Derivation of the Fourier Transform2.182000/07/252003/07/27 16:41:52.607 GMT-5DonJohnsondhj@rice.eduDonJohnsondhj@rice.eduShawnStewartmrshawn@alumni.rice.eduBenjaminFitebfite@rice.eduMariyahPoonawalamariyah@rice.eduPrashantSinghprash@ece.rice.eduFourier seriesFourier transforminverse Fourier transformParseval's theorempulseThis module shows how to derive the scintillating and useful Fourier transform.
Fourier series clearly open the frequency domain as an
interesting and useful way of determining how circuits and
systems respond to periodic input signals.
Can we use similar techniques for nonperiodic signals? What is
the response of the filter to a single pulse? Addressing these
issues requires us to find the Fourier spectrum of all signals,
both periodic and nonperiodic ones. We need a definition for
the Fourier spectrum of a signal, periodic
or not. This spectrum is calculated by what is known as the
Fourier transform.
Let
sTt
be a periodic signal having period
T.
We want to consider what happens to this signal's spectrum as we
let the period become longer and longer. We denote the spectrum
for any assumed value of the period by
ckT.
We calculate the spectrum according to the familiar formula
ckT1TtT2T2sTt2ktT
where we have used a symmetric placement of the integration
interval about the origin for subsequent derivational
convenience. Let f be a
fixed frequency equaling
kT;
we vary the frequency index
k
proportionally as we increase the period. Define
STfTckTtT2T2sTt2ft
making the corresponding Fourier series
sTtkSTf2ft1T
As the period increases, the spectral lines become closer
together, becoming a continuum. Therefore,
TsTtstfSf2ft
with
Sftst2ftSf
is the Fourier transform of
st (the Fourier transform is symbolically denoted by the
uppercase version of the signal's symbol) and is defined
for any signal for which the integral () converges.
Let's calculate the Fourier transform of the pulse
signal,
pt.
Pftpt2ftt0Δ2ft12f2fΔ1Pf2fΔfΔf
Note how closely this result resembles the expression for
Fourier
series coefficients of the periodic pulse signal.
Spectrum
The upper plot shows the magnitude of the Fourier series
spectrum for the case of
T1
with the Fourier transform of
pt
shown as a dashed line. For the bottom panel, we expanded the
period to
T5,
keeping the pulse's duration fixed at 0.2, and computed its
Fourier series coefficients.
shows how increasing the
period does indeed lead to a continuum of coefficients, and that
the Fourier transform does correspond to what the continuum
becomes. The quantity
tt
has a special name, the sinc (pronounced "sink")
function, and is denoted by
sinct.
Thus, the magnitude of the pulse's Fourier transform equals
ΔsincfΔ.
The Fourier transform relates a signal's time and frequency
domain representations to each other. The direct Fourier
transform (or simply the Fourier transform) calculates a
signal's frequency domain representation from its time-domain
variant (). The inverse
Fourier transform ()
finds the time-domain representation from the frequency
domain. Rather than explicitly writing the required integral, we
often symbolically express these transform calculations as
ℱs
and
ℱS,
respectively.
ℱsSftst2ftℱSstfSf2ft
We must have
stℱℱst
and
SfℱℱSf,
and these results are indeed valid with minor exceptions.
Recall that the Fourier series for a square wave gives a value
for the signal at the discontinuities equal to the average
value of the jump. This value may differ from how the signal
is defined in the time domain, but being
unequal at a point is indeed minor.
Showing that you "get back to where you started" is difficult
from an analytic viewpoint, and we won't try here. Note that the
direct and inverse transforms differ only in the sign of the
exponent.
The differing exponent signs means that some curious results
occur when we use the wrong sign. What is
ℱSf?
In other words, use the wrong exponent sign in evaluating
the inverse Fourier transform.
ℱSffSf2ftfSf2ftst
Properties of the Fourier transform and some useful transform
pairs are provided in the accompanying tables ( and ).
Especially
important among these properties is Parseval's
Theorem, which states that power computed in either
domain equals the power in the other.
tst2fSf2
Of practical importance is the conjugate symmetry property: When
st
is real-valued, the spectrum at negative frequencies equals the
complex conjugate of the spectrum at the corresponding positive
frequencies. Consequently, we need only plot the positive
frequency portion of the spectrum (we can easily determine the
remainder of the spectrum).
How many Fourier transform operations need to be applied to
get the original signal back:
ℱ⋯ℱsst?
ℱℱℱℱstst.
We know that
ℱSffSf2ftfSf2ftst. Therefore, two Fourier transforms applied to
st
yields
st.
We need two more to get us back where we started.
