Abstract: A method of selecting a virtual machine (VM) on a mobile device within a wireless communication network based upon context of an incoming event. For example, a virtual intelligence engine can select a VM to handle an incoming phone call based upon the context of the phone call. If the phone call is work-related, then the virtual intelligence engine may select a first VM, while if the incoming phone call is a personal phone call, then the virtual intelligence engine may select a second VM different from the first VM. The VMs can utilize different operating systems.

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: This disclosure describes an in-motion proximity guidance system that may alert a mobile device user of a likelihood that a projected pathway of an in-motion mobile device will intersect with a projected pathway of another in-motion mobile device or a location of a stationary object. The in-motion proximity guidance may further trigger visual and/or audible alerts to indicate an imminent collision. These alerts may be emitted from the in-motion mobile devices or stationary sensor devices physically coupled to stationary objects. Further, the in-motion proximity guidance system may transmit a corrective action to a collision avoidance system of a vehicle that is communicatively coupled to a mobile device in order to reduce a likelihood of an imminent collision. The in-motion proximity guidance system may also interact with a smart traffic light system, such that a sequence of traffic light indications may be altered to avoid an imminent collision between vehicles.

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: 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: 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: 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: 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: 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: This disclosure describes an in-motion proximity guidance system that may alert a mobile device user of a likelihood that a projected pathway of an in-motion mobile device will intersect with a projected pathway of another in-motion mobile device or a location of a stationary object. The in-motion proximity guidance may further trigger visual and/or audible alerts to indicate an imminent collision. These alerts may be emitted from the in-motion mobile devices or stationary sensor devices physically coupled to stationary objects. Further, the in-motion proximity guidance system may transmit a corrective action to a collision avoidance system of a vehicle that is communicatively coupled to a mobile device in order to reduce a likelihood of an imminent collision. The in-motion proximity guidance system may also interact with a smart traffic light system, such that a sequence of traffic light indications may be altered to avoid an imminent collision between vehicles.

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: A telecommunication carrier may stitch data from multiple sources to support device automation and access control. A state may be assigned to a user of a user device at a telecommunication carrier based on a data stitch of information from multiple data sources. The data sources may include data on a geolocation of the user device. The state may be provided to a rules engine at a remote location via a carrier network of the telecommunication carrier. An indication from the rules engine that the user device is granted or denied access to one or more entities at the location based on the state may be received via the carrier network at the telecommunication carrier. In turn, the telecommunication carrier may provide the indication of the granted or denied access to the user device of the user.

Abstract: A user device implements a certificate authority for issuing digital certificates that extend to other computing devices a level of trust to a particular user paired with the user device. The user device may obtain user persona information, generate a user key, and combine the user key with a device key for the generation of a digital certificate. The computing device may further transmit the digital certificate to a certificate management system, which manages interactions between other computing devices and the user device or authorizes operation of other computing devices by the particular user based on the digital certificate.

Abstract: A user device implements a certificate authority for issuing digital certificates that extend to other computing devices a level of trust to a particular user paired with the user device. The user device may obtain user persona information, generate a user key, and combine the user key with a device key for the generation of a digital certificate. The computing device may further transmit the digital certificate to a certificate management system, which manages interactions between other computing devices and the user device or authorizes operation of other computing devices by the particular user based on the digital certificate.

Abstract: A method of selecting a virtual machine (VM) on a mobile device within a wireless communication network based upon context of an incoming event. For example, a virtual intelligence engine can select a VM to handle an incoming phone call based upon the context of the phone call. If the phone call is work-related, then the virtual intelligence engine may select a first VM, while if the incoming phone call is a personal phone call, then the virtual intelligence engine may select a second VM different from the first VM. The VMs can utilize different operating systems.

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: This disclosure describes an in-motion proximity guidance system that may alert a mobile device user of a likelihood that a projected pathway of an in-motion mobile device will intersect with a projected pathway of another in-motion mobile device or a location of a stationary object. The in-motion proximity guidance may further trigger visual and/or audible alerts to indicate an imminent collision. These alerts may be emitted from the in-motion mobile devices or stationary sensor devices physically coupled to stationary objects. Further, the in-motion proximity guidance system may transmit a corrective action to a collision avoidance system of a vehicle that is communicatively coupled to a mobile device in order to reduce a likelihood of an imminent collision. The in-motion proximity guidance system may also interact with a smart traffic light system, such that a sequence of traffic light indications may be altered to avoid an imminent collision between vehicles.

Abstract: A system and method for establishing a dynamic wireless communication network with a plurality of autonomous aerial vehicles, such as drones. The drones can dynamically change the size and availability of the communication network, and work with an existing communication network, such as cellular telecommunications or internet protocol networks. The drones can therefore create and maintain a robust network in response to a variety of needs, such as emergency response areas or large sporting events. Further, the drones can establish communication hotspots for mobile devices, and can alternately be configured to create a data pipeline.

Abstract: Systems and processes that may be implemented to manage access by software applications to various resources of a user telecommunications device are disclosed. The systems and processes may implement a trust policy which reflects privacy criteria selected by a user of the user telecommunications device, wherein the trust policy overrides registered permissions of the software applications. The user telecommunication device may include a memory that stores a software application has been granted registered permissions to access a input and/or output component of the user telecommunications device as well as a trust policy has been set by the user to proscribe access by that particular software application to the input and/or output component. In implementing the trust policy, the software application may be prevented from accessing the input and/or output component notwithstanding the software application having registered permissions to access the input and/or output component.