Provided are a system and method for controlling a workflow across domains on the basis of a hierarchical engine framework. Inventive workflow control makes it possible to configure a flexible hierarchical engine framework and provide a workflow service with low latency. Also, the system and method make it possible to control a workflow by building an engine and a data pipeline across domains.

Systems and methods are described to predict spikes in requests for content on a computing network based on referrer field values of prior requests associated with spikes. Specifically, a traffic spike prediction service is disclosed that can analyze information regarding past requests on the computing network to detect a spike in requests to a content item, where a significant number of request within the spike include a common referrer field value. The traffic spike prediction service can then detect a request to a second content also including the common referrer field value, and predict that a spike is expected to occur with respect to the second content. The traffic spike prediction service can manage the expected spike by increasing an amount of computing resources available to service requests to the second content.

There is disclosed in one example an application-specific integrated circuit (ASIC), including: an artificial intelligence (AI) circuit; and circuitry to: identify a flow, the flow including traffic diverted from a core cloud service of a network to be serviced by an edge node closer to an edge of the network than to the core of the network; receive telemetry related to the flow, the telemetry including fine-grained and flow-level network monitoring data for the flow; operate the AI circuit to predict, from the telemetry, a future service-level demand for the edge node; and cause a service parameter of the edge node to be tuned according to the prediction.

Peripheral devices such as wearables can link to mobile devices to access network elements. These peripheral devices can comprise a communication part and a processing part. Each of these parts, specially the processing part of the next item in a communication chain, can be multiple times larger and stronger than the previous linked item. For instance, the peripheral device can be connected to the mobile device which can be in line connected to an NodeB device. Because the processing power of mobile device can be several times stronger than the peripheral, a mobile edge computing platform and a multi-access application function facilitate sharing of processing power capabilities between the peripheral devices, mobile devices, and/or the NodeB devices.

A base station determines, based on transmission quality information of a fronthaul and channel quality information of a terminal, a resource and a transmission scheme of the fronthaul assigned to the terminal, and controls, based on determined information, the transmission scheme of a signal to be transmitted to the fronthaul using the determined resource.

Adaptive ambient services are provided. In some embodiments, an adaptive ambient service includes providing an ambient service profile. In some embodiments, an ambient service includes implementing an ambient service profile for assisting control of the communications device use of an ambient service on a wireless network, in which the ambient service profile includes a plurality of service policy settings, and in which the ambient service profile is associated with an ambient service plan that provides for initial access to the ambient service with limited service capabilities prior to activation of a new service plan; monitoring use of the ambient service based on the ambient service profile; and adapting the ambient service profile based on the monitored use of the ambient service.

A method, device and system for creating resources during a user equipment (UE) hands over from a non-3.sup.rd Generation Partnership Project (non-3GPP) system to a 3GPP system are provided. A serving gateway (Serving GW) receives a first resource request message, such as Create Default Bearer Request message, including handover indication information indicating the handover from a mobility management network device, e.g., a MME. As the received resource request message includes the handover indication information, the Serving GW includes the handover indication information in a second resource request message and then sends the second resource request message to a PDN GW. After receiving the second resource request message, the PDN GW policy and charging control (PCC) rules to be used by the UE in the 3GPP access system so as to create the resources used by the UE in the 3GPP system.

A method and system for transferring user equipment (UE) in a mobile communication system are provided. According to the method, a source core (CN) network determines to transfer a UE that it serves and sends a transfer instruction carrying UE transfer restriction information to the UE; an access network receives a transfer request that is sent by the UE according to the restriction information carried in the transfer instruction; the access network selects a target CN entity that is different from the source CN entity for the UE; and the UE is transferred to the target CN entity. The method and system provided by the disclosure are applicable to user transferring between CN entities in any communication network. The transferring is initiated by a network side entity, and a more preferable CN entity is selected for the UE to provide a better service.

Methods and systems for Link Binding Management (LBM), including architectural design, detailed procedures, and embodiments to related standards, are described herein. In a first embodiment, an LBM Architecture A is disclosed which includes four logical entities: a Resource Creator (RC), a Source Resource Host (SRH), a Destination Resource Host (DRH), and a Link Binding Coordinator (LBC). Interactions are defined for these four entities to cooperate in order to efficiently manage link bindings (e.g. link binding creation, link binding update, etc) between source and destination resources. In a second embodiment, an LBM Architecture B is also disclosed which includes a Resource Repository (RR), a SRH.sub.2, a DRH, and a LBC. Interactions on those actors are developed towards efficient link binding management. Detailed procedures for LBM Architecture B are also disclosed.

Some embodiments provide a method for a first network slice selector that selects network slices for connections from endpoint devices located within a first geographic range. The method selects a network slice for a connection between a mobile endpoint device and a network domain that originates when the mobile endpoint device is located within the first geographic range. The method stores state that maps the connection to the selected network slice. The method forwards data traffic belonging to the connection from the mobile endpoint device onto the selected network slice using the stored state. After the mobile endpoint device moves from the first geographic range to a second geographic range, the method receives data traffic belonging to the connection from a second network slice selector that selects network slices for connections from endpoint devices within the second geographic range and forwards said received data traffic onto the selected network slice.