wideband fm/pm signals
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Wideband FM/PM Signals. Dr. Ali Hussein Muqaibel Electrical Engineering Department King Fahd University of Petroleum & Minerals. When do we call it Wideband ?. Narrowband. Otherwise. Wideband. What is the Bandwidth of Wideband FM?. Nyquist sampling theorem - PowerPoint PPT PresentationTRANSCRIPT
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Dr. Ali Hussein MuqaibelElectrical Engineering Department
King Fahd University of Petroleum & Minerals
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( )( ) cosFM c fk at t tg A
( ) 1fk a t Narrowband
Otherwise Wideband
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t
mp
–mp
ˆ ( )m t
( )m t
t t t
( )p pm tm m
ˆ ( )p pm tm m
t = 1/2Bm
Nyquist sampling theoremm(t) with a bandwidth of Bm (Hz), the minimum sampling frequency is 2Bmˆ ( ) ˆo )s (c
t
FM c fg t A t k dm
( ) ( )cost
FM c fg t A t k dm
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t
mp
–mp
ˆ ( )m t
( )m t
t t t
t=1/2Bm
t
gFM(t)
( )c f p i c f pk m t k m
t=1/2Bm
t
t0
z(t) Frequency i
0( ) 2 cos imz t A rect B t t t
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1
sinc
i+4Bmi–4Bmi
c– k fm p – 4B m c– k fm p
c c+ k fm p + 4 B m c+ k fm p
. . . . . .. . .. . .
|G F M ( ) |
2 (rad/s)
2 (rad
8
8 /s)FM f
m
p mBW m
B
k B
0( ) 2 cos imz t A rect B t t t 0 0( ) sinc sinc4 4 4
i ii i
m
tj j
m m
tAZ e eB B B
It is not delta!
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2 8 (rad/s)
2 8 (rad/s)FM f p m
m
BW k m B
B
Using the fact that f = kf mp/2 , the bandwidth in Hz becomes
24 (Hz)
22 4 (Hz)
2 2 (Hz)
f pFM m
m
m
k mBW B
f B
f B
In practice, this bandwidth is higher than the actual bandwidth of FM signals. Consider for example narrowband FM. Using this formula for the bandwidth, we see that the bandwidth is
twice the actual bandwidth.
2 2 (Hz) 2 (Hz)
2 2 (rad/s)FM m m
m
BW f B f B
B
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where Bm = Bandwidth of the Message Signal m(t) in Hz,
and = kf mp f = kf mp/2.
2 2 (Hz)
2 2 (rad/ )
( )
s
2 HzmFM m
m
BW f B
B
f B
mf B 2 (Hz) FMBW f
Special CaseFor very wideband FM
For narrowband FM mB f 2 (Hz) FM mBW B
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2 =2 / 1 2 1 (Hz)FM m m m mBW f B B f B B
For FM/PM, the modulation index or deviation ratio ,β, is defined as
Accordingly we may rewrite Carson's rule as
m
fB
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Notice that the above results can be readily extended for PM:
( ) ( )
,where =max ( )
2 22
i c p
p p p
p pPM m m
t k m t
k m m m t
k mBW f B B
Notice that •BWFM depends on the max(m(t)).•BWPM depends on the frequency content (change of m(t)) which is related to max ( )m t
.
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On the text book do examples 5.3-5.4 & 5.5 (In the class we start 5.3 then continue 5.3
& 5.4 to see the effect of doubling the amplitude of the message also examine the effect of time expansion/compression. Do example 5.5.
Historical Note: Read the historical Note about Edwin H. Armstrong (1890-1954)
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We started FM with the objective of saving bandwidth but this out to be wrong. So why FM what are the features that make FM applicable?
1.FM can exchange bandwidth for quality a. Signal to Noise Ration (SNR) α (Transmission bandwidth)2
b. Recall that AM has limited bandwidth2.FM has constant amplitude (fixed Power)3.FM is Immune to nonlinearity. 4.……..