6.02 Fall 2010 Lecture #14 - MITweb.mit.edu/6.02/www/f2010/handouts/lectures/L14.pdf6.02 Fall 2010...
Transcript of 6.02 Fall 2010 Lecture #14 - MITweb.mit.edu/6.02/www/f2010/handouts/lectures/L14.pdf6.02 Fall 2010...
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6.02 Fall 2010
Lecture #14
• Frequency Domain Sharing
• Spectrum and the Fourier Series
• Fourier Series Examples
• Rise Time and Spectrum
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Frequency Domain Sharing – Big Picture
• Questions
– What is Modulation (Mod in figure)?
– What do typical X’s look like?
– What should the Demodulator be?
– What is the relation between and
Channel+X
Mod
Mod
Mod
x1[n]
x2[n]
xP [n]
...Y
DeMod
DeMod
DeMod
...
y1[n]
y2[n]
yP [n]
xi[n] yi[n]
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xP [n]
cos1n
Cosine Modulation
x[n] =PP
i=1 xi[n] cosin...
cosPn
x1[n]
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Ideal Channel Case
?
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Cosine in Time
x[n] = cos ¼3n = 1
2ej¼3n + 1
2e¡j
¼3n
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Sine in Time
x[n] = sin ¼3n = ¡j
2ej¼3n + j
2e¡j
¼3n
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Sine Fourier Series, 2 Imaginary values
x[n] =
N2¡1X
k=¡N2
X[k]ej2¼Nkn =
¡j2ej¼3n +
j
2e¡j
¼3n
X[k]
2¼
Nk
Note
horizontal
axis ranges
over
–pi to pi!
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Fast Rise Pulse
x[n]
n
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Spectrum of Fast Rise Pulse
x[n] =
N2¡1X
k=¡N2
X[k]ej2¼Nkn
X[k]
2¼
Nk
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Slow Rise Pulse
x[n]
n
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Spectrum Slow Rise Pulse
x[n] =
N2¡1X
k=¡N2
X[k]ej2¼Nkn
X[k]
2¼
Nk
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Key Fourier Series Advantage
x[n] =
N2¡1X
k=¡N2
X[k]ej2¼Nkn
HX Y
y[n] =
N2¡1X
k=¡N2
H(ej2¼Nk)X[k]ej
2¼Nkn
y[n] =Pn
m=0 h[m]x[n¡m]
OR
H(ej) =PL
m=0 h[m]e¡jm