This application provides a method, device, and system for determining a bandwidth for service flow transmission. The method includes: A first device obtains a first traffic sampling set of a service flow, where the first traffic sampling set includes one or more pieces of traffic sampling information. The first device obtains a service level parameter corresponding to the service flow and a reliability probability of meeting the service level parameter. The first device determines, based on the first traffic sampling set, the service level parameter, and the reliability probability, a bandwidth for transmitting the service flow.

Implementations relate to identifying an event disrupting connectivity to a first network; determining, for an apparatus, that the apparatus has a connection to a second network; transmitting a message indicating to one or more neighboring devices that the apparatus has network connectivity; receiving a first relay request from a first device and a second relay request from a second device; forwarding, using the connection to the second network, a message associated with the first relay request; and transmitting, to the second device, a backoff message.

Disclosed are various embodiments for customer-defined capacity limit plans in communication networks. In one embodiment, a request for a service from a radio-based network is received from a first client device. A network function in the radio-based network is determined to be at a capacity limit. Service from the network function to a second client device to the network function is suspended in response to determining that the network function in the radio-based network is at the capacity limit and based at least in part on a rule set specific to the radio-based network. The first client device is provided access to the network function instead of the second client device.

Methods, apparatuses and computer programs are disclosed. The method of allocating network resources to a plurality of media flows in a communications network, the method comprising the steps of: determining a media content characteristic for the plurality of media flows; partitioning the plurality of media flows into one or more media flow groups based on the media content characteristic; initiating allocation of a separate network resource pool to the one or more media flow groups to be used by media flows belonging to respective media flow group.

Modifying quality of service treatment for data flows A method of transmitting a data flow via a network is disclosed where the network supports transmission of data in accordance with a plurality of Quality of Service, QoS, models. Prior to transmission of the data flow, a client system configures a first class of service for the data flow based on a first QoS model, and a first portion of the data flow is transmitted through the network in accordance with the first class of service. In response to detecting a renegotiation condition, the network communicates with the client system to configure a second class of service for the data flow based on a second QoS model, and a subsequent portion of the data flow is transmitted through the network using the second class of service.

Some implementations of the disclosure are directed to a method, comprising: receiving a plurality of traffic flows transmitted by a plurality of user devices; determining, at a modem, a user device of the user devices that is associated with each of the traffic flows; classifying, at the modem, each of the traffic flows according to a class of service associated with a traffic class; and allocating, at the modem, bandwidth to each of the traffic flows based on the traffic flow's class of service and the user device associated with the traffic flow. A total available bandwidth may be allocated to the traffic flows as a function of traffic classes associated with the traffic flows, the classes of services associated with the traffic flows, and the user devices that transmitted the traffic flows.

Method for synchronizing control applications via a communication network for transferring time-critical data, wherein network infrastructure devices determine, for the forwarding of datagrams associated with selected data streams, respective time delays between a planned transmission time of the datagram and an actual transmission time of the datagram in question, where the selected data streams are assigned to control applications running on communication terminals, and where a beginning of a next end-node-side transfer cycle is determined by a starting-node-side control application based on the time delay determined by a preceding network infrastructure device in question, an accumulated maximum time delay and a transmission time of the datagrams to achieve synchronization between transfer cycles of starting-node-side control applications and transfer cycles of end-node-side control applications.

Virtual application and desktop delivery may be optimized by supplying application metadata and user intent to the device between a client and a server hosting resources for the delivery. The data packets used to deliver the virtual application or desktop may be also tagged with references to the application. By supplying the metadata and tagging packets with the metadata, an intermediary network device may provide streams of data packets at the target QoS. In addition, the device may apply network resource allocation rules (e.g., firewalls and QoS configuration) for redirected content retrieved by the client out of band relative to a virtual channel such as the Internet. The network resource allocation rules may differ for different types of resources accessed. The device may also control a delivery agent on the server to modify communication sessions established through the virtual channels based on network conditions.

An efficient structure and methodology are provided for communicating in a network using a contract implemented in a packet or frame. In various embodiments, a user can generate a contract clause having a constraint for communicating in the network, and determine a communication layer at which to process the constraint during communication in the network. The user device can insert the contract clause in a position in a packet corresponding to the communication layer and can transmit the packet from the user device. In various embodiments, a network node that receives a packet can identify a contract clause in a packet and can process a constraint from the contract clause. The network node can track performance of the constraint and provide accountability in response to the tracking of the performance with respect to terms associated with the constraint in the contract clause.

The present disclosure envisages optimization of a time-sensitive fog network deployed in an industrial environment. The time-sensitive fog network comprises a plurality of fog nodes communicably coupled to a plurality of industrial equipments referenced as endpoints. Each fog node is embodied with a plurality of computer-based resources including computational resources, storage resources, security resources, network resources, application-specific resources, and device-specific resources. The resource constraints that warrant the endpoints to cooperate with specific fog nodes to access specific resources are manifested as a compute profile, a storage profile, a security profile, a network profile, an application-specific profile, and a device-specific profile. The endpoints are optimally provisioned to cooperate with the fog nodes and consume the computer-based resources embodied therein, based on a deployment model that optimally and deterministically correlates the plurality of computer-based resources embodied in each of the fog nodes to the resource profiles attributed to each of the endpoints.