适用于 OFDM 应用的 64 点 Radix-42 MDC FFT 高效面积架构

IF 2.2 3区工程技术 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Integration-The Vlsi Journal Pub Date : 2024-07-24 DOI:10.1016/j.vlsi.2024.102244

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引用次数: 0

摘要

在这项研究中，我们为基于正交频分复用（OFDM）的 IEEE 802.11a 无线局域网（LAN）基带提出了一种 64 点radix-42 流水线快速傅立叶变换（FFT）架构，它具有面积效率高的特点。我们采用多延迟换向器（MDC）架构进行硬件实现。拟议的 64 点 FFT 采用改进的常数乘法器来计算复数乘法，以取代复数乘法器，并避免使用只读存储器（ROM）在内部存储捻系数系数。通过使用改进的常数乘法器，减少了设计的面积。所提出的radix-42流水线 FFT 架构采用 45 nm CMOS 技术合成，电源电压为 1.1 V。该设计共占用 15.31K 逻辑门，耗散功率为 8.6 mW，功率延迟积为 430e-12。

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An area efficient 64 point Radix-42 MDC FFT architecture for OFDM applications

In this research,we present a 64-point radix- $4^{2}$ pipelined Fast Fourier Transform(FFT) architecture which is area-efficient for an orthogonal frequency division multiplexing(OFDM) based IEEE 802.11a wireless Local area network(LAN) baseband. We adopt Multiple Delay Commutator(MDC) architecture for hardware implementation. The proposed 64-point FFT adopts a modified constant multiplier to compute complex multiplication in place of complex multipliers and to avoid read-only memory(ROM),which is used to store twiddle factor coefficients internally. The area of the design is reduced by using modified constant multiplier. The proposed radix- $4^{2}$ pipelined FFT architecture is synthesized using 45 nm CMOS technology with a supply voltage of 1.1 V. The proposed design occupies 15.31K total gates,dissipates 8.6 mW of power and the power delay product is 430 $e^{- 12}$ .

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来源期刊

Integration-The Vlsi Journal 工程技术-工程：电子与电气

CiteScore

3.80

自引率

5.30%

发文量

107

审稿时长

6 months

期刊介绍： Integration''s aim is to cover every aspect of the VLSI area, with an emphasis on cross-fertilization between various fields of science, and the design, verification, test and applications of integrated circuits and systems, as well as closely related topics in process and device technologies. Individual issues will feature peer-reviewed tutorials and articles as well as reviews of recent publications. The intended coverage of the journal can be assessed by examining the following (non-exclusive) list of topics: Specification methods and languages; Analog/Digital Integrated Circuits and Systems; VLSI architectures; Algorithms, methods and tools for modeling, simulation, synthesis and verification of integrated circuits and systems of any complexity; Embedded systems; High-level synthesis for VLSI systems; Logic synthesis and finite automata; Testing, design-for-test and test generation algorithms; Physical design; Formal verification; Algorithms implemented in VLSI systems; Systems engineering; Heterogeneous systems.