, and/or information concerning an area surrounding the electronic device, such as ambient light intensity. Based on captured information, a triggering event associated with, for example, a theft, a change in location, or a transfer of possession may be detected by a processing system. Once a triggering event occurs, systems of the present disclosure may initiate additional biometric authentication procedures.

Abstract: Systems and methods for reducing bandwidth loss in IPv6 packet switching networks. A network appliance is configured to sample IPv6 packets and mirror sampled packets to a working memory or memory structure, such as a queue. A transport layer payload is extracted from each sampled packet and a transport layer checksum validation operation is performed. Upon detecting an error, the network appliance updates a dropped packet rate or other metric.

Abstract: The disclosed technology includes at least one method performed by a system of a telecommunications network. The system can establish a communications link between the wireless device and a network access node (NAN) of the 5G network. While connected over a non-mmW band, the wireless device autonomously schedules data downloads to occur when the wireless device is on an mmW band. The system then receives a request from the wireless device to perform the data downloads, which can be enabled by a packet gateway (PGW) upon receiving a confirmation by the NAN that the wireless device can connect over the mmW band. Otherwise, the PGW denies the wireless device's request to perform the data downloads, which can be enforced by the NAN.

Abstract: A label switching router for a switching network configured for source routing can be configured to modify one or more reported properties of a link associated with that router based on one or more link quality metrics. For example, a router can include a link with available bandwidth of 10 Gbps, a value that can be used by a headend when evaluating nodes of the network against a set of constraints required by a particular requested connection or tunnel. A link of that router may exhibit an increased bit error rate which can be used by the label switching router to artificially deflate available bandwidth, thereby reducing the number of label switching paths including the router are selected by the headend.

Abstract: A mobile sensor reader for Internet of Things (IoT) devices includes a wireless communications system, a memory configured to store sensor data received via the wireless communications system from an IoT device, and a processor. The processor is configured to monitor for remote electronic data collectors that come within a communication range of the wireless communications system as at least one of the mobile sensor reader or one of the remote electronic data collectors move to different locations; determine a first parameter of a remote electronic data collector that has come within the communication range of the wireless communications system; determine a second parameter of the mobile sensor reader or the sensor data; and forward the sensor data to the remote electronic data collector, via the wireless communications system, at least partly in response to the first parameter and the second parameter satisfying a set of one or more conditions.

Abstract: An electronic device includes a network communications interface, a processor, and a memory configured to store instructions that, when executed by the processor, cause the processor to instantiate a set of processes; receive, over a network and via the network communications interface, a policy for network socket creation; receive, from the set of processes, a set of requests to create a first set of network sockets used to communicate over the network via the network communications interface; collect telemetry pertaining to a second set of network sockets used to communicate over the network via the network communications interface; allow or block creation of network sockets in the first set of network sockets, in accordance with the collected telemetry and the policy for network socket creation; and transmit at least part of the collected telemetry to a controller, over the network and via the network communications interface.

Abstract: Systems, methods, and apparatuses for providing cellular network enhancements may utilize sensors mounted on or within a cellular base stations to collect information concerning environmental and/or shelter conditions. The collected information may be used by processing devices to predict a future load on a cellular network and may be used to optimize the number of channels needed for a particular base station. The collected information may also be transmitted to electronic devices in a cell coverage area to inform users of the electronic devices of the detected environmental and/or shelter conditions.

Abstract: An unmanned aerial vehicle (UAV) is disclosed. The UAV includes a flight system, a communications system, and a processing system. The communications system includes a cellular radio configured to support multiple contemporaneous communications connections, including at least a first communications connection with a cellular radio access network, at least a second communications connection with a second UAV in a set of one or more UAVs, and at least a third communications connection with a user equipment (UE) in a set of one or more UEs. The processing system is configured to control the flight system and relay communications between the cellular radio access network, the set of one or more UAVs, and the set of one or more UEs, in accordance with a mesh network protocol.