Tele4653 l4

TELE4653 Digital Modulation &
Coding
PSD
Wei Zhang
w.zhang@unsw.edu.au

School of Electrical Engineering and Telecommunications
The University of New South Wales

Outline

PSD of Modulated Signals with Memory
PSD of Linearly Modulated Signals
PSD of CPM Signals

TELE4653 - Digital Modulation & Coding - Lecture 4. March 22, 2010. – p.1/1

PSD of Mod. Signal with Memory

Assume that the BP modulated signal v(t) with a LP equivalent
signal vl (t) as
∞
vl (t) = sl (t − nT ; In ) (1)
n=−∞

where sl (t; In ) ∈ {s1l (t), s2l (t), · · · , sM l (t)} is one of the possible
M LP equivalent signals determined by the information
sequence up to time n, denoted by In = (· · · , In−2 , In−1 , In ). We
assume that In is stationary process.



The autocorrelation function (ACF) of vl (t) is given by

Rvl (t + τ, t) = E[vl (t + τ )vl∗ (t)] (2)
∞ ∞
= E[sl (t + τ − nT ; In )s∗ (t − mT ; Im )]
l
n=−∞ m=−∞

It can be seen that vl (t) is a cyclostationary process. The
average of Rvl (t + τ, t) over one period T is given by
∞ ∞ T
¯ 1
Rvl (τ ) = E[sl (t + τ − nT ; In )s∗ (t − mT ; Im )]dt
l
T n=−∞ m=−∞ 0
∞
1 ∞
= E[sl (u + τ − kT ; Ik )s∗ (u; I0 )]du
l (3)
T
k=−∞ −∞

∞
Let
gk (τ ) = E[sl (t + τ ; Ik )s∗ (t; I0 )]dt.
l (4)
−∞

The Fourier transform of gk (τ ) can be calculated as

Gk (f ) = E [Sl (f ; Ik )Sl∗ (f ; I0 )] (5)

Using (4) in (3) yields
∞
¯ 1
Rvl (τ ) = gk (τ − kT ) (6)
T
k=−∞

¯
The Fourier transform of Rvl (τ ), i.e., PSD of vl (t) is given by
∞
1
Svl (f ) = Gk (f )e−j2πkf T (7)
T
k=−∞


We further deﬁne

Gk (f ) = Gk (f ) − G0 (f ). (8)

Eq. (7) can be written as (using G−k (f ) = Gk∗ (f ))
∞ ∞
1 1
Svl (f ) = Gk (f )e−j2πkf T + G0 (f )e−j2πkf T
T T
k=−∞ k=−∞
∞ ∞
2 −j2πkf T 1 k
= Gk (f )e + 2 G0 (f )δ(f − )
T T T
k=1 k=−∞
(c) (d)
Svl (f ) + Svl (f ) (9)

where (c) and (d) represent the continuous and the discrete
components. TELE4653 - Digital Modulation & Coding - Lecture 4. March 22, 2010. – p.5/1

PSD of Linearly Mod. Signals

For linearly modulated signals (ASK, PSK, QAM), the LP
equivalent of the modulated signal is of the form
∞
vl (t) = In g(t − nT ) (10)
n=−∞

where {In } is the stationary information sequence and g(t) is the
basic modulation pulse. Comparing Eq. (10) and (1), we have

sl (t; In ) = In g(t) (11)



Using (11) in (5) yields

Gk (f ) = E[Ik I0 |G(f )|2 ] = RI (k)|G(f )|2
∗
(12)

where RI (k) represents the autocorrelation function of {I n } and
G(f ) is the FT of g(t). Therefore, using (7) and (12), the PSD of
vl (t) is
∞
1
Svl (f ) = |G(f )|2 RI (k)e−j2πkf T (13)
T
k=−∞
1
= |G(f )|2 SI (f ) (14)
T



As can be seen from (14), the shape of PSD is determined
by the shape of the pulse |G(f )| and the PSD of the
sequence {In }, i.e., SI (f ).
One method to control the PSD of the modulated signal is
spectral shaping by precoding through controlling the
correlation properties of the information sequence.
For instance, a precoding form is Jn = In + αIn−1 . By
changing the value of α, we can control the PSD.


