Method and apparatus for transmitting an internet protocol...

Optical: systems and elements – Deflection using a moving element – Using a periodically moving element

Reexamination Certificate

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Details

C359S199200, C359S199200

Reexamination Certificate

active

06317236

ABSTRACT:

BACKGROUND OF THE INVENTION
The present invention relates generally to systems for transmitting data over fiber optic networks, and specifically to systems for transmitting an encoded Internet protocol (IP) packet directly over an optical or photonic layer of a fiber optic network without the overhead and expense of adapting the IP packet to another encoding format.
The global Internet has become a gateway to information for the general public. Given the online availability of this seemingly endless resource of information, a desire to quickly access this information has driven an evolution in the telecommunications industry and, in particular, in telecommunications networks. As telecommunications networks evolve, the growth in data traffic on the networks appears to outpace the growth in voice traffic. Some industry commentators have noted that the average packet size in telecommunications networks has increased from 280 bytes to 330 bytes in 1998 alone. Additionally, these commentators have noted that the average session duration has decreased down to only 13 seconds. In summary, the growth in data traffic along with changing characteristics of the data traffic itself has forced many telecommunications service providers to seek a more efficient and higher bandwidth mechanism for transporting data traffic.
One efficient type of telecommunications network for transporting such data traffic is a packet-based telecommunications network. A packet-based telecommunications network is a communication network using protocols in which messages are divided into packets before they are sent. Each packet is individually transmitted and can follow different routes to its destination within the network. Once all of the packets forming the message have arrived at the destination, the message is recompiled from the packets and delivered as a whole message.
An example of such a packet-based telecommunications network is an IP-based network. Essentially, an IP-based network uses Internet protocol or IP as the protocol to handle addressing of packets. Some networks combine IP with a higher level protocol called transport control protocol (TCP), which establishes a virtual connection or link between a destination and a source. Those skilled in the art will be familiar with IP-based networks and the current version of IP called IPv
4
, which is promulgated by the Internet Engineering Task Force (IETF). A newer version of IP called IPv
6
or IPng (IP Next Generation) is currently under development by IETF.
Many data networks generally rely upon a conventional Synchronous Optical Network (SONET) layer to transport data within the network. This is due to the ability of SONET to support international standards for interconnecting networks and SONET's desirably efficient use of bandwidth. Basically, SONET defines interface standards beginning at the physical layer level of the Open Systems Interconnection (OSI) Reference Network Model developed by the International Organization for Standardization (ISO). The interface standards defined by SONET describe a synchronous hierarchy of interface rates that allow data sequences at differing rates to be multiplexed within a SONET frame, which is then transmitted as an optical signal. The synchronous hierarchy of SONET results in an overhead percentage that does not vary as the rate increases. Each time one multiplexes to a higher rate, the lower-rate signals are synchronously byte-interleaved to produce the higher rate. Since the lower-rate signals are synchronous to one another, no additional overhead is needed (e.g., with stuffing bytes and associated signaling) to support rate matching. Those skilled in the art will be familiar with the OSI Reference Network Model and additional features of SONET standards, equipment and systems.
Furthermore, those skilled in the art will understand that conventional SONET systems are implemented with multiple layers. In general, each of the layers are responsible for specific functions. The lowest layer is a photonic or optical layer while other layers add functionality (such as framing, scrambling, and error monitoring) used by devices in the network. The photonic or optical layer essentially converts electrical signals to optical signals and is responsible for maintaining the pulse shape, wavelength and power levels of the optical signals. The photonic or optical layer is analogous to the physical layer as described in the OSI Reference Network Model.
While each of the other layers in SONET systems has a particular amount of overhead associated the particular layer's functionality added to the system, the photonic or optical layer has none. In other words, at the bottom layer of the network model, the photonic or optical layer adds no extra processing or data overhead to a packet of information when transmitting an optical signal representing the packet directly over the photonic or optical layer of the network.
Due to the synchronous nature of SONET, one problem that may be encountered when using SONET to transport IP packets is maintaining a synchronous clock within the network at all times. Applicant has observed that long pattern sequences of the same value may undesirably cause loss of a clock signal in the network. Typically, the bits of a packet transmitted directly over the photonic or optical layer are encoded in a conventional non-return-to-zero (NRZ) encoding format. After a finite number of consecutive bits at the same logic level, the clock signal may drop out because the optical signal being transmitted remains at a constant, DC, unmodulated level as a quasi-continuous wave state. Once the clock signal drops out, future packets may be lost when they arrive at the optical receiver because the timing of the packet is no longer synchronous.
In order to avoid this problem and help maintain a synchronous clock, the SONET layer for transporting IP packets usually scrambles the payload (conventionally referred to as a Synchronous Payload Element) of the packet. Scrambling of the payload essentially breaks up long pattern sequences that may be input to SONET equipment within the network. By breaking up the long pattern sequences, the electro-optics within SONET equipment, such as clock recovery circuitry in optical receivers, can function properly and packets are not lost.
Unfortunately, extra hardware and processing is required to scramble and unscramble (i.e., multiplex and demultiplex) the payload of an IP packet in SONET. In other words, another layer of encoding or adapting of the IP packet is required in addition to encoding bits of the IP packet directly into light pulses. For example, a conventional statistical time division multiplexer is a device within a router that accepts electrical input from a variety of sources and provides a multiplexed optical signal output representing a SONET frame (which may include an IP packet). The statistical multiplexer also has scrambling hardware to enable the router to ensure that a clock signal can be easily recovered by the receiver of the SONET frame. This extra hardware and the associated overhead for scrambling the payload of each packet is costly in terms of monetary costs, wasted bandwidth and processing resources within the network. Thus, Applicant has discovered that it would be advantageous to transmit IP packets directly over the optical or photonic layer without having to adapt the IP packet any further while simultaneously maintaining the ability to extract a clock signal at all times.
Point-to-Point (PPP) protocol is a standard method of transmitting different protocol packets, including IP packets, over point-to-point links in the network. Thus, an IP packet may be framed for transmission in the network using PPP in a frame, such as an High Level Data Link Control (HDLC)-like frame. Essentially, HDLC-like frames conform to a protocol at a data link layer allowing for control data flow and error correction. PPP in HDLC-like frames allows for framing of both bit-oriented and octet-oriented synchronous and asynchronous links. Those skilled in the

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