18/08/2015 Continuous Time Fourier Transform
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Continuous Time Fourier TransformThe Fourier expansion coefficient ( in OWN) of a periodic signal is
and the Fourier expansion of the signal is:
which can also be written as:
where is defined as
When the period of approaches infinity , the periodic signal becomes a non
periodic signal and the following will result:
Interval between two neighboring frequency components becomes zero:
Discrete frequency becomes continuous frequency:
Summation of the Fourier expansion in equation (a) becomes an integral:
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the second equal sign is due to the general fact:
Time integral over in equation (b) becomes over the entire time axis:
In summary, when the signal is nonperiodic , the Fourier expansion
becomes Fourier transform. The forward transform (analysis) is:
and the inverse transform (synthesis) is:
Note that is denoted by in OWN.
Comparing Fourier coefficient of a periodic signal with with Fourier spectrum of a non
periodic signal :
we see that the dimension of is different from that of :
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If represents the energy contained in the kth frequency component of a periodic signal
, then represents the energy density of a nonperiodic signal distributed along
the frequency axis. We can only speak of the energy contained in a particular frequency band:
Note on notations:
The spectrum of a time signal can be denoted by or to emphasize the fact that the
spectrum represents how the energy contained in the signal is distributed as a function of frequency or . Moreover, if is used, the factor in front of the inverse transform is dropped
so that the transform pair takes a more symmetric form. On the other hand, as Fourier transform canbe considered as a special case of Laplace transform when the real part of the complex argument
is zero:
it is also natural to denote the spectrum of by (in OWN).
Example 0:
Consider the unit impulse function:
Example 1:
If the spectrum of a signal is a delta function in frequency domain , the
signal can be found to be:
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i.e.,
Example 2:
The spectrum is
This is the sinc function with a parameter , as shown in the figure.
Note that the height of the main peak is and it gets taller and narrower as gets larger. Also note
When approaches infinity, for all , and the spectrum becomes
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Recall that the Fourier coefficient of is
which represents the energy contained in the signal at (DC component at zero frequency), andthe spectrum is the energy density or distribution which is infinity at zero
frequency.
The integral in the above transform is an important formula to be used frequently later:
which can also be written as
Switching and in the equation above, we also have
representing a superposition of an infinite number of cosine functions of all frequencies, which canceleach other any where along the time axis except at where they add up to infinity, an impulse.
Example 3:
The spectrum of the cosine function is
The spectrum of the sine function
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can be similarly obtained to be
Again, these spectra represent the energy density distribution of the sinusoids, while thecorresponding Fourier coefficients
and
represent the energy contained at frequency .
Next: Properties of Fourier Transform Up: handout3 Previous: handout3Ruye Wang 20090705
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