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 a 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.

Abstract: Aspects of the subject disclosure may include, for example, detecting a request for a network service between two network nodes and identifying a network path between the two network nodes, wherein the network path is realized by equipment performing a number of network functions. A first network function of the number of network functions is associated with a first number of redundant virtualized network resources performing at least a similar network function as the first network function. Usage metrics are determined corresponding to the first number of redundant virtualized network resources and a first virtualized network resource of the first number of redundant virtualized network resources is assigned to the network path based on the usage metrics to obtain a first assigned virtualized network resource. The network service is provided between the two network nodes using the first assigned virtualized network resource. Other embodiments are disclosed.

Abstract: Concepts and technologies disclosed herein are directed to master service orchestration of virtual network functions (“VNFs”). According to one aspect of the concepts and technologies disclosed herein, a network functions virtualization (“NFV”) platform includes a hardware resources layer including a plurality of hardware resources, a plurality of VNF resource pools, a plurality of service controllers corresponding to the plurality of VNF resource pools, and a master service orchestrator. The master service orchestrator can, when executed by at least a portion of the plurality of hardware resources, causes the master service orchestrator to perform operations. In particular, the master service orchestrator can receive, from a user equipment (“UE”), a service request.

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: Aspects of the subject disclosure may include, for example, receiving, from an application server, a data transfer request associated with delivery of data from the application server to a wireless communication device that is connected to a mobile communication network, determining a priority score for the data transfer request associated with the wireless communication device according to status information in a subscription profile associated with the wireless communication device, comparing the priority score for the data transfer request associated with the wireless communication device to a plurality of priority scores associated with a plurality of data transfer requests associated with deliver of data to a plurality of wireless communication devices that are connected to the mobile communication network to generate a transfer order mapping of a set of requests comprising the data transfer request and the plurality of data transfer requests, and transferring the data from the application server to the

Abstract: Dynamically switching between broadcast and unicast services for service continuity between wireless networks is presented herein. A system can comprise a detection component configured to determine that a mobile device is receiving a broadcast transmission of broadcast data from a broadcast enabled access point device configured to send, via a broadcast service wireless coverage area, the broadcast data to multiple devices via a point-to-multipoint communication protocol. Further, the detection component can detect a movement of the mobile device from the broadcast service wireless coverage area to a unicast service wireless coverage area. A transfer component can initiate, in response to the detection, a unicast transmission of the broadcast data from a unicast enabled access point device to the mobile device—the unicast enabled access point device configured to send, via the unicast service wireless coverage area, the broadcast data to a single device via a point-to-point communication protocol.

Abstract: Aspects of the subject disclosure may include, for example, detecting a request for a network service between two network nodes and identifying a network path between the two network nodes, wherein the network path is realized by equipment performing a number of network functions. A first network function of the number of network functions is associated with a first number of redundant virtualized network resources performing at least a similar network function as the first network function. Usage metrics are determined corresponding to the first number of redundant virtualized network resources and a first virtualized network resource of the first number of redundant virtualized network resources is assigned to the network path based on the usage metrics to obtain a first assigned virtualized network resource. The network service is provided between the two network nodes using the first assigned virtualized network resource. Other embodiments are disclosed.

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: A method includes receiving, at a server connected to a network, a plurality of emergency alerts from a plurality of devices connected to the network. The method also includes analyzing, by the server, the plurality of emergency alerts to determine an emergency type of each of the plurality of emergency alerts. The method includes categorizing, by the server, the plurality of emergency alerts based on the emergency type of each of the plurality of emergency alerts. The method includes prioritizing a first category of the plurality of emergency alerts and consolidating the plurality of emergency alerts of the first category into a consolidated alert. The method includes causing the consolidated alert to be provided to an emergency responder.

Abstract: Pairing of a radio access network (RAN) slice to a core network (CN) slice is disclosed. The pairing can be based on RAN slice information, CN slice information, and device information. The device information can enable access to corresponding information from a data store, such as historical pairing correlated to a device, device type, etc. Moreover, other supplemental information, such as service information, can also be employed in determining the pairing. In an aspect, the other supplemental information can enable access to corresponding information form a data store, such as other CN slices comprising an identified virtual network function, historical performance of previously determined pairing(s), etc. A determined pairing can be modified before provisioning or after provisioning based on the RAN slice information, CN slice information, supplemental information, or corresponding information.

