A method (100) for managing resource usage across domains in a communication network is disclosed. The communication network comprises a radio access domain, a core domain and a transport domain providing connectivity between the radio access domain and the core domain. The method comprises receiving from the core domain an indication of load status of gateway nodes in the core domain (110), receiving from the transport domain an indication of load status of transport resources in the transport domain (120), normalising across the core and transport domain a cost of using resources in each domain (130), calculating, on the basis of the normalised costs, optimal chains of resources in the core and transport domains for providing a service from different radio access nodes to different possible Access Point Names (APNs) (140), and sending to the core and transport domains information about the calculated optimal resource chains (150). Also disclosed are methods for managing resource usage in a core domain, a transport domain and a radio access domain of a communication network, together with cross domain, core domain, transport domain and radio access domain control elements.

Methods of managing audio data transmissions over a network disclosed herein may include the step of selecting a client device from a plurality of client devices as a participating device, each client device of the plurality of client devices being in data communication with a network. The methods may include the step of signaling the participating device over said network thereby initiating transmitting of audio data from the participating device at least in part over said network for live broadcasting, the audio data being indicative of a speaking voice being input into a participating device microphone of the participating device. The methods may include the step of minimizing latency in transmitting of the audio data by throttling data being communicated over said network by one or more client devices of the plurality of client devices only while the participating device is transmitting audio data over said network.

Apparatuses, methods, and systems are disclosed for communication configuration selection. One apparatus includes a receiver that receives configuration information for multiple communication configurations. The configuration information corresponds to services having different performance requirements, and the performance requirements include latency, reliability, peak data rate, efficiency overhead, control overhead, system capacity, or some combination thereof. The apparatus also includes a processor that selects a communication configuration of the multiple communication configurations. The apparatus communicates using the selected communication configuration.

A method for determining a Quality of Experience associated with a real-time communication session between user devices includes monitoring the real-time communication session and determining at least one quality indicator of the Quality of Experience, at least one first performance indicator of a Quality of Service, and at least one second performance indicator of the Quality of Service. Based on the quality indicator and the first performance indicator, the method determines, among a family of correlation functions indicative of the correlation between the Quality of Experience and a Quality of Service in respect of a generic real-time communication session, a correlation function which is indicative of the correlation between the Quality of Experience and the Quality of Service in respect of the monitored real-time communication session. Then the method applies the first performance indicator and the second performance indicator to the correlation function to determine said Quality of Experience.

A method (200) of configuring a telecommunications network (100), the method comprising the steps 5 of: identifying a User Equipment (UE) (110) utilizing the telecommunications network; ascertaining physical capability information associated with a user of the identified UE (220); determining a network configuration in dependence upon the ascertained physical capability information (240); and configuring a network connection for the identified UE according to the determined network configuration (250).

Various example implementations are directed to circuits, apparatuses, and methods for providing virtual computing services. One example involves a set of computing servers communicatively coupled to the data storage device. The set of computer servers provide a respective virtual data center for each of a plurality of accounts, and the respective virtual data center for each account provides 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.

Systems and methods for providing mobile services are disclosed. In one implementation, an access point (AP) is provided, which may include a set of one or more base-station functions for use by a user equipment (UE) connected to the AP over a wireless communication interface. The one or more base-station functions may be configured to receive information from the UE. The AP may further include a set of one or more core-network functions configured to receive the information from the set of one or more base-station functions and a distributed portion of a service. The distributed portion of the service may be configured to receive the information from the one or more core-network functions and communicate the information to a corresponding cloud portion of the service running on a cloud platform. The service may be provided by a combination of the distributed portion and the cloud portion of the service. The distributed portion of the service may be further configured to receive a response from the cloud portion of the service based on processing performed by the cloud portion on the cloud platform.

Systems and methods are disclosed to provide packet copy management for service chain processing within virtual processing systems. A packet manager virtual machine (VM) controls access to shared memory that stores packet data for packets being processed by service chain VMs operating within a virtual processing environment. For certain embodiments, the packet manager VM is configured to appear as a destination NIC (network interface controller), and virtual NICs (vNICs) within the service chain VMs are configured to process packet data using pointers to access the packet data within the shared memory. Once packet data is processed by one service chain VM, the next service chain VM within the service chain is able to access the processed packet data within the shared memory through the packet manager VM. Once all service chain processing has completed, the resulting packet data is available from the shared memory for further use or processing.

A method for setting a policy for Over-The-Top (OTT) calls in a mobile network is provided. The method includes determining whether a cell of the mobile network has at least one neighboring cell of at least one roaming partner of the mobile network, and determining a bearer policy for routing OTT calls in the cell based on whether the cell is determined to have the at least one neighboring cell of the at least one roaming partner. The determined bearer policy indicates whether the OTT calls in the cell are to be routed on a dedicated bearer or a default bearer for connecting to an Internet Access Point Name (APN).

Active management of a data network facilitates the high-quality live broadcast of captured digital audio from multiple client devices present in a venue. In various aspects, the system includes a network hub. The network hub transmits and receives data from a plurality of the client devices which may be personal mobile devices. A network manager component manages communications of the client devices with the network hub. The network manager uses measured dynamic network parameters and determines conditions for maintaining audio quality according to configurable rules. The dynamic network parameters may include device qualification(s), live measured audio quality of service metrics, and unwanted data packets. In various aspects, dynamic authentication and de-authentication of client devices as well as data transmission throttling of client devices are techniques utilized for active network management. The network manager maintains audio quality for the client device configured or selected to broadcast over the public address system.