# convolution in R

I tried to do convolution in R directly and using FFTs then taking inverse. But it seems from simple observation it is not correct. Look at this example:

``````# DIRECTLY
> x2\$xt
[1] 24.610 24.605 24.610 24.605 24.610
> h2\$xt
[1] 0.003891051 0.003875910 0.003860829 0.003845806 0.003830842
> convolve(h2\$xt,x2\$xt)
[1] 0.4750436 0.4750438 0.4750435 0.4750437 0.4750435

# USING INVERSE FOURIER TRANSFORM
> f=fft(fft(h2\$xt)*fft(x2\$xt), inv=TRUE)
> Re(f)/length(f)
[1] 0.4750438 0.4750435 0.4750437 0.4750435 0.4750436
>
``````

Lets take the index 0. At 0, the convolution should simply be the last value of x2\$xt (24.610) multiplied by first value of h2\$xt (0.003891051) which should give convolution at index 0 = 24.610*0.003891051 = 0.09575877 which is way off from 0.4750436.

Am I doing something wrong? Why is the values so different from expected?

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## 1 Answer

Both `convolve` and `fft` are circular. The first element of convolution must be the dot product of these two series. The results you obtain are correct in this sense.

To perform a linear convolution use:

``````convolve(h2\$xt,x2\$xt,type="open")
``````

Circular convolution is also applied in this case but a required amount of zeros are padded to inputs to achieve linear convolution.

I believe there is not a direct way to achieve linear convolution with `fft` in R. However this doesn't really matter beacuse `convolve` itself uses the FFT approach you posted.

## Circular Convolution

A discrete signal x is periodic if there is a period N such that x[n] = x[n+N] for all n. Such signals can be represented by N samples from x[0] to x[N-1].

``````... x[-2] x[-1] x[0] x[1] x[2] ... x[N-2] x[N-1] x[N] x[N+1] ...
^    this part is sufficient   ^
``````

A regular definition of convolution between aperiodic x and y is defined as:

``````(x * y)[n] = sum{k in [-inf, inf]}(x[k]y[n-k])
``````

However, for periodic signals, this formula does not produce finite results. To overcome this problem we define the circular convolution between periodic x and y.

``````(x * y)[n] = sum{k in [0, N-1]}(x[i]y[n-k])
``````

When these two signals are represented with N values only, we can use y[n-k+N] in place of y[n-k] for negative values of n-k.

The cool thing with circular convolution is that it can calculate the linear convolution between box signals, which are discrete signals that have a finite number of non-zero elements.

Box signals of length N can be fed to circular convolution with 2N periodicity, N for original samples and N zeros padded at the end. The result will be a circular convolution with 2N samples with 2N-1 for linear convolution and an extra zero.

Circular convolution is generally faster than a direct linear convolution implementation, because it can utilize the Fast Fourier Transform, a fast algorithm to calculate the Discrete Fourier Transform, which is only defined for periodic discrete signals.

Please see:

Also see:

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thanks. is there a linear version of FFT such that the inverse of that would give linear convolution result? –  user236215 Mar 7 '11 at 16:36
Also, I still can't clearly understand the difference between linear and circular convolution. Could you explain it briefly? –  user236215 Mar 7 '11 at 16:36
@user236215: Please see the new answer. –  junjanes Mar 7 '11 at 18:50
very nice. thank you! –  user236215 Mar 7 '11 at 19:30