Abstract: Described herein are techniques for receiving an alert associated with an entity and dynamically determining, based on the alert and on substantially real-time attributes for the entity, a geographically dispersed group in which each member of the geographically dispersed group either is a device associated with the entity or shares at least one attribute with the entity. The techniques further include requesting information about the entity from the geographically dispersed group, receiving information from at least a subset of the group, and taking action responsive to the alert based on the received information.

Abstract: A remote location monitoring arrangement within a wireless communication network. The monitoring arrangement comprises a tracking device for securing to an object. The monitoring arrangement further comprises one or more sentinel devices arranged within at least one of (i) around a boundary area or (ii) within the boundary area, wherein the boundary area is an area in which a user wishes the object to remain. The monitoring arrangement also comprises a monitoring device in communication with at least one of (i) the one or more sentinel devices or (ii) the tracking device such that at least one of (i) at least one of the one or more sentinel devices or (ii) the tracking device alerts the monitoring device over the wireless communication network that (i) the tracking device has left the boundary area or (ii) another object has entered the boundary areas.

Abstract: An input system includes one or more sensor devices that communicate via a local network and collect sensor data, which may be processed by a machine learning model to identify patterns in the data and recognize unusual conditions or potential safety issues. Sensor data may be processed by individual sensor devices having sufficient processing resources, or may be offloaded to a local or remote processor. Notifications may be generated with regard to safety issues, and user input may be received that indicates whether to treat a newly recognized pattern as a problem requiring corrective action, a one-time occurrence, or a pattern to be added to a list of known patterns. Sensor devices may collect data both within and outside the vehicle, and may communicate with in-vehicle systems, mobile computing devices, or other computing devices.

Abstract: This disclosure describes techniques that facilitate granting an access privilege to a client device based on selectively authenticating biometric data. Particularly, a biometric authentication system may generate an authentication policy that authenticates a client identity via biometric authentication protocols. The authentication policy may be based on a security policy of the computing resource associated with the access privilege. The biometric authentication protocols may be based on a kinematic behavior, body chemistry, or physical features of the client. Each biometric authentication protocol may be assigned an authentication score that reflects a confidence that a biometric sample used to gain an access privilege does in fact correspond to the client. Further, an authentication policy may include a random selection of biometric authentication protocols that comply with a security policy of the computing resource.

Abstract: This disclosure describes techniques that facilitate granting an access privilege to a client device based on selectively authenticating biometric data. Particularly, a biometric authentication system may generate an authentication policy that authenticates a client identity via biometric authentication protocols. The authentication policy may be based on a security policy of the computing resource associated with the access privilege. The biometric authentication protocols may be based on a kinematic behavior, body chemistry, or physical features of the client. Each biometric authentication protocol may be assigned an authentication score that reflects a confidence that a biometric sample used to gain an access privilege does in fact correspond to the client. Further, an authentication policy may include a random selection of biometric authentication protocols that comply with a security policy of the computing resource.

Abstract: Systems and methods are described herein for managing communications for a connected vehicle, such as between the connected vehicle and other connected vehicle and/or between the connected vehicle and infrastructure entities, such as providers of services to the connected vehicle. For example, a communication network, such as a network provided by a network carrier, may include various cloud engines or other network-based servers that manage, coordinate, and/or provision communications between the connected vehicle and other parties, such as vehicles, road devices, buildings, and other infrastructure entities.

Abstract: Systems and methods are described herein for managing communications for a connected vehicle, such as between the connected vehicle and other connected vehicle and/or between the connected vehicle and infrastructure entities, such as providers of services to the connected vehicle. For example, a communication network, such as a network provided by a network carrier, may include various cloud engines or other network-based servers that manage, coordinate, and/or provision communications between the connected vehicle and other parties, such as vehicles, road devices, buildings, and other infrastructure entities.

Abstract: Systems and methods for authorizing drones with access to airborne fulfillment centers (AFCs) and other warehouse facilities are described. For example, the systems and methods perform multiple authentication processes, including a physical authentication process and a virtual or electronic authentication process, when determining whether a drone is authorized to access an AFC. Once authorized, the drone may access the AFC to pick up and/or deliver packages or other products, to recharge, to seek repairs, to be housed, and so on.

Abstract: Systems and processes that may be implemented to maintain an up-to-date communication bridge between an Internet-of-Things (IoT) physical network and a cellular telecom network are described herein. The systems and processes may eliminate an incompatibility of a hub device with physical layer technologies (PLTs), e.g. 4G or 5G technology, or various IoT protocols. The hub device may include one or more FPGAs that are configured to facilitate communication using one or more PLTs and/or IoT protocols. The hub device may receive information corresponding to different PLTs and/or IoT protocols, e.g. that the hub device is currently incompatible with, and may reprogram one or more of the FPGAs based on this information to eliminate such incompatibilities.

Abstract: Self-healing charging devices and techniques for identifying and/or troubleshooting causes of performance degradation in user devices are described. A charging device described herein can receive first data from a user device connected to the charging device and analyze the first data to determine diagnostic data associated with the user device. Based at least in part determining the diagnostic data, the charging device described herein can provide an indication via at least one of the charging device or the user device, the indication signifying available actions that can be taken to improve performance of the user device. The charging devices described herein can enable users to easily identify issues causing and/or leading to performance degradation on their user devices and remedy and/or prevent problems that cause the performance degradation while corresponding user devices are charging via the charging devices.

Abstract: A collision avoidance system within an augmented reality environment determines a hazard and notifies the user of the hazard. By determining that the attention of the user is focused on the mobile computing device, and that there is a hazardous condition that the user is approaching, the device provides an alert to the user as to the hazardous condition to protect the user from the hazard. Known hazardous conditions can be stored and provided to a mobile computing device when that mobile computing device is within the vicinity of the known hazardous conditions. The system can also create geofences and provide notifications to the user when a boundary is approached or crossed.

Abstract: Systems and methods for allowing a user to control sharing of network bandwidth in a peer-to-peer environment are described herein. An example telecommunications device includes a user interface device, a processor and a memory device. The telecommunications device identifies one or more time parameters related to bandwidth sharing based on a first operation of the user interface device and identifies one or more bandwidth parameters related to bandwidth sharing based on a second operation of the user interface device. The telecommunications device allows one or more other devices access to one or more networks via one of the telecommunications device or a second device associated with the user, based at least on the identified one or more time parameters and the one or more bandwidth parameters.

Abstract: Example techniques described herein can provision network functional modules for execution in trusted execution environments of portable computing devices. A monitoring application of a portable computing device can validate a trusted execution environment of the portable computing device, determine a present operational capacity of the portable computing device, and transmit indications of the validation and the present operational capacity to a control node via an authenticated connection. The application can detect a remote computing device on one network and determine that the remote device has a trusted execution environment. The application can report the computing device to the control node on another network. A network functional module can receive a request and determine that the portable computing device cannot perform an operation of the request.

Abstract: Systems and methods for allowing a user to control sharing of network bandwidth in a peer-to-peer environment are described herein. An example telecommunications device includes a user interface device, a processor and a memory device. The telecommunications device identifies one or more time parameters related to bandwidth sharing based on a first operation of the user interface device and identifies one or more bandwidth parameters related to bandwidth sharing based on a second operation of the user interface device. The telecommunications device allows one or more other devices access to one or more networks via one of the telecommunications device or a second device associated with the user, based at least on the identified one or more time parameters and the one or more bandwidth parameters.

Abstract: A device may remotely immobilize a vehicle via peer-to-peer device communication or network assisted communication. Initially, a request inputted by a user to initiate vehicle immobilization of a vehicle may be received at a master control device. The master control device may send an information query command to the vehicle communication device of the vehicle via proximity communication. Subsequently, the master control device may receive a device identifier from the vehicle communication device via the proximity communication. A vehicle immobilization request that includes the device identifier may be sent from the master control device to a wireless communication carrier. The request may prompt the wireless communication carrier to broadcast an immobilization command via a cellular communication network to the vehicle communication device of the vehicle that is identified by the device identifier.

Abstract: Updated radio protocol data may be propagated in a peer-to-peer (P2P) distribution scheme so that peer devices that are incompatible with a particular radio protocol may be dynamically re-configured to communicate with other devices using the particular radio protocol. A remote server(s) may push updated radio protocol data to a hub device, which thereafter disseminates the radio protocol data to other peer devices. These peer devices can forward the data to downstream peer devices, and so on, without further intervention by the remote server(s) that initiated the distribution. The transfer of radio protocol data over P2P connections may occur using a broadcasting technique where, prior to the transfer, a device in possession of the radio protocol data broadcasts an indication to nearby peer devices, which can receive the broadcast and indicate to the broadcaster whether they are ready to receive the radio protocol data.

Abstract: A system and method of optimizing a mobile traffic network are provided. A local network group comprising a plurality of user devices is created. One of the plurality of the user devices is selected to act as a gateway for the remaining user devices of the local network group. The selected user device is provisioned to act as a gateway for the local network group. A message is sent to the plurality of user devices of the local network group to route communication through the selected user device via a short range wireless communication technology.

Abstract: A device may remotely immobilize a vehicle via peer-to-peer device communication or network assisted communication. Initially, a request inputted by a user to initiate vehicle immobilization of a vehicle may be received at a master control device. The master control device may send an information query command to the vehicle communication device of the vehicle via proximity communication. Subsequently, the master control device may receive a device identifier from the vehicle communication device via the proximity communication. A vehicle immobilization request that includes the device identifier may be sent from the master control device to a wireless communication carrier. The request may prompt the wireless communication carrier to broadcast an immobilization command via a cellular communication network to the vehicle communication device of the vehicle that is identified by the device identifier.

Abstract: A system and method of providing security service to a mobile traffic network are provided. A local network group comprising a plurality of user devices that are subscribed to the security service is created. One of the plurality of the user devices is selected to act as a firewall for the plurality of user devices of the local network group. The selected user device is provisioned to act as a firewall for the local network group. A message is sent to the plurally of user devices of the local network group to route communication through the selected user device via a short range wireless communication technology.

Abstract: An automation hub may automatically identify the arrival of a package to a location and provide a notification of the delivery to a user. A package authenticator may be generated via the automation hub at the location for embedment in a packaging of a product that is being ordered from a merchant for delivery to the location. Subsequently, the package authenticator may be associated with a pending delivery of the product at the location in response to receiving an indication that the package authenticator is submitted to the merchant via an order. The presence of an arrived package authenticator may be detected in proximity of the location via a sensor that is connected to the automation hub. A notification of arrival for the product may be generated for presentation on connected user devices in response to the arrived package authenticator matching the package authenticator.