Fourier Transform of Time Functions

DC Level

Example Find the Fourier Transform of the constant 1. Use duality and the fact that the transform of δ(t) is 1

Fourier Transform of Periodic Signals

We can also define a Fourier Transform for periodic signals. If a signal has both periodic and aperiodic components, then this will enable us to use one transform to deal with both the periodic and aperiodic components.

Can we take the Fourier Transform of a periodic signal? For example, we can write:

but we can not directly calculate this integral because it does not converge. So we will generalize the Fourier Transform to include impulses in the frequency domain.

We can use either the Duality or Modulation Properties to show that:

We can check this by taking Inverse Fourier Transform (and using the sifting property):

Now let's consider a general periodic signal x(t) that we can represent as a Fourier Series:

Since we know that:

by linearity of the Fourier Transform, we get that:

Thus we see that a periodic signal has a Fourier Transform that is an infinite impulse train at discrete frequencies kω₀ with weights of 2πC_k (many or most of the weights are usually 0).

Example Find the Fourier Transform of cos(ω₀t).

Pulsed Cosine

Example Find the Fourier Transform of the pulsed cosine:

You can do it directly and also using the multiplication property.

Let's show this graphically: