Some embodiments of the invention provide a method for proactively optimizing network performance for a software-defined wide area network (SD-WAN), which connects multiple devices operating in multiple network segments, during an active network flow. The method monitors the SD-WAN for network events related to the active network flow. The method detects a particular network event at a first device in a first segment in the SD-WAN traversed by the active network flow. Based on the particular network event, the method performs a proactive action on at least a second device in a second network segment in the SD-WAN that will be traversed by the active network flows in order to mitigate a potential negative impact of the particular network event on the performance of the SD-WAN to improve overall network performance.

A system that determines whether a trigger has occurred within a cloud infrastructure. The system, in response to determining that a trigger has occurred, extracts characteristics from one or more virtual network functions (VNFs) of a service chain. The system, in response to extracting characteristics from the one or more VNFs, determines rehoming actions for each of the one or more VNFs. The system, in response to determining rehoming actions, predicts a rehoming delay or a chain downtime for each of the rehoming actions for each of the one or more VNFs. The system determines an optimal rehoming action from the rehoming actions for at least one of the one or more VNFs using the rehoming delay or the chain downtime for each rehoming action of the rehoming actions. The system performs the optimal rehoming action for the at least one of one or more VNFs.

Novel tools and techniques are provided for implementing network application programming interface (“API”), and, more particularly, API to provide network metrics and network resource control to users. In some embodiments, a computing system might receive customer network telemetry data from a first network via a gateway API, might receive service provider network telemetry data from a second network(s) via a network API, might compile the customer network telemetry data and the service provider network telemetry data, might receive a request from a user to access information regarding network services associated with the user, might filter the compiled customer network telemetry data and the compiled service provider network telemetry data to isolate first telemetry data and second telemetry data, respectively, might provide the user with access to at least one of the first telemetry data or the second telemetry data, and might provide the user with options to control network resources.

Aspects of the subject disclosure may include, for example, a method in which a processing system receives data at an edge node of a network that also includes regional nodes and central nodes. The processing system also determines a latency criterion associated with an application for processing the data; the application corresponds to an application programming interface. The method also includes processing the data in accordance with the application, monitoring a latency associated with the processing, and determining whether the latency meets the latency criterion. The processing system dynamically assigns data processing resources so that the latency meets the latency criterion; the resources include computation, network and storage resources of the edge node, a central node, and a regional node in communication with the edge node and the central node. Other embodiments are disclosed.

In accordance with embodiments disclosed herein, there are provided apparatus, systems and methods for implementing and using optimized control systems for aggregation of multiple broadband connections over radio interfaces. For example, such a system may include: a processor and a memory to perform instructions embodied by the system; a plurality of antennas; a traffic coordinator to interface to two or more wireless communications nodes together, through the system, in which each of the wireless communications nodes have access to a wide Area Network (WAN) backhaul connection independent of the system; a first wireless communications interface to a first wireless communication node established via a first of the plurality of antennas, the first wireless communications node having access to a first WAN backhaul connection; a second wireless communications interface to a second wireless communications node established via a second of the plurality of antennas, the second wireless communications node having access to a second WAN backhaul connection distinct from the first WAN backhaul connection; and a control module to receive information on traffic flows through the system and a radio environment within which the system operates, in which the control module to: issue commands to control the formation and continuation of connections of the first and second wireless communications interfaces to WAN connections and WAN backhaul connections, and to further provide scheduling and routing instructions for the WAN connections and WAN backhaul connections. Other related embodiments are disclosed.

A method and system are for generating a report for delivery to or access or query by a network operator by determining, by a server-side proxy, optimization efficiency for traffic in a wireless network, tracking, by the server-side proxy, user-related information in the wireless network, generating, based on at least one of the optimization efficiency and the user-related information, a report for delivery to or access by an operator of the wireless network, the report including an alert of viral take-up of a new application, and performing, by the server-side proxy, traffic optimization functions alleviating traffic in the wireless network.

A method and system are for generating a report for delivery to or access or query by a network operator by determining, by a server-side proxy, optimization efficiency for traffic in a wireless network, tracking, by the server-side proxy, user-related information in the wireless network, generating, based on at least one of the optimization efficiency and the user-related information, a report for delivery to or access by an operator of the wireless network, the report including an alert of viral take-up of a new application, and performing, by the server-side proxy, traffic optimization functions alleviating traffic in the wireless network.

A network device (ND) includes packet processing circuitry and performance optimization circuitry. The packet processing circuitry is connected to a network and is configured to process communication packets for communicating over the network. The packet processing circuitry includes a plurality of configuration registers for setting one or more operation parameters of the ND. The performance optimization circuitry is configured to improve a performance measure of the ND by iteratively calculating the performance measure and adjusting values of one or more of the configuration registers based on the performance measure.

The present disclosure describes methods and systems for an automatic device discovery. A registration request is transmitted to register a media device with a server, the registration request comprising a device identifier associated with the media device. A discovery request is caused to be issued to allow client devices previously registered with the server and connected to the first network to discover the media device, wherein the discovery request is to cause at least a subset of the client devices previously registered with the server and connected to the first network to initiate discovery of the media device without requesting permission from a user of a respective client device to initiate the discovery of the media device, wherein the at least the subset of the client devices includes two or more client devices each associated with an auto-connect status. An identifier of each of the one or more client devices that are previously registered with the server and connected to a first network and an indication of whether each of the one or more client devices has discovered the media device are received, wherein each of the plurality of client devices is associated with a registration identifier pertaining to the first network.

The disclosure provides an approach for service deployment. Embodiments include receiving an indication of user intent for deployment of one or more services in a network from a user that is not an administrator of the network, wherein the indication of the user intent comprises a domain specific language (DSL). Embodiments include parsing the indication of the user intent to determine one or more constraints for deploying the one or more services. Embodiments include receiving topology information for the network, wherein the topology information comprises associations between racks and machines in the network. Embodiments include receiving network performance information for the network. Embodiments include determining one or more deployment rules for the one or more services based on the one or more constraints, the topology information, and the network performance information. Embodiments include deploying the one or more services in the network based on the one or more deployment rules.