非相干OCDMA系统的并行FPGA实现

2014 11th Annual High Capacity Optical Networks and Emerging/Enabling Technologies (Photonics for Energy) Pub Date : 2014-12-01 DOI:10.1109/HONET.2014.7029383

W. Saif, S. Aldosari, R. Djemal, H. Fathallah

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引用次数: 1

摘要

光学码分多址(OCDMA)技术相对于其他多址技术的潜在优势在过去十年中引起了人们的极大兴趣。OCDMA的全光实现通常被认为太复杂而无法实现，特别是对于成本敏感的应用。另一方面，OCDMA编码器/解码器的电子实现具有更高的成本效益，但其吞吐量受到电子处理瓶颈的限制。在本文中，我们提出了一种OCDMA收发器的电子实现，它利用了新兴的高速FPGA收发器技术，提供高达28 Gb/s的速度。虽然所提出的OCDMA系统的芯片速率可以接近如此高的速度，但由于并行架构允许芯片同时处理，编码器/解码器处理可以以低得多的速度运行。所提出的设计得益于其低资源利用率，这使得它适用于更小、更经济的FPGA器件。除此之外，FPGA器件的可重构性进一步降低了整体系统成本。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Parallel FPGA implementation of incoherent OCDMA systems

The potential advantages of optical CDMA (OCDMA) over other multi access techniques attracted considerable interest over the past decade. All-optical implementations of OCDMA are often considered to be too complex to implement especially for cost-sensitive applications. On the other hand, electronic realization of OCDMA encoders/decoders are more cost effective but its throughput is restricted by the electronic processing bottleneck. In this paper, we propose an electronic implementation of OCDMA transceivers that takes advantage of newly emerging high-speed FPGA transceiver technologies, which offer speeds of up to 28 Gb/s. Though the chip rate of the proposed OCDMA system can approach such high speeds, the encoder/decoder processing can operate at much lower speed thanks to the parallel architecture that allows chips to be processed simultaneously. The proposed design benefits from its low resource utilization, which makes it suitable for smaller, affordable FPGA devices. This is in addition to the reconfigurability of FPGA devices, which further reduce the overall system cost.

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2014 11th Annual High Capacity Optical Networks and Emerging/Enabling Technologies (Photonics for Energy)

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