Abstract: A network processing device stores and aligns data received from an input port prior to forwarding the data to an output port. Data packets arrive at various input ports already having an output queue or virtual output queue assigned. A buffer manager groups one or more packets destined for the same output queue into blocks, and stores the blocks in a buffer memory. A linked list is created of the trunks, which is an ordered collection of blocks. The trunks are sent to a high speed second memory and stored together as a unit. In some embodiments the trunks are split on boundaries and stored in a high speed memory. Once the trunks are stored in the high speed second memory, the corresponding data is erased from the write combine buffer memory and the pointers that made up the linked list are returned to a free block pointer pool. The data can then be read from the high speed second memory very quickly, passed through a switching fabric, and placed back on the computer network for its next destination.

Abstract: For electrical backplanes and the like, a power plane adaptation to improve the propagation of high-speed signals through clearances in an embedded power plane is disclosed. In exemplary embodiments, the power plane is segmented in a high-speed connector region, such that a portion of the metal layer that forms the power plane is retained in the high-speed connector region—but isolated from the power-delivery portion of the power plane. The isolated portion is connected to digital ground, and clearances are formed therein where high-speed signaling throughholes will pass through the region. In some embodiments, various attainable advantages include better manufacturability, better matching and control of high-speed signaling throughhole impedance, and improved noise isolation. Other embodiments are described and claimed.

Abstract: The disclosed board fabrication techniques and design features enable the construction of a reliable, high-layer-count, and economical backplane for routers and the like that require a large number of signaling paths across the backplane at speeds of 2.5 Gbps or greater, as well as distribution of significant amounts of power to router components. The disclosed techniques and features allow relatively thick (e.g., three- or four-ounce copper) power distribution planes to be combined with large numbers of high-speed signaling layers in a common backplane. Using traditional techniques, such a construction would not be possible because of the number of layers required and the thickness of the power distribution layers. The disclosed embodiments use novel layer arrangements, material selection, processing techniques, and panel features to produce the desired high-speed layers and low-noise high-power distribution layers in a single mechanically stable board.

Abstract: A high-speed, high-power modular router is disclosed. As opposed to conventional designs using optical backplane signaling and/or bus bars for power distribution, the disclosed embodiments combine high-power, low-noise power distribution with high-speed signal routing in a common backplane. Disclosed backplane features allow backplane signaling at 2.5 Gbps or greater on electrical differential pairs distributed on multiple high-speed signaling layers. Relatively thick power distribution layers are embedded within the backplane, shielded from the high-speed signaling layers by digital ground layers and other shielding features. A router using such a backplane provides a level of performance and economy that is believed to be unattainable by the prior art.

Abstract: A network processing device stores and aligns data received from an input port prior to forwarding the data to an output port. Data packets arrive at various input ports already having an output queue or virtual output queue assigned. A buffer manager groups one or more packets destined for the same output queue into blocks, and stores the blocks in a buffer memory. A linked list is created of the trunks, which is an ordered collection of blocks. The trunks are sent to a high speed second memory and stored together as a unit. In some embodiments the trunks are split on boundaries and stored in a high speed memory. Once the trunks are stored in the high speed second memory, the corresponding data is erased from the write combine buffer memory and the pointers that made up the linked list are returned to a free block pointer pool. The data can then be read from the high speed second memory very quickly, passed through a switching fabric, and placed back on the computer network for its next destination.