Convolution Theorem

For example

Consider this example.

The same image in the frequency domain can be represented as.

Now what’s the relationship between image or spatial domain and frequency domain. This relationship can be explained by a theorem which is called as Convolution theorem.

Convolution Theorem

The relationship between the spatial domain and the frequency domain can be established by convolution theorem.

The convolution theorem can be represented as.

It can be stated as the convolution in spatial domain is equal to filtering in frequency domain and vice versa.

The filtering in frequency domain can be represented as following:

The steps in filtering are given below.

At first step we have to do some pre – processing an image in spatial domain, means increase its contrast or brightness
Then we will take discrete Fourier transform of the image
Then we will center the discrete Fourier transform, as we will bring the discrete Fourier transform in center from corners
Then we will apply filtering, means we will multiply the Fourier transform by a filter function
Then we will again shift the DFT from center to the corners
Last step would be take to inverse discrete Fourier transform, to bring the result back from frequency domain to spatial domain
And this step of post processing is optional, just like pre processing , in which we just increase the appearance of image.

Filters

The concept of filter in frequency domain is same as the concept of a mask in convolution.

After converting an image to frequency domain, some filters are applied in filtering process to perform different kind of processing on an image. The processing include blurring an image, sharpening an image e.t.c.

The common type of filters for these purposes are:

Ideal high pass filter
Ideal low pass filter
Gaussian high pass filter
Gaussian low pass filter

In the next tutorial, we will discuss about filter in detail.

Previous Page Print Page