PSD of CPM

The CPM is expressed as

s(t; I) = A cos[2πfc t + φ(t; I)] (15)

where ∞
φ(t; I) = 2πh Ik q(t − kT ) (16)
k=−∞

The ACF of the LP equivalent vl (t) = ejφ(t;I) is given by
∞
Rvl (t + τ ; t) = E exp j2πh Ik [q(t + τ − kT ) − q(t − kT )]
k=−∞
∞
= E exp {j2πhIk [q(t + τ − kT ) − q(t − kT )]} (17)
k=−∞

PSD of CPM

Assume the symbols in {Ik } are statistically i.i.d. with
probabilities Pn = Prob{Ik = n}, n = ±1, ±3, · · · , ±(M − 1).
Taking expectation of (17) over the symbols {Ik }, we obtain

Rvl (t + τ ; t)
 
∞ M −1
=  exp{j2πhn[q(t + τ − kT ) − q(t − kT )]}
k=−∞ n=−(M −1),n odd
(18)

Finally, the average ACF is
T0
¯ v (τ ) = 1
Rl Rvl (t + τ ; t)dt (19)
T 0

PSD of CPM

Deﬁne ΦI (h) the characteristic function of the random sequence
{In } as
M −1
ΦI (h) = E[ejπhIn ] = Pn ejπhn (20)
n=−(M −1),n odd

Then, the PSD of the CPM signal is given by [proof pp. 139-141]
∞
Svl (f ) = ¯
Rvl (τ )e−j2πf τ dτ (21)
−∞
(L+1)T ¯
LT
¯ Rvl (τ )e−j2πf τ dτ
= 2 Rvl (τ )e−j2πf τ dτ + LT
0 1 − ΦI (h)e−j2πf T
(22)


PSD of CPFSK

For CPFSK, the pulse shape g(t) is rectangular and zero outside
the interval [0, T ]. In this case, the PSD may be expressed as
M M M
1 2 2
Sv (f ) = T An (f ) + 2 Bnm (f )An (f )Am (f ) (23)
M M
n=1 n=1 m=1

where
sin π[f T − 1 (2n − 1 − M )h]
2
An (f ) = (24)
π[f T − 1 (2n − 1 − M )h]
2
cos(2πf T − αnm ) − Φ cos αnm
Bnm (f ) = (25)
1 + Φ2 − 2Φ cos 2πf T
αnm = πh(m + n − 1 − M ) (26)
sin M πh
Φ Φ(h) = (27)
M sin πh

PSD of CPFSK

The PSD of CPFSK for M = 2, 4, and 8 is shown in next pages
as a function of f T with modulation index h = 2fd T as a
parameter.
The origin in the ﬁgures corresponds to the carrier f c . Only
half of the bandwidth occupancy is shown.
It shows that the PSD of CPFSK is smooth for h < 1,
peaked for h = 1, and much broader for h > 1.
In system design, to conserve bandwidth we have h < 1.


M=2

from Digital Communications (5th Ed.) – John G. Proakis and Masoud Salehi

M=4


M=8


PSD of MSK and OQPSK

As a special case of CPFSK, MSK has h = 1 . Then, the PSD is
2
given by
2
16A2 Tb cos 2πf Tb
Sv (f ) = (28)
π2 1 − 16f 2 Tb2

In contrast, the PSD of Offset QPSK is
2
sin 2πf Tb
Sv (f ) = 2A2 Tb (29)
2πf Tb

The PSD of the MSK and OQPSK signals are illustrated in the
ﬁgure on next page.


PSD of MSK and OQPSK

Comparison of spectra:
The main lobe of MSK is 50% wider than that for OQPSK.
The side lobes of MSK fall off faster.
MSK is signiﬁcantly more bandwidth-efﬁcient than OQPSK.


Tele4653 l4

Recommended

Recommended

More Related Content

What's hot

What's hot (20)

Viewers also liked

Viewers also liked (20)

Similar to Tele4653 l4

Similar to Tele4653 l4 (20)

More from Vin Voro

More from Vin Voro (20)

Recently uploaded

Recently uploaded (20)

Tele4653 l4