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I am seeing a lot of literature in which they say the by using the fft one can reach a faster convolution. I know that one needs to get fft and and then ifft from the results, but I really do not understand why using the fft can make the convolution to be faster?

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FFT is faster than direct convolution if the convolution's kernel is "large". This is explained in a question on Programmer's SE programmers.stackexchange.com/q/171757/4280 –  DarenW Jan 30 '13 at 7:45

1 Answer 1

FFT speeds up convolution for large enough filters, because convolution requires N multiplications (and N-1) additions for each output sample and conversely (2)N^2 operations for a block of N samples.

Taking account, that one has to double the block size for FFT processing by adding zeroes, each block requires (2)*(2N)*log(2N) operations to perform FFT, 2N operations to multiply and again 4N*log(2N) operations to perform inverse FFT, there is a break even point, where 8Nlog2N <= 2N^2.

The fundamental reasons are:

1) a discrete time-domain signal can be represented as a sum of frequencies.
2) convolution in time domain (O(N^2)) equals multiplication of frequencies in frequency domain (O(N)) 3) the transformation is invertible
4) there exists a method to convert a signal from time domain to frequency domain in less than N^2 operations (that's the first F in 'Fast Fourier Transform').

The straight forward FT is O(N^2), where each Frequency domain element F(i) = Sigma f(i) * exp(i*pi/N).

However the FFT is based on an observation that exp(i*pi/N) has certain symmetries, allowing the calculation to be split in odd/even vectors. The even vectors can be calculated at the expense of O(N) while the odd vectors require a full FT of half the size. As this can be repeated until N=2, the overall complexity will be (proportional to) Nlog(N).

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A word of caution: the primary operations in FFT are also complex (meaning that a complex multiplication requires 4 real multiplications and 2 additions, or 3 multiplications and 5 additions with Karatsuba decomposition) Anyway KNlog(kN) will be eventually smaller than N^2. –  Aki Suihkonen Jan 30 '13 at 7:00
    
So, why the computational cost in fft space is smaller than time, I mean, does it use a smaller pieces of data or it is something else? What is your mean by filters? –  Nicole Jan 30 '13 at 7:11
    
FFT has to use larger blocks. –  Aki Suihkonen Jan 30 '13 at 7:36
    
-1. This explanation is incomplete, incorrect, and misleading. See programmers.stackexchange.com/questions/171757/… for a better explanation. –  thang Feb 1 '13 at 8:52
    
@AkiSuihkonen, please read that link. You've collapsed everything into N, which obscures the real issue. In typical image filtering, you have a large image that is WxW (using terminology of that link) and a filter that is KxK. This is already assuming square. The benefit of FFT in convolution is a function of how big K is with respect to W. It's simple-minded to collapse everything into N, and that obscures the real issue. In fact, matlab's conv2 function does not use FFT for this reason. In most image filtering applications, K << W. –  thang Feb 1 '13 at 9:07

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