Systems and methods are described for using opportunistically delayed delivery of content to address sub-optimal bandwidth resource usage in network infrastructures that allow subscribers to share forward link resources. According to some embodiments, content is identified as delayable and assigned to a delaycast queue and/or service flow. For example, a server system of a satellite communications system identifies content that can be delayed to exploit future excess link capacity through multicasting and to exploit subscriber-side storage resources. Some implementations attempt to exploit any excess link resources at any time, while others exploit unused bandwidth only during certain times or when a certain threshold of resources is available. Various embodiments also provide content scoring and/or other prioritization techniques for optimizing exploitation of the delaycast queue.

Systems, methods, apparatuses, and computer readable media may be configured for establishing at least one session for delivery of multimedia. In an aspect, a first transmission of data fragments of a first component and a second transmission of data fragments of a second component may be transmitted and synchronized for presentation. If an inactivity event is detected the session may be maintained while reducing bandwidth consumption.

Disclosed are systems, methods, and non-transitory computer-readable media for bandwidth allocation in multi-track media communication that can include receiving a set of inbound media tracks; resolving track priority configuration for the set of media tracks; resolving media constraints that are at least partially derived from properties of the set of media tracks; producing bandwidth allocation configuration based on at least the track priority configuration and media constraints; and allocating bandwidth to outbound media tracks within a communication link to a client device wherein bandwidth of the outbound media tracks is allocated based on the bandwidth allocation configuration.

An example method for lockless communications network resource quota sharing occurs at a first charging node of a distributed charging system comprising multiple charging nodes. The example method comprises: receiving, from a requesting entity, a first communications network resource quota request for requesting a first resource amount from the shared resources plan; without confirming that the shared resources plan has enough available resources to allot the first resource amount, providing, to the requesting entity, a first communications network resource quota for the first member, wherein the first communications network resource quota indicates a second resource amount less than the first resource amount and/or wherein the first communications network resource quota is associated with a validity time indicating when the first communications network resource quota expires; and sending, to a second charging node, a first resource reservation request for reserving resources of the shared resources plan.

Systems and methods are described herein for inserting supplemental content into a QAM signal. A unicast QAM signal between a server and a client device for delivery of content is established. The QAM signal has a particular frequency corresponding to the channel on which it will be transmitted to the client device. A request or other signal may be received from the client device requesting that supplemental content be inserted into the QAM signal. A portion of the bandwidth of the QAM signal is allocated for the supplemental content. The supplemental content is transcoded into a supplemental QAM signal in the particular frequency. The supplemental content may be packetized content such as internet protocol-based content and may be retrieved from a server or database. The supplemental QAM signal is then inserted into the unicast QAM signal using the allocated portion of the bandwidth.

A session management function (SMF) receives, from a wireless device, an indication that an always-on packet data unit (PDU) session is requested. The SMF determines to establish the PDU session as an always-on PDU session based on: the indication that the always-on PDU session is requested; and the PDU session being for an ultra-reliable low-latency communication (URLLC) service. The SMF sends, to the wireless device, an indication that the PDU session is to be established as the always-on PDU session.

Systems and methods for providing multi-perimeter firewalls via a virtual global network are disclosed. In one embodiment the network system may comprise an egress ingress point in communication with a first access point server, a second access point server in communication with the first access point server, an endpoint device in communication with the second access point server, a first firewall in communication with the first access point server, and a second firewall in communication with the second access point server. The first and second firewalls may prevent traffic from passing through their respective access point servers. The first and second may be in communication with each other and exchange threat information.

Embodiments provide apparatuses, systems, and methods related to an electronic device that includes first one or more ports to transmit data from the electronic device, and one or more buffers to buffer the data prior to transmission of the data on the ports. The electronic device may further includes a bandwidth management module to: identify a bandwidth required to transmit an amount of the data on the first one or more ports; identify bandwidth-related parameters of the first one or more ports; and identify, based on the bandwidth-related parameters and the bandwidth required to transmit the amount of the data, buffer allocation of the data. The electronic device may further include a buffer management module coupled with the bandwidth management module, the buffer management module to allocate the data to the one or more buffers based on the buffer allocation. Other embodiments may be described and claimed.

A technique is described for quantifying a change in a system parameter in response to a perturbation of another system parameter by identifying a region of influence of the perturbation and by limiting the propagation of the perturbation to the identified region.

Some embodiments provide policy-driven methods for deploying edge forwarding elements in a public or private SDDC for tenants or applications. For instance, the method of some embodiments allows administrators to create different traffic groups for different applications and/or tenants, deploys edge forwarding elements for the different traffic groups, and configures forwarding elements in the SDDC to direct data message flows of the applications and/or tenants through the edge forwarding elements deployed for them. The policy-driven method of some embodiments also dynamically deploys edge forwarding elements in the SDDC for applications and/or tenants after detecting the need for the edge forwarding elements based on monitored traffic flow conditions.