A method for cross-domain service optimization is implemented on a computing device and includes defining at least one key quality indicator (KQI) target for at least one end-to-end (E2E) service, where the at least one E2E service crosses more than one domain of a communications network, receiving an indication of quality of experience (QoE) for the at least one E2E service, based on the indication of QoE, translating the at least one KQI target to at least one set of service optimization instructions for each domain from among the more than one domain, and for said each domain, applying the service optimization instructions.

A method for determining a quality of voice transmitted by electrical signals between a first telecommunication terminal and a second telecommunication terminal in a telecommunication network, the method comprising: identifying a model type for the first telecommunication terminal and the second telecommunication terminal respectively; identifying at least one operating parameter for the telecommunication network; selecting at least one call aspect (i) of the transmitted voice wherein a quality of the transmitted voice shall be determined for the at least one call aspect; identifying a value of at least one quality parameter (KQI.sub.A/B, i, n) for the at least one call aspect (i) for at least one of the first telecommunication terminal and the second telecommunication terminal as a function of a value of at least one selected engineering parameter (KPI.sub.A/B) of the at least one telecommunication terminal as well as a function of the at least one operating parameter.

An unregistered cable modem is in a cable operator network having a computer, a dynamic host configuration protocol (DHCP) server, a spoofing domain name system (DNS) server and a good DNS server, a captive portal application, and a trivial file transfer protocol (TFTP) server. The cable modem is provisioned by the cable modem obtaining a configuration, rebooting, and activating the configuration. The computer obtains a plurality of computer configuration parameters including an IP address of the spoofing DNS. The spoofing DNS server answers an HTTP request from the computer with an IP address associated with the captive portal application. The captive portal obtains an activation code from the computer, verifies the activation code is correct, and forces the cable modem to reboot.

An optimization platform system includes a network interface configured to communicate with a plurality user devices and a plurality of servers in a network; a processor communicatively coupled to the network interface; and memory storing instructions that, when executed, cause the processor to obtain network measurements including Quality of Service (QoS) measurements and one of measured Quality of Experience (QoE) measurements and inferred QoE measurements from the QoS measurements for one or more streams in the network, wherein each of the one or more streams has a type selected from a group consisting of a video stream, a Voice over Internet Protocol (VoIP) call, a gaming stream, and an Augmented Reality (AR)/Virtual Reality (VR) stream, and wherein the QoE measurements and the inferred QoE measurements of each of the one or more streams is based on the type of the respective stream, analyze the QoE measurements to determine poor QoE in the network, determine remedial actions in the network to repair the poor QoE, and cause implementation in the network.

Various example implementations are directed to circuits, apparatuses, and methods for providing virtual computing services. According to an example embodiment, an apparatus includes a data storage device and a set of computing servers communicatively coupled to the data storage device. The set of computer servers are configured to provide a respective virtual data center for each of a plurality of accounts. The respective virtual data center for each account is configured to provide virtual services specified in a respective settings file for the account stored in the data storage device. The virtual data center for at least one of the accounts includes a set of virtual desktops and a set virtual servers, including at least one Voice-over-IP (VoIP) server. The VoIP server provides VoIP service for a plurality of users of the account.

A system for providing small cell backhaul network communications includes a small cell backhaul network including a plurality of small cell network nodes each including transceivers for establishing wireless communication links with at least two other small cell network nodes and enabling communication with the at least two other small cell network nodes within the small cell backhaul network. The small cell backhaul network interconnecting an edge network with a core network through the plurality of small cell network nodes and enabling communication between the edge network and the core network over the wireless communications links. A software defined network (SDN) controller controls wireless communications links with each of the plurality of small cell network nodes. The transceivers at each of the plurality of small cell network nodes establish link configurations between the small cell network node and the at least two other small cell network nodes of the small cell backhaul network. A plurality of LTE interfaces, each associated with one of the small cell network nodes of the small cell backhaul network for provide control plane connectivity between the small cell network nodes and the SDN controller via a control channel and reduce SDN control latency.

A method for cross-domain service optimization is implemented on a computing device and includes defining at least one key quality indicator (KQI) target for at least one end-to-end (E2E) service, where the at least one E2E service crosses more than one domain of a communications network, receiving an indication of quality of experience (QoE) for the at least one E2E service, based on the indication of QoE, translating the at least one KQI target to at least one set of service optimization instructions for each domain from among the more than one domain, and for each domain, applying the service optimization instructions.

A system and method is provided for a predictive connectivity layer. In the disclosed embodiments, resources, such as bandwidth, processing, and memory, at a network node are dynamically allocated based on one or more predicted user behaviors. A predicted user behavior may be determined based on one or more previous actions of a user or a group of users at the network node. For example, if a user accesses the network node to download a particular web site at the same time every morning, the predictive technique may determine that the user will attempt to download the same web site the next morning, and therefore cache a copy of the web site before the user's next attempt to access the network through the network node, Similarly, the network node may predict an amount of bandwidth or other resources to allocate based on previous behavior of one or more users.

A device may collect network performance data associated with a user equipment of a network. The network performance data may include information associated with a plurality of performance indicators of the network. The device may process information associated with a first portion of the plurality of performance indicators to determine a first performance category experience score, and information associated with a second portion of the plurality of performance indicators to determine a second performance category experience score. The device may process the first performance category experience score and the second performance category experience score to determine a network experience score. The device may determine whether the network experience score satisfies a threshold value. The device may perform one or more actions based on determining that the network experience score satisfies the threshold value.

Systems and methods for providing a network management platform for managing a plurality of deployments are described herein. In an embodiment, a server computer receives a request to generate a plurality of network deployments, including first interface elements and rules for a first network deployment and second interface elements and rules for a second network deployment. The server computer sends the first network deployment to a first plurality of client computing devices and sends the second network deployment to a second plurality of client computing devices. When the server computer receives network usage data from the first and second plurality of computing devices, the server computer provides the network usage data to a network operation with an identification of a corresponding deployment.