Multiplex communications – Channel assignment techniques – Using a separate control line or bus for access control
Reexamination Certificate
1998-06-05
2001-06-12
Nguyen, Chau (Department: 2663)
Multiplex communications
Channel assignment techniques
Using a separate control line or bus for access control
C370S463000, C370S439000
Reexamination Certificate
active
06246692
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to packet switching fabrics for use in data communications networks. Specifically, the present invention pertains to a packet switching fabric having a plurality of devices arranged in a ring topology and intercoupled coupled via data ring segments to form a data ring, and also via control ring segments to form a control ring used for implementing a resource reservation protocol for managing bandwidth resources of the data ring.
2. Description of the Prior Art
Switching devices are essential components of data communication networks including local area networks (LANs), such as ETHERNET, and wide area networks (WANs). Common switching devices include cross bar switching devices, and packet switching fabrics. A packet switching fabric is an interconnection architecture which uses multiple stages of switches to route transactions between a source address and a destination address of a data communications network. A packet switching fabric may have a variety of different architectures, or topologies.
Cross bar switching devices typically include a number, N, of input ports, N output ports, and a switching matrix having redundant interconnection resources requiring a complexity of NxN for selectively connecting the input ports to the output ports. One problem with cross bar switching devices is scalability of the number of network ports. Because of the NxN complexity of the interconnection resources, exponential costs are incurred when increasing the number of network ports of a cross bar switching device.
Because packet switching fabrics include multiple switching devices, fabrics provide better scalability because each of the switching devices of the fabric includes a plurality of network ports and the number of switching devices of the fabric may be increased to increase the number of network connections for the switch. However, prior art packet switching fabrics usually have a bus topology including a back plane, or bus, having a plurality of slots for cards including the network ports. One problem with such switching devices is modularity. While a number of cards having additional network ports may be inserted into slots of the back plane to increase the total number of network ports, the maximum number of cards which may be added is limited because the back plane may support only a limited number of cards due to loading effects on the back plane. Therefore, the modularity problem of bus architecture packet switching fabrics imposes a limit on the scalability of the number of network ports of the fabric.
Typically, each device of a switching fabric includes a plurality of switch devices each including: network ports for transmitting and receiving data packets to and from network nodes via network communication links; and internal data link ports for transmitting and receiving data packets to and from other switch devices of the fabric.
The switching devices of a switching fabric may be configured in any one of a variety of topologies, or architectures. In a switching fabric having a ring architecture, the devices are configured in a ring topology. Because each connection in a ring architecture switching fabric is a point to point link, ring architecture switching fabrics allow for higher frequencies and greater throughput between devices than bus architecture fabrics.
Typical prior art ring architecture switching fabrics are controlled by a token ring protocol wherein only one device of the ring transmits data at a time. Therefore, prior art ring architecture switching fabrics are not commonly used for network switching which requires high data throughput. An important objective of the present invention is to provide ring architecture packet switching fabric which is capable of concurrently processing an increased number of interconnect transactions between multiple source devices and corresponding destination devices thereby allowing for greater switching throughput.
Each switch device of a switching fabric reads header information of a data packet received from a source node via one of its network ports to dynamically route the data packet to an appropriate destination network port, or ports, which is communicatively to a destination node specified by a destination address carried in the header information of the data packet. The destination network port may be a local network port of the same device having the source port at which the packet is received, or a network port of another device of the switching fabric. The process of transferring a data packet received at a network port of a source device to a network port of a destination device is referred to as an interconnect transaction. In order to transfer data from a source device to a destination device, an internal source-destination path coupling the source port to the destination port is required.
In many data communications networks, and particularly in local area networks, (e.g., ETHERNET), when a destination node of the network begins receiving a data packet, the transmission of the data packet to that node cannot be interrupted, even by transmission of an idle signal. Therefore, transmission of a data packet from the destination output port of the switching fabric to the destination node must not be interrupted. Therefore, most switching fabrics include transmit buffers at each network port which are large enough to store a whole packet of data. However, this is undesirable because large buffers require limiting the number of network ports which can be implemented on an integrated circuit.
Another objective of the present invention is to provide a ring architecture packet switching fabric wherein each integrated circuit device of the fabric has higher integration thereby allowing for an increased number of network ports.
A further objective of the present invention is to provide a packet switching fabric providing convenient scalability wherein the total number of network ports supported by the fabric may be scaled up without incurring exponential costs such as in cross bar switching devices.
Yet another objective of the present invention is to provide a packet switching fabric which provides higher data transfer rates through source-destination paths between switching devices of the fabric thereby allowing for cut-through packet transfer between a source device and the destination port. Achieving this objective of the present invention also provides a packet switching fabric wherein each switching device of the fabric has an increased number of ports.
SUMMARY OF THE INVENTION
A packet switching fabric according to the present invention includes a data ring, a control ring, a plurality of data communication network links each having at least one network node coupled thereto, and a plurality of switching devices coupled together by the data ring and the control ring, so that the network links can be selectively communicatively coupled. The packet switching fabric includes a data ring processing sub-system, a network interface sub-system, and a control ring sub-system.
The data ring processing sub-system includes a data input interface for receiving bursts of data from an adjacent one of the devices via at least one of a plurality of data ring channels concurrently active on the data ring, and a data output interface for transmitting bursts of data to an adjacent one of the devices via at least one of the plurality of data ring channels.
The network interface sub-system, coupled to the data ring processing sub-system, includes at least one network port coupled to one of the network links, each network port having a port ID value associated therewith. The network interface sub-system also includes a packet buffer for storing received data packets in memory locations specified by corresponding address pointers, each of the received data packets being received via an associated source port of the network ports. Each of the data packets includes header information specifying a destination address of a destination node. The p
Chao Jason
Dai William
Shih Cheng-Chung
Arent Fox Kintner & Plotkin & Kahn, PLLC
Broadcom Corporation
Lee Chiho Andrew
Nguyen Chau
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