# How to plot a 2D FFT in Matlab?

I am using fft2 to compute the Fourier Transform of a grayscale image in MATLAB.

What is the common way to plot the magnitude of the result?

Assuming that `I` is your input image and `F` is its Fourier Transform (i.e. `F = fft2(I)`)

You can use this code:

``````F = fftshift(F); % Center FFT

F = abs(F); % Get the magnitude
F = log(F+1); % Use log, for perceptual scaling, and +1 since log(0) is undefined
F = mat2gray(F); % Use mat2gray to scale the image between 0 and 1

imshow(F,[]); % Display the result
``````
• +1. You might add a comment on why you are using the log(F+1) and not log(F) - (Due to log(0) non-defined value) Nov 25, 2012 at 8:18

Here is an example from my HOW TO Matlab page:

``````close all; clear all;

imagesc(img)
img   = fftshift(img(:,:,2));
F     = fft2(img);

figure;

imagesc(100*log(1+abs(fftshift(F)))); colormap(gray);
title('magnitude spectrum');

figure;
imagesc(angle(F));  colormap(gray);
title('phase spectrum');
``````

This gives the magnitude spectrum and phase spectrum of the image. I used a color image, but you can easily adjust it to use gray image as well.

ps. I just noticed that on Matlab 2012a the above image is no longer included. So, just replace the first line above with say

``````img = imread('ngc6543a.jpg');
``````

and it will work. I used an older version of Matlab to make the above example and just copied it here.

On the scaling factor

When we plot the 2D Fourier transform magnitude, we need to scale the pixel values using log transform to expand the range of the dark pixels into the bright region so we can better see the transform. We use a `c` value in the equation

``````s = c log(1+r)
``````

There is no known way to pre detrmine this scale that I know. Just need to try different values to get on you like. I used `100` in the above example.

• if you use imagesc (without setting the c-limits) there is no meaning for the constant c you are using
– emem
Mar 2, 2015 at 14:32
• You're applying `fftshift` in the spatial and the frequency domains. That . . . can't be right, no? Oct 25, 2015 at 20:14