Notes on the FFT
C. S. Burrus
Department of Electrical and Computer Engineering
Rice University, Houston, TX 77005, e-mail: csb@rice.edu
September 29, 1997
This file is mirrored from http://www-dsp.rice.edu/research/fft/fftnote.asc.
HTML formatting added by SGJ.
The original seems to have disappeared as of March 2002.
This is a note describing results on efficient algorithms to
calculate the discrete Fourier transform (DFT). The purpose is to
report work done at Rice University, but other contributions used by
the DSP research group at Rice are also cited. Perhaps the most
interesting is the discovery that the Cooley-Tukey FFT was described
by Gauss in 1805 [1]. That gives some indication of the age of
research on the topic, and the fact that a recently compiled
bibliography [2] on efficient algorithms contains over 3400 entries
indicates its volume. Three IEEE Press reprint books contain papers on
the FFT [3, 4, 5]. An excellent general purpose FFT program has been
described in [6, 7] and is available over the internet.
There are several books [8, 9, 10, 11, 12, 13, 14, 15, 16] that
give a good modern theoretical background for this work, one book [17]
that gives the basic theory plus both FORTRAN and TMS 320 assembly
language programs, and other books [18, 19, 20] that contains a
chapter on advanced FFT topics. The history of the FFT is outlined in
[21, 1] and excellent survey articles can be found in [22, 2 3]. The
foundation of much of the modern work on efficient algorithms was done
by S. Winograd. This can be found in [24, 25, 26]. An outline and
discussion of his theorems can be found in [18] as well as [8, 9, 1 0,
11].
Efficient FFT algorithms for length-2M were described by Gauss and
discovered in modern times by Cooley and Tukey [27]. These have been
highly developed and good examples of FORTRAN programs can be found in
[17]. Several new algorithms have been published that require the
least known amount of total arithmetic [28, 29, 30, 31, 32]. [A lower arithmetic count was obtained in 2004 —SGJ] Of these,
the split-radix FFT [29, 30, 33, 34] seems to have the best structure
for programming, and an efficient program has been written [35] to
implement it . A mixture of decimation- in-time and
decimation-in-frequency with very good efficiency is given in [36].
Theoretical bounds on the number of multiplications required for the
FFT based on Winograd's theories are given in [11, 37]. Schemes for
calculating an in-place, in-order radix-2 FFT are given in [38, 39,
40]. Discussion of various forms of unscramblers is given in [41, 42,
43, 44, 45, 46, 47, 48, 49]. A discussion of the relation of the
computer architecture, algorithm and compiler can be found in [50,
51].
The "other" FFT is the prime factor algorithm (PFA) which uses an
index map originally developed by Thomas and by Good. The theory of
the PFA was derived in [52] and further developed and an efficient
in-order and in-place program given in [53, 17]. More results on the
PFA are given in [54, 55, 40, 56, 57]. A method has been developed to
use dynamic programming to design optimal FFT programs that minimize
the number of additions and data transfers as well as multiplications
[58]. This new approach designs custom algorithms for a particular
computer architecture. An efficient and practical development of
Winograd's ideas has given a design method that does not require the
rather difficult Chinese remainder theorem [18, 59] for short prime
length FFT's. These ideas have been used to design modules of length
11, 13, 17, 19, and 25 [60]. Other methods for designing short DFT's
can be found in [61, 62]. A use o f these ideas with distributed
arithmetic and table look-up rather than multiplication is given in
[63]. A pro gram that implements the nested Winograd Fourier transform
algorithm (WFTA) is given in [8] but it has n to proven as fast or as
versatile as the PFA [53]. An interesting use of the PFA was announced
[64] in searching for large prime numbers.
These efficient algorithms can not only be used on DFT's but on
other transforms with a similar structure. They have been applied to
the discrete Hartley transform [65, 66] and the discrete cosine
transform [32, 67, 68 ].
The fast Hartley transform has been proposed as a superior method
for real data analysis but that has been shown not to be the case. A
well-designed real-data FFT [69] is always as good as or better than a
well-designed Hartley transform [65, 70, 71, 72, 73]. The Bruun
algorithm [74, 75] also looks promising for real data applications as
does the Rader-Brenner algorithm [76, 77, 72]. A novel approach to
calculating the inverse DFT is given in [78].
General length algorithms include [79, 80, 81]. For lengths that
are not highly composite or prime, the chirp z-transform in a good
candidate [17, 82] for longer lengths and an efficient order-N^2
algorithm called the QFT [83, 84, 85] for shorter lengths. A method
which automatically generate s near-optimal prime length Winograd
based programs has been given in [59, 86, 87, 88, 89]. This gives the
same efficiency for shorter lengths (i.e. N 19) and new algorithms
for much longer lengths and with well -structured algorithms. Special
methods are available for very long lengths [90, 91]. A very
interesting general length FFT system called the FFTW has been
developed by Frigo and Johnson at MIT which uses a library of
efficient "codelets" which are composed for a very efficient
calculation of the DFT on a wide variety of computers [6, 7]. For most
lengths and on most computers, this is the fastest FFT today.
The use of the FFT to calculate discrete convolution was one of
its earliest uses. Although the more direct rectangular transform [92]
would seem to be more efficient, use of the FFT or PFA is still
probably the fastest method on a general purpose computer or DSP chip
[93, 69, 70, 94] although the use of distributed arithmetic [63] or
number theoretic transforms [95] with special hardware may be even
faster. Special algorithms for use with the short-time Fourier
transform [96] and for the calculation of a few DFT values [97, 98,
99] and for recursive implementation [100] have also been
developed. An excellent analysis of efficient programming the FFT on
DSP microprocessors is given in [101, 51]. Formulations of the DFT in
terms of tensor or Kronecker products look promising for developing
algorithms for parallel and vector computer architectures [102, 12,
103, 104, 105, 106, 107].
Various approaches to calculating approximate DFTs have been based
on cordic methods, short word lengths, or some form of pruning. A new
method that uses the characteristics of the signals being transformed
has combined the discrete wavelet transform (DWT) combined with the
DFT to give an approximate FFT with O(N) multiplications [108, 109,
110, 111] for certain signal classes.
The study of efficient algorithms not only has a long history and
large bibliography, it is still an exciting research field where new
results are used in practical applications.
More information can be found on the Rice DSP Group's web page:
http://www.dsp.rice.edu and this document can be found at:
http://www.dsp.rice.edu/res/fft/fftnote.asc.
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