Note that the mathematical relationships between the time domain
and frequency domain versions of the same signal are termed
transforms. We are transforming (in the
nontechnical meaning of the word) a signal from one
representation to another. We express Fourier transform
pairs as
↔stSf. A signal's time and frequency domain representations
are uniquely related to each other. A signal thus "exists" in
both the time and frequency domains, with the Fourier transform
bridging between the two. We can define an information carrying
signal in either the time or frequency domains; it behooves the
wise engineer to use the simpler of the two.
A common misunderstanding is that while a signal exists in both
the time and frequency domains, a single formula expressing a
signal must contain only time or frequency:
Both cannot be present simultaneously. This situation mirrors
what happens with complex amplitudes in circuits: As we reveal
how communications systems work and are designed, we will define
signals entirely in the frequency domain without explicitly
finding their time domain variants. This idea is shown in another module where we
define Fourier series coefficients according to letter to be
transmitted. Thus, a signal, though most familiarly defined in
the time-domain, really can be defined equally as well (and
sometimes more easily) in the frequency domain. For example,
impedances depend on frequency and the time variable cannot
appear.
We will learn that
finding a linear, time-invariant system's output in the time
domain can be most easily calculated by determining the input
signal's spectrum, performing a simple calculation in the
frequency domain, and inverse transforming the result.
Furthermore, understanding communications and information
processing systems requires a thorough understanding of signal
structure and of how systems work in both
the time and frequency domains.
The only difficulty in calculating the Fourier transform of any
signal occurs when we have periodic signals (in either
domain). Realizing that the Fourier series is a special case of
the Fourier transform, we simply calculate the Fourier series
coefficients instead, and plot them along with the spectra of
nonperiodic signals on the same frequency axis.
Short Table of Fourier Transform PairsstSfatut12faat2a42f2a2pt1tΔ20tΔ2fΔf2WttSf1fW0fW
Fourier Transform Properties
Time-Domain
Frequency Domain
Linearity
a1s1ta2s2ta1S1fa2S2f
Conjugate Symmetry
stSfSf
Even Symmetry
ststSfSf
Odd Symmetry
ststSfSf
Scale Change
sat1aSfa
Time Delay
stτ2fτSf
Complex Modulation
2f0tstSff0
Amplitude Modulation by Cosine
st2f0tSff0Sff02
Amplitude Modulation by Sine
st2f0tSff0Sff02
Differentiation
tst2fSf
Integration
αtsα12fSf
if
S00
Multiplication by ttst12fSf
Area
tstS0
Value at Origin
s0fSf
Parseval's Theorem
tst2fSf2
In communications, a very important operation on a signal
st
is to amplitude modulate it. Using this operation
more as an example rather than elaborating the communications
aspects here, we want to compute the Fourier transform —
the spectrum — of
1st2fct
Thus,
1st2fct2fctst2fct
For the spectrum of
2fct,
we use the Fourier series. Its period is
1fc,
and its only nonzero Fourier coefficients are
c±112.
The second term is not periodic unless
st
has the same period as the sinusoid. Using Euler's relation,
the spectrum of the second term can be derived as
st2fctfSf2ft2fct
Using Euler's relation for the cosine,
st2fct12fSf2ffct12fSf2ffctst2fct12fSffc2ft12fSffc2ftst2fctfSffcSffc22ft
Exploiting the uniqueness property of the Fourier transform,
we have
ℱst2fctSffcSffc2
This component of the spectrum consists of the original
signal's spectrum delayed and advanced in
frequency. The spectrum of the amplitude modulated
signal is shown in .
A signal which has a triangular shaped spectrum is shown in
the top plot. Its highest frequency — the largest
frequency containing power — is
W
Hz. Once amplitude modulated, the resulting spectrum
has "lines" corresponding to the Fourier series components
at
±fc
and the original triangular spectrum shifted to components
at
±fc
and scaled by
12.
Note how in this figure the signal
st
is defined in the frequency domain. To find its time domain
representation, we simply use the inverse Fourier transform.
What is the signal
st
that corresponds to the spectrum shown in the upper panel of
?
The signal is the inverse Fourier transform of the
triangularly shaped spectrum, and equals
stWWtWt2
What is the power in
xt,
the amplitude-modulated signal? Try the calculation in
both the time and frequency domains.
The result is most easily found in the spectrum's formula:
the power in the signal-related part of
xt
is half the power of the signal
st.
In this example, we call the signal
st
a baseband signal because its power is contained at
low frequencies. Signals such as speech and the Dow Jones
averages are baseband signals. The baseband signal's
bandwidth equals W,
the highest frequency at which it has power. Since xt's
spectrum is confined to a frequency band not close to the origin
(we assume
≫fcW), we have a bandpass signal. The
bandwidth of a bandpass signal is not its
highest frequency, but the range of positive frequencies where
the signal has power. Thus, in this example, the bandwidth is
2WHz. Why a signal's bandwidth should depend on
its spectral shape will become clear once we develop
communications systems.