A novel Internet protocol (IP) transmission and routing is proposed over coherent multiple array (M-ary) frequency shift keying optical code-division multiple-access (FSK-OCDMA) network with incoherent demodulation. The architecture also benefits from the use of the co-channel interference canceller. In contrast to wavelength-division multiple-access (WDMA), a fewer set of wavelengths are needed as a result of M-ary source coding. As the spreading codes, double-padded modified prime codes (DPMPC) have been employed. The performance has been analyzed in terms of the users' channel utilization in the network and compared with common incoherent pulse-position modulation technique. The results indicate that this architecture is very power efficient and enhances the network capacity. With the advantage of shorter code length, DPMPC also improves the throughput. It is shown that for a maximum bit-rate, the network performance can be improved by reducing the channel utilization. Since each IP packet is buffered only at the edge of this network, the buffer delay is considerably reduced. The novel encoder adjusting time management reduces the switching time notably rather than traditional routing. Our analytical investigation clearly indicates that this OCDMA technique can be an excellent candidate for the future ultra-fast high bit-rate optical IP networks.
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机译:该文提出一种基于非相干解调的相干多阵列(M-ary)频移键控光码分多址(FSK-OCDMA)网络的互联网协议(IP)传输和路由。该架构还受益于同信道干扰消除器的使用。与波分多址 (WDMA) 相比,由于 M 元源编码,需要的波长集更少。作为扩码,采用了双填充修饰素数(DPMPC)。从用户在网络中的信道利用率方面分析了其性能,并与常见的非相干脉冲位置调制技术进行了比较。结果表明,该架构非常节能,并增强了网络容量。DPMPC 具有代码长度较短的优点,还可以提高吞吐量。结果表明,对于最大比特率,可以通过降低信道利用率来提高网络性能。由于每个 IP 数据包仅在该网络的边缘进行缓冲,因此缓冲延迟大大降低。与传统的布线相比,新颖的编码器可调整时间管理,显著缩短开关时间。我们的分析研究清楚地表明,这种OCDMA技术可以成为未来超高速高比特率光IP网络的绝佳候选者。
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