5.1 Discretisation of Continuous Signals
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gF(t) = A ⋅rect ( t
∆T )
(5.2)
of the pulse shaper, which generates a rectangular pulse rect(t)¹ (see Figure 5.4):
f∆T(t) = fTa(t) ∗gF(t) =
∞
∫
τ=−∞
∞
∑
k=−.∞
f(kTa) ⋅δ(τ −kTa) ⋅A ⋅rect ( t −τ
∆T ) dτ
= A
∞
∑
k=−∞
f(kTa)
∞
∫
τ=−∞
δ(τ −kTa) ⋅rect ( t −τ
∆T ) dτ
= A
∞
∑
k=−∞
f(kTa) ⋅rect ( t −kTa
∆T
) .
(5.3)
Since a multiplication in the time domain corresponds to a convolution in the fre-
quency domain and, conversely, a convolution in the time domain corresponds to a
multiplication in the frequency domain, the associated spectrum can be determined
by a convolution of the input signal spectrum F(f) with the spectrum of a Dirac-pulse
train and then a multiplication of this spectrum with the spectrum of a square pulse:
fTa(t) =
∞
∑
k=−∞
f(kTa) ⋅δ(t −kTa) ,
FTa(f) = F(f) ∗F{
+∞
∑
ν=−∞
δ(t −νTa)}
⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟⏟
∑∞
ν=−∞
1
Ta δ(f−ν
Ta )
=
+∞
∫
ψ=−∞
F(f −ψ) ⋅( 1
Ta
+∞
∑
ν=−∞
δ (ψ −ν
Ta
)) ⋅dψ
= 1
Ta
+∞
∑
ν=−∞
F (f −ν
Ta
)
and further using the relation for the rectangular function rect(t) and its Fourier trans-
form Frec(f):
Frec(f) = F {rect(t)} = si(πf)
(5.4)
and the similarity theorem
F {f(at)} = 1
|a| F ( j2πf
a
)
with
a
̸= 0 , a = const.
(5.5)
1 rect(t) := 1 from a Dirac pulse for −0.5 ≤t ≤0.5; otherwise rect(t) := 0.