Abstract: Protocol agnostic wrapping (PAW) and/or data analytics engine (DAE) functions are embedded within a service capability exposure function (SCEF) entity for handling dynamic device triggering, event monitoring, and/or reporting of Internet of things (IoT) devices. The enhanced SCEF creates a dynamic mobility network infrastructure model for global IoT connectivity and new services delivery. The PAW function can be utilized for enhancing massive IoT devices connectivity with their respective application servers in the next-generation mobility network. By employing the PAW function, the SCEF can generate and securely expose flexible application programming interfaces (APIs) to the external network of various third party IoT application service providers, which in turn can utilize the APIs to access their targeted IoT devices via network elements and extract critical device and network capabilities on an event basis.

Abstract: Aspects of the subject disclosure may include, for example, a method, including routing, by a system comprising a processor, session status information from a content server to a first media gateway device, the first media gateway device initiating first communicative couplings according to the session status information for transmission of a first media stream from the content server to a group of wireless communication nodes over a multicast-broadcast single frequency network.

Abstract: The concepts and technologies disclosed herein are directed to network functions virtualization (“NFV”) leveraging unified traffic management and real-world event planning. According to one aspect of the concepts and technologies disclosed herein, a virtual network traffic management system (“VNTMS”) can receive, via a traffic congestion monitor, from a virtual network function (“VNF”), a traffic congestion indicator that includes a traffic congestion state indicative of network traffic congestion experienced by the VNF. The VNTMS can analyze the traffic congestion indicator to determine a traffic management action to be taken to alleviate at least a portion of the network traffic congestion experienced by the VNF, and instruct a traffic congestion action responder to provide the traffic management action to the VNF.

Abstract: Control plane devices are selected by an access point for establishment of end-to-end control plane for a user equipment (UE) coupled to (or requesting to couple to) the access point. In one aspect, the selection is based on data extracted during the setup and/or registration messages communicated between the access point and UE during attachment of the UE to the access point and/or an internal derived mapping of the control pane devices to the access point. In one example, a control plane device pool is segregated to and different sets of control plane devices are selected and utilized to handle traffic associated with different services to improve scaling and flexibility.

Abstract: Providing network device selection for broadcast content is disclosed. Changes to a LTE or LTE-B network can be propagated in real-time, or near-real-time, to a mapping profile representative of the LTE or LTE-B network. This mapping profile can be employed in updating the LTE or LTE-B network. Further, the mapping profile can be employed in establishing a new LTE-B session, adapting an existing LTE-B session, maintaining an existing LTE-B session, etc. Access to a selection rule can enable the LTE or LTE-B network to rank a determined bearer path of the LTE or LTE-B network. LTE-B network and service management can be performed by the LTE-B network or components thereof, such as, at a BMSC component. Moreover, network device selection for broadcast content can be virtualized.

Abstract: Critical radio resources can be intelligently and dynamically managed across traditional consumer mobility and Internet of things (IoT) services in an end-to-end manner. A selective offloading scheme based on monitored traffic dynamics can be utilized to ensure that IoT traffic is steered, on-demand, to a customized and/or dedicated core network slice, thereby enhancing consumer and IoT services experience. In one example, within the IoT domain, traffic can be steered to the customized and/or dedicated core network slice based on various factors, for example, device category and/or congestion per radio carrier, to minimize service disruptions and deliver superior mobility network functionality and/or end-user experience.

Abstract: One or more protocols between a control plane entity (e.g., a mobility management entity (MME)) and its peer nodes (e.g., mobile switching center (MSC) and/or short message service center (SMSC)) are enhanced to improve short messaging services for Internet of things (IoT) devices. Oftentimes, IoT devices enter an extended sleep mode during which they cannot be reached by the control plane entity. In one aspect, the control plane entity can determine a wait period based on information, such as, but not limited to, device context data, mapping tables, policy data, commercial traffic data, latency data, device delay tolerance, sleep mode timer values, etc. The wait period can be provided to the peer nodes, which can utilize the wait period to control one or more message retry mechanisms based on IoT device behaviors resulting in an improvement of overall IoT service behaviors and a delivery of superior IoT customer experience.

Abstract: Systems and methods utilize a machine type communication interworking function and mapping function to manage and route requests from a variety of devices in data networks.

Abstract: A cell broadcast emergency services delivery mechanism for vehicular Internet of Things (IoT) communication is provided. A method can comprise receiving, from a federal emergency management agency device, first data representing federal management emergency event data, aggregating second data representing an emergency event associated with a vehicle with the first data to form third data, based on the emergency event data and the third data, determining a commonality between the first data and the second data, in response to determining the commonality between the first data and the second data, generating metadata, and broadcasting the metadata to the vehicle.

Abstract: Systems and methods utilize a machine type communication interworking function and mapping function to manage and route requests from a variety of devices in data networks.

Abstract: Concepts and technologies are disclosed herein for initiating signaling in mobile management entity pools using workflows. A processor can execute an orchestrator application. The processor can receive location data that indicates a geographic location at which a virtual mobility management entity has been instantiated and registered. The processor can obtain a mobility management entity topology that defines boundaries of two or more mobile management entity pools and identify, based on the location data, one of the mobility management entity pools in which the virtual mobility management entity is located. The processor can identify pool elements included in the mobility management entity pool, obtain a workflow for establishing and configuring the pool elements, and request establishment of signaling between the virtual mobile management entity and the pool elements.