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: 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: Aspects of the subject disclosure may include, for example, allocating virtual network function resources for a wireless connection with a gateway device, facilitating establishing the wireless connection with the gateway device utilizing the virtual network function resources to provide for transmitting of data from the gateway device to an application server where the data is stored by the gateway device until a determination is made that a threshold associated with the data has been satisfied, and tearing down the virtual network function resources responsive to a determination that the transmitting of the data from the gateway device to the application server via the wireless connection has been completed. Other embodiments are disclosed.

Abstract: A dynamic recovery system for a network comprising: an orchestrator, the orchestrator communicates with at least one mobility management entity in the network to monitor at least one of a key performance and a key capacity indicator; the orchestrator upon detecting that the at least one the key performance and key capacity indicator is above an operator configured threshold: instantiates at least one virtual mobility management entity, disables a communications profile towards the mobility management entity, and provides a communications profile toward at least one virtual mobility management entity.

Abstract: Aspects of the subject disclosure may include, for example, determining a compatibility of the mobile station with a 3GPP IMS architecture. In response to determining that the mobile station is compatible with the 3GPP IMS architecture, a transfer is facilitated of the machine-type communication message to the mobile station via a network element of an IMS network core. In response to determining that the mobile station is not compatible with the 3GPP IMS architecture a forwarding is facilitated of the machine-type communication message to a machine-type communication interworking function associated with the mobile station, wherein the machine-type communication interworking function facilitates a directing of the machine-type communication message to the mobile station via an SGs interface of a mobility management entity of an evolved packet core of a 3GPP long term evolution network. Other embodiments are disclosed.

Abstract: Concepts and technologies disclosed herein are directed to master service orchestration of virtual network functions (“VNFs”). According to one aspect of the concepts and technologies disclosed herein, a network functions virtualization (“NFV”) platform includes a hardware resources layer including a plurality of hardware resources, a plurality of VNF resource pools, a plurality of service controllers corresponding to the plurality of VNF resource pools, and a master service orchestrator. The master service orchestrator can, when executed by at least a portion of the plurality of hardware resources, causes the master service orchestrator to perform operations. In particular, the master service orchestrator can receive, from a user equipment (“UE”), a service request.

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: A method includes receiving, at a server connected to a network, a plurality of emergency alerts from a plurality of devices connected to the network. The method also includes analyzing, by the server, the plurality of emergency alerts to determine an emergency type of each of the plurality of emergency alerts. The method includes categorizing, by the server, the plurality of emergency alerts based on the emergency type of each of the plurality of emergency alerts. The method includes prioritizing a first category of the plurality of emergency alerts and consolidating the plurality of emergency alerts of the first category into a consolidated alert. The method includes causing the consolidated alert to be provided to an emergency responder.

Abstract: Concepts and technologies disclosed herein are directed to universal peer-to-peer signaling network virtualization and orchestration. According to one aspect of the concepts and technologies disclosed herein, a universal DIAMETER orchestrator can determine DIAMETER peer nodes to be utilized to handle DIAMETER signaling traffic for a service. The universal DIAMETER orchestrator can allocate transport resources over which a transport connection between the DIAMETER peer nodes can be established. In some embodiments, the universal DIAMETER orchestrator can allocate the transport resources on-demand. The universal DIAMETER orchestrator can allocate DIAMETER resources to provision DIAMETER signaling interfaces to handle the DIAMETER signaling traffic between the DIAMETER peer nodes. In some embodiments, the universal DIAMETER orchestrator can allocate the DIAMETER resources in accordance with a rule to override a traditional DIAMETER routing agent.

Abstract: Aspects of the subject disclosure may include, for example, identifying a machine-type communication message directed to a mobile station and determining a compatibility of the mobile station with a 3GPP IMS architecture. In response to determining that the mobile station is compatible with the 3GPP IMS architecture, a forwarding is facilitated of the machine-type communication message to the mobile station via a network element of an IMS network core. In response to determining that the mobile station is not compatible with the 3GPP IMS architecture a forwarding is facilitated of the machine-type communication message to a machine-type communication, interworking function associated with the mobile station, wherein the machine-type communication, interworking function facilitates a directing of the machine-type communication message to the mobile station via an SGs interface of a mobility management entity of an evolved packet core of a 3GPP long term evolution network. Other embodiments are disclosed.