A communication system that may include a traffic management module and a communication interface module. The communication interface module is arranged to: estimate a status of multiple channels by utilizing hardware channel status estimators, generate filler packets in response to the status of the multiple channels; wherein the filler packets are associated with the multiple channels; send the filler packets to the traffic management module. The traffic management module is arranged to receive multiple input packets that are associated with multiple channels, receive the filler packets; apply a traffic management scheme on the multiple input packets and the filler packets to provide multiple intermediate packets that comprise (a) multiple filler traffic managed packets and (b) multiple non-filler traffic managed packets.

A system, method, and computer program product are provided for transmitting network communications at a point in time automatically determined based on communication rates. In use, a communication to be transmitted over a network is identified, utilizing a device. Additionally, a point in time at which to transmit the communication over the network is automatically determined by the device, utilizing at least one rate for the communication. Further, transmission of the communication over the network is initiated at the determined point in time, utilizing the device.

A data center failure management system and method in a Software Defined Networking (SDN) deployment. In one embodiment, an SDN controller associated with the data center is configured to learn new flows entering the data center and determine which flows require flow stickiness. Responsive to the determination, the SDN controller generates commands to one or more switching nodes and/or one or more border gateway nodes to redirect the sticky flows arriving at the switching nodes via ECMP routes from the gateway nodes or avoid the ECMP routes by the gateway nodes in order to overcome certain failure conditions encountered in the data center, an external network, or both.

A first device transmits a first Fibre Channel frame with a first priority to a second device. The first device receives a second Fibre Channel frame from the second device, where the second Fibre Channel frame has a second priority indicated by the second device. The first device determines whether to adopt the second priority indicated by the second device or whether to continue to use the first priority for transmitting subsequent Fibre Channel frames to the second device.

Bandwidth management systems and methods performed in a Software Defined Networking (SDN) controlled network include, responsive to detecting congestion on one or more network services with identifiable data therein, obtaining policy associated with the congested network services and causing bandwidth on demand in the network to mitigate the congestion if the bandwidth on demand is possible in the network and permitted based on the policies of the congested network services; responsive to the congestion remaining subsequent to the bandwidth on demand or if the bandwidth on demand is not possible or permitted, orchestrating bandwidth for the congested network services based on their associated priority in their policy; and, responsive to the congestion remaining subsequent to the orchestrating bandwidth based on priority, orchestrating bandwidth for the congested network services based on an amount remaining to download for each of the congested network services.

Through the identification of different packet-types, packets can be handled based on an assigned packet handling identifier. This identifier can, for example, enable forwarding of latency-sensitive packets without delay and allow error-sensitive packets to be stored for possible retransmission. In another embodiment, and optionally in conjunction with retransmission protocols including a packet handling identifier, a memory used for retransmission of packets can be shared with other transceiver functionality such as, coding, decoding, interleaving, deinterleaving, error correction, and the like.

Multi-link transportation of media, video and other data of the type having multiple layers, streams and/or encodings is contemplated. The multi-link transportation may be facilitated with a scheduler configured to schedule the various layers, streams, encodings, etc. for transportation over selectable communication links, such as based on reliability, capacity and/or other operating characteristics.

Example implementations relate to end-to-end quality of service in storage area networks. For example, a method includes receiving input at a target from a user, the input to assign a priority level to a logical unit. This may include registering the logical unit priority level at a switch using an in-band communication in response to the priority level being assigned to the logical unit. This can also include instructing a host to implement the priority level using the in-band communication in response to the priority level being assigned to the logical unit. Further, the methods and systems may enforce the priority level with the host, the switch, and the target.

A transit device receives a target token request sent by a data transmit end, and sends the target token request to a data receive end. The data receive end may determine, based on the target token request, a target token packet corresponding to the target token request, and then send the target token packet to the transit device based on a priority identifier. The transit device determines a sending rate of the token packet based on a link bandwidth of the current device, a preset packet length of a token packet, and a preset packet length of the data packet, and sends the target token packet to the data transmit end based on the priority identifier and the sending rate of the token packet. The transit device may send the target data packet to the data receive end.

The present disclosure discloses a method and a network device for adaptive resource allocation in congested wireless local area network deployment. Specifically, a network device dynamically assigns priorities of client devices associated with a remote access point based at least on an application type or a traffic type corresponding to each client device. Further, the network device transmits the priorities of the client devices to the remote access point in response to the wired uplink being unavailable. The priorities of the client devices facilitate the remote access point to limit a number of client devices connected to the remote access point subsequent to the wired uplink being unavailable.