Abstract: Providing integrated LTE-B network and service management is disclosed. Changes to an LTE or LTE-B network can be propagated in real-time, or near-real-time, to a mapping profile representative of the LTE or LTE-B network. This mapping profile can be employed in updating the LTE or LTE-B network. Further, the mapping profile can be employed in establishing a new LTE-B session, adapting an existing LTE-B session, maintaining an existing LTE-B session, etc. Access to a reporting rule can enable the LTE or LTE-B network to proactively report changes to the LTE or LTE-B network. Integrated LTE-B network and service management can be integrated and/or centralized, such as, at a carrier-network, core-component. Moreover, integrated LTE-B network and service management can be virtualized.

Abstract: Aspects of the subject disclosure may include, for example, a method, including receiving from media gateway devices session information that determines communicative couplings between media gateway devices and wireless communication nodes, and detecting a failure of a first media gateway device that provides for transmission of media streams to a first group of wireless communication nodes over a multicast-broadcast single frequency network.

Abstract: Providing network device selection for broadcast content is disclosed. Changes to a LTE or LTE-B network can be propagated in real-time, or near-real-time, to a mapping profile representative of the LTE or LTE-B network. This mapping profile can be employed in updating the LTE or LTE-B network. Further, the mapping profile can be employed in establishing a new LTE-B session, adapting an existing LTE-B session, maintaining an existing LTE-B session, etc. Access to a selection rule can enable the LTE or LTE-B network to rank a determined bearer path of the LTE or LTE-B network. LTE-B network and service management can be performed by the LTE-B network or components thereof, such as, at a BMSC component. Moreover, network device selection for broadcast content can be virtualized.

Abstract: A method includes receiving a request for a communication session from a user device, identifying a first resource from a plurality of resources, wherein the first resource is associated with a first service control layer for a radio access network and wherein the plurality of resources includes at least one virtual network function (VNF), identifying a second resource from the plurality of resources, wherein the second resource is associated with a second service control layer for LTE core functions, identifying a third resource from the plurality of resources, wherein the third resource is associated with a third service control layer for content delivery, allocating a virtual machine to be used to instantiate the at least one VNF, instantiating the at least one VNF and establishing the communication session by facilitating communications between the first service control layer, the second service control layer and the third service control layer.

Abstract: Location based provisioning and broadcasting of content utilizing a multimedia broadcast service is presented herein. A system can comprise a service component, a location component, and a content component. The service component can be configured to receive a request for a client service. The location component can be configured to determine, based on the request, a location corresponding to a mobile device. Based on the location, the content component can be configured to provision a broadcast service device to source content corresponding to the client service, and initiate a broadcast transmission of the content to the mobile device, e.g., using a broadcast enabled access point device that is configured to send broadcast data to multiple devices via a point-to-multipoint communication protocol.

Abstract: Concepts and technologies disclosed herein are directed to policy driven emergency traffic handling for machine-to-machine (“M2M”) device communication. According to one aspect of the concepts and technologies disclosed herein, an M2M application server can receive a plurality of emergency messages from a mobility management entity (“MME”) over a control plane interface. The plurality emergency message can be generated by a plurality of M2M devices in response to an emergency event. The M2M application server can filter, based upon a policy, the plurality of emergency messages to remove duplicate messages of the plurality of emergency messages in order to create a clean group of emergency messages. The M2M application server can forward the clean group of emergency messages to at least one public safety answering point (“PSAP”).

Abstract: Aspects of the subject disclosure may include, for example, determining a request to transfer data to a group of wireless communication devices within an area. Wireless base stations of a wireless mobility network are identified, responsive to the request, wherein the wireless base stations provide wireless communication services within the area, including a Multimedia Broadcast Multicast Service (MBMS) service. A wireless transmission is facilitated of a first broadcast message by the wireless base stations, wherein the first broadcast message identifies the group of wireless communication devices. The broadcast message is transmitted by way of the MBMS service of the wireless communication services. The first broadcast message initiates a state transition to an active state for a plurality of wireless communication devices of the group of wireless communication devices configured in an idle state. Other embodiments are disclosed.

Abstract: Providing integrated LTE-B network and service management is disclosed. Changes to an LTE or LTE-B network can be propagated in real-time, or near-real-time, to a mapping profile representative of the LTE or LTE-B network. This mapping profile can be employed in updating the LTE or LTE-B network. Further, the mapping profile can be employed in establishing a new LTE-B session, adapting an existing LTE-B session, maintaining an existing LTE-B session, etc. Access to a reporting rule can enable the LTE or LTE-B network to proactively report changes to the LTE or LTE-B network. Integrated LTE-B network and service management can be integrated and/or centralized, such as, at a carrier-network, core-component. Moreover, integrated LTE-B network and service management can be virtualized.

Abstract: Concepts and technologies disclosed herein are directed to an enhanced data download mechanism for power constrained Internet of Things (“IoT”) devices. An IoT file share server can receive an update file from an IoT application server. The IoT file share server can calculate a file chunk size based upon a device type of the IoT device and a file size of the update file. The file chunk size can be calculated such that each file chunk of a plurality of file chunks is downloadable to the IoT device in single awake period of the IoT device. The IoT file share server can partition the update file into a plurality of file chunks to be sent to the IoT device, each of which can include a portion of the update file, and the portion can be of the file chunk size.