FPGA IMPLEMENTATION OF EFFICIENT VLSI ARCHITECTURE FOR FIXED POINT 1-D DWT US...
NaveeN
1. Presented by,
Naveen C
M.E. VLSI DESIGN
SONA COLLEGE OF TECHNOLOGY
SALEM
AN EFFICIENT PIPELINED
FEEDFORWARD-FFT ARCHITECTURE
USING SPLIT RADIX
2. To reduce the number of adders and multipliers
in FFT.
To increase the speed by reducing time delay
between consecutive inputs using pipelining.
OBJECTIVE
3. ABSTRACT
Generally FFT has complex operations which
needs more computational time. Complex operations
can be reduced by using split radix algorithm. Split
radix FFT has been designed with Feedforward
pipelining architecture and this can reduce the delay
between the consecutive inputs, and speed of
computation can been increased.
6. Split radix algorithm will use the advantages of both
radix 2 and radix 4 algorithm.
Split radix have in-place property.
It have its own butterfly structure.
PROPOSED ALGORITHM
14. CONCLUSION
• The paper shows the use of Split-radix FFT
with feedforward pipelining (MDC).
• The SRFFT decreases the number of addition
and complex operations. Due to pipelining the
time latency is been reduced and by increasing
the number of parallel samples, throughput of
the design is increased.
• Thus this design provides efficient results in
performance using SRFFT.
15. REFERENCE
1. Garrido. M.,Grajal. J.,“Pipelined Radix 2K
Feedforward FFT
Architectures”, IEEE Trans. vol. 21, no. 1, January 2013.
2. Duhamel. P, “Implementation of "Split-radix" FFT algorithms
for complex, real, and real-symmetric data,” IEEE trans. vol.
assp-34. no. 2, april 1986.
3. J. W. Cooley and J. W. Tukey, “An algorithm for machine
computation of complex Fourier series,” Math Comput., vol. 19,
pp. 297- 301, 1965.
4. E. H. Wold and A. M. Despain, “Pipeline and parallel-
pipeline FFT processors for VLSI implementations,” IEEE
Trans. Comput., vol. C-33, no. 5, pp. 414–426, May 1984.