Chapter 3: AC Sources and AC Characteristic
JeremyLauKarHei
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Dec 29, 2021
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About This Presentation
AC Sources and AC Characteristic
Slide Content
BEKG 1123
PRINCIPLES OF ELECTRIC &
ELECTRONICS
PRINCIPLES OF ELECTRIC &
ELECTRONICS
2
CHAPTER 3:
AC Sources
and
AC Characteristic
CHAPTER 3:
AC Sources
and
AC Characteristic
AC Source
Learning Outcome
•In this part, we will cover on:
4.1 Waveform type
4.2 AC characteristic
3
Learning Outcome
•In this part, we will cover on:
4.1 Waveform type
4.2 AC characteristic
3
4
•AC is an electrical current whose magnitude and
direction vary sinusoidallywith time.
•Such as current reverses at regular time intervals
and has alternately positive and negative values.
INTRODUCTION
•AC is an electrical current whose magnitude and
direction vary sinusoidallywith time.
•Such as current reverses at regular time intervals
and has alternately positive and negative values.
INTRODUCTION
5
•The circuits analysis is considering the time-
varying voltage source or current source.
•Circuits driven by sinusoidal current or voltage
sources are called ac circuits.
•A sinusoid can be express in either sineor
cosineform.
INTRODUCTION..cont
•The circuits analysis is considering the time-
varying voltage source or current source.
•Circuits driven by sinusoidal current or voltage
sources are called ac circuits.
•A sinusoid can be express in either sineor
cosineform.
INTRODUCTION..cont
Difference between DC and AC
DC AC
6
V
5V
1kHz
R
I
V/I
t
V
5V
I
R
V/I
t
DC AC
6
V
5V
1kHz
R
I
V/I
t
V
5V
I
R
V/I
t
AC Characteristics
7
•AC signals are generated by:
–AC generator
–Electronic function generator
•Types of AC waveforms:
–Sine wave
–Square wave
–Triangle wave
–Saw-tooth wave
7
•AC signals are generated by:
–AC generator
–Electronic function generator
•Types of AC waveforms:
–Sine wave
–Square wave
–Triangle wave
–Saw-tooth wave
Characteristics of sine wave
8
•The sinusoidal waveform (sine wave) is the fundamental of
AC current and AC voltage waveform.
8
•The sinusoidal waveform (sine wave) is the fundamental of
AC current and AC voltage waveform.
Characteristics of sine wave
9
•Sine waves are characterized by the amplitude and period
of waveform.
•Amplitude:
–Is the maximum value of voltage or current.
•Period:
–Is time interval for 1 complete cycle.0 V
10 V
-10 V
15 V
-15 V
-20 V
t ( s)
0 25 37.5 50.0
20 V
The amplitude (A) of
this sine wave is
20 V
The period is 50.0 s
A
T
9
•Sine waves are characterized by the amplitude and period
of waveform.
•Amplitude:
–Is the maximum value of voltage or current.
•Period:
–Is time interval for 1 complete cycle.0 V
10 V
-10 V
15 V
-15 V
-20 V
t ( s)
0 25 37.5 50.0
20 V
The amplitude (A) of
this sine wave is
20 V
The period is 50.0 s
A
T
Characteristics of sine wave
10
•The period of a sine wave can be measured between any two
corresponding points on the waveform.
TTTT
T T
A
By contrast, the amplitude of a sine wave is only measured from the
center to the maximum point.
10
•The period of a sine wave can be measured between any two
corresponding points on the waveform.
TTTT
T T
A
By contrast, the amplitude of a sine wave is only measured from the
center to the maximum point.
Characteristics of sine wave
11
•Frequency:
–Frequency ( f ) is the number of cycles that a sine wave completes in
one second.
–Frequency is measured in hertz(Hz).
•Example:
3.0 Hz
If 3 cycles of a wave occur in one second, the frequency is
1.0 s
11
•Frequency:
–Frequency ( f ) is the number of cycles that a sine wave completes in
one second.
–Frequency is measured in hertz(Hz).
•Example:
3.0 Hz
If 3 cycles of a wave occur in one second, the frequency is
1.0 s
Characteristics of sine wave
12
•Relationship between period and frequency
–The period and frequency are reciprocals of each other.
–Frequency = 1/ time for 1 complete cycle
•Examples:
–If the period is 50 s, what is the frequency?
–If frequency is 60Hz, what is the period?
andf
T
1
T
f
1
12
•Relationship between period and frequency
–The period and frequency are reciprocals of each other.
–Frequency = 1/ time for 1 complete cycle
•Examples:
–If the period is 50 s, what is the frequency?
–If frequency is 60Hz, what is the period?
andf
T
1
T
f
1
13
Waveform Terms &
Definitions
Definitions:
Period–the time taken to complete a cycle, T(s)
Peak value–the maximum instantaneous value measured from its zero value, V
p@
V
m(V)
Peak-to-peak value–the maximum variation between the maximum positive
instantaneous value and the maximum negative value, V
p-p(V)
Instantaneous voltage / current -has a value that corresponds to a specific time t.
Every waveform has an infinity number of instantaneous values. Such a waveform
is described as the parameter as a function of time. In the case of a voltage it will
be written as v(t).
Cycle –the portion of a waveform contained in one period of time. For a sine wave,
it is the complete event starting with a rise from zero energy to a maximum
amplitude, its return to zero, the rise to a maximum in the opposite direction, and
then its return to zero.
Waveform Terms &
Definitions
Definitions:
Period–the time taken to complete a cycle, T(s)
Peak value–the maximum instantaneous value measured from its zero value, V
p@
V
m(V)
Peak-to-peak value–the maximum variation between the maximum positive
instantaneous value and the maximum negative value, V
p-p(V)
Instantaneous voltage / current -has a value that corresponds to a specific time t.
Every waveform has an infinity number of instantaneous values. Such a waveform
is described as the parameter as a function of time. In the case of a voltage it will
be written as v(t).
Cycle –the portion of a waveform contained in one period of time. For a sine wave,
it is the complete event starting with a rise from zero energy to a maximum
amplitude, its return to zero, the rise to a maximum in the opposite direction, and
then its return to zero.
14
WAVEFORM TERMS & DEFINITIONS contd.
WAVEFORM TERMS & DEFINITIONS contd.
15
Sinusoids
•Consider the expression of a sinusoidal voltage
where ( ) sin
m
v t V t
= the amplitude of the sinusoid
= the angular frequency in radians/s
= the argument of the sinusoid
m
V
t
Sinusoids
•Consider the expression of a sinusoidal voltage
where ( ) sin
m
v t V t
= the amplitude of the sinusoid
= the angular frequency in radians/s
= the argument of the sinusoid
m
V
t
16
•The sinusoid repeats itself every Tseconds, thus
Tis called the periodof the sinusoid or the time
taken tocomplete one cycle. (s)
SINUSOIDS contd.
•The sinusoid repeats itself every Tseconds, thus
Tis called the periodof the sinusoid or the time
taken tocomplete one cycle. (s)
SINUSOIDS contd.
17
•The number of cycles per second is called
frequency, f. (Hz)
•Angular frequency, ω. (rad/s)
•An important value of the sinusoidal function is
its RMS (root-mean-square) value.
SINUSOIDS contd.1
f
T
2f
2
m
RMS dc
V
VV
•The number of cycles per second is called
frequency, f. (Hz)
•Angular frequency, ω. (rad/s)
•An important value of the sinusoidal function is
its RMS (root-mean-square) value.
SINUSOIDS contd.1
f
T
2f
2
m
RMS dc
V
VV
18
•Note: Radian measure
–ωis usually expressed in radian/s
–2radians = 360
–to convert from degrees to radians, multiply by /180.
–to convert from radians to degrees, multiply by 180/.
•From the general expression of the sinusoidal
voltage, we can find the value of voltage at any
given instant of time.
SINUSOIDS contd.
•Note: Radian measure
–ωis usually expressed in radian/s
–2radians = 360
–to convert from degrees to radians, multiply by /180.
–to convert from radians to degrees, multiply by 180/.
•From the general expression of the sinusoidal
voltage, we can find the value of voltage at any
given instant of time.
SINUSOIDS contd.
19
•If the waveform does not pass through zero at
t=0, it has a phase shift.
•For a waveform shifted left,
•For waveform shifted right,
where ( ) sin
m
v t V t = phase angle of the sinusoid function
SINUSOIDS contd. ( ) sin
m
v t V t
•If the waveform does not pass through zero at
t=0, it has a phase shift.
•For a waveform shifted left,
•For waveform shifted right,
where ( ) sin
m
v t V t = phase angle of the sinusoid function
SINUSOIDS contd. ( ) sin
m
v t V t
20
SINUSOIDS contd.
SINUSOIDS contd.
21
Example:
1.Find the amplitude, phase, period and
frequency of the sinusoid
Solution:
Amplitude, V
m = 12V
Phase, = 10˚
Angular frequency, ω = 50rad/s
thus the period, T=
The frequency, f=
SINUSOIDS contd. 22
50
0.1257s
7.958
1
z
T
H ( ) 12sin 50 10v t t
Example:
1.Find the amplitude, phase, period and
frequency of the sinusoid
Solution:
Amplitude, V
m = 12V
Phase, = 10˚
Angular frequency, ω = 50rad/s
thus the period, T=
The frequency, f=
SINUSOIDS contd. 22
50
0.1257s
7.958
1
z
T
H ( ) 12sin 50 10v t t
22
2.A sinusoidal voltage is given by the expression
V = 300 cos (120t + 30).
a)What is the frequency in Hz?
b)What is the period of the voltage in miliseconds?
c)What is the magnitude of V at t = 2.778ms?
d)What is the RMS value of V?
Solution:
a) Given ω= 120= 2f, thus f = 60Hz
b) T = 1/f = 16.67ms
c) V = V = 300 cos (120x2.778m + 30)
= 300 cos (60+ 30) = 0V
d) Vrms = 300/√2 = 212.13V
SINUSOIDS contd.
2.A sinusoidal voltage is given by the expression
V = 300 cos (120t + 30).
a)What is the frequency in Hz?
b)What is the period of the voltage in miliseconds?
c)What is the magnitude of V at t = 2.778ms?
d)What is the RMS value of V?
Solution:
a) Given ω= 120= 2f, thus f = 60Hz
b) T = 1/f = 16.67ms
c) V = V = 300 cos (120x2.778m + 30)
= 300 cos (60+ 30) = 0V
d) Vrms = 300/√2 = 212.13V
SINUSOIDS contd.
23
•Consider the following:
SINUSOIDS contd.1
( ) sin
m
v t V t
2
( ) sin
m
v t V t
•Consider the following:
SINUSOIDS contd.1
( ) sin
m
v t V t
2
( ) sin
m
v t V t
24
•The v
2is occurred first in time.
•Thus it can be said that v
2leads v
1by or v
1
lagsv
2by .
•If ≠ 0 we can say v
1and v
2are out of phase.
•If = 0 we can say v
1and v
2are in phase.
•v
1and v
2 can be compared in this manner
because they operate at the same frequency (do
not need to have the same amplitude).
SINUSOIDS contd.
•The v
2is occurred first in time.
•Thus it can be said that v
2leads v
1by or v
1
lagsv
2by .
•If ≠ 0 we can say v
1and v
2are out of phase.
•If = 0 we can say v
1and v
2are in phase.
•v
1and v
2 can be compared in this manner
because they operate at the same frequency (do
not need to have the same amplitude).
SINUSOIDS contd.
25
•Transformation between cosine and sine form
Converting from negative to positive magnitude
where
SINUSOIDS contd.sin cos( 90 )
cos sin( 90 )
AA
AA
sin sin( 180 )
cos cos( 180 )
AA
AA
At
•Transformation between cosine and sine form
Converting from negative to positive magnitude
where
SINUSOIDS contd.sin cos( 90 )
cos sin( 90 )
AA
AA
sin sin( 180 )
cos cos( 180 )
AA
AA
At
26
Example:
1.For the following sinusoidal voltage, find the
value vat t = 0s and t = 0.5s.
v = 6 cos (100t + 60˚)
Solution:
Note: both ωt and must be in same unit before adding them up.
SINUSOIDS contd.
at t = 0.5s
v = 6 cos (50 rad +60˚)
= 4.26V
at t = 0s
v = 6 cos (0+60˚)
= 3V
Example:
1.For the following sinusoidal voltage, find the
value vat t = 0s and t = 0.5s.
v = 6 cos (100t + 60˚)
Solution:
Note: both ωt and must be in same unit before adding them up.
SINUSOIDS contd.
at t = 0.5s
v = 6 cos (50 rad +60˚)
= 4.26V
at t = 0s
v = 6 cos (0+60˚)
= 3V
27
2.Calculate the phase angle between
v1 = -10 cos (ωt + 50)
v2 = 12 sin (ωt -10)
State which sinusoid is leading.
Solution:
In order to compare v1 and v2, we must express them in
the same form (either in cosine or sine function) with
positive magnitude.Note: the value of must be
between 0to 180
v1 = -10 cos (ωt + 50) = 10 cos (ωt + 50-180)
= 10 cos (ωt -130)
SINUSOIDS contd.
2.Calculate the phase angle between
v1 = -10 cos (ωt + 50)
v2 = 12 sin (ωt -10)
State which sinusoid is leading.
Solution:
In order to compare v1 and v2, we must express them in
the same form (either in cosine or sine function) with
positive magnitude.Note: the value of must be
between 0to 180
v1 = -10 cos (ωt + 50) = 10 cos (ωt + 50-180)
= 10 cos (ωt -130)
SINUSOIDS contd.
28
and
v2 = 12 sin (ωt -10) =12 cos (ωt -10-90)
= 12 cos (ωt -100)
the equation v2 can be written in the following form
v2 = 12 cos (ωt -130+ 30)
‘+30’ in the above expression means v2 leads v1 by 30
SINUSOIDS contd.
and
v2 = 12 sin (ωt -10) =12 cos (ωt -10-90)
= 12 cos (ωt -100)
the equation v2 can be written in the following form
v2 = 12 cos (ωt -130+ 30)
‘+30’ in the above expression means v2 leads v1 by 30
SINUSOIDS contd.
AC Charateristic
Learning Outcomes
At the end of this part, students should be able to;
1.identify a sinusoidal waveform and measure
its characteristics.
2.apply phasorto analyze alternating signals.
3.use a phasorto represent a sine wave.
Learning Outcomes
At the end of this part, students should be able to;
1.identify a sinusoidal waveform and measure
its characteristics.
2.apply phasorto analyze alternating signals.
3.use a phasorto represent a sine wave.
Introduction
A sinusoidis a signal that has the form of the sine or cosine
function.
A sinusoidal currentis usually referred to as alternating
current (ac).
Such a current reverses at regular time intervals and has
alternately positive and negative values.
AC circuits are the circuits driven by sinusoidal current or
voltage sources.
A sinusoidis a signal that has the form of the sine or cosine
function.
A sinusoidal currentis usually referred to as alternating
current (ac).
Such a current reverses at regular time intervals and has
alternately positive and negative values.
AC circuits are the circuits driven by sinusoidal current or
voltage sources.
Introduction
Introduction
Average Value
Understanding the
average value using a
sand analogy:
The average height of the
sand is that height obtained if
the distance form one end to
the other is maintained while
the sand is leveled off.
Understanding the
average value using a
sand analogy:
The average height of the
sand is that height obtained if
the distance form one end to
the other is maintained while
the sand is leveled off.
Average Value (cont)
The algebraic sum of the areas must be determined, since some area
contributions will be from below the horizontal axis.
Area above the axis is assigned a positive sign and area below the axis is
assigned a negative sign.
The average value of any current or voltage is the value indicated on a
dc meter –over a complete cycle the average value is the equivalent dc
value.
The algebraic sum of the areas must be determined, since some area
contributions will be from below the horizontal axis.
Area above the axis is assigned a positive sign and area below the axis is
assigned a negative sign.
The average value of any current or voltage is the value indicated on a
dc meter –over a complete cycle the average value is the equivalent dc
value.
Effective (RMS) Value
Effective value arises from the need to measure the effectiveness of
the voltage or current source in delivering the power to resistive load.
Definition:Effective value of periodic current is the dc current that
delivers the same average power to a resistor as the periodic current.
Effective value is given by ,
This indicates that effective value is the square root of the
average of the square of the periodic signal. dtv
T
V
T
eff
0
21 dti
T
I
T
eff
0
21
Effective value arises from the need to measure the effectiveness of
the voltage or current source in delivering the power to resistive load.
Definition:Effective value of periodic current is the dc current that
delivers the same average power to a resistor as the periodic current.
Effective value is given by ,
This indicates that effective value is the square root of the
average of the square of the periodic signal. dtv
T
V
T
eff
0
21 dti
T
I
T
eff
0
21
Effective (RMS) Value (cont)
For the sinusoid the effective or rms
value is
Similarly for
T
m
T
mrms
dtt
T
I
tdtI
T
I
0
2
0
22
)2cos1(
2
1
cos
1
2
m
rms
I
I ,cos)( tVtv
m 2
m
rms
V
V ,cos)( tIti
m
For the sinusoid the effective or rms
value is
Similarly for
T
m
T
mrms
dtt
T
I
tdtI
T
I
0
2
0
22
)2cos1(
2
1
cos
1
2
m
rms
I
I ,cos)( tVtv
m 2
m
rms
V
V ,cos)( tIti
m
Phasors
Sinusoids are easily expressed in terms of phasors.
A phasoris a complex number that represents the amplitude
and phaseof the sinusoid.
Complex number can be written in one of the following three
forms:
a.Rectangular form:
b.Polar form:
c.Exponential form:jyxz rz j
rez
Sinusoids are easily expressed in terms of phasors.
A phasoris a complex number that represents the amplitude
and phaseof the sinusoid.
Complex number can be written in one of the following three
forms:
a.Rectangular form:
b.Polar form:
c.Exponential form:jyxz rz j
rez
where:
j=
x =real part of z
y = imaginary part of z
r= the magnitude of z
ϕ= the phase of z1
j=
x =real part of z
y = imaginary part of z
r= the magnitude of z
ϕ= the phase of z1
Relationship between Rectangular and
Polar Form2 2 1
; tan
y
r x y
x
cos ; sinx r y r cos sinz x jy r r j r
or
Thus, z may be written as,
Note: addition and subtractionof complex number better perform in rectangularform.
Multiplication and divisionin polar form.
Polar Form2 2 1
; tan
y
r x y
x
cos ; sinx r y r cos sinz x jy r r j r
or
Thus, z may be written as,
Note: addition and subtractionof complex number better perform in rectangularform.
Multiplication and divisionin polar form.
Basic Properties of Complex Numbers
Addition :
Subtraction :
Multiplication :
Division :212121
rrzz 21
2
1
2
1
r
r
z
z
212121
yyjxxzz
212121
yyjxxzz
Addition :
Subtraction :
Multiplication :
Division :212121
rrzz 21
2
1
2
1
r
r
z
z
212121
yyjxxzz
212121
yyjxxzz
Reciprocal :
Square Root :
Complex Conjugate :
note:
In general,
rz
11 2/rz
j
rerjyxz
j
j
1
sinjcose
j
Square Root :
Complex Conjugate :
note:
In general,
rz
11 2/rz
j
rerjyxz
j
j
1
sinjcose
j
As we know, the sinusoidal voltage can be represented in sine
or cosine function.
First, consider the cosine function as in:
This expression is in time domain.
In phasor method, we no longer consider in time domain instead
in phasor domain (also known as frequency domain). ( ) cos
m
v t V t
or cosine function.
First, consider the cosine function as in:
This expression is in time domain.
In phasor method, we no longer consider in time domain instead
in phasor domain (also known as frequency domain). ( ) cos
m
v t V t
The cosine function will be represented in phasor and complex
number such as:
For example:
Transform the sinusoid:
v(t) = 12 cos (377t -60˚)
thus,
( ) cos
cos sin
m
m
mm
v t V t
V
V j V
39.1066012 jv or
number such as:
For example:
Transform the sinusoid:
v(t) = 12 cos (377t -60˚)
thus,
( ) cos
cos sin
m
m
mm
v t V t
V
V j V
39.1066012 jv or
The phasor representation carries only the amplitudeand phase
angle information.
The frequency term is dropped since we know that the
frequency of the sinusoidal response is the same as the source.
The cosine expression is also dropped since we know that the
response and source are both sinusoidal.
angle information.
The frequency term is dropped since we know that the
frequency of the sinusoidal response is the same as the source.
The cosine expression is also dropped since we know that the
response and source are both sinusoidal.
Sinusoid-phasor Transformation
Time-domain representation Phasor-domain Representation
cos
sin 90
cos I
sin I 90
mm
mm
mm
mm
V t V
V t V
It
It
* to get the phasor representation of a sinusoid, we express it in cosineform.
Time-domain representation Phasor-domain Representation
cos
sin 90
cos I
sin I 90
mm
mm
mm
mm
V t V
V t V
It
It
* to get the phasor representation of a sinusoid, we express it in cosineform.
and
Thus, the phasor diagram is:
mVV θII
m-∠=
Thus, the phasor diagram is:
mVV θII
m-∠=
Differentiation and Integration
Time Domain Phasor Domain dt
dv Vj
vdt j
V
Time Domain Phasor Domain dt
dv Vj
vdt j
V
Example 1
Evaluate the following complex numbers:oo
o
jjb
jja
3010)]43/()403510.[(
*]605)41)(25.[(
Evaluate the following complex numbers:oo
o
jjb
jja
3010)]43/()403510.[(
*]605)41)(25.[(
Example 1:Solution
6713515
6713515
334521813
606051813
6054125
.j.
.j.
.j.j
sinjcosj
jj
*
*
*
*
o
(a) Using polar-rectangular transformation, addition and subtraction,
(b)Using calculator,2.2293.8 j
6713515
6713515
334521813
606051813
6054125
.j.
.j.
.j.j
sinjcosj
jj
*
*
*
*
o
(a) Using polar-rectangular transformation, addition and subtraction,
(b)Using calculator,2.2293.8 j
Example 2
Transform these sinusoids to phasors: Vtvb
Atia
5030sin4)(
)4050cos(6)(
Transform these sinusoids to phasors: Vtvb
Atia
5030sin4)(
)4050cos(6)(
Example 2: Solution
Refer to sinusoids to phasors transformation table:
a)
b) Since
soA406I
V140t30cos4
9050t30cos450t30sin4v
90AcosAsin
V1404V
Refer to sinusoids to phasors transformation table:
a)
b) Since
soA406I
V140t30cos4
9050t30cos450t30sin4v
90AcosAsin
V1404V
Example 3
Given y
1= 20 cos (100t -30)and y
2= 40 cos (100t + 60).Express
y
1+ y
2as a single cosine function.
Solution:
In phasor form
Thus, y
1+ y
2= 44.72 cos (100t + 33.4)
4.3372.44
64.2432.37
64.34201032.17
60403020
6040&3020
21
21
j
jj
yy
yy
Given y
1= 20 cos (100t -30)and y
2= 40 cos (100t + 60).Express
y
1+ y
2as a single cosine function.
Solution:
In phasor form
Thus, y
1+ y
2= 44.72 cos (100t + 33.4)
4.3372.44
64.2432.37
64.34201032.17
60403020
6040&3020
21
21
j
jj
yy
yy
Circuit Elements in Phasor Domain
Circuit analysis is much simpler if it is done in phasor domain.
In order to perform the phasor domain analysis, we need to
transform all circuit elements to its phasor equivalent.
Transform the voltage-current relationship from time domain to
the frequency domain for each element.
Circuit analysis is much simpler if it is done in phasor domain.
In order to perform the phasor domain analysis, we need to
transform all circuit elements to its phasor equivalent.
Transform the voltage-current relationship from time domain to
the frequency domain for each element.
Phasor Relationships for Resistor
If current through resistor is:
The voltage across Ris V=IR(Ohm’s Law); in phasor form:
But; phasor representation of the current is:
Hence: V=RI
m
m
II
tIi )cos(
mRIV
m
I
I=
Phasor domain
Ohm’s Law in phasor form
If current through resistor is:
The voltage across Ris V=IR(Ohm’s Law); in phasor form:
But; phasor representation of the current is:
Hence: V=RI
m
m
II
tIi )cos(
mRIV
m
I
I=
Phasor domain
Ohm’s Law in phasor form
Time domain Phasor domain
Phasor Relationships for Inductor
If current through inductor is:
The voltage across the inductor:
Which transforms to the phasor
But
Hence
m
I
I=)tcos(LI)tsin(LI
dt
di
Lv
mm
90 90
mLIV )cos( tIi
m LIjLIjV
m
If current through inductor is:
The voltage across the inductor:
Which transforms to the phasor
But
Hence
m
I
I=)tcos(LI)tsin(LI
dt
di
Lv
mm
90 90
mLIV )cos( tIi
m LIjLIjV
m
Time domain Phasor domain
The current and voltage are 90
o
out of
phase (voltage leads current by 90
o
)
The current and voltage are 90
o
out of
phase (voltage leads current by 90
o
)
Phasor Relationships for Capacitor
Given voltage through capacitor is:
The current through capacitor is:
But
Thus: where
And )cos( tVv
m dt
dv
Ci )90cos()sin( tCVtCVi
mm 90
mCVI 901j CVjCVjI
m
m
V )/(CjIV
Given voltage through capacitor is:
The current through capacitor is:
But
Thus: where
And )cos( tVv
m dt
dv
Ci )90cos()sin( tCVtCVi
mm 90
mCVI 901j CVjCVjI
m
m
V )/(CjIV
Time domain Phasor domain
Voltage –Current Relationships
Element Time domain
Frequency domain
R
L
CRiv dt
di
Lv dt
dv
Ci RIV LIjV Cj
I
V
Element Time domain
Frequency domain
R
L
CRiv dt
di
Lv dt
dv
Ci RIV LIjV Cj
I
V
Example 4
a)If voltage v= 10 cos(100t + 30⁰) is applied to a 50μFcapacitor,
calculate the current through the capacitor.
b)What is the voltage across a 2μFcapacitor when the current
through it is i= 4 sin (10
6
t + 25⁰) A?
Ans:
a) 50 cos (100t + 120⁰) mA
b) 2 sin (10
6
t -65⁰) V
a)If voltage v= 10 cos(100t + 30⁰) is applied to a 50μFcapacitor,
calculate the current through the capacitor.
b)What is the voltage across a 2μFcapacitor when the current
through it is i= 4 sin (10
6
t + 25⁰) A?
Ans:
a) 50 cos (100t + 120⁰) mA
b) 2 sin (10
6
t -65⁰) V
Impedance
Previously:
In terms of the ratio of the phasor voltage to the phasor current:
Ohm’s Law in phasor form for any type of elementCj
I
V,LIjV,RIV
CjI
V
Lj
I
V
R
I
V
1
,, ZIV or,
I
V
Z
Previously:
In terms of the ratio of the phasor voltage to the phasor current:
Ohm’s Law in phasor form for any type of elementCj
I
V,LIjV,RIV
CjI
V
Lj
I
V
R
I
V
1
,, ZIV or,
I
V
Z
Impedances and Admittances of Passive
Elements
Element Impedance
Admittance
R
L
CRZ LjZ Cj
1
Z
R
1
Y Lj
1
Y
CjY
Elements
Element Impedance
Admittance
R
L
CRZ LjZ Cj
1
Z
R
1
Y Lj
1
Y
CjY
Equivalent circuits at dc and high
frequencies
frequencies
Impedance in Rectangular Form
The impedance may be expressed in rectangular form as
where R= Re Zis the resistanceand X= Im Zis the reactance.
The impedance is inductive when Xis positive or capacitive
when Xis negative.
The impedance may be also be expressed in polar form asjXRZ ZZ
The impedance may be expressed in rectangular form as
where R= Re Zis the resistanceand X= Im Zis the reactance.
The impedance is inductive when Xis positive or capacitive
when Xis negative.
The impedance may be also be expressed in polar form asjXRZ ZZ
where
and ZjXRZ R
X
tan,XRZ
122
sinZX,cosZR
and ZjXRZ R
X
tan,XRZ
122
sinZX,cosZR
Impedance Combinations
Consider the Nseries-connected
impedances shown in figure.
The same current Iflows through
the impedances.
Applying KVL around the loop gives
The equivalent impedance at the input terminals is
or)Z...ZZ(IV...VVV
N21N21 +++=+++= N21eq
Z...ZZ
I
V
Z +++== N21eq Z...ZZZ +++=
Consider the Nseries-connected
impedances shown in figure.
The same current Iflows through
the impedances.
Applying KVL around the loop gives
The equivalent impedance at the input terminals is
or)Z...ZZ(IV...VVV
N21N21 +++=+++= N21eq
Z...ZZ
I
V
Z +++== N21eq Z...ZZZ +++=
Voltage Divider of Series Circuit
If N= 2, the current through the
impedances is
Since V
1= Z
1Iand V
2= Z
2I,
then:21ZZ
V
I
+
= V
ZZ
Z
V,V
ZZ
Z
V
21
2
2
21
1
1
+
=
+
=
If N= 2, the current through the
impedances is
Since V
1= Z
1Iand V
2= Z
2I,
then:21ZZ
V
I
+
= V
ZZ
Z
V,V
ZZ
Z
V
21
2
2
21
1
1
+
=
+
=
Parallel Circuit
We can obtain the equivalent impedance or admittance of the N
parallel-connected impedances shown in figure.
The cross voltage each impedance is the same.
We can obtain the equivalent impedance or admittance of the N
parallel-connected impedances shown in figure.
The cross voltage each impedance is the same.
Parallel Circuit
Applying KCL at the top node
The equivalent impedance is
And the equivalent admittance isN21eq
Z
1
...
Z
1
Z
1
V
1
Z
1
N21eq Y....YYY )
Z
1
...
Z
1
Z
1
(VI...III
N21
N21
Applying KCL at the top node
The equivalent impedance is
And the equivalent admittance isN21eq
Z
1
...
Z
1
Z
1
V
1
Z
1
N21eq Y....YYY )
Z
1
...
Z
1
Z
1
(VI...III
N21
N21
Current Divider of Parallel Circuit
Eg: When N= 2, as shown in Figure
5.19, the equivalent impedance
becomes
since V = IZ
eq=I
1Z
1=I
2Z
2
the currents
in the impedances are 21
21
2121eq
eq
ZZ
ZZ
Z/1Z/1
1
YY
1
Y
1
Z
I
ZZ
Z
I,I
ZZ
Z
I
21
1
2
21
2
1
Eg: When N= 2, as shown in Figure
5.19, the equivalent impedance
becomes
since V = IZ
eq=I
1Z
1=I
2Z
2
the currents
in the impedances are 21
21
2121eq
eq
ZZ
ZZ
Z/1Z/1
1
YY
1
Y
1
Z
I
ZZ
Z
I,I
ZZ
Z
I
21
1
2
21
2
1
Example 5
Find the input impedance of the circuit in figure below. Assume that
the circuit operates at =50rad/s.
Find the input impedance of the circuit in figure below. Assume that
the circuit operates at =50rad/s.
Example 6
Find Z
eq
in the circuit.
Ans: Z
eq= 1 + j0.5 Ω
Find Z
eq
in the circuit.
Ans: Z
eq= 1 + j0.5 Ω
Example 7
Find v(t)and i(t)in the circuit of Figure below.5 0.1F
+
v
-
Vs = 10 cos 4t
i
Find v(t)and i(t)in the circuit of Figure below.5 0.1F
+
v
-
Vs = 10 cos 4t
i
Example 7: Solution
v
s=10 cos 4t → V
s=
The impedance is
Hence the current V010
5.2j5
1.04j
1
5
Cj
1
5Z
A57.26789.18.0j6.1
5.2j5
010
Z
V
I
s
v
s=10 cos 4t → V
s=
The impedance is
Hence the current V010
5.2j5
1.04j
1
5
Cj
1
5Z
A57.26789.18.0j6.1
5.2j5
010
Z
V
I
s
Example 7: Solution cont
Hence the voltage across the capacitor
Converting I and V to the time domain,V
jCj
I
IZV
C
43.6347.4
1.04
57.26789.1
V43.63t4cos47.4tv
A57.26t4cos789.1ti
Hence the voltage across the capacitor
Converting I and V to the time domain,V
jCj
I
IZV
C
43.6347.4
1.04
57.26789.1
V43.63t4cos47.4tv
A57.26t4cos789.1ti
Example 8
Determine v(t)and i(t).+
v
-
+
-
4Ω
i
0.2H
v
s= 20 sin (10t+ 30⁰) V
Ans: i(t) = 4.472 cos (4t+3.43⁰) A
v(t) = 8.944 cos (4t+93.43⁰) V
Determine v(t)and i(t).+
v
-
+
-
4Ω
i
0.2H
v
s= 20 sin (10t+ 30⁰) V
Ans: i(t) = 4.472 cos (4t+3.43⁰) A
v(t) = 8.944 cos (4t+93.43⁰) V
Chapter Summary
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