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LECTURE 15: DISCRETE-TIME FOURIER TRANSFORM. Objectives: Derivation of the DTFT Transforms of Common Signals Properties of the DTFT Lowpass and Highpass Filters - PowerPoint PPT PresentationTRANSCRIPT
ECE 8443 – Pattern RecognitionECE 3163 – Signals and Systems
• Objectives:Derivation of the DTFTTransforms of Common SignalsProperties of the DTFTLowpass and Highpass Filters
• Resources:Wiki: Discete-Time Fourier TransformJOS: DTFT DerivationMIT 6.003: Lecture 9CNX: DTFT PropertiesSKM: DTFT Properties
• URL: .../publications/courses/ece_3163/lectures/current/lecture_15.ppt• MP3: .../publications/courses/ece_3163/lectures/current/lecture_15.mp3
LECTURE 15: DISCRETE-TIME FOURIER TRANSFORM
ECE 3163: Lecture 15, Slide 2
Discrete-Time Fourier Series• Assume x[n] is a discrete-time periodic signal. We want to represent it as a
weighted-sum of complex exponentials:
Note that the notation <N> refers to performing the summation over an N samples which constitute exactly one period.
• We can derive an expression for the coefficients by using a property of orthogonal functions (which applies to the complex exponential above):
• Multiplying both sides by and summing over N terms:
• Interchanging the order of summation on the right side:
• We can show that the second sum on the right equals N if k = r and 0 if k r:
otherwise,0...,2,,0,)/2( NNkN
eNn
nNjk
Nn Nk
nNrkjk
Nn Nk
nNjrnNjkk
Nn
nNjr eceecenx )/2)(()/2()/2()/2(
TececnxNk
njkk
Nk
nTjkk /2, 0
)/2( 0
nNjre )/2(
Nn
nNrkj
Nkk
Nn
nNjr ecenx )/2)(()/2(
Nn
nNjkk enx
Nc )/2(1
ECE 3163: Lecture 15, Slide 3
Discrete-Time Fourier Series (Cont.)• This provides a closed-form expression for the Discrete-Time Fourier Series:
• Note that the DT Fourier Series coefficients can be interpreted as in the CT case – they can be plotted as a function of frequency (k0) and demonstrate the a periodic signal has a line spectrum.
• As expected, this DT Fourier Series (DTFS) obeys the same properties we have seen for the CTFS and CTFT).
• Next, we will apply the DTFS to nonperiodic signals to produce the Discrete-Time Fourier Transform (DTFT).
(analysis)11
)(synthesis/2,
0
0
)/2(
0)/2(
Nn
njk
Nn
nNjkk
Nk
njkk
Nk
nTjkk
enxN
enxN
c
Tececnx
ECE 3163: Lecture 15, Slide 4
Periodic Extension• Assume x[n] is an aperiodic,
finite duration signal.
• Define a periodic extension of x[n]:
• Note that:
• We can apply the complex Fourier series:
• Define: . Note this is periodic in with period 2.
• This implies: . Note that these are evenly spaced samples of
our definition for .
22
],[~ NnNnxnx
][~~ nxNnx
Nasnxnx ][~
njk
n
njkN
Nn
njkN
Nnn
njkN
Nkk
enxN
enxN
enxN
c
Tecnx
002
1
0
0
][1][~1][~1
/2,~
2/
2/
0
2/
2/
nj
n
j enxN
eX
][1
01 jkn eX
Nc
jeX
ECE 3163: Lecture 15, Slide 5
• Derive an inverse transform:
• As• This results in our Discrete-Time Fourier Transform:
Notes:
• The DTFT and inverse DTFT are not symmetric. One is integration over a finite interval (2π), and the other is summation over infinite terms.
• The signal, x[n] is aperiodic, and hence, the transform is a continuous function of frequency. (Recall, periodic signals have a line spectrum.)
• The DTFT is periodic with period 2. Later we will exploit this property to develop a faster way to compute this transform.
