Radix-43 based two-dimensional FFT architecture with efficient data reordering scheme

Kala S.; Mathew Jimson; Jose Babita R.; Nalesh S.

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Radix-43 based two-dimensional FFT architecture with efficient data reordering scheme

机译：基于Radix-4 3 的二维FFT架构，具有高效的数据重排序方案

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Multi-dimensional Discrete Fourier Transforms (DFTs) play an important role in signal and image processing applications. Image reconstruction is a key component in signal processing applications like medical imaging, computer vision, face recognition etc. Two dimensional fast Fourier Transform (2D FFT) and Inverse FFT plays vital role in reconstruction. In this paper we present a fast 64 x 64 point 2D FFT architecture based on radix-43 algorithm using a parallel unrolled radix-4(3) FFT as the basic block. Our radix-4(3) architecture is a memory optimized parallel architecture which computes 64-point FFT, with least execution time. Proposed architecture produces reordered output of both 64-point one dimensional (1D) FFT and 64 x 64 point 2D FFT, without using any additional hardware for reordering. The proposed architecture has been implemented in UMC 40nm CMOS technology with clock frequency of 500 MHz and area of 0.841 mm(2). The power consumption of proposed architecture is 358 mW at 500 MHz. Energy efficiency (FFTs computed per unit of energy) is 341 points/Joule. Computation time of 64 x 64 point FFT is 8.19 mu s. ASIC implementation results shows better performance of proposed work in terms of computation time when compared with state-of-art implementation. Proposed architecture has also been implemented in Virtex-7 FPGA which gives comparable area.

机译：多维离散傅里叶变换（DFT）在信号和图像处理应用中起着重要作用。图像重建是信号处理应用（如医学成像，计算机视觉，人脸识别等）中的关键组件。二维快速傅里叶变换（2D FFT）和逆FFT在重建中起着至关重要的作用。在本文中，我们提出了一种基于radix-43算法的快速64 x 64点2D FFT架构，其中使用了并行展开的radix-4（3）FFT作为基本块。我们的radix-4（3）架构是内存优化的并行架构，可计算64点FFT，执行时间最短。提出的体系结构可产生64点一维（1D）FFT和64 x 64点2D FFT的重新排序输出，而无需使用任何其他硬件进行重新排序。所提议的体系结构已在UMC 40nm CMOS技术中实现，时钟频率为500 MHz，面积为0.841 mm（2）。拟议架构的功耗在500 MHz时为358 mW。能量效率（按能量单位计算的FFT）为341点/焦耳。 64 x 64点FFT的计算时间为8.19μs。与最新的实现方式相比，ASIC的实现结果显示了在计算时间方面拟议工作的更好性能。拟议的架构也已在Virtex-7 FPGA中实现，其面积可比。

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《Computers & Digital Techniques, IET》 |2019年第2期|78-86|共9页
作者
Kala S.; Mathew Jimson; Jose Babita R.; Nalesh S.;
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作者单位

Cochin Univ Sci & Technol, Sch Engn, Kochi 22, Kerala, India;

Indian Inst Technol Patna, Dept Comp Sci & Engn, Patna, Bihar, India;

Cochin Univ Sci & Technol, Sch Engn, Kochi 22, Kerala, India;

Cochin Univ Sci & Technol, Dept Elect, Kochi 22, Kerala, India;

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正文语种 eng
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application specific integrated circuits; parallel architectures; field programmable gate arrays; computational complexity; discrete Fourier transforms; fast Fourier transforms; CMOS logic circuits; two-dimensional FFT architecture; signal processing systems; image reconstruction; signal processing applications; medical imaging; computer vision; FFT computation; parallel unrolled radix-4; memory optimised parallel architecture; data reordering; discrete Fourier transforms; multidimensional DFT; two-dimensional fast Fourier transform; application specific integrated circuit; face recognition; 2D FFT architecture; radix-4(3) algorithm; row-column decomposition; UMC complementary metal oxide semiconductor; power consumption; Virtex 7 field programmable gate array; power 358; 0 mW; frequency 500; 0 MHz; time 8; 19 mus; size 40; 0 nm; size 0; 841 mm;

机译：应用特定的集成电路;实地可编程门阵列;计算复杂性;离散傅里叶变换;快速傅里叶变换;CMOS逻辑电路;二维FFT架构;信号处理系统;图像重建;信号处理应用;医学成像;计算机愿景;FFT计算;并行展开的基数-4;内存优化并行架构;数据重新排序;离散傅里叶变换;多维DFT;二维快速傅里叶变换;应用特定集成电路;面部识别;2D FFT架构;RADIX-4（3）算法;行列分解;UMC互补金属氧化物半导体;功耗;Virtex 7现场可编程门阵列;功率358;0 MW;频率为500;0 MHz;时间8;19亩;尺寸40;尺寸0;841毫米;
入库时间 2022-08-18 04:30:38

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专利

1. Radix-43 based two-dimensional FFT architecture with efficient data reordering scheme [J] . Kala S., Mathew Jimson, Jose Babita R., Computers & Digital Techniques, IET . 2019,第2期

机译：基于RADIX-4 ^{3 具有高效数据重新排序方案的二维FFT架构}
2. Efficient input reordering for the DCT based on a real-valued decimation-in-time FFT [J] . Storn R. IEEE signal processing letters . 1996,第8期

机译：基于实值实时抽取FFT的DCT的有效输入重新排序
3. A Highly Efficient Multicore Floating-Point FFT Architecture Based on Hybrid Linear Algebra/FFT Cores [J] . Ardavan Pedram, John D. McCalpin, Andreas Gerstlauer Journal of signal processing systems for signal, image, and video technology . 2014,第1a2期

机译：基于混合线性代数/ FFT核的高效多核浮点FFT架构
4. FPGA Implementation of Radix-4-Based Two-Dimensional FFT with and Without Pipelining Using Efficient Data Reordering Scheme [C] . Ashutosh Kumar, Shashank Gavel, Ajay Singh Raghuvanshi International Conference on Nanoelectronics Circuits Communication System . 2019

机译：使用高效数据重新排序方案，FPGA实现基于基于基于Radix-4的二维FFT
5. Development of a wireless health monitoring system with an efficient power management scheme based on localized time-varying data analyses. [D] . Zhao, He. 2008

机译：开发具有基于局部时变数据分析的高效电源管理方案的无线健康监控系统。
6. CoDR: Correlation-Based Data Reduction Scheme for Efficient Gathering of Heterogeneous Driving Data [O] . Junho Park, Yoojin Chung, Jongmoo Choi 2020

机译：CoDR：高效收集异构驾驶数据的基于相关性的数据约简方案
7. Efficient Input Reordering for the DCT Based on a Real-Valued Decimation in Time FFT [O] . Rainer Storn 1995

机译：基于时间FFT中的实值抽取的DCT的有效输入重新排序

Radix-43 based two-dimensional FFT architecture with efficient data reordering scheme

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