Abstract: Illustrative embodiments process large amounts of unstructured data by producing, from the unstructured data, a plurality of work items. Each work item includes an item of unstructured data, and corresponding work item metadata. Each work item may be claimed by a corresponding consumer node. In illustrative embodiments, a consumer node claims a work item only when the work item is compatible with the consumer node. The consumer node then processes the claimed work item by performing a specified task on the item of unstructured data associated with the work item.

Abstract: Illustrative embodiments process large amounts of unstructured data by producing, from the unstructured data, a plurality of work items. Each work item includes an item of unstructured data, and corresponding work item metadata. The work items are stored in a work item queue, where they may be claimed by, and processed by, a consumer node from a set of consumer nodes.

Abstract: A network switch includes multiple interface cards and a backplane that interconnects the interface cards. The interface cards receive network traffic and perform time and line switching on the data. The network traffic can include a combination of time division multiplexed (TDM) data and network data (e.g., ATM cells, IP packets). In one embodiment, the channels that carry network traffic to the interface cards are pre-configured as either TDM channels or network channels. The channels are processed as appropriate for their respective types by the interface cards. Because both TDM and network traffic can be processed by a single interface card, the number of cards within the network switch can be reduced.

Abstract: The network switch described herein provides a cell/packet switching architecture that switches between line interface cards across a meshed backplane. In one embodiment, the switching can be accomplished at, or near, line speed in a protocol independent manner. The protocol independent switching provides support for various applications including Asynchronous Transfer Mode (ATM) switching, Internet Protocol (IP) switching, Multiprotocol Label Switching (MPLS) switching, Ethernet switching and frame relay switching. The architecture allows the network switch to provision service on a per port basis. In one embodiment, the network switch provides a non-blocking topology with both input and output queuing and per flow queuing at both ingress and egress. Per flow flow-control can be provided between ingress and egress scheduling. Strict priority, round robin, weighted round robin and earliest deadline first scheduling can be provided.

Abstract: A method and apparatus for transferring information in a communications system is described. In one embodiment, the method comprises creating a frame of information on a first line card and sending the frame over a backplane to a second line card using a serial link interconnect. The frame comprises first, second and third portions. The first portion includes information to process the second and third portions. The second portion has packet and time-division multiplexed (TDM) data in multiple channels. Each of the channels is allocable to packet data or TDM data. The third portion includes data placed into the frame to accommodate for differences in timing references between the line cards.

Abstract: A network switch includes multiple interface cards and a backplane that interconnects the interface cards. The interface cards receive network traffic and perform time and line switching on the data. The network traffic can include a combination of time division multiplexed (TDM) data and network data (e.g., ATM cells, IP packets). In one embodiment, the channels that carry network traffic to the interface cards are pre-configured as either TDM channels or network channels. The channels are processed as appropriate for their respective types by the interface cards. Because both TDM and network traffic can be processed by a single interface card, the number of cards within the network switch can be reduced.

Abstract: The network switch described herein provides a cell/packet switching architecture that switches between line interface cards across a meshed backplane. In one embodiment, the switching can be accomplished at, or near, line speed in a protocol independent manner. The protocol independent switching provides support for various applications including Asynchronous Transfer Mode (ATM) switching, Internet Protocol (IP) switching, Multiprotocol Label Switching (MPLS) switching, Ethernet switching and frame relay switching. The architecture allows the network switch to provision service on a per port basis. In one embodiment, the network switch provides a non-blocking topology with both input and output queuing and per flow queuing at both ingress and egress. Per flow flow-control can be provided between ingress and egress scheduling. Strict priority, round robin, weighted round robin and earliest deadline first scheduling can be provided.