Design and implementation of a 1024-point high-speed FFT processor based on the FPGA

Author

Sheng Zhou ; Xiaochun Wang ; Jianjun Ji ; Yanqun Wang

Author_Institution

Inst. of Biomed. Eng., Tianjin, China

Volume

2

fYear

2013

fDate

16-18 Dec. 2013

Firstpage

1112

Lastpage

1116

Abstract

To design a Fast Fourier Transform (FFT) processor to meet the needs for high-speed and real-time signal processing. A 1024-point, 32-bit, fixed, complex FFT processor is designed based on a field programmable gate array (FPGA) by using the radix-2 decimation in frequency (DIF) algorithm and the pipeline structure in the butterfly module and the ping-pone operation in data storage unit. When the primary clock is 100 MHz, the 1024-point FFT calculation takes about 62.95 us. The processor is fast enough for processing the high-speed and real time signals. The result provides reference values that theoretical study of the FFT algorithm can be applied into the adaptive dynamic filter of an ultrasonic diagnostic system and an ultrasonic Doppler flow measurement system.

Keywords

adaptive filters; fast Fourier transforms; field programmable gate arrays; DIF algorithm; FPGA; adaptive dynamic filter; butterfly module; data storage unit; fast Fourier transform processor; field programmable gate array; high-speed FFT processor; ping-pone operation; radix-2 decimation in frequency algorithm; real-time signal processing; ultrasonic Doppler flow measurement system; ultrasonic diagnostic system; Algorithm design and analysis; Field programmable gate arrays; Mathematical model; Radiation detectors; Random access memory; Signal processing; Signal processing algorithms; 1024-point FFT; Butterfly; Ping-pong operation; Verilog HDL; field programmable gate array;

fLanguage

English

Publisher

ieee

Conference_Titel

Image and Signal Processing (CISP), 2013 6th International Congress on

Conference_Location

Hangzhou

Print_ISBN

978-1-4799-2763-0

Type

conf

DOI

10.1109/CISP.2013.6745222

Filename

6745222