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, 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: 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: Initiation of a network slice event is disclosed. The network slice event can be initiated in response to, and according to a determined a network slice event instruction. The network slice event can result in modification of network slices of a network. The modification of the network slices can correspond to a change in the performance of the network. The modification of the network slices can comprise adding a new slice, removing an existing slice, adapting an existing slice, etc. Artificial intelligence, machine learning, etc., can be employed to provide an inference related to determining the network slice event instruction. The slice event can be implemented via a network controller, for example an ONAP component, based on the network slice event instruction.

Abstract: Core network slices that belong to a given operator community are efficiently tracked at the network control/user plane functions level, with rich data analytics in real-time based on their geographic instantiations. In one aspect, an enhanced vendor agnostic orchestration mechanism is utilized to connect a unified management layer with an integrated slice-components data analytics engine (SDAE), a slice performance engine (SPE), and a network slice selection function (NSSF) in a closed-loop feedback system with the serving network functions of one or more core network slices. The tight-knit orchestration mechanism provides economies of scale to mobile carriers in optimal deployment and utilization of their critical core network resources while serving their customers with superior quality.

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: 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: 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: Core network slices that belong to a given operator community are efficiently tracked at the network control/user plane functions level, with rich data analytics in real-time based on their geographic instantiations. In one aspect, an enhanced vendor agnostic orchestration mechanism is utilized to connect a unified management layer with an integrated slice-components data analytics engine (SDAE), a slice performance engine (SPE), and a network slice selection function (NSSF) in a closed-loop feedback system with the serving network functions of one or more core network slices. The tight-knit orchestration mechanism provides economies of scale to mobile carriers in optimal deployment and utilization of their critical core network resources while serving their customers with superior quality.

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: 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: 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: Aspects of the subject disclosure may include, for example, a method, including routing 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. A loss of operating performance of the first media gateway device may be detected and the session status information re-routed from the content server to a second media gateway device responsive to the detecting of the loss of operating performance of the first media gateway device, the second media gateway device initiating second communicative couplings according to the session status information for transmission of the first media stream from the content server to the group of wireless communication nodes to enable distribution to a group of end user devices.

Abstract: Aspects of the subject disclosure may include, for example, identifying positioning information associated with a wireless communication device, determining a current location of the wireless communication device based on the positioning information, detecting a location change based on the current location of the wireless communication device, and responsive to the detection of the location change, sending a location change notification to a location management entity. Other embodiments are disclosed.

Abstract: A method and apparatus for providing a virtual network function in a visited network are disclosed. For example, the method receives an attach request or a handover for a user endpoint device, determines a home network for the user endpoint device, receives a profile of the user endpoint device, determines a policy for providing a service to the user endpoint device in accordance with the profile, determines a set of virtual network functions needed for providing the service to the user endpoint device in accordance with the policy, grants the attach request or the handover, designates for each virtual network function of the set of virtual network functions that is needed for providing the service, a corresponding virtual network function for serving the user endpoint device at a location of the user endpoint device, and provides the service to the user endpoint device via the set of virtual network functions.

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: 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: 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: 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, receiving a request to initiate a wireless media broadcast of media content by way of a wireless mobility network to mobile devices within a geographical area, wherein the media content is provided by a first mobile device. A group of wireless access terminals is determined based on the geographical area, wherein the group of wireless access terminals provides wireless services of the wireless mobility network to a serving area within the geographical area. The group of wireless access terminals is directed to initiate a Multimedia Broadcast/Multicast Service (MBMS) bearer service to distribute the media content to the group of mobile devices within the serving area. Other embodiments are disclosed.