Signals and systems-5

Signals and Systems-V
Prof: Sarun Soman
Manipal Institute of Technology
Manipal

Non-periodic Signals: Fourier-Transform
Representations
No restrictions on the period of the sinusoids used to represent
non-periodic signal.
Frequencies can take a continuum of values.
For CT non periodic signal the range is from −∞ to ∞
For DT non periodic signal the range is from −ߨ to ߨ
CTFT
‫ݔ‬ ‫ݐ‬ =
1
2ߨ
න ܺ(݆߱)݁௝ఠ௧݀߱
ஶ
ିஶ
(1)
DTFT
‫ݔ‬ ݊ =
1
2ߨ
න ܺ(݆Ω)݁௝Ω௡݀Ω
గ
ିగ
(2)
Prof: Sarun Soman, MIT, Manipal 2

Continuous Time Non-periodic Signals: The
Fourier Transform
CTFT is used to represent a continuous time non-periodic signal
as a superposition of complex sinusoids.
‫ݔ‬ ‫ݐ‬ =
1
2ߨ
න ܺ(݆߱)݁௝ఠ௧݀߱
ஶ
ିஶ
Where
ܺ ݆߱ = න ‫݁)ݐ(ݔ‬ି௝ఠ௧݀‫ݐ‬
ஶ
ିஶ
ܺ ݆߱ is the frequency domain representation of ‫)ݐ(ݔ‬
The weight on each sinusoid is
௑ ௝ఠ
ଶగ

Continuous Time Non-periodic Signals: The
Fourier Transform
CTFT is used to analyze the characteristics of CT systems and the
interaction b/w CT signals and systems.
Eq(1) and (2) may not converge for all functions of x(t)
Dirichlet conditions for non periodic signal
x(t) is absolutely integrable
න ‫)ݐ(ݔ‬ ݀‫ݐ‬ < ∞
ஶ
ିஶ
x(t) has a finite number of maxima, minima and discontinuities in any
finite interval.
The size of each discontinuity is finite
Eg. Unit step function is not absolutely integrable

Example
1.Find the FT of ‫ݔ‬ ‫ݐ‬ = ݁ଶ௧‫.)ݐ−(ݑ‬
Ans:
ܺ ݆߱ = න ‫݁)ݐ(ݔ‬ି௝ఠ௧݀‫ݐ‬
ஶ
ିஶ
ܺ ݆߱ = න ݁ଶ௧
଴
ିஶ
݁ି௝ఠ௧݀‫ݐ‬
=
݁ ଶି௝ఠ ௧
2 − ݆߱
|ିஶ
଴
=
1
2 − ݆߱
2.‫ݔ‬ ‫ݐ‬ = ݁ି ௧
Ans:
ܺ ݆߱ = න ‫݁)ݐ(ݔ‬ି௝ఠ௧
݀‫ݐ‬
ஶ
ିஶ
ܺ ݆߱ = න ݁௧
଴
ିஶ
݁ି௝ఠ௧
݀‫ݐ‬
+ න ݁ି௧
݁ି௝ఠ௧
݀‫ݐ‬
ஶ
଴
=
݁ ௝ఠାଵ ௧
݆߱ + 1
|ିஶ
଴
+
݁ି ௝ఠାଵ ௧
−(݆߱ + 1)
|଴
ஶ
=
1
1 + ݆߱
+
1
݆߱ + 1
=
2
1 + ݆߱

Example
Find the FT of ‫ݔ‬ ‫ݐ‬
Ans:
Rectangular pulse is absolutely
integrable provided ܶ < ∞
ܺ ݆߱ = න ‫݁)ݐ(ݔ‬ି௝ఠ௧
݀‫ݐ‬
ஶ
ିஶ
ܺ ݆߱ = න ‫݁)ݐ(ݔ‬ି௝ఠ௧݀‫ݐ‬
்
ି்
= −
1
݆߱
݁ି௝ఠ௧݀‫|ݐ‬ି்
்
=
݁௝ఠ்
− ݁ି௝ఠ்
݆߱
= 2
sin ߱ܶ
߱
, ߱ ≠ 0
For ߱ = 0
lim
ఠ→଴
2
sin ߱ܶ
߱
= 2ܶ
Zero crossing points
߱ܶ = ±݉ߨ
߱ = ±
݉ߨ
ܶ
, ݉ = ±1, ±2, ±3 … . .

Example
Ans:
ܺ ݆߱ = න ‫݁)ݐ(ݔ‬ି௝ఠ௧
݀‫ݐ‬
ஶ
ିஶ
ܺ ݆߱ = න (1)
଴
ିଶ
݁ି௝ఠ௧݀‫ݐ‬
+ න (−1)
ଶ
଴
݁ି௝ఠ௧݀‫ݐ‬
ܺ ݆߱ =
݁ି௝ఠ௧
−݆߱
|ିଶ
଴
+
݁ି௝ఠ௧
݆߱
|଴
ଶ
=
݁௝ଶఠ − 1
݆߱
+
݁ି௝ଶఠ − 1
݆߱
= ݆
2
߱
+
2 cos 2߱
݆߱
Find FT
t
x(t)
2-2
1

Example
‫ݔ‬ ‫ݐ‬ = ߜ(‫)ݐ‬
Draw the spectrum
Ans:
ܺ ݆߱ = න ‫݁)ݐ(ݔ‬ି௝ఠ௧
݀‫ݐ‬
ஶ
ିஶ
ܺ ݆߱ = න ߜ(‫)ݐ‬ ݁ି௝ఠ௧
݀‫ݐ‬
ஶ
ିஶ
Using sifting property
ܺ ݆߱ = 1
Inverse CTFT
Determine the time domain signal
ܺ ݆߱ = ݁ିଶఠ‫)߱(ݑ‬
Ans:
‫ݔ‬ ‫ݐ‬ =
1
2ߨ
න ܺ(݆߱)݁௝ఠ௧
݀߱
ஶ
ିஶ
‫ݔ‬ ‫ݐ‬ =
1
2ߨ
න ݁ିଶఠ݁௝ఠ௧݀߱
ஶ
଴
=
1
2ߨ
݁(ିଶା௧)ఠ
(−2 + ݆‫)ݐ‬
|଴
ஶ
=
1
2ߨ
݁(ିଶା௧)ஶ − 1
−2 + ݆‫ݐ‬
ܺ ݆߱
߱
0

Example
=
1
2ߨ(2 − ݆‫)ݐ‬
Find inverse CTFT
ࢄ ࢐࣓ = ൝
‫ܛܗ܋‬ ૛࣓ , ࣓ <
࣊
૝
૙, ࢕࢚ࢎࢋ࢘࢝࢏࢙ࢋ
Ans:
‫)ݐ(ݔ‬ =
1
2ߨ
න ܺ(݆߱)݁௝ఠ௧
݀
ஶ
ିஶ
߱
=
1
2ߨ
න
݁௝ଶఠ + ݁ି௝ଶఠ
2
గ
ସ
ି
గ
ସ
݁௝ఠ௧݀߱
=
1
2ߨ
න
1
2
݁௝ ଶା௧ ఠ
గ
ସ
ି
గ
ସ
݀߱
+
1
2ߨ
න
1
2
݁௝(௧ିଶ)ఠ݀߱
గ
ସ
ି
గ
ସ
=
1
2ߨ
݁௝ ଶା௧ ఠ
2(‫ݐ‬ + 2)
|ି
గ
ସ
గ
ସ
+
1
2ߨ
݁௝ ௧ିଶ ఠ
2(‫ݐ‬ − 2)
|ି
గ
ସ
గ
ସ

Example
=
1
2ߨ
቎
sin
ߨ
4
‫ݐ‬ + 2
(‫ݐ‬ + 2)
+
sin
ߨ
4
‫ݐ‬ − 2
(‫ݐ‬ − 2)
቏
‫ݔ‬ ‫ݐ‬
=
1
2ߨ
sin
ߨ
4
‫ݐ‬ + 2
(‫ݐ‬ + 2)
+
sin
ߨ
4
‫ݐ‬ − 2
(‫ݐ‬ − 2)
1
8
, ‫ݐ‬ = ±2
Find the time domain signal
corresponding to the frequency
spectrum.
Ans:

Example
ܺ ݆߱ = ൜
݁ି௝ଶఠ
, ߱ < 2
0, ‫݁ݏ݅ݓݎ݄݁ݐ݋‬
‫)ݐ(ݔ‬ =
1
2ߨ
න ܺ(݆߱)݁௝ఠ௧
݀
ஶ
ିஶ
߱
‫)ݐ(ݔ‬ =
1
2ߨ
න ݁ି௝ଶఠ
݁௝ఠ௧
݀
ଶ
ିଶ
߱
=
1
2ߨ
݁௝ ௧ିଶ ఠ
(‫ݐ‬ − 2)
|ିଶ
ଶ
=
1
ߨ(‫ݐ‬ − 2)
sin 2(‫ݐ‬ − 2)
‫ݔ‬ ‫ݐ‬ =
1
ߨ(‫ݐ‬ − 2)
sin 2(‫ݐ‬ − 2) , ‫ݐ‬ ≠ 2
2
ߨ
, ‫ݐ‬ = 2
Find the time domain signal corresponding
to the spectrum.
Ans:
‫)ݐ(ݔ‬ =
1
2ߨ
න ܺ(݆߱)݁௝ఠ௧݀
ஶ
ିஶ
߱
‫)ݐ(ݔ‬ =
1
2ߨ
න ݁௝ఠ௧
݀
ௐ
ିௐ
߱
=
1
݆ߨ‫ݐ‬
݁௝ௐ௧ − ݁ି௝ௐ௧
2

Example
=
sin ܹ‫ݐ‬
ߨ‫ݐ‬
‫)ݐ(ݔ‬ =
ܹ
ߨ
sin ܹ‫ݐ‬
ܹ‫ݐ‬
, ‫ݐ‬ ≠ 0
For ‫ݐ‬ = 0
lim
௧→଴
sin ܹ‫ݐ‬
ߨ‫ݐ‬
‫ݔ‬ ‫ݐ‬ =
ܹ
ߨ
Zero crossing points
ܹ‫ݐ‬ = ±݉ߨ, ݉ = ±1,2,3 … .
‫ݐ‬ = ±
݉ߨ
ܹ

Properties of Fourier Transform
Linearity
Linearity property is the basis of the partial fraction method for
determining inverse FT.
Eg.
Find ‫)ݐ(ݔ‬
ܺ ݆߱ =
−݆߱
(݆߱)ଶ+3݆߱ + 2
ܽ‫ݔ‬ ‫ݐ‬ + ܾ‫ݔ‬ ‫ݐ‬ ܽܺ ݆߱ + ܾܻ(݆߱)

Example
=
ܿଵ
݆߱ + 1
+
ܿଶ
݆߱ + 2
ܿଵ = 1, ܿଶ = −2
ܺ ݆߱ =
1
݆߱ + 1
−
2
݆߱ + 2
Using the transformation table
1
1
݆߱ + 1
+ −2
1
݆߱ + 2
↔ 1 ݁ି௧‫ݑ‬ ‫ݐ‬
+ (−2)݁ିଶ௧‫)ݐ(ݑ‬
‫ݔ‬ ‫ݐ‬ = ݁ି௧‫ݑ‬ ‫ݐ‬ − 2݁ିଶ௧‫)ݐ(ݑ‬
Symmetry Property: Real and
Imaginary Signals.
If ‫)ݐ(ݔ‬ is real and even
ܺ(݆߱) is real
If ‫)ݐ(ݔ‬ is real and odd
ܺ(݆߱) is imaginary
Time Shift properties
‫ݐ(ݔ‬ − ‫ݐ‬଴) ↔ ݁ି௝ఠబ௧ܺ(݆߱)
• Shift in time domain leaves the
magnitude spectrum unchanged
• Introduces a phase shift that is
linear function of
frequency(݁ି௝ఠబ௧).
݁ି௔௧‫)ݐ(ݑ‬ ↔
1
݆߱ + ܽ

Differentiation Property
Differentiation in time
݀
݀‫ݐ‬
‫)ݐ(ݔ‬ ↔ ݆߱ܺ(݆߱)
• Differentiation in time domain
corresponds to multiplying by j߱
in frequency domain.
• This operation accentuates high
frequency components.
Eg.
݁ି௔௧‫)ݐ(ݑ‬ ↔
1
݆߱ + ܽ
݀
݀‫ݐ‬
݁ି௔௧‫)ݐ(ݑ‬ ↔ (݆߱)
1
݆߱ + ܽ
Differentiation in Frequency
−݆‫ݐ‬ ‫)ݐ(ݔ‬ ↔
݀
݀߱
ܺ(݆߱)
Eg.
Use differentiation property to find
FT of ‫ݔ‬ ‫ݐ‬ = ‫݁ݐ‬ି௔௧‫)ݐ(ݑ‬
Ans:
Using differentiation property
−݆‫ݐ‬ ‫)ݐ(ݔ‬ ↔
݀
݀߱
ܺ(݆߱)
‫ݐ‬ ‫)ݐ(ݔ‬ ↔
1
−݆
݀
݀߱
ܺ(݆߱)
‫݁ݐ‬ି௔௧ ↔ ݆
݀
݀߱
1
݆߱ + ܽ

‫݁ݐ‬ି௔௧
↔
1
݆߱ + ܽ ଶ
Integration
න ‫ݔ‬ ߬ ݀߬ =
1
݆߱
ܺ ݆߱ + ߨܺ(݆0)ߜ(߱)
௧
ିஶ
• De emphasizing high frequency
components.
Eg.
FT of unit step using integration
property
Ans:
‫ݑ‬ ‫ݐ‬ = න ߜ ߬ ݀߬
௧
ିஶ
ߜ(‫)ݐ‬ ↔ 1
Using integration property
න ߜ ߬ ݀߬
௧
ିஶ
↔
1
݆߱
1 + ߨߜ ߱
Convolution property
‫ݔ‬ ‫ݐ‬ ∗ ݄(‫)ݐ‬ ↔ ܺ ݆߱ ‫)݆߱(ܪ‬
Eg.
Let the input to a system with impulse
response ݄ ‫ݐ‬ = 2݁ିଶ௧
‫)ݐ(ݑ‬ be
‫ݔ‬ ‫ݐ‬ = 3݁ି௧
‫ݑ‬ ‫ݐ‬ .

Ans:
2݁ିଶ௧‫)ݐ(ݑ‬ ↔
2
݆߱ + 2
3݁ି௧ ↔
3
݆߱ + 1
Using convolution property
‫ݕ‬ ‫ݐ‬ = ‫ݔ‬ ‫ݐ‬ ∗ ݄(‫)ݐ‬
ܻ ݆߱ = ܺ ݆߱ ‫)݆߱(ܪ‬
ܻ ݆߱ =
6
(݆߱ + 2)(݆߱ + 1)
=
ܿଵ
݆߱ + 2
+
ܿଶ
݆߱ + 1
ܿଵ = −6, ܿଶ = 6
ܻ ݆߱ =
−6
݆߱ + 2
+
6
݆߱ + 1
‫ݕ‬ ‫ݐ‬ = −6݁ିଶ௧
‫ݑ‬ ‫ݐ‬ + 6݁ି௧
‫)ݐ(ݑ‬
Modulation property
‫ݔ‬ ‫ݐ‬ ‫ݖ‬ ‫ݐ‬ ↔
1
2ߨ
ܺ ݆߱ ∗ ܼ(݆߱)

• Slope of the linear phase term is
equal to the time shift (‫ݐ‬଴).
Eg.
‫ݔ‬ ‫ݐ‬ = ݁ି௧ାଶ
‫ݐ(ݑ‬ − 2)
Ans:
݁ି௧
‫ݑ‬ ‫ݐ‬ ↔
1
݆߱ + 1
݁ି௧ାଶ
‫ݐ(ݑ‬ − 2) ↔ ݁ି௝ఠ(ଶ)
1
݆߱ + 1
Frequency Shift Properties
݁௝ఊ௧
‫)ݐ(ݔ‬ ↔ ܺ(݆(߱ − ߛ))
• A frequency shift corresponds to
multiplication in time domain by a
complex sinusoid whose frequency
is equal to the shift.
Eg.
‫ݔ‬ ‫ݐ‬ ↔
2
߱
sin(߱ߨ)
݁௝ଵ଴௧‫)ݐ(ݔ‬
↔
2
߱ − 10
sin(ߨ(߱ − 10))
Scaling Property
‫)ݐ(ݔ‬ ↔ ܺ(݆߱)
‫)ݐܽ(ݔ‬ ↔
1
ܽ
ܺ ݆
߱
ܽ
Scaling the signal in time domain
introduces inverse scaling in
frequency domain representation &
an amplitude scaling.

Parseval’s Theorem
Parseval’s theorem states that energy or power in time domain
representation is equal to the energy or power in frequency
domain.
න ‫)ݐ(ݔ‬ ଶ݀‫ݐ‬
ஶ
ିஶ
=
1
2ߨ
න ܺ(݆߱) ଶ݀߱
ஶ
ିஶ
Duality property
There is a consistent symmetry b/w the time and Frequency
domain representation of signals.
A rectangular pulse in either time or frequency domain
corresponds to a sinc function in either frequency or time.

We may interchange time and frequency
This interchangeability property is termed duality.

݂(‫)ݐ‬
ி்
‫ܨ‬ ݆߱
‫)ݐ݆(ܨ‬
ி்
2ߨ݂(−߱)
Using duality property find the
duality property of ‘1’
Ans:
ߜ(‫)ݐ‬
ி்
1
1
ி்
2ߨߜ −߱
Find the FT of ‫ݔ‬ ‫ݐ‬ =
ଵ
ଵା௝௧
Ans:
݁ି௧‫ݑ‬ ‫ݐ‬
ி் 1
݆߱ + 1
Replace ߱ by ‫ݐ‬
1
݆‫ݐ‬ + 1

Using duality
݁ି௧‫ݑ‬ ‫ݐ‬
ி் 1
݆߱ + 1
1
݆‫ݐ‬ + 1
ி்
2ߨ݁ఠ‫)߱−(ݑ‬

Discrete Time Non-periodic Signals: The
Discrete Time Fourier Transform
DTFT is used to represent a discrete-time -periodic signal as a
superposition of complex sinusoids.
DTFT would involve a continuum of frequencies on the
interval−ߨ < Ω < ߨ
‫ݔ‬ ݊ =
1
2ߨ
න ܺ(݁௝Ω
)݁௝Ω௡
݀
గ
ିగ
Ω
Where
ܺ ݁௝Ω = ෍ ‫݁]݊[ݔ‬ି௝Ω௡
ஶ
௡ୀିஶ
ܺ ݁௝Ω is termed as the frequency domain representation of
‫]݊[ݔ‬

Example
Find the DTFT of the exponential
sequence ‫ݔ‬ ݊ =
ଵ
ସ
௡
‫݊[ݑ‬ + 4]
Ans:
ܺ ݁௝Ω = ෍ ‫݁]݊[ݔ‬ି௝Ω௡
ஶ
௡ୀିஶ
= ෍
1
4
௡
݁ି௝Ω௡
ஶ
௡ୀିସ
Let ݊ + 4 = ݈
= ෍
1
4
௟ିସ
݁ି௝Ω(௟ିସ)
ஶ
௟ୀ଴
=
1
4
ିସ
݁௝Ωସ
෍
1
4
݁ି௝Ω
௟ஶ
௟ୀ଴
= 256݁௝ସΩ
1
1 −
1
4
݁ି௝Ω
Evaluate the DTFT of signal x[n]
shown in Fig. Find the expression for
magnitude and phase spectra.
0 1 2
3
-1-2-3
n
‫]݊[ݔ‬
1
-1

Example
ܺ ݁௝Ω
= ෍ ‫݁]݊[ݔ‬ି௝Ω௡
ஶ
௡ୀିஶ
= ‫ݔ‬ −3 ݁௝ଷΩ
+ ‫ݔ‬ −2 ݁௝ଶΩ
+ ‫ݔ‬ 2 ݁ି௝ଶΩ + ‫ݔ‬ 3 ݁ି௝ଷΩ
= ݁௝ଷΩ + ݁௝ଶΩ + ݁ି௝ଶΩ − ݁ି௝ଷΩ
= 2݆ sin 3Ω + 2 cos 2Ω
ܺ ݁௝Ω
= 2 ܿ‫ݏ݋‬ଶ 2Ω + ‫݊݅ݏ‬ଶ 2Ω
< ܺ ݁௝Ω
= ‫݊ܽݐ‬ିଵ
sin 3Ω
cos 2Ω
‫ݔ‬ ݊ = ܽ ௡ , ܽ < 1
Ans:
ܺ ݁௝Ω
= ෍ ‫݁]݊[ݔ‬ି௝Ω௡
ஶ
௡ୀିஶ
= ෍(ܽ݁ି௝Ω)௡+ ෍ (ܽ݁௝Ω)ି௡
ିஶ
௡ୀିଵ
ஶ
௡ୀ଴
=
1
1 − ܽ݁ି௝Ω
+ ܻ
ܻ = ෍ (ܽ݁௝Ω
)ି௡
ିஶ
௡ୀିଵ
Let ݊ = −݉

Example
ܻ = ෍ (ܽ݁௝Ω
)௠
ஶ
௠ୀଵ
ܻ = ෍ (ܽ݁௝Ω)௠
ஶ
௠ୀ଴
− 1
=
1
1 − ܽ݁௝Ω
− 1
=
ܽ݁௝Ω
1 − ܽ݁௝Ω
ܺ ݁௝Ω =
1
1 − ܽ݁ି௝Ω
+
ܽ݁௝Ω
1 − ܽ݁௝Ω
=
1 − ܽଶ
1 + ܽଶ − 2ܽ cos Ω
Obtain the DTFT of rectangular pulse
‫ݔ‬ ݊ = ൜
1, ݊ ≤ ‫ܯ‬
0, ݊ > ‫ܯ‬
Ans:
ܺ ݁௝Ω
= ෍ ‫݁]݊[ݔ‬ି௝Ω௡
ஶ
௡ୀିஶ

Example
ܺ ݁௝Ω = ෍ 1݁ି௝Ω௡
ெ
௡ୀିெ
Let ݈ = ݊ + ‫ܯ‬
ܺ ݁௝Ω
= ෍ ݁ି௝Ω(௟ିெ)
ଶெ
௟ୀ଴
= ݁௝Ωெ ෍ ݁ି௝Ω௟
ଶெ
௟ୀ଴
= ݁௝Ωெ
1 − ݁ି௝Ω ଶெାଵ
1 − ݁ି௝Ω
= ݁௝Ωெ
݁ି௝
Ω
ଶ
ଶெାଵ ݁௝
Ω
ଶ
ଶெାଵ
− ݁ି௝
Ω
ଶ
ଶெାଵ
1 − ݁ି௝Ω
=
݁௝Ωெ
݁ି௝
Ω
ଶ
ଶெାଵ
݁ି௝
Ω
ଶ
݁௝
Ω
ଶ
ଶெାଵ
− ݁ି௝
Ω
ଶ
ଶெାଵ
݁௝
Ω
ଶ − ݁ି௝
Ω
ଶ
=
sin Ω
2‫ܯ‬ + 1
2
sin
Ω
2
, Ω ≠ 0,2ߨ …
Ω=0

Example
ܺ ݁௝Ω
= lim
Ω↔଴
cos Ω
2‫ܯ‬ + 1
2
∗
2‫ܯ‬ + 1
2
cos
Ω
2
∗
1
2
= 2‫ܯ‬ + 1
Find the DTFT of the signal
‫ݔ‬ ݊ = cos
ߨ݊
5
+ ݆ sin
ߨ݊
5
;
݊ ≤ 10
Ans:
‫ݔ‬ ݊ = ݁௝
గ௡
ହ
ܺ ݁௝Ω
= ෍ ݁௝
గ௡
ହ
ଵ଴
௡ୀିଵ଴
݁ି௝Ω௡
Let ݊ + 10 = ݉
= ෍ ݁
ି௝
గ
ହିΩ
೘షభబ
ଶ଴
௠ୀ଴

Example
= ݁
ି௝ଵ଴
గ
ହ
ିΩ 1 − ݁
௝ଶଵ
గ
ହ
ିΩ
1 − ݁
௝
గ
ହ
ିΩ
=
sin
21
2
ߨ
5
− Ω
sin
1
2
ߨ
5
− Ω

Inverse DTFT
Find the inverse DTFT using partial
fraction expansion.
ܺ ݁௝Ω =
3 −
1
4
݁ି௝Ω
1 −
1
16
݁ି௝ଶΩ
Ans:
ܺ ݁௝Ω
=
‫ܣ‬
1 −
1
4
݁ି௝Ω
+
‫ܤ‬
1 +
1
4
݁ି௝Ω
‫ܣ‬ =
3 −
1
4
݁ି௝Ω
1 +
1
4
݁ି௝Ω
|௘షೕΩୀସ
‫ܣ‬ = 1
‫ܤ‬ =
3 −
1
4
݁ି௝Ω
1 −
1
4
݁ି௝Ω
|௘షೕΩୀିସ
‫ܤ‬ = 2
ܺ ݁௝Ω =
1
1 −
1
4
݁ି௝Ω
+
2
1 +
1
4
݁ି௝Ω
‫ݔ‬ ݊ =
1
4
௡
‫ݑ‬ ݊ + 2
−1
4
௡
‫]݊[ݑ‬

z transform
• DTFT- complex sinusoidal representation of a DT signal
• ‫ݖ‬ transform – Representation in terms of complex exponential
signals.
• ‫ݖ‬ transform is the discrete time counterpart to Laplace
transform
Why ‫ݖ‬ transform?
• More general classification of DT signal.
• A broader characterization of DT LTI systems & its interaction
with signals.

Z transform
Eg.
DTFT exists only if impulse response is absolutely summable.
DTFT exists only for stable LTI systems.
‫ݖ‬ transform of the impulse response exists for unstable LTI
systems and signals.
‫ݖ‬ transform of the impulse response is the transfer function of
the system.
‫ݖ‬ = ‫݁ݎ‬௝Ω
‫ݎ‬ − ݉ܽ݃݊݅‫,݁݀ݑݐ‬ Ω − ݈ܽ݊݃݁
‫ݔ‬ ݊ = ‫ݖ‬௡ complex exponential signal.

Z transform
‫ݔ‬ ݊ = ‫ݎ‬௡ cos Ω݊ + ݆‫ݎ‬௡ sin Ω݊
If ‫ݎ‬ = 1, ‫]݊[ݔ‬ is a complex sinusoid.
Applying ‫]݊[ݔ‬ to an LTI system
‫ݕ‬ ݊ = ݄ ݊ ∗ ‫]݊[ݔ‬
= ෍ ݄ ݇ ‫݊[ݔ‬ − ݇]
ஶ
௞ୀିஶ
‫ݔ‬ ݊ = ‫ݖ‬௡
‫ݕ‬ ݊ = ෍ ݄[݇]‫ݖ‬௡ି௞
ஶ
௞ୀିஶ

z transform
= ‫ݖ‬௡
෍ ݄[݇]‫ݖ‬ି௞
ஶ
௞ୀିஶ
Transfer function
‫ܪ‬ ‫ݖ‬ = ෍ ݄[݇]‫ݖ‬ି௞
ஶ
௞ୀିஶ
‫ݖ‬ transform of ‫]݊[ݔ‬
ܺ ‫ݖ‬ = ෍ ‫ݖ]݊[ݔ‬ି௡
ஶ
௡ୀିஶ
(1)
Convergence
• ‫ݖ‬ transform exist when eqn(1)
converges.
• Necessary condition is absolute
summability.
෍ ‫ݖ]݊[ݔ‬ି௡
ஶ
௡ୀିஶ
< ∞ (2)
‫ݖ‬ = ‫݁ݎ‬௝Ω
‫ݖ‬ି௡ = ‫ݎ‬ି௡
Equation (2) can be written as
෍ ‫ݎ]݊[ݔ‬ି௡
ஶ
௡ୀିஶ
< ∞

z transform
• The range ′‫′ݎ‬ for which eq(2) converges is termed as Region of
Convergence(ROC)
• ‫ݎ]݊[ݔ‬ି௡ is absolutely summable even though ‫]݊[ݔ‬ is not.
• Ability to work with signals that doesn't have a DTFT is a
significant advantage offered by the ‫ݖ‬ transform.
Z-plane.

transform
ࢠ transform of a causal exponential
signal
Determine the ‫ݖ‬ transform of the
signal ‫ݔ‬ ݊ = ߙ௡
‫.]݊[ݑ‬ Depict the
ROC and the location of poles and
zeros of ܺ(‫)ݖ‬ in the ‫ݖ‬ plane.
Ans:
ܺ ‫ݖ‬ = ෍ ‫ݖ]݊[ݔ‬ି௡
ஶ
௡ୀିஶ
ܺ ‫ݖ‬ = ෍ ߙ௡‫ݖ]݊[ݑ‬ି௡
ஶ
௡ୀିஶ
= ෍
ߙ
‫ݖ‬
௡
ஶ
௡ୀ଴
The sum converges only if
ߙ
‫ݖ‬
< 1
‫ݖ‬ > ߙ
ܺ ‫ݖ‬ =
1
1 − ߙ‫ݖ‬ିଵ
, ‫ݖ‬ > ߙ
ܺ(‫)ݖ‬in pole-zero form
=
‫ݖ‬
‫ݖ‬ − ߙ
, ‫ݖ‬ > ߙ
Pole zero plot and ROC

‫ݖ‬ transform
ࢠ transform of non-causal
exponential signal
Determine the ‫ݖ‬ transform of the
signal ‫ݕ‬ ݊ = −ߙ௡‫ݑ‬ −݊ − 1 .Depict
the ROC and the locations of poles
and zeros of ܺ ‫ݖ‬ in the ‫ݖ‬ plane.
Ans:
ܻ ‫ݖ‬ = ෍ ‫ݖ]݊[ݕ‬ି௡
ஶ
௡ୀିஶ
= − ෍ ߙ௡
ିଵ
ିஶ
‫ݖ‬ି௡
Let ݇ = −݊
ܻ ‫ݖ‬ = − ෍
‫ݖ‬
ߙ
௞
ஶ
௞ୀଵ
= − ෍
‫ݖ‬
ߙ
௞
ஶ
௞ୀ଴
− 1
= 1 − ෍
‫ݖ‬
ߙ
௞
ஶ
௞ୀ଴
The sum converges, provided
௭
ఈ
< 1
‫ݖ‬ < ߙ
= 1 −
1
1 − ‫ߙݖ‬ିଵ
, ‫ݖ‬ < ߙ

transform
=
1 − ‫ߙݖ‬ିଵ − 1
=
−‫ߙݖ‬ିଵ
= −
‫ݖ‬
ߙ − ‫ݖ‬
=
‫ݖ‬
‫ݖ‬ − ߙ
, ‫ݖ‬ < ߙ
ROC plot
‫ݖ‬ transform is same but ROC is
different
z transform of a two sided signal
Determine the z-transform of
‫ݔ‬ ݊ = −‫ݑ‬ −݊ − 1 +
ଵ
ଶ
௡
‫.]݊[ݑ‬
Depict the ROC and the locations of
poles and zeros of ܺ(‫)ݖ‬ in the plane.
ܺ ‫ݖ‬ = ෍
1
2
௡
‫ݖ]݊[ݑ‬ି௡
ஶ
௡ୀିஶ
− ‫݊−[ݑ‬
− 1]‫ݖ‬ି௡
= ෍
1
2‫ݖ‬
௡
− ෍
1
‫ݖ‬
௡ିଵ
௡ୀିஶ
ஶ
௡ୀ଴
= ෍
1
2‫ݖ‬
௡
+ 1 − ෍ ‫ݖ‬௞
ஶ
௞ୀ଴
ஶ
௡ୀ଴
Both the sum converges when
‫ݖ‬ >
1
2
ܽ݊݀ ‫ݖ‬ < 1

‫ݖ‬ transform
ܺ ‫ݖ‬ =
1
1 −
1
2
‫ݖ‬ିଵ
+ 1 −
1
1 − ‫ݖ‬
,
1
2
< ‫ݖ‬ < 1
Pole zero form
ܺ ‫ݖ‬ =
‫ݖ‬
‫ݖ‬ −
1
2
+
‫ݖ‬
‫ݖ‬ − 1
ܺ ‫ݖ‬ =
‫ݖ‬ଶ
− ‫ݖ‬ + ‫ݖ‬ଶ
−
1
2
‫ݖ‬
‫ݖ‬ −
1
2
‫ݖ‬ − 1
ܺ ‫ݖ‬ =
‫ݖ‬ 2‫ݖ‬ −
3
2
‫ݖ‬ −
1
2
‫ݖ‬ − 1
,
1
2
< ‫ݖ‬ < 1
Find the z transform and ROC
‫ݔ‬ ݊ = 7
1
3
௡
‫ݑ‬ ݊ − 6
1
2
௡
‫]݊[ݑ‬
Ans:
ܺ ‫ݖ‬ = ෍ ‫ݖ]݊[ݔ‬ି௡
ஶ
௡ୀିஶ
= ෍ 7
1
3
௡
‫ݖ‬ି௡ − ෍ 6
1
2
௡
‫ݖ‬ି௡
ஶ
௡ୀ଴
ஶ
௡ୀ଴
Sum converges, ‫ݖ‬ >
ଵ
ଷ
and ‫ݖ‬ >
ଵ
ଶ
=
7
1 −
1
3
‫ݖ‬ିଵ
−
6
1 −
1
2
‫ݖ‬ିଵ

transform
ROC must not include any poles
ROC , ‫ݖ‬ >
ଵ
ଶ
Find z transform and ROC
‫ݔ‬ ݊ =
1
2
௡
Ans:
‫ݔ‬ ݊ =
1
2
௡
‫ݑ‬ ݊ +
1
2
ି௡
‫݊−[ݑ‬ − 1]
ܺ ‫ݖ‬ =
1
1 −
1
2
‫ݖ‬ିଵ
+ ෍
1
2
ି௡
‫ݖ‬ି௡
ିଵ
௡ୀିஶ
෍
‫ݖ‬
2
ି௡
ିଵ
௡ୀିஶ
Let ݇ = −݊
෍
‫ݖ‬
2
ି௞
ஶ
௞ୀଵ
෍
2
‫ݖ‬
௞
− 1
ஶ
௞ୀ଴
Sum converges
ଶ
௭
< 1, ‫ݖ‬ < 2
1
1 − 2‫ݖ‬ିଵ
− 1

‫ݖ‬ transform
2‫ݖ‬ିଵ
1 − 2‫ݖ‬ିଵ
ܺ ‫ݖ‬ =
1
1 −
1
2
‫ݖ‬ିଵ
+
2‫ݖ‬ିଵ
1 − 2‫ݖ‬ିଵ
ROC
1
2
< ‫ݖ‬ < 2
Find the z transform of ‫ݔ‬ ݊ = ߜ[݊]
Ans:
ܺ ‫ݖ‬ = ෍ ߜ[݊]‫ݖ‬ି௡
ஶ
௡ୀିஶ
= 1
ROC
No zeros and poles, ROC is all z plane
‫ݔ‬ ݊ = ߜ ݊ − ݇ , ݇ > 0
Ans:
ܺ ‫ݖ‬ = ෍ ߜ[݊ − ݇]‫ݖ‬ି௡
ஶ
௡ୀିஶ
= (1)‫ݖ‬ି௞
ROC all z-plane except ‫ݖ‬ = 0
Note: If ‫ݔ‬ ݊ of finite duration, then
ROC is entire z-plane except possibly
‫ݖ‬ = 0 or ‫ݖ‬ = ∞

z transform

Signals and systems-5

Recommended

Recommended

More Related Content

What's hot

What's hot (20)

Similar to Signals and systems-5

Similar to Signals and systems-5 (20)

Recently uploaded

Recently uploaded (20)

Signals and systems-5