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Lecture 18-19: Linear Modulations Aliazam Abbasfar.

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Presentation on theme: "Lecture 18-19: Linear Modulations Aliazam Abbasfar."— Presentation transcript:

1 Lecture 18-19: Linear Modulations Aliazam Abbasfar

2 Outline Amplitude Modulation DSB/AM/SSB/VSB

3 DSB modulation Double sideband modulation x o (t) = A c x(t) cos(  c t) Lowpass signal x I (t) = x(t), x Q (t) = 0 A(t), (t)= ? X o (t) = ½ A c [ X(f-f c ) + X(f+f c ) ] Symmetric spectrum around f c Bandwidth : 2W Upper and lower sidebands Transmitted power G Xo (t) = ¼ A c 2 [ G X (f-f c ) + G X (f+f c ) ] P Xo = ½ A c 2 P X = P c P X P c = Unmodulated carrier power

4 DSB demodulation Coherent demodulation y(t) = 2A cos( c t) x o (t) = A Ac x(t) + A Ac x(t) cos(2 c t) Filter out x(t) cos(2 c t) by a LPF z(t) = A Ac x(t) = K x(t) Coherent demodulation Phase and frequency of the carrier is known Phase offset z(t) = K cos() x(t) Lower gain Frequency offset (f) z(t) = K cos(f t) x(t) Distortion

5 AM modulation Amplitude modulation x o (t) = A c (1+x(t)) cos(  c t)  : modulation index (1+x(t)) > 0 (<= 1 if |x(t)|<1) Signal DC value = 0 Lowpass signal x I (t) = 1+x(t), x Q (t) = 0 A(t) = 1+x(t), (t)= 0 X o (t) = ½A c [(f-f c ) + (f+f c ) ] + ½ A c [ X(f-f c ) + X(f+f c ) ] Symmetric spectrum around f c Additional tone at f c Transmitted power P Xo = ½ A c 2 (1+  ) P X = P c (1+  P X ) Efficiency:  AM =   P X / (1+  P X ) <= 50%

6 AM demodulation Envelope detection Very simple circuits Using non-linear circuits Half-wave/full-wave rectifier Good for radio broadcast Expensive TX (only 1) Cheap RXs (many)

7 SSB modulation Single sideband modulation Send only one of the sidebands LSSB or USSB Filter out other sideband Signal usually has a DC hole X o (f) = X(f-f c )u(f-f c ) ; f>0 Bandwidth : W Spectrally efficient Not symmetric Transmitted power P Xo = ½ P DSB = ½ P c P X Good for FDM Low bandwidth Low power

8 SSB modulation - 2 Lowpass signal x I (t) = ½ x(t), x Q (t) =  ½ x(t) IQ modulator Weaver modulator

9 SSB demodulation Coherent demodulation y(t) = 2A cos( c t) x o (t) = ½ A A c x(t) [1+cos(2 c t)] - ½ A A c x(t) sin(2 c t) Filter out high freq. terms by a LPF z(t) = ½ A Ac x(t) = K x(t) Phase offset z(t) = K cos() x(t) + K sin() x(t) Lower gain + distortion Frequency offset (f) z(t) = K cos(f t) x(t) + K sin(f t) x(t) Distortion IQ demodulator Multiply with both cos( c t) and sin( c t) Complex demodulator No distortion

10 VSB modulation Vestigial sideband modulation Send one of the sidebands and and part of other Filter out part of other sideband Keeps signal DC components X o (f) = X(f-f c ) H(f) ; f>0 Bandwidth > W Not symmetric Transmitted power P SSB < P Xo < P DSB Used in video broadcast Low bandwidth Keeps low frequencies Low power

11 VSB modulation H(f) has odd symmetry around f c H(f) = (1 +j H VSB )/2 H VSB is a realizable filter Lowpass signal x I (t)= ½ x(t), x Q (t) =  ½ x(t)*h VSB (t) IQ modulator

12 VSB demodulation Coherent demodulation y(t) = ½ A A c x(t) [1+cos(2 c t)] - ½ A A c x’(t) sin(2 c t) Filter out high frequency terms by a LPF z(t) = ½ A Ac x(t) = K x(t) Phase offset z(t) = K cos() x(t) + K sin() x’(t) Lower gain + distortion Frequency offset (f) z(t) = K cos(f t) x(t) + K sin(f t) x(t) Distortion Use IQ demodulator

13 Reading Carlson Ch. 4.2, 4.3 and 4.4 Proakis 2.5, 3.1, 3.2

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