The Discrete-Time Fourier Transform
0000000
21)2(
21)1(~
njk
N
Nk
jknjkN
Nk
jknjkN
Nk
jk eeXN
eeXeeXN
nx
dN
nxnxN 00 ,02],[][~,
equation)(analysis][
equation)(synthesis21][
2
n
njj
njj
enxeX
deeXnx
ECE 3163: Lecture 15, Slide 6
Example: Unit Pulse and Unit Step• Unit Pulse:
The spectrum is a constant (and periodic over the range [-,].• Shifted Unit Pulse:
Time delay produces a phase shift linearly proportional to . Note that these functions are also periodic over the range [-,].
• Unit Step:
Since this is not a time-limited function, it hasno DTFT in the ordinary sense. However, it can be shown that the inverse of this function isa unit step:
1][][
][][
n
nj
n
njj enenxeX
nnx
0
0
0
00
0
and1
][][
][][
neeXeeX
eennenxeX
nnnx
njjnjj
nj
n
nj
n
njj
][][ nunx
)(1
1
j
j
eeX
ECE 3163: Lecture 15, Slide 7
Example: Exponential Decay• Consider an exponentially decaying signal:
1][][ anuanx n
j
n
nj
n
njn
n
njj
ae
aeeaenxeX
11
)(][00
2
2222222
)cos(21
1Hence,
)cos(21)(sin)(cos)cos(21))sin(())cos(1(
:Note
aaeX
aaaaaaa
j
22 ))sin(())cos(1(
1)sin())cos(1(
11
1
aa
jaaaeeX jj
ECE 3163: Lecture 15, Slide 8
The Spectrum of an Exponentially Decaying Signal
a
a
aa
aaeX
a
a
aa
aaeX
j
j
11
)1(
1)21(
1)cos(21
111
)1(
1)21(
1)0cos(21
1
2
2
2
2
2
20
Lowpass Filter:
Highpass Filter:
ECE 3163: Lecture 15, Slide 9
Finite Impulse Response Lowpass Filter
1
11
1
,0,1,0
][NnNnN
Nnnh
)2/sin())2/1(sin(
)( 11
1
1
1
NeeeX
N
Nn
njN
Nn
njj
• The frequency response ofa time-limited pulse is alowpass filter.• We refer to this type of
filter as a finite impulse response (FIR) filter.• In the CT case, we obtained
a sinc function (sin(x)/x) for the frequency response. This is close to a sinc function, and is periodic with period 2.
ECE 3163: Lecture 15, Slide 10
Example: Ideal Lowpass Filter (Inverse)
c
cnn
denh cnj
sin)1(
21][
The Ideal Lowpass Filter Is Noncausal!
ECE 3163: Lecture 15, Slide 11
Properties of the DTFT• Periodicity:• Linearity:• Time Shifting:• Frequency Shifting:
Example:
CTFT)thefrom(different)2( jj eXeX
jj ebYeaXnbynax ][][
jnj eXennx 00
)( 00 jnj eXnxe
][)1(][ nxnxeny nnj
Note the roleperiodicityplays in theresult.
ECE 3163: Lecture 15, Slide 12
Properties of the DTFT (Cont.)• Time Reversal:• Conjugate Symmetry:
Also:
• Differentiation inFrequency:
• Parseval’s Relation:
• Convolution:
][][
jeX
ddjnnx
jj eXeXnx *real][
functionsoddareImand
functionsevenareReand
jj
jj
eXeX
eXeX
oddandimaginarypurelyisodd,andrealis][
evenandrealiseven,andrealis][
j
j
eXnx
eXnx
jeXnx ][
deXnx j
n
2
2
2
21][
)()()(][*][][ jjj eXeHeYnhnxny
ECE 3163: Lecture 15, Slide 13
Properties of the DTFT (Cont.)• Time-Scaling: )(
otherwise0kofmultipleaisnif]/[
][ jkk eX
knxnx
ECE 3163: Lecture 15, Slide 14
Example: Convolution For A Sinewave
ECE 3163: Lecture 15, Slide 15
Summary• Introduced the Discrete-Time Fourier Transform (DTFT) that is the analog of
the Continuous-Time Fourier Transform.
• Worked several examples.
• Discussed properties: