基于并行结构的低功耗MB-OFDM PHY基带调制解调器的实现

2013 International Conference on Emerging Trends in VLSI, Embedded System, Nano Electronics and Telecommunication System (ICEVENT) Pub Date : 2013-04-11 DOI:10.1109/ICEVENT.2013.6496541

G. Ramadoss, G. Prakash

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引用次数: 0

摘要

多频带正交频分复用调制解调器需要在短时间内处理大量的计算，以支持53 ~ 480mbps的高数据速率。为了在满足性能要求的同时降低功耗，提出了一种多路并行架构。本文介绍了几种新的优化技术，以实现具有8路并行结构的基带调制解调器的资源高效实现，例如新的(解)交织器、包同步器和载波频偏补偿器的处理结构。此外，我们还描述了如何有效地设计其他几个组件。详细的分析表明，我们的优化技术平均可以减少27.6%的门计数，而所有技术都不会降低系统的整体性能。采用0.18 μm CMOS工艺，整个基带调制解调器的栅极数和功耗约为474 kgates，在66 MHz时为248 mW。

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Implementation of low power MB-OFDM PHY baseband modem with parallel architecture

The multi-band orthogonal frequency division multiplexing modem needs to process large amount of computations in short time for support of high data rates from 53 to 480 Mbps. In order to satisfy the performance requirement while reducing power consumption, a multi way parallel architecture has been proposed. In this paper introduced several novel optimization techniques for resource efficient implementation of the baseband modem which has 8-way, parallel architecture, such as new processing structures for a (de)interleaver and a packet synchronizer and a carrier frequency offset compensator. Also, we describe how to efficiently design several other components. The detailed analysis shows that our optimization techniques could reduce the gate count by 27.6% on average, while none of techniques degraded the overall system performance. With 0.18-μm CMOS process, the gate count and power consumption of entire baseband modem were about 474 kgates and 248 mW at 66 MHz.

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2013 International Conference on Emerging Trends in VLSI, Embedded System, Nano Electronics and Telecommunication System (ICEVENT)

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